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The Staphylococcus aureus two component system (TCS) sae governs expression of numerous virulence factors, including Eap (extracellular adherence protein), which in turn among other functions also mediates invasion of host cells. The sae TCS is encoded by the saePQRS operon, with saeS coding for the sensor histidine kinase (SaeS) and saeR encoding the response regulator (SaeR). The saeRS system is preceded by two additional open reading frames (ORFs), saeP and saeQ, which are predicted to encode a lipoprotein (SaeP) and a membrane protein (SaeQ), respectively. Earlier, we have shown that SDS-containing subinhibitory concentrations of biocides (Perform®) and SDS alone activate sae transcription and increase cellular invasiveness in S. aureus strain Newman. The effect is associated with an amino acid exchange in the N-terminus of SaeS (L18P), specific to strain Newman.
In this work, the role of whether the two additional genes, saePQ coding for the accessory proteins SaeP and SaeQ, respectively, are involved in SDS-mediated saeRS was investigated. It could demonstrated that the lack of the SaeP protein resulted in an increased saeRS transcription without SDS stress in both SaeSL/P variants, while the SDS effect was less pronounced on sae and eap expression compared to the Newman wildtype, suggesting that the SaeP protein represses the sae system. Also, SDS-mediated inductions of sae and eap transcription along with enhanced invasion were found to be dependent on presence of the SaeSP variant in Newman wildtype. On the other hand, the study also shows that the saePQ region of the sae operon is required for fully functional two-component system saeRS under normal growth conditions, but it is not involved in SDS-mediated activation of the saeS signaling and sae-target class I gene, eap.
In the second approach, the study investigates whether SDS-induced sae expression and host cell invasion is common among S. aureus strains not carrying the (L18P) point mutation. To demonstrate this strain Newman, its isogenic saeS mutants, and various S. aureus isolates were analysed for sae, eap expression and cellular invasiveness. Among the strains tested, SDS exposure resulted only in an increase of sae transcription, Eap production and cellular invasiveness in strain Newman wild type and MRSA strain ST239-635/93R, the latter without an increase in Eap. Interestingly, the epidemic community-associated MRSA strain, USA300 LAC showed a biphasic response in sae transcription at different growth stages, which, however, was not accompanied by increased invasiveness. All other clinical isolates investigated displayed a decrease of the parameters tested. While in strain Newman the SDS effect was due to the saeSP allele, this was not the case in strain ST239-635/93R and the biphasic USA300 strains. Also, increased invasiveness of ST239-635/93R was found to be independent of Eap production. Furthermore, to investigate the global effect of SDS on sae target gene expression, strain Newman wild-type and Newman ∆sae were treated with SDS and analyzed for their transcription profiles of sae target genes using microarray assays. We could show that subinhibitory concentrations of SDS upregulate and downregulate gene expression of several signaling pathways involved in biosynthetic, metabolic pathways as well as virulence, host cell adherence, stress reponse and many hypothetical proteins.
In summary, the study sheds light on the role of the upstream region saePQ in SDS-mediated saeRS and eap expression during S. aureus SDS stress. Most importantly, the study also shows that subinhibitory SDS concentrations have pronounced strain-dependent effects on sae transcription and subsequent host cell invasion in S. aureus, with the latter likely to be mediated in some strains by other factors than the known invasin Eap and FnBP proteins. Moreover, there seems to exist more than the saeSP-mediated mechanism for SDS-induced sae transcription in clinical S. aureus isolates. These results help to further understand and clarify virulence and pathogenesis mechanisms and their regulation in S. aureus.
Flatworm parasites (platyhelminths) cause serious infection diseases in humans, such as schistosomiasis and hydatid disease, mainly prevalent in developing countries. However, the current repertoire of drug armamentarium used to combat flatworm infections is limited. For instance, praziquantel is the only drug available for mass treatment of Schistosoma infections. In contrast to their hosts, flatworm parasites possess a distinct redox arrangement of redox pathways in which the selenoenzyme thioredoxin glutathione reductase (TGR) controls the overall redox homeostasis. Interference with this enzyme leads to parasite death. Hence, this key redox enzyme seems to be a new promising drug target against flatworm infections.
Because most flatworms are difficult to cultivate in the laboratory (e.g. Echinococcus granulosus experimental infection in mice takes about 10 month to develop into cysts), this work was focused on Mesocestoides vogae (syn. corti), a non-human flatworm parasite which is an interesting laboratory model to study other flatworm infections: it is very rare in humans, can be easily manipulated both in vivo and in vitro and grows extremely fast in mice. With the aim to assess TGR inhibitors as possible drugs to treat flatworm infections, the thioredoxin and glutathione pathways of M.vogae were studied. Here, the objectives were to study whether the biochemical pathways that maintain the redox homeostasis in M. vogae conform to the general biochemical scenario proposed for other platyhelminth parasites.
Here, it was proven that M. vogae extracts possess both thioredoxin and glutathione reductase activities. The thioredoxin and glutathione reductase activities were partially purified from total extracts by a combination of ammonium sulfate precipitation, anion exchange and hydroxyapatite chromatography. Both activities co-purified in all steps which strongly indicates the existence of TGR rather than a single TR and GR. Furthermore partially purified activities could be inhibited by the organogold compound auranofin, a known TGR inhibitor. Moreover, the glutathione reductase activity displays hysteresis (a peculiar kinetic behavior) at high concentrations of oxidised glutathione, a feature typical of flatworm TGRs, but not of conventional GR. Although M. vogae activities could not be purified to homogeneity, the overall results strongly indicate that this flatworm possesses TGR and lacks conventional GR and TR.
Furthermore the thiadiazole WPQ75 and the N-oxide VL16E (a furoxan derivate) were identified as inhibitors of TGR activity of M.vogae at a 10 µM concentration. These inhibitors were able to kill M.vogae larval worms in vitro as well as in experimental infection in mice.
Due to the existence of TGR activity in M.vogae, the possibility to inhibit this activity with recently discovered inhibitors of flatworm TGR and the successes achieved by testing these inhibitors both in vitro and in vivo, it is strongly evident that M. vogae would be an excellent model to assess TGR inhibitors in flatworm infections.
The consequences of habitat change for human well-being are assumed to be especially extreme in Burkina Faso. The country is located in a highly drought-sensitive zone of West Africa, and small‐scale subsistence farmers may be especially affected if losses of biodiversity lead to changes in ecosystem functioning; many depend on more or less degraded lands for agricultural production.
The overall aim of the present thesis consequently was to characterize the functional traits of soil-organisms which are crucial for a productive and balanced soil environment in the study region – termites and ants. They are true ecosystem engineers whose activity alters the habitat. Through soil-turnover in the course of constructing biogenic structures of varying size and nature (mounds, nests, galleries, soil-sheetings, foraging-holes), they bioturbate huge amounts of soil masses and exert massive effects on soil structure, positively influencing the fertility, stability, aeration and water infiltration rate into soils; and they provide habitats for other species. In sub-Saharan Africa, ants and termites are the only active soil macrofauna during the long dry season; in the sub-Sahel zone of Burkina Faso, termites even represent the only active, quantitatively remarkable decomposers all year round. Since no information was available about the actual diversity of the focal arthropods, I divided the thesis in two main parts: In the first part, a baseline study, I assessed the local termite and ant fauna, and investigated their quantitative and qualitative response to changing habitat parameters resulting from increasing human impact (‘functional response traits’). In the second and applied part, I addressed the impact of the biogenic structures which are important for the restoration of degraded soils (‘functional effect traits’).
Two traditional agricultural systems characteristic for the study region were selected. Each system represented a land-use intensification gradient comprising four distinct habitats now differing in the magnitude of human intervention but formerly having the same initial state. The first disturbance gradient, the temporal cross-section of a traditional soil water conservation technique to restore degraded heavily encrusted, barren soil named Zaï in Ouahigouya (Yatenga province, sub-Sahel zone); the second disturbance gradient, an agriculture type using crop rotation and fallow as nutrient management techniques near Fada N’Gourma (Gourma province, North-Sudanese zone).
No standard protocol existed for the assessment of termite and ant diversity in semi-arid (agro-) ecosystems; two widely accepted standard protocols provided the basis for the newly revised and combined rapid assessment protocol ‘RAP’: the ALL protocol for leaf litter ants of Agosti and Alonso (2000), and the transect protocol for termites in tropical forests of Jones and Eggleton (2000). In each study site, three to four replicate transects were conducted during the rainy seasons (2004—2008).
The RAP-protocol turned out to be very effective to characterize, compare and monitor the taxonomic and functional diversity of termites and ants; between 70% and 90% of the estimated total species richness were collected on all levels (transects, habitats, regions). Together in both regions, 65 ant species (25 genera) and 39 termite species (13 genera) were collected. These findings represent the first records for Burkina Faso. The data indicate a high sensitivity of termites and ants to land-use intensification. The diversity strongly decreased with increasing anthropogenic impact in the North-Sudan region. In total, 53 ant species (23 genera) and 31 termite species (12 genera) were found. Very promising results concerning the recovery potential of the soil-arthropods’ diversity were gathered in the Zaï system. The diversity of both taxa strongly increased with increasing habitat rehabilitation – in total, 41 ant species (16 genera) and 33 termite species (11 genera) were collected. For both taxa significant differences could be noted in the shape of the density variations along the gradient. For instance termites: Fungus-growers showed the greatest adaptability to different management practices. The greatest variations between the habitats were observed in soil and grass-feeding termites. Whole functional groups were missing in heavily impacted habitats, e.g. soil-, grass-, and wood-feeders were absent in the degraded site in the sub-Sahel zone. Several environmental parameters could be identified which significantly explained a great part of the variations in the composition of the arthropods’ communities; they indicate the importance of the habitats’ structural complexity (vegetation structure) and concomitant effects on diurnal temperature and moisture fluctuations, the availability of food sources, and the soil-structure. The diversity of termites in the sub-Sahel region was strongly correlated with the crown-cover percentages, the topsoils’ sand-content, and the availability of litter; in the North-Sudan region with the cumulated woody plant basal area, the topsoils’ clay- and organic matter-content. The parameters identified for ant communities in the Zaï system, were the height of trees, the topsoils’ clay-content and air humidity; in the North-Sudan region the habitats’ crown-cover percentages, the quantity of litter and again the height of trees.
In the second part of the thesis, I first rapidly assessed the (natural) variations in the amount of epigeal soil-structures along the two disturbance gradients in order to judge the relative importance of termites and ants for soil-turnover. The results illustrated impressively that a) in all study sites, termites were the main bioturbators while ant structures were of minor importance for soil turn-over; b) earthworms and grass-feeding termites contributed significantly to soil turn-over in the more humid North-Sudan region; and c) the bioturbated soil mass varied between seasons and years, however, the relative importance of the different taxa seemed to be fairly constant. In the sub-Sahel zone, fungus-growing Odontotermes and Macrotermes species fully take over the important function of bioturbation, leading to the transport of huge amounts of fine-textured soil material to the surface; with increasing habitat restoration, coarse fragments decreased in the upper horizons and became concentrated deeper along the soil profile.
Consequently, in the applied part, I concentrated on the bioturbation activity of fungus-growing termites in the four main stages of the Zaï system: crusted bare soil (initial stage), millet field, young and old forest. In each of the four Zaï sites nine experimental blocks (each comprising four plots of 1m2) were used to stimulate the foraging activity of fungus-growing termites with different, locally available organic materials (Aristida kerstingii hay, Bombax costatum wooden blocks, compost and a control without any organic amendment). The experiment was conducted twice for the duration of four weeks (rainy season 2005, dry season 2006). The plots were regularly checked and the increase of the area covered by sheetings chronologically followed. After four weeks a) all sheeting-soil was collected, air dried and separately weighed according to the different genera, and b) the foraging-holes were counted and their diameter measured. Additionally, c) ponded water infiltration was measured in selected plots, and d) the physicochemical properties of sheeting-soil were analyzed. In case of complete consumption of the offered hay during the experimental 4-weeks-duration, the same procedure (a, b) was followed before adding new hay to the respective plot.
The comparison between the different plots, sites and seasons revealed clearly that hay was the most attractive bait; for each gram of hay removed, Odontotermes brought about 12 g soil to the surface, Macrotermes 4 g. Odontotermes was the only genus attracted by organic material to the degraded area, and was therefore the decisive primary physical ecosystem engineer in the Zaï system, initiating the restoration process. The mass of soil bioturbated in the course of foraging increased strongly from the degraded, barren towards the most rehabilitated reforested site. Combining all 36 experimental plots per Zaï stage, Odontotermes bioturbated 31.8 tons of soil per hectare and month dry season in the degraded area, and 32.4 tons ha-1 mon-1 in the millet fields; both genera moved 138.9 tons ha-1 mon-1 in the young and 215.5 tons ha-1 mon-1 in the old Zaï forest. Few comparable figures were found in the literature. In northern Burkina Faso, both genera constructed 20 tons of sheetings ha-1 mon-1 after mulching with a straw-wood mixture (Mando & Miedema 1997), and in Senegal, around 10 tons ha-1 mon-1 were moved in heavily foraged plots (Rouland et al. 2003). Within a site, soil turn-over and the number of foraging holes created was always highest in hay, followed by compost, then by wood and in the end control. The fungus-growers’ foraging-activity was leading to an enormous increase in surface pore space – after one month of induced foraging activity in hay-plots, the median number of foraging-holes increased from 142 m-2 in the degraded site up to 921 m-2 in the old Zaï forest. The creation of subterranean galleries and macropores significantly increased the water infiltration rate by a mean factor 2–4.
Laboratory analyses revealed that sheeting-soil differed strongly from the respective control soil as well as between the seasons, the food-type covered, and the two genera. Odontotermes-sheetings differed in more parameters than Macrotermes-sheetings, and dry season sheetings differed in more parameters (and more strongly) than rainy season sheetings. In the present study, soil organic matter, carbon and nitrogen contents were significantly increased in all dry season sheetings; in the rainy season mainly in those built on compost. Texture analysis pointed out that both genera used topsoil and soil from deeper horizons in varying mixture ratios, thereby supporting findings of Jouquet et al. (2006).
To summarize, the present thesis contributes to a better understanding of the functional response traits of termites and ants to changing environmental parameters resulting from increasing human impact. The RAP-protocol represents an easy-to-learn and very effective method to representatively characterize, compare and monitor the taxonomic and functional diversity of termites and ants. The experiment has provided conclusive evidence of the importance of the consideration of fungus-growing termites (particularly Odontotermes and Macrotermes species) when aiming to restore infertile, degraded and crusted soils and to maintain a sustainable agricultural production in the Sahel‐Sudanese zone of West Africa.
Molecular and developmental characterization of the Echinococcus multilocularis stem cell system
(2014)
The metacestode larva of Echinococcus multilocularis is the causative agent of alveolar echinococcosis (AE), one of the most dangerous zoonotic diseases in the Northern Hemisphere. Unlike “typical” metacestode larvae from other tapeworms, it grows as a mass of interconnected vesicles which infiltrates the liver of the intermediate host, continuously forming new vesicles in the periphery. From these vesicles, protoscoleces (the infective form for the definitive host) are generated by asexual budding. It is thought that in E. multilocularis, as in other flatworms, undifferentiated stem cells (so-called germinative cells in cestodes and neoblasts in free-living flatworms) are the sole source of new cells for growth and development. Therefore, this cell population should be of central importance for the progression of AE.
In this work, I characterized the germinative cells of E. multilocularis, and demonstrate that they are indeed the only proliferating cells in metacestode vesicles. The germinative cells are a population of undifferentiated cells with similar morphology, and express high levels of transcripts of a novel non-autonomous retrotransposon family (ta-TRIMs). Experiments of recovery after hydroxyurea treatment suggest that individual germinative cells have extensive self-renewal capabilities. However, germinative cells also display heterogeneity at the molecular level, since only some of them express conserved homologs of fgfr, nanos and argonaute genes, suggesting the existence of several distinct sub-populations. Unlike free-living flatworms, cestode germinative cells lack chromatoid bodies. Furthermore, piwi and vasa orthologs are absent from the genomes of cestodes, and there is widespread expression of some conserved neoblast markers in E. multilocularis metacestode vesicles. All of these results suggest important differences between the stem cell systems of free-living flatworms and cestodes.
Furthermore, I describe molecular markers for differentiated cell types, including the nervous system, which allow for the tracing of germinative cell differentiation. Using these molecular markers, a previously undescribed nerve net was discovered in metacestode vesicles. Because the metacestode vesicles are non-motile, and the nerve net of the vesicle is independent of the nervous system of the protoscolex, we propose that it could serve as a neuroendocrine system. By means of bioinformatic analyses, 22 neuropeptide genes were discovered in the E. multilocularis genome. Many of these genes are expressed in metacestode vesicles, as well as in primary cell preparations undergoing complete metacestode regeneration. This suggests a possible role for these genes in metacestode development. In line with this hypothesis, one putative neuropeptide (RGFI-amide) was able to stimulate the proliferation of primary cells at a concentration of 10-7 M, and the corresponding gene was upregulated during metacestode regeneration.
Object six Degrees of Freedom (6DOF) pose estimation is a fundamental problem in many practical robotic applications, where the target or an obstacle with a simple or complex shape can move fast in cluttered environments. In this thesis, a 6DOF pose estimation algorithm is developed based on the fused data from a time-of-flight camera and a color camera. The algorithm is divided into two stages, an annealed particle filter based coarse pose estimation stage and a gradient decent based accurate pose optimization stage. In the first stage, each particle is evaluated with sparse representation. In this stage, the large inter-frame motion of the target can be well handled. In the second stage, the range data based conventional Iterative Closest Point is extended by incorporating the target appearance information and used for calculating the accurate pose by refining the coarse estimate from the first stage. For dealing with significant illumination variations during the tracking, spherical harmonic illumination modeling is investigated and integrated into both stages. The robustness and accuracy of the proposed algorithm are demonstrated through experiments on various objects in both indoor and outdoor environments. Moreover, real-time performance can be achieved with graphics processing unit acceleration.
Recently a new state of matter was discovered in which the bulk insulating state in a material is accompanied by conducting surface or edge states. This new state of matter can be distinguished from a conventional insulator phase by the topological properties of its band structure which led to the name "topological insulators". Experimentally, topological insulator states are mostly found in systems characterized by a band inversion compared to conventional systems. In most topological insulator systems, this is caused by a combination of energetically close bands and spin orbit coupling. Such properties are found in systems with heavy elements like Hg and Bi. And indeed, the first experimental discovery of a topological insulator succeeded in HgTe quantum wells and later also in BiSb bulk systems.
Topological insulators are of large interest due to their unique properties: In 2-dimensional topological insulators one dimensional edge states form without the need of an external magnetic field (in contrast to the quantum Hall effect). These edge states feature a linear band dispersion, a so called Dirac dispersion. The quantum spin Hall states are helical edge states, which means they consist of counterpropagating oppositely spin polarized edge channels. They are therefore of great potential for spintronic applications as well as building blocks for new more exotic states like Majorana Fermions. 3-dimensional topological insulators feature 2-dimensional surface states with only one Dirac band (also called Dirac cone) on each surface and an interesting spin texture where spin and momentum are locked perpendicular to each other in the surface plane. This unique surface band structure is predicted to be able to host several exotic states like e.g. Majorana Fermions (in combination with superconductors) and magnetic monopole like excitations.
This PhD thesis will summarize the discovery of topological insulators and highlights the developments on their experimental observations. The work focuses on HgTe which is up to now the only topological insulator material where the expected properties are unambiguously demonstrated in transport experiments. In HgTe, the topological insulator properties arise from the inversion of the Gamma_6 and Gamma_8 bands. The band inversion in HgTe is due to a combination of a high spin orbit splitting in Te and large energy corrections (due to the mass-velocity term) to the energy levels in Hg. Bulk HgTe, however, is a semimetal, which means for the conversion into a topological insulator a band gap has to be opened. In two dimensions (HgTe quantum well structures) this is achieved via quantum confinement, which opens a band gap between the quantum well subbands. In three dimensions, strain is used to lift the degeneracy of the semimetallic Gamma_8 bands opening up a band gap.
The thesis is structured as follows:
- The first chapter of this thesis will give a brief overview on discoveries in the field of topological insulators. It focuses on works relevant to experimental results presented in the following chapters. This includes a short outline of the early predictions and a summary of important results concerning 2-dimensional topological insulators while the final section discusses observations concerning 3-dimensional topological insulators.
- The discovery of the quantum spin Hall effect in HgTe marked the first experimental observation of a topological insulator. Chapter 2 will focus on HgTe quantum wells and the quantum spin Hall effect.
Above a critical thickness, HgTe quantum wells are predicted to host the quantum spin Hall state, the signature of a 2-dimensional topological insulator. HgTe quantum wells exhibiting low carrier concentrations and at the same time high carrier mobilities are required to be able to measure the quantum spin Hall effect. The growth of such high quality HgTe quantum wells was one of the major goals for this work. Continuous optimization of the substrate preparation and growth conditions resulted in controlled carrier densities down to a few 10^10 cm^-2. At the same time, carrier mobilities exceeding 1 x 10^6 cm^2/Vs have been achieved, which provides mean free paths of several micrometers in the material. Thus the first experimental evidence for the existence of the quantum spin Hall edge states succeeded in transport experiments on microstructures: When the Fermi energy was located in the bulk band gap a residual quantized resistance of 2e^2/h was found. Further experiments focused on investigating the nature of transport in this regime. By non-local measurements the edge state character could be established. The measured non-local resistances corresponded well with predictions from the Landauer-Büttiker theory applied to transport in helical edge channels.
In a final set of experiments the spin polarization of the edge channels was investigated. Here, we could make use of the advantage that HgTe quantum well structures exhibit a large Rashba spin orbit splitting. In systems with a large Rashba spin orbit splitting a spin accumulation is expected to occur at the edge of the sample perpendicular to a current flow. This so-called spin Hall effect was then used as a spin injector and detector. Using split gate devices it was possible to bring spin Hall and quantum spin Hall state into direct contact, which enabled an all electrical detection of the spin polarization of the quantum spin Hall edge channels.
- HgTe as a 3-dimensional topological insulator will be presented in chapter 3. Straining the HgTe layer enables the observation of topological insulator behavior. It was found that strain can be easily implemented during growth by using CdTe substrates. CdTe has a slightly larger lattice constant than HgTe and therefore leads to tensile strain in the HgTe layer as long as the growth is pseudomorphic. Magnetotransport studies showed the emergence of quantum Hall transport with characteristic signatures of a Dirac type bandstructure. Thus, this result marks the first observation of the quantum Hall effect in the surface states of a 3-dimensional topological insulator.
Transport experiments on samples fitted with a top gate enabled the identification of contributions from individual surfaces. Furthermore, the surface state quantum Hall effect was found to be surprisingly stable, perturbations due to additional bulk transport could not be found, even at high carrier densities of the system.
- Chapters 4 - 6 serve as in depth overviews of selected works: Chapter 4 presents a detailed overview on the all electrical detection of the spin Hall effect in HgTe quantum wells. The detection of the spin polarization of the quantum spin Hall effect is shown in chapter 5 and chapter 6 gives a detailed overview on the quantum Hall effect originating from the topological surface state in strained bulk HgTe.
The investigations discussed in this thesis pioneered the experimental work on the transport properties of topological insulator systems. The understanding of the fundamental properties of topological insulators enables new experiments in which e.g. the inclusion of magnetic dopants or the interplay between topological insulator and superconductors can be investigated in detail.
Staphylococcus aureus is a major threat to public health systems all over the globe. This second most cause of nosocomial infections is able to provoke a wide variety of different types of infection in humans and animals, ranging from superficial skin and skin structure infections to invasive disease like sepsis or pneumonia. But not enough, this pathogen is also notorious in acquiring and/or developing resistance to antimicrobial compounds, thus limiting available treatment options severely. Therefore, development of new compounds and strategies to fight S. aureus is of paramount importance. But since only 1 out of 5 compounds, which entered clinical trials, becomes a drug, the preclinical evaluation of promising compounds has to be reconsidered, too. The aim of this thesis was to address both sides of this problem: first, to improve preclinical testing by incorporating in vivo imaging technologies to the preclinical testing procedure in order to acquire additional and clearer data about efficacy of promising compounds and second, by evaluating lysostaphin, which is a promising, new option to fight S. aureus infections.
The first aim of this thesis focused on the establishment of a dual modality in vivo imaging platform, consisting of Bioluminescence Imaging (BLI) and Magnetic Resonance Imaging (MRI), to offer detailed insights into the course and gravity of S. aureus infection in the murine thigh infection model. Since luciferase-expressing S. aureus strains were generated in former studies and enabled thus bioluminescence imaging of bacterial infection, this technology should be implemented into the compound evaluation platform in order to non-invasively track the bacterial burden over time. MRI, in contrast, was only rarely used in earlier studies to visualize and measure the course of infection or efficacy of anti-bacterial therapy. Thus, the first set of experiments was performed to identify benefits and drawbacks of visualizing S. aureus infections in the mouse model by different MR methods. Native, proton-based MR imaging showed in this regard increased T2 relaxation times in the infected thigh muscles, but it was not possible to define a clear border between infected and uninfected tissue. Iron oxide nanoparticles and perfluorocarbon emulsions, two MR contrast agents or tracer, in contrast, offered this distinction. Iron oxide particles were detected in this regard by their distortion of 1H signal in proton-based MRI, while perfluorocarbon emulsion was identified by 19F MRI. Mammals do not harbor sufficient intrinsic amounts of 19F to deliver specific signal and therefore, 19F MR imaging visualizes only the signal of administered perfluorocarbon emulsion. The in vivo accumulation of perfluorocarbon emulsion can be imaged by 19F MRI and overlayed on a simultaneously acquired 1H MR image, which shows the anatomical context in clear detail. Since this is advantageous compared to contrast agent based MR methods like iron oxide particle-based MRI, further experiments were performed with perfluorocarbon emulsions and 19F MRI.
Experimental studies to elucidate the accumulation of perfluorocarbon emulsion at the site of infection showed robust 19F MR signals after administration between day 2 and at least day 8 p.i.. Perfluorocarbon emulsion accumulated in all investigated mice in the shape of a ‘hollow sphere’ at the rim of the abscess area and the signal remained stable as long as the infection prevailed. In order to identify the mechanism of accumulation, flow cytometry, cell sorting and histology studies were performed. Flow cytometry and cell sorting analysis of immune cells at the site of infection showed that neutrophils, monocytes, macrophages and dendritic cells carried contrast media at the site of infection with neutrophils accounting for the overwhelming portion of perfluorocarbon signal. In general, most of the signal was associated with immune cells, thus indicating specific immune cell dependent accumulation. Histology supported this observation since perfluorocarbon emulsion related fluorescence could only be visualized in close proximity to immune cell nuclei.
After establishing and testing of 19F MRI with perfluorocarbon emulsions as infection imaging modality, the effects of antibiotic therapy upon MR signal was investigated in order to evaluate the capability of this modality for preclinical testing procedure. Thus, the efficacy of vancomycin and linezolid, two clinically highly relevant anti - S. aureus compounds, were tested in the murine thigh infection model. Both of them showed reduction of the colony forming units and bioluminescence signal, but also of perfluorocarbon emulsion accumulation strength and volume at the site of infection, which was visualized and quantified by 19F MRI. The efficacy pattern with linezolid being more efficient in clearing bacterial infection was shown similarly by all three methods. In consequence, 19F MRI with perfluorocarbon emulsion as MR tracer proved to be capable to visualize antibacterial therapy in preclinical testing models.
The next step was consequently to evaluate a promising new compound against S. aureus infections. Thus, lysostaphin, an endo-peptidase that cleaves the cell wall of S. aureus, was tested in different concentrations alone or in combination with oxacillin for efficacy in murine thigh and catheter associated infection models. Lysostaphin only in the concentration of 5 mg/kg body weight or combined with oxacillin in the concentration of 2 mg/kg showed strong reduction of bacterial burden by colony forming unit determination and bioluminescence imaging in both models. The perfluorocarbon accumulation was investigated in the thigh infection model by 19F MRI and was strongly reduced in terms of volume and signal strength in both above-mentioned groups. In general, lysostaphin showed comparable or superior efficacy than vancomycin or oxacillin alone. Therefore, further development of lysostaphin for the treatment of S. aureus infections is recommended by these experiments. Overall, the antibiotic efficacy pattern of all applied antibiotic regimens was similar with all three applied methods, demonstrating the usefulness of MRI for antibiotic efficacy testing. Importantly, treatment with oxacillin either alone or in combination with lysostaphin resulted in stronger perfluorocarbon emulsion accumulation at the site of infection than expected compared to the results from bioluminescence imaging and colony forming unit determination. This might be an indication for immunomodulatory properties of oxacillin.
Further murine infection experiments demonstrated in this context a differential release of cytokine and chemokines in the infected thigh muscle in dependence of the applied antibacterial therapy. Especially treatment with oxacillin, but to a less degree with minocycline or linezolid, too, exhibited high levels of various cytokines and chemokines, although they reduced the bacterial burden efficiently. In consequence, possible immunomodulatory effects of antibacterial compounds have to be taken into account for future applications of imaging platforms relying on the visualization of the immune response. However, this observation opens a new field for these imaging modalities since it might be extraordinary interesting to study the immunomodulatory effects of compounds or even bacterial factors in vivo. And finally, a two modality imaging platform which combines methods to visualize on the one hand the bacterial burden and on the other hand the immune response offers an innovative, new platform to study host-pathogen interaction in vivo in a non-invasive fashion.
In summary, it could be shown that perfluorocarbon emulsions accumulate in immune cells at the site of infection in the murine S. aureus thigh infection model. The accumulation pattern shapes a ‘hollow sphere’ at the rim of the abscess area and its size and perfluorocarbon content is dependent on the severity of disease and/or efficacy of antibiotic therapy. Thus, 19F MRI with perfluorocarbon emulsions is a useful imaging modality to visualize sites and course of infection as well as to evaluate promising antibacterial drug candidates. Furthermore, since the accumulation of tracer depends on immune cells, it might be additionally interesting for studies regarding the immune response to infections, auto-immune diseases or cancer, but also to investigate the efficacy of immunomodulatory compounds and immunization.
GAS2L3 was identified recently as a target gene of the DREAM complex (Reichert et al., 2010; Wolter et al., 2012). It was shown that GAS2L3 is expressed in a cell cycle specific manner and that depletion of the protein leads to defects in cytokinesis and genomic instability (Wolter et al., 2012).
Major aim of this thesis was, to further characterize the biochemical properties and physiological function of GAS2L3.
By in vitro co-sedimentation and bundling assays, GAS2L3 was identified as a cytoskeleton associated protein which bundles, binds and crosslinks F-actin and MTs. GST pulldown assays and co-immunoprecipitation experiments revealed that GAS2L3 interacts in vitro and in vivo with the chromosomal passenger complex (CPC), a very important regulator of mitosis and cytokinesis, and that the interaction is mediated by the GAR domain of GAS2L3 and the C-terminal part of Borealin and the N-terminal part of Survivin. Kinase assays showed that GAS2L3 is not a substrate of the CPC but is strongly phosphorylated by CDK1 in vitro. Depletion of GAS2L3 by shRNA influenced protein stability and activity of the CPC. However pharmacological studies showed that the decreased CPC activity is not responsible for the observed cytokinesis defects upon GAS2L3 depletion. Immunofluorescence experiments revealed that GAS2L3 is localized to the constriction zone by the CPC in a GAR dependent manner and that the GAR domain is important for proper protein function.
New interacting proteins of GAS2L3 were identified by stable isotope labelling by amino acids in cell culture (SILAC) in combination with tandem affinity purification and subsequent mass spectrometrical analysis. Co-immunoprecipitation experiments further confirmed the obtained mass spectrometrical data.
To address the physiological function of GAS2L3 in vivo, a conditional and a non-conditional knockout mouse strain was established. The non-conditional mouse strain showed a highly increased mortality rate before weaning age probably due to heart failure. The physiological function of GAS2L3 in vivo as well as the exact reason for the observed heart phenotype is not known at the moment.
This dissertation presents controller design methodologies for a formation of cooperative mobile robots to perform trajectory tracking and convoy protection tasks. Two major problems related to multi-agent formation control are addressed, namely the time-delay and optimality problems. For the task of trajectory tracking, a leader-follower based system structure is adopted for the controller design, where the selection criteria for controller parameters are derived through analyses of characteristic polynomials. The resulting parameters ensure the stability of the system and overcome the steady-state error as well as the oscillation behavior under time-delay effect. In the convoy protection scenario, a decentralized coordination strategy for balanced deployment of mobile robots is first proposed. Based on this coordination scheme, optimal controller parameters are generated in both centralized and decentralized fashion to achieve dynamic convoy protection in a unified framework, where distributed optimization technique is applied in the decentralized strategy. This unified framework takes into account the motion of the target to be protected, and the desired system performance, for instance, minimal energy to spend, equal inter-vehicle distance to keep, etc.
Both trajectory tracking and convoy protection tasks are demonstrated through simulations and real-world hardware experiments based on the robotic equipment at Department of Computer Science VII, University of Würzburg.
In this work, a novel method for estimating the relative pose of a known object is presented, which relies on an application-specific data fusion process. A PMD-sensor in conjunction with a CCD-sensor is used to perform the pose estimation. Furthermore, the work provides a method for extending the measurement range of the PMD sensor along with the necessary calibration methodology. Finally, extensive measurements on a very accurate Rendezvous and Docking testbed are made to evaluate the performance, what includes a detailed discussion of lighting conditions.
Structural and biochemical characterization of gephyrin and various gephyrin-ligand complexes
(2014)
Efficient synaptic neurotransmission requires the exact apposition of presynaptic terminals and matching neurotransmitter receptor clusters on the postsynaptic side. The receptors are embedded in the postsynaptic density, which also contains scaffolding and regulatory proteins that ensure high local receptor concentrations. At inhibitory synapses the cytosolic scaffolding protein gephyrin assumes an essential organizing role within the postsynaptic density by the formation of self-oligomers which provide a high density of binding sites for certain -amino butyric acid type A (GABAA) and the large majority of glycine receptors (GlyR). Gephyrin contains two oligomerization domains: In isolation, the 20 kDa N-terminal G domain (GephG) and the 46 kDa E domain (GephE) trimerize and dimerize, respectively. In the full-length protein the domains are interconnected by a central ~150 amino acid linker, and only GephG trimerization is utilized, whereas GephE dimerization is prevented, thus suggesting the need for a trigger to release GephE autoinhibition, which would pave the way for the formation of higher oligomers and for efficient receptor clustering. The structural basis for this GephE autoinhibition has remained elusive so far, but the linker was reported to be sufficient for autoinhibition. This work dealt with the biochemical and structural characterization of apo-gephyrin and gephyrin in complexes with ligands which are known to promote the formation of synaptic gephyrin clusters (collybistin and neuroligin 2) and reorganize them (dynein light chain 1).
For full-length gephyrin no structural information has been available so far. Atomic force microscopy (AFM) and small-angle X-ray scattering (SAXS) analyses described in this thesis disclosed that the gephyrin trimer forms a highly flexible assembly, which, due to the long linker, can switch between compact and extended conformational states in solution, with a preference for compact states. This partial compaction and potentially GephE autoinhibition are achieved by interactions of parts of the linker with the G and E domains, as suggested by circular dichroism spectroscopy. However, the linker on its own cannot account for GephE blockage, as size exclusion chromatography experiments coupled with multi angle light scattering detection (SEC-MALS) and SAXS analyses revealed that a gephyrin variant only encompassing the linker and GephE (GephLE) forms dimers and not monomers as suggested by an earlier study. The oligomeric state of GephLE and the observation that several gephyrin variants, in which linker segments of varying length were deleted, predominantly formed trimers, suggested the presence of a linker independent mechanism of GephE dimerization blockade. Taken together, the data indicated that linker-dependent and linker-independent mechanisms mediate gephyrin autoinhibition.
In the second project gephyrin’s interaction with DYNLL1 (Dynein LC8 Light Chain 1) was characterized. DYNLL1 is a 25 kDa dimer incorporated into the dynein motor and provides two binding sites, each of which can accommodate an octapeptide derived from gephyrin’s linker region (referred to as GephDB). Originally, DYNLL1 was regarded as a cargo adaptor, linking gephyrin-GlyR complexes to the dynein motor, thus driving their retrograde transport and leading to a decrease of synaptic gephyrin-GlyR complexes.
Building on these studies, this thesis assessed the cargo hypothesis as well as the so far unclear stoichiometry of the gephyrin-DYNLL1 complex. The cargo scenario would require ternary complex formation between gephyrin, DYNLL1 and the dynein intermediate chain (DIC) of the dynein motor. However, such a complex could not be detected by analytical size exclusion chromatography (aSEC) experiments – presumably because gephyrin and DIC competed for a common binding site in DYNLL1. This finding was consistent with a single DYNLL1 dimer capturing two linker segments of a single gephyrin trimer as suggested by a 26 kDa mass increase of the gephyrin species in the presence of DYNLL1 in SEC-MALS experiments. aSEC experiments at even higher concentrations (~20 µM gephyrin and ~80 µM DYNLL1) indicated that the affinity of GephDB was significantly impaired in the context of full-length gephyrin but also in a variant that bears only GephG and the first 39 residues of the linker (GephGL220). Presumably due to avidity effects two linkers stably associated with a single DYNLL1 dimer, whereas the third DYNLL1 binding motif remained predominantly unoccupied unless high concentrations of GephGL220 (50 µM) and DYNLL1 (200 µM) were used. These findings indicate that an interplay between GephG and the N-terminal linker segment mediates the attenuation of GephDB affinity towards DYNLL1 and that preventing DYNLL1 from the induction of higher gephyrin oligomers is either advantageous for DYNLL1-mediated reorganization of gephyrin-GlyR clusters or that DYNLL1 exerts possibly two (concentration-dependent) actions on gephyrin.
The gephyrin-collybistin-neuroligin 2 complex was the subject of the third project. Previously, collybistin and gephyrin were observed to mutually trigger their translocation to the postsynaptic membrane, where the disordered cytoplasmic tail of the postsynaptic cell adhesion molecule NL2 (NL2cyt) causes the anchoring of collybistin 2 (CB2) by binding to its SH3 domain, thereby releasing SH3 domain mediated autoinhibiton of CB2 binding to the membrane phospholipid phosphatidylinositol-3-phosphate. Critical for this event is the binding of gephyrin to both CB2 and NL2, presumably via GephE.
Following up on these previous studies biochemical data presented in this thesis confirm the formation of the ternary complex. Unexpectedly, analyses by means of native polyacrylamide gel electrophoresis pointed to: (1) The existence of a complex containing NL2cyt and CB2 lacking the SH3 domain and consequently an additional NL2 binding site in CB2. (2) Attenuated gephyrin-collybistin complex formation in the presence of the SH3 domain. (3) A requirement for high NL2cyt concentrations (> 30 µM) during the formation of the ternary complex. This might allow for the regulation by other factors such as additional binding partners or posttranslational modifications. Although of preliminary character, these results provide a starting point for future studies, which will hopefully elucidate the interplay between gephyrin, collybistin, NL2 and certain GABAA receptors.
Functionally active (conformational) autoantibodies directed against the β1-adrenergic receptor (β1-AR) are supposed to have a pathogenic relevance in human heart failure, particularly in idiopathic dilated cardiomyopathy (DCM). Prevalence of anti-β1-autoantibodies (anti-β1-aabs) in the healthy population is almost negligible, whereas it amounts to up to 30% in heart failure patients with idiopathic DCM. As β1-ARs are not restricted to the heart and are also highly expressed in particular segments of the nephron, it is conceivable that such autoantibodies might also affect kidney function to some extent through the activation of renal β1-ARs.
In the kidney, β1-ARs are highly abundant in the juxtaglomerular apparatus, the distal convoluted tubules, the collecting duct, and the renal arteries. However, the functional significance of β1-ARs at these particular sites along the nephron is poorly understood, as are the effects of conformational stimulating anti-β1-aabs on renal β1-ARs. From the available literature, it is well known that the β1-adrenergic system is involved in, e.g., the regulation of renin-secretion from juxtaglomerular cells. In addition, the β1-adrenergic system is thought to be involved in the regulation of the urine pH via type B-intercalated cells in the collecting duct. In contrast, the regulation of salt- and fluid-secretion in the medullary collecting duct appears to occur independently from the SNS.
As a consequence, the present work aimed to unravel the potential pathophysiological links between renal function, alterations in the cardiovascular system, and circulating agonist-like anti- β1-abs. We analyzed possible renal effects of anti-β1-abs in a human-analogous rat model. After immunization with a GST-fusion protein containing the second extracellular loop (β1-ECII) of the human β1-AR, Lewis-rats develop functionally active, stimulating, conformational anti-β1-ECII-abs. Within the first 6 months, anti-β1-ECII-ab-positive animals develop a hypertensive phenotype, which after 9 months evolves into a DCM phenotype.
In n=40 GST/ β1-ECII-immunized Lewis rats and n=40 age-matched, 0.9% NaCl-injected control animals, we sequentially (i.e. at months 1, 2, 3, 6, 9, 12, 15, and 18 after start of immunization) analyzed the changes in renal function on a molecular, functional, and structural level. We could show that the presence of stimulating anti-β1-ECII-abs – even though having detrimental effects on the heart – has only a minor impact on kidney function and structure. Within the first 3 months after induction of anti-β1-ECII-abs, the levels and activity of renin were significantly increased in immunized compared to corresponding control animals, which was confirmed by experiments on isolated perfused kidneys, in which anti-β1-ECII-abs were able to directly induce the liberation of renin. However, within several weeks the initial anti-β1-ECII-ab-mediated RAAS activation was counter-regulated by auto-regulatory mechanisms activated in the kidney. Similarly, glomerular filtration rate (GFR) and renal blood flow (RBF) were initially decreased in the presence of the stimulating anti-β1-ECII-abs, but returned to control values within 3 months after immunization of the animals. Although expression of several pro-fibrotic markers was significantly up-regulated in anti-β1-ECII-ab-positive rats, no significant differences were noted on a histomorphological level with regard to the occurrence of renal fibrosis, glomerular damage, tubular damage, and perivascular fibrosis. Only a mild decrease in glomerular filtration function was observed in the kidneys of anti-β1-ECII-ab-positive animals from immunization-month 12 on, apparent by increased levels of urinary protein.
Even though anti-β1-ECII-abs were able to induce mild changes in renal function, their effects were not strong enough to critically damage the kidneys in our rat-model. Differences between immunized anti-β1-ECII-ab-positive and corresponding control rats at later time-points (that is, from immunization-month 12 on) are most likely secondary to the progressive heart failure phenotype that immunized animals develop in the course of the experiment.
The present study is the first to focus on the effects of stimulating anti-β1-ECII-abs on the kidney, and on the prevalence of these effects for the heart (referred to as cardio-renal crosstalk). Although our results were obtained in a rat model, they might contribute to better understand the situation in anti-β1-AR-aab-positive human patients. Following the results of our experiments, treatment of such patients should focus on direct and specific neutralization/elimination of stimulating anti-β1-ECII-aab or at least comprise therapeutic strategies that counteract the anti-β1-ECII-aab-effects on the heart by standard treatment for heart failure (i.e. ACE inhibitors, AT1-receptor blockers, and β-blockers) according to current guidelines.
In this work, three different material systems comprising carbon were researched: (i) Organic polymers and small molecules, in conjunction with fullerene molecules for applications in organic photovoltaics (OPV), (ii) single walled semiconducting carbon nanotubes and (iii) silicon carbide (SiC), whose defect color centers are recently in the limelight as candidates for quantum applications. All systems were analyzed using the optically detected magnetic resonance (ODMR) spectroscopy.
In the OPV chapter, first the intrinsic parameters and orientations of high spin excitons were analyzed in the materials P3HT, PTB7 and DIP. Specifically the influence of ordering in these organic systems was adressed. The second part of the OPV chapter is concerned with triplet generation by electron back transfer in the high-efficiency OPV material combination PTB7:PC71BM.
The carbon nanotube chapter first shows the way to the first unambiguous proof of the existence of triplet excitons in semiconducting (6,5) single-walled carbon nanotubes (SWNT) by ODMR spectroscopy. A model for exciton kinetics, and also orientation and intrinsic parameters were propoesed.
The last part of this work is devoted to spin centers in silicon carbide (SiC). After a brief introduction, the spin multiplicity of the V2 and V3 silicon vacancies, and also of a Frenkel pair and an unassigned defect UD in 6H SiC, and of the V2 vacancy and the Frenkel pair in 4H SiC, was shown to be S=3/2. The spin polarized pumping of the 3/2 manifold of the quartet ground state of the silicon vacancies allows stimulated microwave emission. Furthermore, in 6H SiC, the UD and Frenkel pair were shown to have a large dependence of their intrinsic zero field interaction parameters on the temperature, while the vacancies are temperature independent. The application of the UD and Frenkel pair as temperature sensor, and of the vacancies as a vector magnetic field sensor is discussed.
The aim of this work was to synthesize and functionalize different bio-relevant nanomaterials like silica-coated superparamagnetic iron oxide nanoparticles (SPIONs) as contrast agents for T2 magnetic resonance imaging (MRI) and detonation nanodiamond (DND) with the neurohormone peptide allatostatin 1 (ALST1) and a fluorescent dye. Analytical techniques for the determination and quantification of surface functional groups like amines, azides, and peptides were also developed and established.
Thus, in the first part of the work, a TGF-1 binding peptide and allatostatin 1 (ALST1), both supposed to act as active tumour targeting vectors, were synthesized by solid-phase peptide synthesis (SPPS) and characterized by high pressure liquid chromatography (HPLC) and mass spectrometry. Then, azide-functionalized silica nanoparticles were synthesized by the Stöber process and characterized by transmission electron microscopy (TEM) and infrared spectroscopy (IR). The surface loading of amine and azide groups was determined by a new protocol. The azide groups were reduced with sodium boronhydride to amine and then functionalized with Fmoc-Rink Amide linker according to a standard SPPS protocol. Upon cleavage of Fmoc by piperidine, the resulting dibenzofulvene and its piperidine adduct were quantified by UV/Vis spectroscopy and used to determine the amount of amine groups on the nanoparticle surface. Then, ALST1 and related tyrosine- and phenylalanine substituted model peptides were conjugated to the azide-functionalized silica nanoparticles by copper(I)-catalyzed azide-alkyne dipolar cycloaddition (CuAAC). The successful peptide conjugation was demonstrated by the Pauly reaction, which however is only sensitive to histidine- and tyrosine-containing peptides. As a more general alternative, the acid hydrolysis of the peptides to their individual amino acid building blocks followed by derivatization with phenyl isothiocyanate (PITC) allowed the separation, determination, and quantification of the constituent amino acids by HPLC.
In the second part of the work, amine- and azide-functionalized silica-coated superparamagnetic iron oxide nanoparticles (SPIONs) were synthesized by co-precipitation and subsequent silica-coated based on the Stöber process and characterized by TEM and IR. The amine surface loading was determined by the method already established for the pure silica systems. The azide surface loading could also be quantified by reduction with sodium boronhydride to amine groups and then conjugation to Fmoc-Rink amide linker. Upon cleavage of Fmoc with piperidine, the total amine surface loading was obtained. The amount of azide surface groups was then determined from the difference of the total amine surface loading and the amine surface loading. Thus, it was possible to quantify both amine and azide surface groups on a single nanoparticle system. Superparamagnetic iron oxide nanoparticles (SPIONs) are potent T2 contrast agents for magnetic resonance imaging (MRI). Due to their natural metabolism after injection into the blood stream, SPIONs mostly end up inside macrophages, liver, spleen or kidneys. To generate a potential target-specific SPION-based T2 contrast agent for MRI, the neurohormone peptide ALST1 was conjugated by CuAAC to the azide- and amine functionalized superparamagnetic iron oxide nanoparticles, since ALST1 is supposed to target difficult-to-treat neuroendocrinic tumours due to its analogy to galanin and somastatin receptor ligands. The organic fluorescent dye cyanine 5 (Cy5) was also conjugated to the silica-coated superparamagnetic iron oxide nanoparticles (SPIONs) via a NHS-ester to the amines to enable cell uptake studies by fluorescence microscopy. These constructs were characterized by TEM, dynamic light scattering (DLS), and IR. The amino acids of the conjugated ALST1 were determined by the HPLC method as described before for peptide-modified silica nanoparticle surfaces. Then, the relaxivity r2 was measured at 7 T. However, a r2 value of 27 L/mmolFe·s for the dual ALST1-/Cy5-functionalized silica-coated SPIONs was not comparable to T2 contrast agents in clinical use, since their relaxivity is commonly determined at 1.5 T, and no such instrument was available. However, it can be assumed that the synthesized dual
ALST1-/Cy5-functionalized silica-coated SPION would show a lower r2 at 1.5 T than at 7T. Commercial T2 MRI contrast agents like VSOP-C184 from Ferropharm show at r2 values of about 30 L/mmolFe·s at 1.5 T. Still, the relaxivity of the new material has some potential for application as a T2 contrast agent. Then, the material was used in cell uptake studies by fluorescence microscopy with the conjugated Cy5 dye as a probe. The dual
ALST1-/Cy5-functionalized silica-coated SPION showed a high degree of agglomeration with no cellular uptake unlike described for ALST1-functionalized nanoparticles in literature. It is assumed that upon agglomeration of the particles, constructs form which are unable to be internalized by the cellular endocytotic pathways anymore. As a future perspective, the tendency of the particle to agglomerate should be reduced by changing the coating material to polyethylene glycol (PEG) or chitosan, which are known to be bio-compatible, bio-degradable and prevent agglomeration.
In the third part of the work, the rhenium compound [ReBr(CO)3(L)] with L = 2-phenyl-1H-imidazo[4,5-f][1,10]phenanthroline and its manganese analogue were synthesized by heating the ligand and rhenium pentacarbonyl bromide or and manganese pentacarbonyl bromide respectively, in toluene. However, [MnBr(CO)3(L)] was unstable upon illumination by UV light at 365 nm. Thus, it was dismissed for further application. The photophysical properties of [ReBr(CO)3(L)] were explored, by determination of the excited-state life time by the time-correlated single-photon counting (TCSPC) method and the quantum yield by a fluorescence spectrometer equipped with an integration sphere. A value of = 455 ns, a Stokes shift of 197 nm and a rather low quantum yield =were found. Metal complexes are supposed to have superior properties compared to organic dyes due to their large Stokes shifts, long excited-state life times, and high quantum yields. Thus, amine- and azide-functionalized detonation nanodiamond (DND) as an alternative biological inert carrier system was functionalized with ALST1 to enhance its cell uptake properties. A luminescent probe for cell uptake studies using fluorescence microscopy was also attached, either based on the new rhenium complex or the commercially available organic dye Cy5, respectively. The aldehyde-functionalized rhenium complex was conjugated to the DND via oxime ligation, which is known to be a mild and catalyst-free conjugation method. The amount of peptide ALST1 on the DND was analyzed and quantified after acid hydrolysis and PITC derivatization by HPLC as described before. Then, the ALST1-/luminescent probe-functionalized DND was investigated for its photophysical properties by fluorescence spectroscopy. The Cy5-functionalized material showed a slightly lower fluorescence performance in aqueous solution than reported in literature and commercial suppliers with a life time < 0.4 ns and quantum yields not determinable by integration sphere due to the week signal intensity. The rhenium complex-functionalized material had a very low signal intensity in only aqueous medium, and thus determination of life times and quantum yield by fluorescence spectroscopy was not possible. After incubation with MDA-MB 231 cells, the Cy5-functionalized DND could easily be detected due to its red fluorescence. However, it was not possible to visualize the rhenium complex-functionalized DND with fluorescence microscopy due to the low fluorescence intensity of the complex in aqueous medium and the lack of proper filters for the fluorescence microscope. Cy5-functionalized DND did not show any cellular uptake in fluorescence microscopy after conjugation with ALST1. Since the nanodiamond surface is known to strongly adsorb peptides and proteins, it is assumed that the peptide chain is oriented perpendicular to the nanoparticle surface and thus not able to interact with cell membrane receptors to promote cell uptake of the particles. As a future perspective, the ALST1-promoted cellular uptake of the DND should be improved by using different linker systems for peptide conjugation to prevent adsorption of the peptide chain on the particle surface.
The new analytical methods for amino-, azide-, and peptide-functionalized nanoparticles have great potential to assist in the quantification of nanoparticle surface modifications by UV/Vis spectroscopy and HPLC. The determination of surface amine and azide groups based on the cleavage of conjugated Fmoc-Rink amide linker and detected by UV/Vis spectroscopy is applicable to all amine-/azide-functionalized nanomaterials. However, particles which form very stable suspension with the cleavage mixture can cause quantification problems due to scattering, making an accurate quantification of dibenzofulvene and its piperidine adduct impossible. The detection of tyrosine- and histidine-containing peptides based on the Pauly reaction is well-suited as a fast and easy-to-perform qualitative demonstration of successful peptide surface conjugation. However, its major drawback as a colourimetric approach is that coloured particles cannot be evaluated by this method. The amino acid analysis based on HPLC after acid hydrolysis of peptides conjugated to nanoparticle surfaces to its individual building blocks and subsequent derivatization with PITC, can be used on all nanomaterials with peptide or protein surface modification. It allows detection of amino acids down to picomolar concentrations and even enables analysis of very small peptide surface loadings. However, the resulting HPLC traces are difficult to analyze.
Three new analytical methods based on UV/Vis and HPLC techniques have been developed and established. They assisted in the characterization of the synthesized DND and SPIONs with dual functionalization by ALST1 and Cy5 or [ReBr(CO)3(L)], respectively. However, the nanomaterials showed no cellular uptake due to a high tendency to agglomerate. The cellular uptake should be improved and the tendency to agglomerate of the SPIONs should be reduced by changing the surface coating from silica to either PEG or chitosan. Furthermore, different linker systems for connecting peptides to DND surfaces should be synthesized and evaluated to reduce potential peptide chain adsorption.
Platelet activation and aggregation are essential processes for the sealing of injured vessel walls and preventing blood loss. Under pathological conditions, however, platelet aggregation can lead to uncontrolled thrombus formation, resulting in irreversible vessel occlusion. Therefore, precise regulation of platelet activation is required to ensure efficient platelet plug formation and wound sealing but also to prevent uncontrolled thrombus formation. Rapid elevations in the intracellular levels of cations are a core signaling event during platelet activation. In this thesis, the roles of Ca2+ and Mg2+ channels in the regulation of platelet function were investigated.
Orai1, the major store-operated calcium (SOC) channel in platelets, is not only vital for diverse signaling pathways, but may also regulate receptor-operated calcium entry (ROCE). The coupling between the Orai1 signalosome and canonical transient receptor potential channel (TRPC) isoforms has been suggested as an essential step in the activation of store-operated calcium entry (SOCE) and ROCE in human platelets. However, the functional significance of the biochemical interaction between Orai and TRPC isoforms still remains to be answered. In the first part of this thesis, the functional crosstalk between Orai1 and TRPC6 was addressed. Orai1-mediated SOCE was found to enhance the activity of phospholipases (PL) C and D, to increase diacylglycerol (DAG) production and finally to regulate TRPC6-mediated ROCE via DAG, indicating that the regulation of TRPC6 channel activity seems to be independent of the physical interaction with Orai1. Furthermore, Orai1 and TRPC6 double deficiency led to a reduced Ca2+ store content and basal cytoplasmic Ca2+ concentrations, but surprisingly also enhanced ATP secretion, which may enhance Ca2+ influx via P2X1 and compensate for the severe Ca2+ deficits seen in double mutant platelets. In addition, Orai1 and TRPC6 were not essential for G protein-coupled receptor (GPCR)-mediated platelet activation, aggregation and thrombus formation.
Transient receptor potential melastatin-like 7 (TRPM7) contains a cytosolic serine/threonine protein kinase. To date, a few in vitro substrates of the TRPM7 kinase have been identified, however, the physiological role of the kinase remains unknown. In the second part of this thesis, mice with a point mutation which blocks the catalytic activity of the TRPM7 kinase (Trpm7KI) were used to study the role of the TRPM7 kinase in platelet function. In Trpm7KI platelets phosphatidylinositol-4,5-bisphosphate (PIP2) metabolism and Ca2+ mobilization were severely impaired upon glycoprotein (GP) VI activation, indicating that the TRPM7 kinase regulates PLC function. This signaling defect in Trpm7KI platelets resulted in impaired aggregate formation under flow and protected animals from arterial thrombosis and ischemic brain infarction. Altogether, these results highlight the kinase domain of TRPM7 as a pivotal signaling moiety implicated in the pathogenesis of thrombosis and cerebrovascular events.
Marine sponges (phylum Porifera) are simple, sessile, filter-feeder animals. Microbial symbionts are commonly found in the sponge internal tissue, termed the mesohyl. With respect to the microbial content, sponges are classified as either low-microbial abundance sponges (LMA), or high-microbial abundance sponges (HMA). The HMA/LMA dichotomy was explored in this Thesis using the Red Sea sponges as experimental models. A range of methods encompassing transmission electron microscopy, 16S rRNA gene deep sequencing, and metatranscriptomics was employed towards this goal. Here, particular emphasis was placed on the functional analysis of sponge microbiomes.
The Red Sea sponges Stylissa carteri, Xestospongia testudinaria, Amphimedon ochracea, and Crella cyathophora were classified as HMA or LMA sponges using transmission electron microscopy. The diversity, specificity, and transcriptional activity of microbes associated with the sponges S. carteri (LMA) and X. testudinaria (HMA) and seawater were investigated using 16S rRNA amplicon pyrosequencing. The microbial composition of S. carteri was more similar to that of seawater than to that of X. testudinaria, which is consistent with the observation that the sequence data set of S. carteri contained many more possibly seawater sequences (~24%) than the X. testudinaria data set (~6%). The most abundant operational taxonomic units (OTUs) were shared between all three sources (S. carteri, X. testudinaria, seawater), while rare OTUs were unique to any given source. Despite this high degree of overlap, each sponge species contained its own specific microbiota. S. carteri microbiomes were enriched of Gammaproteobacteria and members of the genus Synechococcus and Nitrospira. Enriched members of X. testudinaria microbiomes included Chloroflexi, Deferribacteres, and Actinobacteria. The transcriptional activity of sponge-associated microorganisms was assessed by comparing 16S rRNA gene with transcript amplicons, which showed a good correlation.
The microbial functional gene repertoire of sponges and seawater from the Red Sea (X. testudinaria, S. carteri) and the Mediterranean (Aplysina aerophoba, Dysidea avara) were investigated with the environmental microarray GeoChip 4. Amplicon sequencing was performed alongside in order to assess microbial diversity. The typical microbial diversity patterns characteristic of HMA (abundance of Gammaproteobacteria, Chloroflexi, Acidobacteria, Deferribacteres, and others) and LMA sponges (abundance of Alpha-, Beta-, Gammaproteobacteria, Cyanobacteria, and Bacteroidetes) were confirmed. The HMA/LMA dichotomy was stronger than any possible geographic pattern based on microbial diversity (amplicon) and functional genes (GeoChip). However upon inspection of individual genes detected by GeoChip, very few specific differences were discernible, including differences related to microbial ammonia oxidation, ammonification (higher gene abundance in sponges over seawater) as well as denitrification (lower gene abundance). Furthermore, a higher abundance of a gene, pcc, representative of archaeal autotrophic carbon fixation was noted in sponges over seawater. Thirdly, stress-related genes, in particular those related to radiation, were found in lower abundances in sponge microbiomes than in seawater. With the exception of few documented specific differences, the functional gene repertoire between the different sources appeared largely similar.
The most actively expressed genes of S. carteri microbiomes were investigated with metatranscriptomics. Prokaryotic mRNA was enriched from sponge total RNA, sequenced using Illumina HiSeq technology, and annotated with the metagenomics Rapid Annotation using Subsystem Technology (MG-RAST) pipeline. High expression of archaeal ammonia oxidation and photosynthetic carbon fixation by members of the genus Synechococcus was detected. Functions related to stress response and membrane transporters were among the most highly expressed by S. carteri symbionts. Unexpectedly, gene functions related to methylotrophy were highly expressed by gammaproteobacterial symbionts. The presence of seawater-derived microbes is indicated by the phylogenetic proximity of organic carbon transporters to orthologs of members from the SAR11 clade. In summary, the most expressed functions of the S. carteri-associated microbial community were revealed and linked to the dominant taxonomic members of the microbiome.
In conclusion, HMA and LMA Red Sea sponges were used as models to gain insights into relevant themes in sponge microbiology, i.e. diversity, specificity, and functional activities. Overall, my Thesis contributes to a better understanding of sponge-associated microbial communities, and the implications of this association to marine ecology.
Quantum theory is considered to be the most fundamental and most accurate physical theory of today. Although quantum theory is conceptually difficult to understand, its mathematical structure is quite simple. What determines this particularly simple and elegant mathematical structure? In short: Why is quantum theory as it is?
Addressing such questions is the aim of investigating the foundations of quantum theory. In the past this field of research was sometimes considered as an academic subject without much practical impact. However, with the emergence of quantum information theory this perception has changed significantly and both fields started to fruitfully influence each other. Today fundamental aspects of quantum theory attract increasing attention and the field belongs to the most exciting subjects of theoretical physics.
This thesis is concerned with a particular branch in this field, namely, with so-called Generalized Probabilistic Theories (GPTs), which provide a unified theoretical framework in which classical and quantum theory emerge as special cases. This is used to examine nonlocal features that help to distinguish quantum theory from alternative toy theories. In order to extend the scope of theories that can be examined with the framework, we also introduce several generalizations to the framework itself.
We start in Chapter 1 with introducing the standard GPT framework and summarize previous results, based on a review paper of the author [New J. Phys. 13, 063024 (2011)]. To keep the introduction accessible to a broad readership, we follow a constructive approach. Starting from few basic physically motivated assumptions we show how a given set of observations can be manifested in an operational theory. Furthermore, we characterize consistency conditions limiting the range of possible extensions. We point out that non-classical features of single systems can equivalently result from higher dimensional classical theories that have been restricted. Entanglement and non-locality, however, are shown to be genuine non-classical features. We review features that have been found to be specific for quantum theory separably or single and joint systems.
Chapter 2 incorporates results published in [J. Phys. A 47(32), pp. 1-32 (2014)] and [Proc. QPL 2011 via EPTCS vol. 95, pp. 183–192 (2012)]. The GPT framework is applied to show how the structure of local state spaces indirectly affects possible nonlocal correlations, which are global properties of a theory. These correlations are stronger than those possible in a classical theory, but happen to show different restrictions that can be linked to the structure of subsystems. We first illustrate the phenomenon with toy theories with particular local state spaces. We than show that a particular class of joint states (inner product states), whose existence depends on geometrical properties of the local subsystems, can only have correlations for a known limited set called Q1. All bipartite correlations of both, quantum and classical correlations, can be mapped to measurement statistics from such joint states.
Chapter 3 shows unpublished results on entanglement swapping in GPTs. This protocol, which is well known in quantum information theory, allows to nonlocally transfer entanglement to initially unentangled parties with the help of a third party that shares entanglement with each. We review our approach published in [Proc. QPL 2011 via EPTCS vol. 95, pp. 183–192 (2012)], which mimics the joint systems' structure of quantum theory by modifying a popular toy theory known as boxworld. However, it is illustrated that this approach fails for bigger multipartite systems due to inconsistencies evoked by entanglement swapping. It turns out that the GPT framework does not allow entanglement swapping for general subsystems with two-dimensional state spaces with transitive pure states. Altering the GPT framework to allow completely globally degrees of freedom, however, enables us to construct consistent entanglement swapping for these subsystems. This construction resembles the situation in quantum theory on a real Hilbert space.
A questionable assumption usually taken in the standard GPT framework is the so-called no-restriction hypothesis. It states that the measurement that are possible in a theory can be derived from the state space. In fact, this assumption seems to exist for reasons of mathematical convenience, but it seems to lack physical motivation. We generalize the GPT framework to also account for systems that do not obey the no-restriction hypothesis in Chapter 4, which presents results published in [Phys. Rev. A 87, 052131 (2013)] and [Proc. QPL 2013, to be published in EPTCS]. The extended framework includes new classes of probabilistic theories. As an example, we show how to construct theories that include intrinsic noise. We also provide a "self-dualization" procedure that requires the violation of the no-restriction hypothesis. This procedure restricts the measurement of arbitrary theories such that the theories act as if they were self-dual. Self-duality has recently gathered lots of interest, since such theories share many features of quantum theory. For example Tsirelson’s bound holds for correlations on the maximally entangled state in these theories. Finally, we characterize the maximal set of joint states that can be consistently defined for given subsystems. This generalizes the maximal tensor product of the standard GPT framework.
The number of newly detected autoantibodies (AB) targeting synaptic proteins in neurological disorders of the central nervous system (CNS) is steadily increasing. Direct interactions of AB with their target antigens have been shown in first studies but the exact pathomecha-nisms for most of the already discovered AB are still unclear. The present study investigates pathophysiological mechanisms of AB-fractions that are associated with the enigmatic CNS disease Stiff person syndrome (SPS) and target the synaptically located proteins amphiphysin or glutamate decarboxylase 65 (GAD65).
In the first part of the project, effects of AB to the presynaptic endocytic protein amphiphysin were investigated. Ultrastructural investigations of spinal cord presynaptic boutons in an es-tablished in-vivo passive-transfer model after intrathecal application of human anti-amphiphysin AB showed a defect of endocytosis. This defect was apparent at high synaptic activity and was characterized by reduction of the synaptic vesicle pool, clathrin coated vesi-cles (CCVs), and endosome like structures (ELS) in comparison to controls. Molecular inves-tigation of presynaptic boutons in cultured murine hippocampal neurons with dSTORM microscopy after pretreatment with AB to amphiphysin revealed that marker proteins involved in vesicle exocytosis (synaptobrevin 2 and synaptobrevin 7) had an altered expression in GA-BAergic presynapses. Endophilin, a direct binding partner of amphiphysin also displayed a disturbed expression pattern. Together, these results point towards an anti-amphiphysin AB-induced defective organization in GABAergic synapses and a presumably compensatory rearrangement of proteins responsible for CME.
In the second part, functional consequences of SPS patient derived IgG fractions containing AB to GAD65, the rate limiting enzyme for GABA synthesis, were investigated by patch clamp electrophysiology and immunohistology. GABAergic neurotransmission at low and high activity as well as short term plasticity appeared normal but miniature synaptic potentials showed an enhanced frequency with constant amplitudes. SPS patient IgG after preabsorption of GAD65-AB using recombinant GAD65 still showed specific synaptic binding to neu-rons and brain slices supporting the hypothesis that additional, not yet characterized AB are present in patient IgG responsible for the exclusive effect on frequency of miniature potentials.
In conclusion, the present thesis uncovered basal pathophysiological mechanisms underlying paraneoplastic SPS induced by AB to amphiphysin leading to disturbed presynaptic architec-ture. In idiopathic SPS, the hypothesis of a direct pathophysiological role of AB to GAD65 was not supported and additional IgG AB are suspected to induce distinct synaptic malfunction.
Stem cells are defined by their capacity to self-renew and their potential to differentiate into multiple cell lineages. Pluripotent embryonic stem (ES) cells can renew indefinitely while keeping the potential to differentiate into any of the three germ layers (ectoderm, endoderm or mesoderm). For decades, ES cells are in the focus of research because of these unique features. When ES cells differentiate they form spheroid aggregates termed “embryoid bodies” (EBs). These EBs mimic post- implantation embryonic development and therefore facilitate the understanding of developmented mechanisms.
During ES cell differentiation, de-repression or repression of genes accompanies the changes in chromatin structure. In ES cells, several mechanisms are involved in the regulation of the chromatin architecture, including post-translational modifications of histones. Post-translational histone methylation marks became one of the best- investigated epigenetic modifications, and they are essential for maintaining pluripotency. Until the first histone demethylase KDM1A was discovered in 2004 histone modifications were considered to be irreversible. Since then, a great number of histone demethylases have been identified. Their activity is linked to gene regulation as well as to stem cell self-renewal and differentiation.
KDM6A and KDM6B are H3K27me3/2-specific histone demethylases, which are known to play a central role in the regulation of posterior development by regulating HOX gene expression. So far less is known about the molecular function of KDM6A or KDM6B in undifferentiated and differentiating ES cells. In order to completely abrogate KDM6A and KDM6B demethylase activity in undifferentiated and differentiating ES cells, a specific inhibitor (GSK-J4) was employed. Treatment with GSK-J4 had no effect on the viability or proliferation on ES cells. However, in the presence of GSK-J4 ES cell differentiation was completely abrogated with cells arrested in G1-phase and an increased rate of apoptosis. Global transcriptome analyses in early-differentiating ES cells revealed that only a limited set of genes were differentially regulated in response to GSK-J4 treatment with more genes up- regulated than down-regulated. Many of the up-regulated genes are linked to DNA damage response (DDR). In agreement with this, DNA damage was found in EBs incubated with GSK-J4. A co-localization of H3K27me3 or KDM6B with γH2AX foci, marking DNA breaks, could be excluded. However, differentiating Eed knockout (KO) ES cells, which are devoid of the H3K27me3 mark, showed an attenuated GSK-J4- induced DDR. Finally, hematopoietic differentiation in the presence of GSK-J4 resulted in a reduced colony-forming potential. This leads to the conclusion that differentiation in the presence of GSK-J4 is also restricted to hematopoietic differentiation.
In conclusion, my results show that the enzymatic activity of KDM6A and KDM6B is not essential for maintaining the pluripotent state of ES cells. In contrast, the enzymatic activity of both proteins is indispensable for ES cell and hematopoietic differentiation. Additionally KDM6A and KDM6B enzymatic inhibition in differentiating ES cells leads to increased DNA damage with an activated DDR. Therefore, KDM6A and KDM6B are associated with DNA damage and in DDR in differentiating ES cells.
Chapter I
The gradual turnover of dead organic material into mineral nutrients is a key ecological function, linking decomposition and primary production, the essential parts of the nutrient-energy cycle. However, disturbances in terms of species or resource losses might impair the equilibrium between production and decomposition. Humanity has converted large proportions of natural landscapes and intensified land-use activity for food production. Globally, only very few areas are totally unaffected by human activity today.
To ensure the maintenance of both essential ecosystem services, knowledge about the interplay of biodiversity and ecosystem functioning as well as effects of intensified management on both is crucial. The vast majority of terrestrial biomass production as well as decomposition take place in forest ecosystems. Though forestry has a long sustainable history in Europe, its intensification during the last century has caused severe impacts on forest features and, consequently, on the associated biota, especially deadwood dependent organisms. Among these, saproxylic beetles are the most diverse group in terms of species numbers and functional diversity, but also most endangered due to habitat loss. These features classify them as ideal research organisms to study effects of intensified forestry on ecosystem services. The BELONGDEAD project located in Germany aimed to investigate deadwood decay and functional consequences of diversity changes in the associated fauna on the decomposition process from the initialisation of deadwood decay to complete degradation.
As part of the BeLongDead project, this dissertation focussed on saproxylic beetle species, thereby evaluating (1) regionally effects of tree species identity of fresh deadwood and (2) forest management of varying intensities on the diversity, abundance and community composition of saproxylic beetles (chapter II); (3) the specialisation degree of different trophic guilds of saproxylic beetles, and thus the stability and robustness of their interaction networks against disturbances (chapter III); (4) the impact of environmental features of local to regional spatial scales on species richness of saproxylic beetles differing in their habitat niche in terms of deadwood decay stages (chapter IV).
Chapter II
The vast majority of European forest ecosystems have been anthropogenically affected, leaving less than 1% of the about 1 milliard hectare as natural forests. A long history of forestry and especially the technological progress during the last century have caused massive habitat fragmentation as well as substantial loss of essential resources in European forest ecosystems. Due to this, the substrate-dependent group of saproxylic beetles has experienced severe species losses. Thus, investigations concerning saproxylic diversity and deadwood volume were badly needed. However, the importance of different deadwood in terms of tree species identity for the colonization by saproxylic beetles under different local and regional management regimes is poorly understood. Therefore, we studied possible regional differences in colonization patterns of saproxylic beetle species in a total of 688 fresh deadwood logs of 13 tree species in 9 sites of managed conifer and beech forests, and unmanaged beech forests, respectively. We found that tree species identity was an important driver in determining saproxylic species composition and abundance within fresh deadwood. However, saproxylic species showed different colonization patterns of deadwood items of the same tree species among the study regions. Regionally consistent, conifer forests were most diverse. We attribute the latter result to the historically adaption of saproxylic beetle species to semi-open forests, which conditions are actually best reflected by conifer forests. To preserve a diverse local species pool of early successional saproxylic beetles, we suggest an equal high degree of deadwood diversity in a tree species context in due consideration of regional differences.
Chapter III
The extinction risk of a particular species corresponds with its species-specific requirements on resources and habitat conditions, in other words with the width of the species` ecological niche. Species with a narrow ecological niche are defined as specialists. Members of this group experience higher extinction risk by resource limitation than generalists, which are able to utilize a variety of resources. For the classification of species as specialists or generalists, thus evaluating possible extinction risks, ecologists use the concept of interaction networks. This method has often been applied for mutualistic or antagonistic plant-animal interactions, but information for networks of detritivores is scarce. Therefore, saproxylic beetle species sampled as described in chapter II were categorised according to their larval diet; additionally their interaction networks (N=108) with 13 dead host tree species were analysed. Specialisation degree was highest for wood-digesting beetles and decreased with increasing trophic level. Also the network indices evaluating robustness and generality indicated a higher susceptibility to species extinctions for xylophagous than for mycetophagous and predatory beetles. The specialisation of xylophagous species on specific tree species might be an adaption to tree species specific ingredients stored for defence against pathogens and pests. However, we conclude that the high specialisation degree of xylophages and thus their higher extinction risk by resource loss harbours certain dangers for ecosystem function and stability as species diversity is positively linked to both.
Chapter IV
Populations depend on individual emigration and immigration events to ensure genetic exchange. For successful migration it is of utmost importance that spatially separated populations are obtainable by specimen. Migratory success depends on the one hand on the species dispersal abilities and on the other on the availability of suitable habitats in the surrounding landscape in which the distinct host populations exist. However, consequences of intensive forest management correspond not only to severe reduction of local deadwood amount, but, among others, also a change in tree species composition and high levels of fragmentation in the surrounding forest area. Saproxylic beetle species differ in their dispersal behaviour according to the temporal availability of their preferred habitat. Generally, early successional saproxylic beetles are able to disperse over large distances, whereas beetles inhabiting advanced decayed wood often remain close to their larval habitat. Due to this, environmental factors might affect saproxylic beetle guilds differently. We classified the saproxylic beetles sampled as described in chapter II according to their calculated habitat niche as early, intermediate or late successional saproxylic beetles. For the different guilds the effects of 14 environmental factors on different spatial scales (stand factors at 0.1 km radius, landscape composition at 2 km radius, and regionally differing abiotic factors in 400 km to 700 km distance) were investigated. Consistently for all guilds, species richness decreased with fragmentation at local and landscape scale, and increased in warmer climate. However, we found contradictory results between the guilds to some extent. We relate this to guild specific habitat requirements of the saproxylic beetles. Therefore, for the development of appropriate conservation practices guild-specific requirements saproxylic beetles have to be considered not only locally but on larger spatial scales.
Chapter V
In conclusion, this dissertation identified main drivers of early successional saproxylic beetle species richness on various spatial scales. Our results emphasize the importance to develop management schemes meeting species-specific and guild-specific habitat requirements of the saproxylic beetle fauna at relevant spatial and temporal scales. Therefore, short-term actions suggested for sustainable forest management should be the focus on a diverse tree species composition consisting of indigenous tree species with respect to regional differences. Moreover, senescent trees, fallen and standing deadwood should remain in the forests, and some tree individuals should be allowed to grow old. Long-term actions should involve the reduction of forest fragmentation and the connection of spatial widely separated forest fragments. Furthermore, to fully understand the effects of forest management long-term research should be conducted to compare habitat requirements of intermediate and late successional beetles with the results presented in this dissertation.
Human risk behavior is the subject of growing research in the field of psychology as well as economics. One central topic is the influence of psychological variables on risk behavior. Studies contained in this work investigated the impact of arousal, framing and motivation on risk behavior.
Arousal can on the one hand be a temporarily stable trait and on the other hand a situation-dependent variable. We showed that low trait arousal, measured via resting heart rate, predicted risky behavior. After physical exercise, state arousal was heightened in the experiment. Participants tended to act less risky after physical exercise. Taken together, the results suggest an inverse relation of arousal and risk behavior. Most studies investigating risk behavior employ a payment method that we call pay-one method: although the gambles that are used consist of many trials, only one trial is paid out. We investigated the effect of the payment method on risk behavior by employing both the pay-one and a pay-all method, which pays out all trials, in a within-subjects design. We found that participants acted about 10% less risky in the pay-one condition compared to the pay-all condition. This result suggests that risk-aversion is over-estimated in common risk paradigms that use the pay-one method.
When we worked on a hard task before, we like to engage in a more likable task afterwards. That observation led to the general classification of tasks in want-to and have-to tasks. Our body system strives towards a balance between those two task types in the sense of a homeostasis. We assessed event-related potentials (ERPs) in a risk game that we treated as a want-to task. When participants worked on a difficult have-to task before, amplitudes of the ERP-components in the risk game were raised compared to a condition where participants worked on an easy task before. We conclude that the motivation shift towards a want-to task after a have-to task can be assessed via ERP amplitudes.
In conclusion, it was shown that arousal, framing and motivation are important psychological variables that influence risk behavior. The specific mechanisms of these influences have been investigated and discussed.
Adipose tissue defects and related pathologies still represent major challenges in reconstructive surgery. Based on to the paradigm ‘replace with alike’, adipose tissue is considered the ideal substitute material for damaged soft tissue [1-3]. Yet the transfer of autologous fat, particularly larger volumes, is confined by deficient and unpredictable long term results, as well as considerable operative morbidity at the donor and recipient site [4-6], calling for innovative treatment options to improve patient care.
With the aim to achieve complete regeneration of soft tissue defects, adipose tissue engineering holds great promise to provide functional, biologically active adipose tissue equivalents. Here, especially long-term maintenance of volume and shape, as well as sufficient vascularization of engineered adipose tissue represent critical and unresolved challenges [7-9]. For adipose tissue engineering approaches to be successful, it is thus essential to generate constructs that retain their initial volume in vivo, as well as to ensure their rapid vascularization to support cell survival and differentiation for full tissue regeneration [9,10]. Therefore, it was the ultimate goal of this thesis to develop volume-stable 3D adipose tissue constructs and to identify applicable strategies for sufficient vascularization of engineered constructs. The feasibility of the investigated approaches was verified by translation from in vitro to in vivo as a critical step for the advancement of potential regenerative therapies.
For the development of volume-stable constructs, the combination of two biomaterials with complementary properties was successfully implemented. In contrast to previous approaches in the field using mainly non-degradable solid structures for mechanical protection of developing adipose tissue [11-13], the combination of a cell-instructive hydrogel component with a biodegradable porous support structure of adequate texture was shown advantageous for the generation of volume-stable adipose tissue. Specifically, stable fibrin hydrogels previously developed in our group [14] served as cell carrier and supported the adipogenic development of adipose-derived stem cells (ASCs) as reflected by lipid accumulation and leptin secretion. Stable fibrin gels were thereby shown to be equally supportive of adipogenesis compared to commercial TissuCol hydrogels in vitro. Using ASCs as a safe source of autologous cells [15,16] added substantial practicability to the approach. To enhance the mechanical strength of the engineered constructs, porous biodegradable poly(ε caprolactone)-based polyurethane (PU) scaffolds were introduced as support structures and shown to exhibit adequately sized pores to host adipocytes as well as interconnectivity to allow coherent tissue formation and vascularization. Low wettability and impaired cell attachment indicated that PU scaffolds alone were insufficient in retaining cells within the pores, yet cytocompatibility and differentiation of ASCs were adequately demonstrated, rendering the PU scaffolds suitable as support structures for the generation of stable fibrin/PU composite constructs (Chapter 3).
Volume-stable adipose tissue constructs were generated by seeding the pre-established stable fibrin/PU composites with ASCs. Investigation of size and weight in vitro revealed that composite constructs featured enhanced stability relative to stable fibrin gels alone. Comparing stable fibrin gels and TissuCol as hydrogel components, it was found that TissuCol gels were less resilient to degradation and contraction. Composite constructs were fully characterized, showing good cell viability of ASCs and strong adipogenic development as indicated by functional analysis via histological Oil Red O staining of lipid vacuoles, qRT-PCR analysis of prominent adipogenic markers (PPARγ, C/EBPα, GLUT4, aP2) and quantification of leptin secretion. In a pilot study in vivo, investigating the suitability of the constructs for transplantation, stable fibrin/PU composites provided with a vascular pedicle gave rise to areas of well-vascularized adipose tissue, contrasted by insufficient capillary formation and adipogenesis in constructs implanted without pedicle. The biomaterial combination of stable fibrin gels and porous biodegradable PU scaffolds was thereby shown highly suitable for the generation of volume-stable adipose tissue constructs in vivo, and in addition, the effectiveness of immediate vascularization upon implantation to support adipose tissue formation was demonstrated (Chapter 4).
Further pursuing the objective to investigate adequate vascularization strategies for engineered adipose tissue, hypoxic preconditioning was conducted as a possible approach for in vitro prevascularization. In 2D culture experiments, analysis on the cellular level illustrated that the adipogenic potential of ASCs was reduced under hypoxic conditions when applied in the differentiation phase, irrespective of the oxygen tension encountered by the cells during expansion. Hypoxic treatment of ASCs in 3D constructs prepared from stable fibrin gels similarly resulted in reduced adipogenesis, whereas endothelial CD31 expression as well as enhanced leptin and vascular endothelial growth factor (VEGF) secretion indicated that hypoxic treatment indeed resulted in a pro-angiogenic response of ASCs. Especially the observed profound regulation of leptin production by hypoxia and the dual role of leptin as adipokine and angiogenic modulator were considered an interesting connection advocating further study. Having confirmed the hypothesis that hypoxia may generate a pro-angiogenic milieu inside ASC-seeded constructs, faster vessel ingrowth and improved vascularization as well as an enhanced tolerance of hypoxia-treated ASCs towards ischemic conditions upon implanatation may be expected, but remain to be verified in rodent models in vivo (Chapter 5).
Having previously been utilized for bone and cartilage engineering [17-19], as well as for revascularization and wound healing applications [20-22], stromal-vascular fraction (SVF) cells were investigated as a novel cell source for adipose tissue engineering. Providing cells with adipogenic differentiation as well as vascularization potential, the SVF was applied with the specific aim to promote adipogenesis and vascularization in engineered constructs in vivo. With only basic in vitro investigations by Lin et al. addressing the SVF for adipose repair to date [23], the present work thoroughly investigated SVF cells for adipose tissue construct generation in vitro, and in particular, pioneered the application of these cells for adipose tissue engineering in vivo.
Initial in vitro experiments compared SVF- and ASC-seeded stable fibrin constructs in different medium compositions employing preadipocyte (PGM-2) and endothelial cell culture medium (EGM-2). It was found that a 1:1 mixture of PGM-2 and EGM-2, as previously established for co-culture models of adipogenesis [24], efficiently maintained cells with adipogenic and endothelial potential in SVF-seeded constructs in short and long-term culture setups. Observations on the cellular level were supported by analysis of mRNA expression of characteristic adipogenic and endothelial markers. In preparation of the evaluation of SVF-seeded constructs under in vivo conditions, a whole mount staining (WMS) method, facilitating the 3D visualization of adipocytes and blood vessels, was successfully established and optimized using native adipose tissue as template (Chapter 6).
In a subcutaneous nude mouse model, SVF cells were, for the first time in vivo, elucidated for their potential to support the functional assembly of vascularized adipose tissue. Investigating the effect of adipogenic precultivation of SVF-seeded stable fibrin constructs in vitro prior to implantation on the in vivo outcome, hormonal induction was shown beneficial in terms of adipocyte development, whereas a strong vascularization potential was observed when no adipogenic inducers were added. Via histological analysis, it was proven that the developed structures were of human origin and derived from the implanted cells. Applying SVF cells without precultivation in vitro but comparing two different fibrin carriers, namely stable fibrin and TissuCol gels, revealed that TissuCol profoundly supported adipose formation by SVF cells in vivo. This was contrasted by only minor SVF cell development and a strong reduction of cell numbers in stable fibrin gels implanted without precultivation. Histomorphometric analysis of adipocytes and capillary structures was conducted to verify the qualitative results, concluding that particularly SVF cells in TissuCol were highly suited for adipose regeneration in vivo. Employing the established WMS technique, the close interaction of mature adipocytes and blood vessels in TissuCol constructs was impressively shown and via species-specific human vimentin staining, the expected strong involvement of implanted SVF cells in the formation of coherent adipose tissue was confirmed (Chapter 7).
With the development of biodegradable volume-stable adipose tissue constructs, the application of ASCs and SVF cells as two promising cell sources for functional adipose regeneration, as well as the thorough evaluation of strategies for construct vascularization in vitro and in vivo, this thesis provides valuable solutions to current challenges in adipose tissue engineering. The presented findings further open up new perspectives for innovative treatments to cure soft tissue defects and serve as a basis for directed approaches towards the generation of clinically applicable soft tissue substitutes.
SNAP25 (Synaptosomal-Associated Protein of 25 kDa; part of the SNARE complex) is involved in the docking and fusion of synaptic vesicles in presynaptic neurons necessary for the regulation of neurotransmitter release, as well as in axonal growth and synaptic plasticity. In humans, different single nucleotide polymorphisms of SNAP25 have repeatedly been associated with attention deficit/hyperactivity disorder (ADHD). Thus, in this study heterozygous Snap25 knockout mice were investigated as a model of ADHD.
Heterozygous (+/-) Snap25 knockout mice as well as their wild-type (+/+) littermates were reared under control conditions or underwent a Maternal Separation (MS) procedure. Starting at the age of 2 months, mice were tested for locomotor activity in a repeated long-term Open Field (OF) task, for attention deficits and impulsive behavior in the 5 Choice Serial Reaction Time Task (5CSRTT), for anxiety-like behavior in the Light-Dark Box (LDB) and for depression-like behavior in the Porsolt Forced Swim Test (FST). The brains of these mice were subsequently tested for the expression of several ADHD related genes in a quantitative Real-Time PCR (qRT-PCR) study. Another group of female mice (+/+; +/-) underwent a one hour OF test after oral administration of 45 mg/kg Methylphenidate (MPH) or placebo.
To find an optimized dosage for this MPH challenge, a pilot study was performed. Wild-type C57BL/6 mice were tested in a long-term OF with several dosages of MPH both intraperitoneally (i.p.) and orally. The brains of these animals were afterwards investigated for neurotransmitter concentrations. In this pilot study the dosages of MPH that were similarly behaviorally effective without causing symptoms of overdosing were 7.5-15 mg/kg intraperitoneally and 30-60 mg/kg orally. However, even though it was possible to find intraperitoneal and oral doses that correlate behaviorally, the neurochemistry was mostly different.
In the study on Snap25-deficient mice, unstressed controls showed a hyperactive phenotype in the second of two long-term OF sessions (60 min) spaced three weeks apart. Considering all groups, there was a significant interaction of stress and genotype in the second session, with animals subjected to MS being overall hyperactive with no genotype differences. In the training phase of the 5CSRTT only effects of stress were found, with MS animals finding and consuming fewer rewards. In the single test trial, several genotype effects became apparent, with tendencies for the number of correct nose pokes and the number of rewards eaten, and a significant effect for the number of rewards eaten directly after the correct response. In all of these variables +/- mice performed worse than their wild-type littermates. In the LDB +/- mice entered the lit compartment of the arena earlier than the controls, thus showing attenuated anxiety-like behavior. Regarding depressive-like behavior in the FST, male +/- mice spent significantly less time struggling than male +/+ mice. In the gene expression study, +/- mice had lower expression levels of Maoa and Comt, and higher expression levels of Nos1 than wild-types. Finally, the locomotor activity response to MPH was exaggerated in +/- mice as compared to controls.
Heterozygous Snap25 knockout mice show some of the behavioral characteristics of ADHD, as for example a mild hyperactivity in a familiar environment, difficulties in the correct execution of a given task and even some behavior that can be interpreted as delay aversion. Additionally, expression levels of three ADHD related genes were changed in these animals. Although the exaggerated locomotor activity response to MPH is not to be expected of an ADHD model, the difference in the response between +/+ and +/- mice nonetheless implicates a potential dysfunction of the brain dopaminergic system.
Abstract
Tobacco addiction is considered as a chronic relapsing disorder, characterized by compul-sive drug seeking and intake. Learning processes are stressed to account for the situational-specific expression of core features of the disorder, e.g., craving for drug, tolerance and ex-cessive consumption. According to incentive theories, smoke conditioned stimuli are hy-pothesized to be appetitive in nature, promoting craving, approach and consummatory be-havior. Commonly, smoking cues are treated as simple excitatory conditioned stimuli formed by a close and reliable overlap with the drug effect. However, the smoking ritual comprises a multitude of stimuli which may give rise to different forms of learning and con-ditioned responses partially opposing each other. Previous research suggests the predictive content and the temporal proximity of smoking stimuli to the drug effect as important de-terminants of cue reactivity. In contrast to stimuli related to the preparatory stage of smok-ing and the start of consumption (BEGIN stimuli), stimuli from the terminal stage of smok-ing (END stimuli) apparently lack high cue reactivity. Several lines of evidence suggest the poor cue properties of terminal stimuli to be related to their signaling of poor smoke availa-bility. Indeed, cue reactivity is commonly decreased when smoking appears to be unavaila-ble. Moreover, the learning literature suggests that stimuli predictive for the non-availability of reward may acquire the capacity to modulate or oppose the responses of ex-citatory conditioned stimuli. Therefore, the aim of the present thesis was to enhance our knowledge of stimulus control in human drug addiction and incentive motivation by running a series of conditioning studies with smoke intake and monetary reward as reinforcer. Sub-jective report and physiological measures of motivational valence and consummatory re-sponse tendencies were used as dependent variables.
The first experiment of this thesis used a differential conditioning paradigm to reveal evi-dence for the conditioning of preparatory and consummatory responses to a CS+ for smok-ing. Neutral pictograms served as CSs and single puffs on a cigarette as US. In line with the predictions of incentive theories, the excitatory CS+ for smoking acquired the ability to evoke an appetitive conditioned response, as indicated by enhanced activity of the M. zy-gomaticus major. Moreover, anticipation of puffing on the cigarette increased the activity of the M. orbicularis oris (lip muscle), indicating the activation of consummatory response tendencies. Finally, the CS+ evoked stronger skin conductance responses, indicative of in-creased autonomic arousal and orienting in preparation for action. In contrast, the rating data were apparently unaffected by the experimental contingency. In sum, the physiological data provide support for the notion that excitatory smoke conditioning gives rise to appeti-tive and consummatory conditioned responses, which may at least partially contribute to the maintenance of tobacco addiction.
The second experiment of this thesis adapted the conditioning protocol of the first study to probe the functional significance of terminal stimuli in the control of addictive behavior. This study manipulated the predictive relationship of BEGIN and END stimuli to smoke rein-forcement to provide further support for the differential reactivity to both stimuli and the retarded (i.e., delayed) conditioning of END stimuli. Overall, the results of the first study of this thesis were conceptually replicated as the association of a BEGIN stimulus with smoke intake resulted in the acquisition of appetitive and consummatory physiological responses. Importantly, the results revealed evidence for a retarded excitatory conditioning of END stimuli. Thus, pairing of an END stimulus with smoke intake failed to produce a conditioned discrimination in terms of motivational valence and autonomic arousal, as indicated by the activity of the M. corrugator supercilii and the skin conductance data. These results provide further support for the notion that END stimuli may be weak cues for smoking. Moreover, in light of the results of the first study of this thesis, the retarded excitatory conditioning of terminal stimuli may be suggestive of an inhibitory response component, which may be re-lated to their signaling of poor smoke availability. In sum, these results add to a growing body of data, which suggest that the expression of cue reactivity may be modulated by the temporal proximity and the availability of the drug effect.
The aim of the third study of this thesis was to provide “proof of concept” for an inhibi-tory conditioning notion of terminal stimuli. In this analog study BEGIN and END stimuli were emulated as discriminative SD and S for monetary reward. During an acquisition phase conditioned inhibition was established to the S predictive of the non-availability of re-ward. Subsequently a retardation test was used to substantiate conditioned inhibition. In this test, excitatory conditioning of the previous S was compared to the excitatory condi-tioning of a novel control stimulus. Importantly, the results revealed evidence for reward conditioned inhibition as indicated by the retarded acquisition of subjective (pleasure and reward expectancy) and physiological (skin conductance and activity of the M. orbicularis oculi) responses. In sum, these results provide support for the notion that stimuli predictive for the non-availability of reward may acquire the capacity to oppose the responses of ex-citatory conditioned stimuli. Thus, future research may benefit from the consideration of inhibitory conditioning processes in drug addiction, which may be of theoretical, methodo-logical and clinical importance.
In sum, the present thesis revealed evidence for 1) an appetitive nature of excitatory condi-tioned smoking cues, 2) the dependency of this learning process on the temporal position of the conditioned stimuli in the intake ritual and 3) the acquisition of conditioned inhibition by a stimulus predictive for the non-availability of reward, as evident in retarded excitatory conditioning. Overall, these studies made a novel contribution to the field of human drug addiction and incentive motivation and provided valuable suggestions for further research.
Numerical Simulations of Heavy Fermion Systems: From He-3 Bilayers to Topological Kondo Insulators
(2014)
Even though heavy fermion systems have been studied for a long time, a strong interest in heavy fermions persists to this day. While the basic principles of local moment formation, Kondo effect and formation of composite quasiparticles leading to a Fermi liquid, are under- stood, there remain many interesting open questions. A number of issues arise due to the interplay of heavy fermion physics with other phenomena like magnetism and superconduc- tivity.
In this regard, experimental and theoretical investigations of He-3 can provide valuable insights. He-3 represents a unique realization of a quantum liquid. The fermionic nature of He-3 atoms, in conjunction with the absence of long-range Coulomb repulsion, makes this material an ideal model system to study Fermi liquid behavior.
Bulk He-3 has been investigated for quite some time. More recently, it became possible to prepare and study layered He-3 systems, in particular single layers and bilayers. The pos- sibility of tuning various physical properties of the system by changing the density of He-3 and using different substrate materials makes layers of He-3 an ideal quantum simulator for investigating two-dimensional Fermi liquid phenomenology.
In particular, bilayers of He-3 have recently been found to exhibit heavy fermion behavior. As a function of temperature, a crossover from an incoherent state with decoupled layers to a coherent Fermi liquid of composite quasiparticles was observed. This behavior has its roots in the hybridization of the two layers. The first is almost completely filled and subject to strong correlation effects, while the second layer is only partially filled and weakly correlated. The quasiparticles are formed due to the Kondo screening of localized moments in the first layer by the second-layer delocalized fermions, which takes place at a characteristic temperature scale, the coherence scale Tcoh.
Tcoh can be tuned by changing the He-3 density. In particular, at a certain critical filling,
the coherence scale is expected to vanish, corresponding to a divergence of the quasiparticle effective mass, and a breakdown of the Kondo effect at a quantum critical point. Beyond the critical point, the layers are decoupled. The first layer is a local moment magnet, while the second layer is an itinerant overlayer.
However, already at a filling smaller than the critical value, preempting the critical point, the onset of a finite sample magnetization was observed. The character of this intervening phase remained unclear.
Motivated by these experimental observations, in this thesis the results of model calcula- tions based on an extended Periodic Anderson Model are presented. The three particle ring exchange, which is the dominant magnetic exchange process in layered He-3, is included in the model. It leads to an effective ferromagnetic interaction between spins on neighboring sites. In addition, the model incorporates the constraint of no double occupancy by taking the limit of large local Coulomb repulsion.
By means of Cellular DMFT, the model is investigated for a range of values of the chemical potential µ and inverse temperature β = 1/T . The method is a cluster extension to the Dy- namical Mean-Field Theory (DMFT), and allows to systematically include non-local correla- tions beyond the DMFT. The auxiliary cluster model is solved by a hybridization expansion CTQMC cluster solver, which provides unbiased, numerically exact results for the Green’s function and other observables of interest.
As a first step, the onset of Fermi liquid coherence is studied. At low enough temperature, the self-energy is found to exhibit a linear dependence on Matsubara frequency. Meanwhile, the spin susceptibility crossed over from a Curie-Weiss law to a Pauli law. Both observations serve as fingerprints of the Fermi liquid state.
The heavy fermion state appears at a characteristic coherence scale Tcoh. This scale depends strongly on the density. While it is rather high for small filling, for larger filling Tcoh is increas- ingly suppressed. This involves a decreasing quasiparticle residue Z ∼ Tcoh and an enhanced mass renormalization m∗/m ∼ Tcoh−1. Extrapolation leads to a critical filling, where the co-
herence scale is expected to vanish at a quantum critical point. At the same time, the effective mass diverges. This corresponds to a breakdown of the Kondo effect, which is responsible for the formation of quasiparticles, due to a vanishing of the effective hybridization between the layers.
Taking only single-site DMFT results into account, the above scenario seems plausible. However, paramagnetic DMFT neglects the ring exchange interaction completely. In or- der to improve on this, Cellular DMFT simulations are conducted for small clusters of size Nc = 2 and 3. The results paint a different physical picture. The ring exchange, by favor- ing a ferromagnetic alignment of spins, competes with the Kondo screening. As a result, strong short-range ferromagnetic fluctuations appear at larger values of µ. By lowering the temperature, these fluctuations are enhanced at first. However, for T < Tcoh they are increas- ingly suppressed, which is consistent with Fermi liquid coherence. However, beyond a certain threshold value of µ, fluctuations persist to the lowest temperatures. At the same time, while not apparent in the DMFT results, the total occupation n increases quite strongly in a very narrow range around the same value of µ. The evolution of n with µ is always continuous, but hints at a discontinuity in the limit Nc → ∞. This first-order transition breaks the Kondo effect. Beyond the transition, a ferromagnetic state in the first layer is established, and the second layer becomes a decoupled overlayer.
These observations provide a quite appealing interpretation of the experimental results. As a function of chemical potential, the Kondo breakdown quantum critical point is preempted by a first-order transition, where the layers decouple and the first layer turns into a ferromagnet. In the experimental situation, where the filling can be tuned directly, the discontinuous transition is mirrored by a phase separation, which interpolates between the Fermi liquid ground state at lower filling and the magnetic state at higher filling. This is precisely the range of the intervening phase found in the experiments, which is characterized by an onset of a finite sample magnetization.
Besides the interplay of heavy fermion physics and magnetic exchange, recently the spin- orbit coupling, which is present in many heavy fermion materials, attracted a lot of interest. In the presence of time-reversal symmetry, due to spin-orbit coupling, there is the possibility of a topological ground state.
It was recently conjectured that the energy scale of spin-orbit coupling can become dom- inant in heavy fermion materials, since the coherence scale and quasiparticle bandwidth are rather small. This can lead to a heavy fermion ground state with a nontrivial band topology; that is, a topological Kondo insulator (TKI). While being subject to strong correlation effects, this state must be adiabatically connected to a non-interacting, topological state.
The idea of the topological ground state realized in prototypical Kondo insulators, in par- ticular SmB6, promises to shed light on some of the peculiarities of these materials, like a residual conductivity at the lowest temperatures, which have remained unresolved so far.
In this work, a simple two-band model for two-dimensional topological Kondo insulators is devised, which is based on a single Kramer’s doublet coupled to a single conduction band. The model is investigated in the presence of a Hubbard interaction as a function of interaction strength U and inverse temperature β. The bulk properties of the model are obtained by DMFT, with a hybridization expansion CTQMC impurity solver. The DMFT approximation of a local self-energy leads to a very simple way of computing the topological invariant.
The results show that with increasing U the system can be driven through a topological phase transition. Interestingly, the transition is between distinct topological insulating states, namely the Γ-phase and M-phase. This appearance of different topological phases is possible due to the symmetry of the underlying square lattice. By adiabatically connecting both in- teracting states with the respective non-interacting state, it is shown that the transition indeed drives the system from the Γ-phase to the M-phase.
A different behavior can be observed by pushing the bare position of the Kramer’s doublet to higher binding energies. In this case, the non-interacting starting point has a trivial band topology. By switching on the interaction, the system can be tuned through a quantum phase transition, with a closing of the band gap. Upon reopening of the band gap, the system is in the Γ-phase, i. e. a topological insulator. By increasing the interaction strength further, the system moves into a strongly correlated regime. In fact, close to the expected transition to the M phase, the mass renormalization becomes quite substantial. While absent in the para- magnetic DMFT simulations conducted, it is conceivable that instead of a topological phase transition, the system undergoes a time-reversal symmetry breaking, magnetic transition.
The regime of strong correlations is studied in more detail as a function of temperature, both in the bulk and with open boundary conditions. A quantity which proved very useful is the bulk topological invariant Ns, which can be generalized to finite interaction strength and temperature. In particular, it can be used to define a temperature scale T ∗ for the onset of the topological state. Rescaling the results for Ns, a nice data collapse of the results for different values of U, from the local moment regime to strongly mixed valence, is obtained. This hints at T ∗ being a universal low energy scale in topological Kondo insulators. Indeed, by comparing T ∗ with the coherence scale extracted from the self-energy mass renormalization, it is found that both scales are equivalent up to a constant prefactor. Hence, the scale T ∗ obtained from the temperature dependence of topological properties, can be used as an independent measure for Fermi liquid coherence. This is particularly useful in the experimentally relevant mixed valence regime, where charge fluctuations cannot be neglected. Here, a separation of the energy scales related to spin and charge fluctuations is not possible.
The importance of charge fluctuations becomes evident in the extent of spectral weight transfer as the temperature is lowered. For mixed valence, while the hybridization gap emerges, a substantial amount of spectral weight is shifted from the vicinity of the Fermi level to the lower Hubbard band. In contrast, this effect is strongly suppressed in the local moment regime.
In addition to the bulk properties, the spectral function for open boundaries is studied as a function of temperature, both in the local moment and mixed valence regime. This allows an investigation of the emergence of topological edge states with temperature. The method used here is the site-dependent DMFT, which is a generalization of the conventional DMFT to inhomogeneous systems. The hybridization expansion CTQMC algorithm is used as impurity solver.
By comparison with the bulk results for the topological quantity Ns, it is found that the
temperature scale for the appearance of the topological edge states is T ∗, both in the mixed valence and local moment regime.
The auditory system is an exquisitely complex sensory organ dependent upon the synchronization of numerous processes for proper function. The molecular characterization of hereditary hearing loss is complicated by extreme genetic heterogeneity, wherein hundreds of genes dispersed genome-wide play a central and irreplaceable role in normal hearing function. The present study explores this area on a genome-wide and single gene basis for the detection of genetic mutations playing critical roles in human hearing.
This work initiated with a high resolution SNP array study involving 109 individuals. A 6.9 Mb heterozygous deletion on chromosome 4q35.1q35.2 was identified in a syndromic patient that was in agreement with a chromosome 4q deletion syndrome diagnosis. A 99.9 kb heterozygous deletion of exons 58-64 in USH2A was identified in one patient. Two homozygous deletions and five heterozygous deletions in STRC (DFNB16) were also detected. The homozygous deletions alone were enough to resolve the hearing impairment in the two patients. A Sanger sequencing assay was developed to exclude a pseudogene with a high percentage sequence identity to STRC from the analysis, which further solved three of the six heterozygous deletion patients with the hemizygous, in silico predicted pathogenic mutations c.2726A>T (p.H909L), c.4918C>T (p.L1640F), and c.4402C>T (p.R1468X). A single patient who was copy neutral for STRC and without pathogenic copy number variations had compound heterozygous mutations [c. 2303_2313+1del12 (p.G768Vfs*77) and c.5125A>G (p.T1709A)] in STRC. It has been shown that STRC has been previously underestimated as a hearing loss gene. One additional patient is described who does not have pathogenic copy number variation but is the only affected member of his family having hearing loss with a paternally segregating translocation t(10;15)(q26.13;q21.1).
Twenty-four patients without chromosomal aberrations and the above described patient with an USH2A heterozygous deletion were subjected to a targeted hearing loss gene next generation sequencing panel consisting of either 80 or 129 hearing-relevant genes. The patient having the USH2A heterozygous deletion also disclosed a second mutation in this gene [c.2276G>T (p.C759F)]. This compound heterozygous mutation is the most likely cause of hearing loss in this patient. Nine mutations in genes conferring autosomal dominant hearing loss [ACTG1 (DFNA20/26); CCDC50 (DFNA44); EYA4 (DFNA10); GRHL2 (DFNA28); MYH14 (DFNA4A); MYO6 (DFNA22); TCF21 and twice in MYO1A (DFNA48)] and four genes causing autosomal recessive hearing loss were detected [GJB2 (DFNB1A); MYO7A (DFNB2); MYO15A (DFNB3), and USH2A]. Nine normal hearing controls were also included. Statistical significance was achieved comparing controls and patients that revealed an excess of mutations in the hearing loss patients compared to the control group. The family with the GRHL2 c.1258-1G>A mutation is only the second family published worldwide with a mutation described in this gene to date, supporting the initial claim of this gene causing DFNA28 hearing loss. Audiogram analysis of five affected family members uncovered the progressive nature of DFNA28 hearing impairment. Regression analysis predicted the annual threshold deterioration in each of the five family members with multiple audiograms available over a number of years.
The contribution of botanical gardens to out-of-school education should be larger than it is currently in Germany. In the curricula of all school types botany plays only a minor role, although plants form the base for all animal life on earth. To increase the attractiveness of botanical gardens for teachers, offers and programs should be created and conducted in didactically sensible manners and allow students an emotional approach towards the topics through trial and experiments. Therefore it is insufficient to conduct guided tours, which are still most common. Student-centered methods, like learning at workstations, or experimental courses, can lead to an improved retention of the contents learned at the out-of-school learning setting. There are, however, methodological differences even within learning at workstations.
In the first part of my study I compared a student- (S) and a teacher-centered (T) type of learning at workstations (chapter III). My intention was to find out, which of both methods results in more positive emotions at the out-of-school learning location and a higher sustainable knowledge increase. Like in all three parts of my study, 8th grade students from so-called “Mittelschulen” and “Realschulen” from Lower Franconia participated in the programs. I evaluated them by using multiple-choice tests assessing the students' knowledge regarding the topic 'plants and water' (see Appendix), following a before-after / control-impact study design. The students' emotions were assessed using the intrinsic motivation inventory directly after the garden visit. Using generalized linear mixed models, I did not find a significant difference between either of the two approaches. A reason for this could be that the students could be practically active in both methods, which made them fairly similar. Given that there was a significant knowledge increase in both methods, and the effort to develop the teacher-centered learning at workstations was much lower, I would suggest to follow that method for educational work in botanical gardens.
Students already have many predefined concepts regarding many topics, especially when these are important in everyday life. These concepts do often not match the scientific state-of-the-art. Still, students bring their so-called 'alternative conceptions' into visits to the botanical garden. According to theory, confronting them with their own conceptions in the light of scientific facts, should foster updating their concepts with scientifically correct additions. To investigate this method regarding my topic 'plants and water', I developed an intervention with experiments on the lotus effect, which also plays a role in everyday life (chapter IV). Topics like the surface tension of the water, which is also found in 6th grade curricula in German schools, were included. Prior to the intervention, I assessed the students' conceptions using questionnaires and used the three most frequent alternative conceptions to develop a multiple-choice test, which was also used in a before-after / control-impact design. A group of students was also confronted with their conceptions during an introductory talk (AC), whereas another was not (NAC). This was conducted in a way, that likely led to dissatisfaction of the students with their own concepts. The analysis of the questionnaires with the Mann-Whitney U test showed, however, no difference between the two groups directly following the treatment. Over longer time, however, the NAC group retained significantly more knowledge. Probably the students confronted with the alternative conceptions remembered the illustrations of these more easily than the scientifically correct view. For some botanical topics it is certainly helpful to include this conceptual change approach, but apparently not for the lotus effect. In this case it is most sensible to focus on the surface structure of water-repellent leaves and fruits, as we describe it in a publication in 'Unterricht Biologie'. For the practical work in botanical gardens I would suggest to rather assess the students' concepts and assumptions in the beginning of an intervention in a botanical garden, especially with respect to feasibility.
In the third part of my study I concentrate on the application of concept maps (chapter V). This method of cross-linking old and newly acquired knowledge is effective, but not very common in Germany, neither in schools, nor in botanical gardens. One group of students followed exclusively a teacher-centered learning at workstations regarding 'plants and water' (NCM), a second group created concept maps directly after the treatment and a second directly before the retention test (CM). The first map was intended to be a means of consolidation, whereas the late map was rather focused on recapitulation of what was learned about six weeks ago. To evaluate that I used the same multiple-choice tests as I did for the first part. The CM group showed a significantly higher knowledge increase, over short and long time-scales, although these students did significantly worse in the pretest than those of the NCM group. Regarding genders, female students profited especially from the first concept map (consolidation), males rather from the second (recapitulation). From the results one can conclude that prominently weaker students benefit from this method. Additionally the gender-related results show that using concept maps multiple times can be beneficial for different types of learners.
In every study there also was a control group (C), which only had to fill out the questionnaires at the same time as the participating students, to account for external factors (like media, etc.).
Especially learning at workstations and concept maps are very appropriate to be conducted at the out-of-school learning location botanical garden and are likely to strongly increase learning success. It is beneficial to mix several methods to achieve the best results in different types of learners. Additionally, when methods in school are mixed with those of out-of-school learning, the education gets more open, practical and colorful. That all resulted in a substantial long-term knowledge gain of all participating students.
This thesis describes the epitaxial growth of the Half-Heusler alloy NiMnSb by molecular beam epitaxy. Its structural and magnetic properties are controlled by tuning the composition and the resulting small deviation from stoichiometry. The magnetic in-plane anisotropy depends on the Mn concentration of the sample and can be controlled in both strength and orientation. This control of the magnetic anisotropy allows for growing NiMnSb layers of a given thickness and magnetic properties as requested for the design of NiMnSb-based devices. The growth and characterization of NiMnSb-ZnTe-NiMnSb heterostructures is presented - such heterostructures form an all-NiMnSb based spin-valve and are a promising basis for spin torque devices.
I. Nowadays, tropical landscapes experience large-scale land use intensification and land conversion driven by increasing demand for resourses. Due to the continuously high demand for tropical timber and politically intended step increase in palm oil production, multiple rounds of logging and subsequent conversion to oil palm plantations became a regionally wide-spread land conversion pattern in Southeast Asia. Although many tree species and some animals are highly threatened by logging, a great number of species groups, such as birds or mammals, have been shown to persist in logged forests. Accordingly, many ecosystem services, such as dung removal, seed dispersal or the activity of scavengers, are functionally maintained in logged forests. In contrast, oil palm plantations have been shown to not only dramatically alter the species composition and reduce biodiversity, but also curtail many crucial biotic and abiotic ecosystem functions. The focus of this dissertation was to investigate the response of anuran species richness and community composition to logging and conversion to oil palm plantation in northern Borneo (chapter II). I analysed the diet of various frog species and their change with habitat degradation. Furthermore, I assessed the shift in the trophic position of the anuran community as well as the response of anuran phylogenetic, dietary, and functional diversity to logging and conversion to oil palm plantations (chapter III). Finally, the resilience of the predator-prey interaction between an ant-specialist toad and its ant prey was analysed using shifts in species-level interactions (chapter IV).
II. This part of the study compares the species richness, relative abundance and community composition of stream anuran assemblages among primary forests, repeatedly logged forests and oil palm plantations. I used a highly standardised sampling setup applying transect-based sampling. Surprisingly, most of the anuran species native to primary forests were able to survive in logged forest streams. In contrast, on average only one third of the forest species richness was found in oil palm plantation streams. However, a high percentage of canopy cover above the plantation streams was able to mitigate this loss substantially. This study demonstrates the high conservation value of logged forests for Southeast Asian anurans. In contrast, the conversion to oil palm plantations leads to a dramatic decline of forest species. However, they have a mainly unused potential to contribute to the protection of parts of the regional anuran biodiversity if conservation-oriented management options are implemented.
III. In this part, I analysed the shifts in trophic position and multiple diversity layers of Southeast Asian stream-dependent anuran species across a gradient of disturbance from primary forest through intensively logged forest to oil palm plantation. For this purpose, I identified the diet composition of 59 anuran species by means of stomach flushing. Furthermore, I use diet composition of frog species as well as species traits to calculate dietary and functional diversity, respectively. I found that the trophic position of the entire anuran community is elevated in heavily disturbed habitats. Furthermore, species diversity, phylogenetic species variation, dietary diversity, and functional diversity were reduced. However, beyond the effect of the decreased species richness, only phylogenetic species variability and functional diversity were significantly impacted by land conversion, indicating a non-random loss of phylogenetic groups and functionally unique species. Overall, the observed changes to species interactions and functional composition suggest a greatly modified role of anurans in altered habitats and major foodweb reorganisation. Such far-reaching changes to the way species groups interact are likely to threaten local biodiversity and ecosystem functioning in natural and particularly modified habitats. However, I could also show, that small-scale habitat quality, provided by riparian reserves, is able to mitigate the negative consequences of land conversion considerably.
IV. Here I assess how logging of rain forest and conversion to oil palm plantations affect the populations of the ant-specialist giant river toad (Phrynoidis juxtaspera), and availability and composition of its ant prey. I measured canopy cover as an estimate for the degree of disturbance. I found that toad abundance decreased with increasing disturbance. At the same time, ant community composition was altered, and local ground-foraging ant species richness increased with disturbance. However, for a given amount of canopy cover, primary forest supported more ant species than altered habitats. Despite these changes, composition of ants consumed by toads was only weakly affected by habitat change, with the exception of the invasive yellow crazy ant (Anoplolepis gracilipes), which was positively selected in oil palm plantations. This suggests that predator-prey interactions can be mostly maintained with habitat disturbance despite shifts in community composition, and even that some predators are capable of exploiting new prey sources in novel ecosystems.
V. I could show that anuran diversity and their trophic interaction is negatively impacted by logging and in particular by conversion to oil palm plantations. From species richness and community composition, my study expanded to phylogenetic, dietary and functional diversity. Furthermore, I investigated the interaction of a particular toad species with its preferred prey (ants), on species level. This increasing degree of detail in my study provided comprehensive results, beyond the detail of many related studies. Overall, conservation of the remaining forest in Southeast Asia is urgently required to protect anuran biodiversity and their trophic interactions.
The first part of this thesis deals with the approximability of the traveling salesman problem. This problem is defined on a complete graph with edge weights, and the task is to find a Hamiltonian cycle of minimum weight that visits each vertex exactly once. We study the most important multiobjective variants of this problem. In the multiobjective case, the edge weights are vectors of natural numbers with one component for each objective, and since weight vectors are typically incomparable, the optimal Hamiltonian cycle does not exist. Instead we consider the Pareto set, which consists of those Hamiltonian cycles that are not dominated by some other, strictly better Hamiltonian cycles. The central goal in multiobjective optimization and in the first part of this thesis in particular is the approximation of such Pareto sets.
We first develop improved approximation algorithms for the two-objective metric traveling salesman problem on multigraphs and for related Hamiltonian path problems that are inspired by the single-objective Christofides' heuristic. We further show arguments indicating that our algorithms are difficult to improve. Furthermore we consider multiobjective maximization versions of the traveling salesman problem, where the task is to find Hamiltonian cycles with high weight in each objective. We generalize single-objective techniques to the multiobjective case, where we first compute a cycle cover with high weight and then remove an edge with low weight in each cycle. Since weight vectors are often incomparable, the choice of the edges of low weight is non-trivial. We develop a general lemma that solves this problem and enables us to generalize the single-objective maximization algorithms to the multiobjective case. We obtain improved, randomized approximation algorithms for the multiobjective maximization variants of the traveling salesman problem. We conclude the first part by developing deterministic algorithms for these problems.
The second part of this thesis deals with redundancy properties of complete sets. We call a set autoreducible if for every input instance x we can efficiently compute some y that is different from x but that has the same membership to the set. If the set can be split into two equivalent parts, then it is called weakly mitotic, and if the splitting is obtained by an efficiently decidable separator set, then it is called mitotic. For different reducibility notions and complexity classes, we analyze how redundant its complete sets are.
Previous research in this field concentrates on polynomial-time computable reducibility notions. The main contribution of this part of the thesis is a systematic study of the redundancy properties of complete sets for typical complexity classes and reducibility notions that are computable in logarithmic space. We use different techniques to show autoreducibility and mitoticity that depend on the size of the complexity class and the strength of the reducibility notion considered. For small complexity classes such as NL and P we use self-reducible, complete sets to show that all complete sets are autoreducible. For large complexity classes such as PSPACE and EXP we apply diagonalization methods to show that all complete sets are even mitotic. For intermediate complexity classes such as NP and the remaining levels of the polynomial-time hierarchy we establish autoreducibility of complete sets by locally checking computational transcripts. In many cases we can show autoreducibility of complete sets, while mitoticity is not known to hold. We conclude the second part by showing that in some cases, autoreducibility of complete sets at least implies weak mitoticity.
It is natural to consider the possibility that the most energetic particles detected (> 10^18 eV), ultra-high-energy cosmic rays (UHECRs), are originated at the most luminous transient events observed (> 10^52 erg s^-1), gamma-ray bursts (GRBs). As a result of the interaction of highly-accelerated, magnetically-confined protons and ions with the photon field inside the burst, both neutrons and UHE neutrinos are expected to be created: the former escape the source and beta-decay into protons which propagate to Earth, where they are detected as UHECRs, while the latter, if detected, would constitute the smoking gun of hadronic acceleration in the sources.
Recently, km-scale neutrino telescopes such as IceCube have finally reached the sensitivities required to probe the neutrino predictions of some of the existing GRB models. On that account, we present here a revised, self-consistent model of joint UHE proton and neutrino production at GRBs that includes a state-of-the-art, improved numerical calculation of the neutrino flux (NeuCosmA); that uses a generalised UHECR emission model where some of the protons in the sources are able to "leak out" of their magnetic confinement before having interacted; and that takes into account the energy losses of the protons during their propagation to Earth. We use our predictions to take a close look at the cosmic ray-neutrino connection and find that the current UHECR observations by giant air shower detectors, together with the upper bounds on the flux of neutrinos from GRBs, are already sufficient to put tension on several possibilities of particle emission and propagation, and to point us towards some requirements that should be fulfilled by GRBs if they are to be the sources of the UHECRs. We further refine our analysis by studying a dynamical burst model, where we find that the different particle species originate at distinct stages of the expanding GRB, each under particular conditions. Finally, we consider a possibility of new physics: the effect of neutrino decay in the flux of UHE neutrinos from GRBs. On the whole, our results demonstrate that self-consistent models of particle production are now integral to the advancement of the field, given that the full picture of the UHE Universe will only emerge as a result of looking at the multi-messenger sky, i.e., at gamma-rays, cosmic rays, and neutrinos simultaneously.
The present thesis examines embodiment—the body’s influence on psychological processes. Bodily states, perceptions, and actions influence cognitive processes; for example, a heavy backpack makes hills look steeper (Proffitt et al., 2003); and faint odors influence orderliness (Holland, Hendriks, & Aarts, 2005). In Chapter 2, embodiment phenomena are reviewed and classified according to three possible underlying mechanisms. Additionally, empirical tests for distinguishing between the workings of these mechanisms are discussed.
The empirical part of the thesis examines one specific embodiment in more detail, namely embodied cleansing. The basic idea in embodied cleansing is that physical cleansing reduces not only physical but also psychological remnants of the past. For example, Chapter 4 examines whether prosocial behavior after one’s own moral or immoral behavior is changed by embodied cleansing; and Chapter 5 examines how changes in optimism and self-esteem as a result of previous success or failure in an achievement test are reduced by embodied cleansing.
The present thesis examines psychological mechanisms that could explain embodied cleansing. For that, Chapter 3 derives and contrasts two possible explanations for embodied cleansing. Chapter 4 tests the effect of physical cleansing when both explanations make converging predictions (with morally negative memories) compared to when the two explanations make differing predictions (with morally positive memories). However, the results of embodied cleansing on prosocial behavior after (im)moral recall could not be examined as (im)moral recall, against expectations, did not influence prosocial behavior in the present paradigm.
Chapter 5 more closely examines one of the two explanations. For that, different aspects of the act of cleaning one’s hands are varied to examine necessary and sufficient criteria for embodied cleansing. The results show that deliberate cleaning is essential for embodied cleansing; additionally the cleaning action has to refer to one’s own body (and not to an object). Thus, a combination of inferential and automatic processes seem to play a role in embodied cleansing. Finally the results are discussed in relation to other embodiment effects and explanations.
The infection of a eukaryotic host cell by a bacterial pathogen is one of the most intimate examples of cross-kingdom interactions in biology. Infection processes are highly relevant from both a basic research as well as a clinical point of view. Sophisticated mechanisms have evolved in the pathogen to manipulate the host response and vice versa host cells have developed a wide range of anti-microbial defense strategies to combat bacterial invasion and clear infections. However, it is this diversity and complexity that makes infection research so challenging to technically address as common approaches have either been optimized for bacterial or eukaryotic organisms. Instead, methods are required that are able to deal with the often dramatic discrepancy between host and pathogen with respect to various cellular properties and processes. One class of cellular macromolecules that exemplify this host-pathogen heterogeneity is given by their transcriptomes: Bacterial transcripts differ from their eukaryotic counterparts in many aspects that involve both quantitative and qualitative traits. The entity of RNA transcripts present in a cell is of paramount interest as it reflects the cell’s physiological state under the given condition. Genome-wide transcriptomic techniques such as RNA-seq have therefore been used for single-organism analyses for several years, but their applicability has been limited for infection studies.
The present work describes the establishment of a novel transcriptomic approach for infection biology which we have termed “Dual RNA-seq”. Using this technology, it was intended to shed light particularly on the contribution of non-protein-encoding transcripts to virulence, as these classes have mostly evaded previous infection studies due to the lack of suitable methods. The performance of Dual RNA-seq was evaluated in an in vitro infection model based on the important facultative intracellular pathogen Salmonella enterica serovar Typhimurium and different human cell lines. Dual RNA-seq was found to be capable of capturing all major bacterial and human transcript classes and proved reproducible. During the course of these experiments, a previously largely uncharacterized bacterial small non-coding RNA (sRNA), referred to as STnc440, was identified as one of the most strongly induced genes in intracellular Salmonella. Interestingly, while inhibition of STnc440 expression has been previously shown to cause a virulence defect in different animal models of Salmonellosis, the underlying molecular mechanisms have remained obscure. Here, classical genetics, transcriptomics and biochemical assays proposed a complex model of Salmonella gene expression control that is orchestrated by this sRNA. In particular, STnc440 was found to be involved in the regulation of multiple bacterial target mRNAs by direct base pair interaction with consequences for Salmonella virulence and implications for the host’s immune response. These findings exemplify the scope of Dual RNA-seq for the identification and characterization of novel bacterial virulence factors during host infection.
Assessing particle deposition in a representative in vitro model of the rat respiratory tract
(2014)
The aim of this thesis was to develop an in vitro model (IVR) of the rat lung for the purpose of investigating the deposition of drug particles in the rat airways. The model attempted to account for the affect of drug product characteristics and physiological parameters on deposition in the lungs. In addition, the model outputs were compared with in vivo lung deposition results from live rats and in silico predictions using published computer model of lung deposition in pre-clinical species.
Initial work focussed on developing an aerosol exposure system capable of dosing small rodent to a range of airborne test materials. The system consists of two main parts; a fluidised bed aerosol generator and connection of the generator output to a nose only exposure chamber capable of accommodating 12 small animals in a single layer. In addition, an aerodynamic particle spectrometer (APS) was installed for continuously measuring the size distribution and airborne concentration of aerosol particles generated in the exposure chamber. System validation showed acceptable degree of variation of the test material tested, Fluorescent Microspheres (FMS) throughout the exposure chamber (CV < 15.0%). Particle size (MMAD ± GSD) using the APS was shown to be stable throughout the exposure periods.
The IVR model developed in this project was based on a number of euthanased (n=7), female Sprague-Dawley rats (weight: 372 ± 56 g), which underwent high-resolution micro-CT scans. The physical model consisted of five sub sections; Extra-Thoracic region containing the snout and nasophyarynx, trachea-bronchial region containing the trachea, bronchi, and bronchioles. All sections of the model were attached to one another in numerical order and housed within a containment unit. At the rear end of the cast, a flexible diaphragm was attached in order to collect the fraction of inhaled particles exiting the TB section and possibly reaching the lung, referred to as the Post-TB section.
A study was conducted to assess the influence of inhalation parameters such as the breathing frequency and tidal volume on total and regional dose distribution using FMS as test material. The major finding of this study was the demonstration of the model sensitivity to changes in breathing parameters especially respiratory frequency, where the data showed increased deposition in the peripheral regions of the model with decreased respiratory frequency. Other studies assessed the effect of particle characteristics on deposition on the IVR model, such as particle size, dose increase and formulation changes.
The results assessing particle size effect showed a slightly higher deposition levels for the 4µm sized particles versus 2µm sized particles in the head region; 90.8 ± 3.6% and 88.2 ± 6.6%. However, this difference did not reach statistical significance (P> 0.05) probably due to the polydispersity of aerosolised FMS particles. In addition, the regional deposition analysis showed an increased lung peripheral deposition with the smaller particles. In addition, the model was shown to be sensitive to changes in formulation composition mediated by inclusion of MgSt.
The next stage of work was to validate the model in terms of comparison with lung deposition for in vivo rats. For lung deposition comparison, the absolute amount deposited in the IVR lung model (expressed as µg/kg) was shown to have a reasonably strong correlation with in vivo lung concentration measures (µg/kg); R2= 0.66, P < 0.05. Compounds were predicted well and within 2-folds of the measured lung deposition values. However, knowing the variability in biological systems and the multiple components required to estimate lung doses, predictions within 2-fold of the measured values would seem reasonable
In terms of comparison with in silico model predictions using MPPD, similar deposition levels were noted between the two models, particularly when the data was expressed as percentage of total particles inhaled. The data showed the highest deposition levels were noted in the head region (> 80%) and less than 5.0% deposition for the peripheral lung fractions.
With regards to using the IVR model to assess the relationship between dose, particle size and efficacy, an in vivo study using FP with different particle sizes (2.0 and 4.0 µm) but same doses ( 100 and 1000 µg/kg). This study demonstrated that exposure of rat to FP powder resulted in a dose-dependent inhibition of neutrophils in BAL fluids. However, a clear difference in neutrophils suppression was demonstrated for equivalent doses but different particle sizes of FP, where the smaller FP particles (2.0 µm) induced a greater level of neutrophils suppression in comparison with larger FP particles (4.0 µm). In addition, a reasonably good correlation for the relationship between lung deposition in the IVR model and a neutrophils suppression level was demonstrated. Furthermore this data support the hypothesis that regional deposition is an important determinant in efficacy. Therefore, this suggests that the IVR model may be a useful as a tool to describe in vivo efficacy with in vitro data. However, further studies should be conducted to evaluate the validity of this model and relationship.
The IVR model has a number of important limitations. First, the model is based on scans up to generation four of the rat respiratory tract as this represented the limits of the micro-CT scanning technology at the time of this study. Therefore deposition in the deeper region of the lung may not be reflected precisely in the IVR model. Second, the regional deposition data generated using the model tended to show an overestimation of deposition in head region and an underestimation of deposition in the peripheral regions of the lung, in comparison with in vivo lung deposition data. Third, the current model does not take into account lung clearance. However, the amount of the drug present in the in vivo lungs is dependent on numerous physiological processes such as dissolution, passive or active absorption into the systemic circulation, binding to lung tissue and mucociliary clearance. Consequently, the results generated using this IVR model for drug molecules with high lung clearance rate should be treated with some caution.
Future work extending this research could go in a number of directions. In this research, a representative model of the rat respiratory tract was constructed from analysis of imaging data from a number of euthanised Sprague-Dawley rats. This model represented the “average respiratory tract” in terms of dimensions of Sprague-Dawley rats. However, there is considerable variability in the airway dimensions between rats. This variability encompasses a number of factors such as the strains of rats, sex and age, and disease state. Thus, it may be possible to produce a small number of airway models to represent small and large rats and scaled to represent the extrathoracic and peripheral regions based on literature reports of their dimensions in different rat populations. This approach will then enable the effect of intersubject airway dimensions for different rat populations on aerosol deposition to be thoroughly examined.
In addition, due to the limitation of the micro-CT technology used to construct the physical IVR model, detailed morphology only up to generation 4 were captured. However, recent advances in MRI technology, such as the use of in situ-MRI based scanning technology have enabled rat airway morphometry to be extended to 16 airway generation. This coupled with improvements in the resolutions of rapid-prototyping process means it may be possible to construct a rat model that reflects the in vivo lung morphology more accurately, and thus enable greater understanding of the link between aerosol deposition and airway geometry.
In conclusion, a model cast of the rat lung was developed and validated to allow the deposition of inhaled particles in the rat lung to be investigated. The model may be used to estimate the lung concentration in vivo rats in preference to exposure concentration measurements based on filter samples which have been shown to be a poor indicator of the lung concentration immediately after exposure. In addition, the model has the potential to be used along with live rats in an inhalation rig in pulmonary pharmaceutics research and may facilitate in development of inhaled formulations to target specific regions within the lung as well as screening of inhaled drugs in preclinical setting.
WISP3 is a member of the CCN family which comprises six members found in the 1990’s: Cysteine-rich,angiogenic inducer 61 (CYR61, CCN1), Connective tissue growth factor (CTGF, CCN2), Nephroblastoma overexpressed (NOV, CNN3) and the Wnt1 inducible signalling pathway protein 1-3 (WISP1-3, CCN4-6).They are involved in the adhesion, migration, mitogenesis, chemotaxis, proliferation, cell survival, angiogenesis, tumorigenesis, and wound healing by the interaction with different integrins and heparan sulfate proteoglycans. Until now the only member correlated to the musculoskeletal autosomal disease Progressive Pseudorheumatoid Dysplasia (PPD) is WISP3. PPD is characterised by normal embryonic development followed by cartilage degradation over time starting around the age of three to eight years. Animal studies in mice exhibited no differences between knock out or overexpression compared to wild type litter mates, thus were not able to reproduce the symptoms observed in PPD patients. Studies in vitro and in vivo revealed a role for WISP3 in antagonising BMP, IGF and Wnt signalling pathways. Since most of the knowledge of WISP3 was gained in epithelial cells, cancer cells or chondrocyte cell lines, we investigated the roll of WISP3 in primary human mesenchymal stem cells (hMSCs) as well as primary chondrocytes.
WISP3 knock down was efficiently established with three short hairpin RNAs in both cell types, displaying a change of morphology followed by a reduction in cell number. Simultaneous treatment with recombinant WISP3 was not enough to rescue the observed phenotype nor increase the endogenous expression of WISP3. We concluded that WISP3 acts as an essential survival factor, where the loss resulted in the passing of cell cycle control points followed by apoptosis. Nevertheless, Annexin V-Cy3 staining and detection of active caspases by Western blot and immunofluorescence staining detected no clear evidence for apoptosis. Furthermore, the gene expression of the death receptors TRAILR1 and TRAILR2,important for the extrinsic activation of apoptosis, remained unchanged during WISP3 mRNA reduction. Autophagy as cause of cell death was also excluded, given that the autophagy marker LC3 A/B demonstrated to be uncleaved in WISP3-deficient hMSCs. To reveal correlated signalling pathways to WISP3 a whole genome expression analyses of WISP3-deficient hMSCs compared to a control (scramble) was performed. Microarray analyses exhibited differentially regulated genes involved in cell cycle control, adhesion, cytoskeleton and cell death. Cell death observed by WISP3 knock down in hMSCs and chondrocytes might be explained by the induction of necroptosis through the BMP/TAK1/RIPK1 signalling axis. Loss of WISP3 allows BMP to bind its receptor activating the Smad 2/3/4 complex which in turn can activate TAK1 as previously demonstrated in epithelial cells. TAK1 is able to block
caspase-dependent apoptosis thereby triggering the assembly of the necrosome resulting in cell death by necroptosis.
Together with its role in cell cycle control and extracellular matrix adhesion, as demonstrated in human mammary epithelial cells, the data supports the role of WISP3 as tumor suppressor and survival factor in cells of the musculoskeletal system as well as epithelial cells.
While TGF-β is able to regulate miRNA expression in numerous cell types, TGF-β-dependent changes in the miRNA profile of CD8+ T cells had not been studied before. Considering that TGF-β suppresses CD8+ T cell effector functions in numerous ways, we wondered whether induction of immune-regulatory miRNAs could add to the known transcriptional effects of TGF-β on immune effector molecules. In this study, we used miRNA arrays, deep sequencing and qRT-PCR to identify miRNAs that are modulated by TGF-β in human CD8+ T cells. Having found that the TGF-β-dependent downregulation of NKG2D surface expression in NK cells and CD8+ T cells does not go along with a corresponding reduction in mRNA levels, this pathway appeared to be a possible target of TGF-β-inducible miRNAs. However, this hypothesis could not be confirmed by miRNA reporter assays. Instead, we observed that DAP10 transcription is suppressed by TGF-β which in turn negatively affects NKG2D surface expression. In spite of promising preliminary experiments, technical difficulties associated with the transfection of primary NK cells and NK cell lines unfortunately precluded the final proof of this hypothesis.
Instead, we focused on the TGF-β-induced changes in the miRNome of CD8+ T cells and confirmed the induction of the miR-23a cluster members, namely miR-23a, miR-27a and miR-24 by three different techniques. Searching for potential targets of these miRNAs which could contribute to the immunosuppressive action of TGF-β in T cells, we identified and confirmed a previously unknown regulation of IFN-γ mRNA by miR-27a and miR-24. Newly generated miRNA reporter constructs further revealed that LAMP1 mRNA is a target of miR-23a. Upon modulation of the miR-23a cluster in CD8+ T cells by the respective miRNA antagomirs and mimics, significant changes in IFN-γ expression confirmed the functional relevance of our findings. Effects on CD107a/LAMP1 expression were, in contrast, rather minimal. Still, overexpression of the miR-23a cluster attenuated the cytotoxic activity of antigen-specific CD8+ T cells. Taken together, these functional data reveal that the miR-23a cluster not only is induced by TGF-β, but also exerts a suppressive effect on CD8+ T-cell effector functions, even in the absence of TGF-β signaling.
In this work, a model-based acceleration of parameter mapping (MAP) for the determination of the tissue parameter T1 using magnetic resonance imaging (MRI) is introduced. The iterative reconstruction uses prior knowledge about the relaxation behavior of the longitudinal magnetization after a suitable magnetization preparation to generate a series of fully sampled k-spaces from a strongly undersampled acquisition. A Fourier transform results in a spatially resolved time course of the longitudinal relaxation process, or equivalently, a spatially resolved map of the longitudinal relaxation time T1.
In its fastest implementation, the MAP algorithm enables the reconstruction of a T1 map from a radial gradient echo dataset acquired within only a few seconds after magnetization preparation, while the acquisition time of conventional T1 mapping techniques typically lies in the range of a few minutes. After validation of the MAP algorithm for two different types of magnetization preparation (saturation recovery & inversion recovery), the developed algorithm was applied in different areas of preclinical and clinical MRI and possible advantages and disadvantages were evaluated.
Fear conditioning is an efficient model of associative learning, which has greatly improved our knowledge of processes underlying the development and maintenance of pathological fear and anxiety. In a differential fear conditioning paradigm, one initially neutral stimulus (NS) is paired with an aversive event (unconditioned stimulus, US), whereas another stimulus does not have any consequences. After a few pairings the NS is associated with the US and consequently becomes a conditioned stimulus (CS+), which elicits a conditioned response (CR).
The formation of explicit knowledge of the CS/US association during conditioning is referred to as contingency awareness. Findings about its role in fear conditioning are ambiguous. The development of a CR without contingency awareness has been shown in delay fear conditioning studies. One speaks of delay conditioning, when the US coterminates with or follows directly on the CS+. In trace conditioning, a temporal gap or “trace interval” lies between CS+ and US. According to existing evidence, trace conditioning is not possible on an implicit level and requires more cognitive resources than delay conditioning.
The associations formed during fear conditioning are not exclusively associations between specific cues and aversive events. Contextual cues form the background milieu of the learning process and play an important role in both acquisition and the extinction of conditioned fear and anxiety. A common limitation in human fear conditioning studies is the lack of ecological validity, especially regarding contextual information. The use of Virtual Reality (VR) is a promising approach for creating a more complex environment which is close to a real life situation.
I conducted three studies to examine cue and contextual fear conditioning with regard to the role of contingency awareness. For this purpose a VR paradigm was created, which allowed for exact manipulation of cues and contexts as well as timing of events. In all three experiments, participants were guided through one or more virtual rooms serving as contexts, in which two different lights served as CS and an electric stimulus as US. Fear potentiated startle (FPS) responses were measured as an indicator of implicit fear conditioning. To test whether participants had developed explicit awareness of the CS-US contingencies, subjective ratings were collected.
The first study was designed as a pilot study to test the VR paradigm as well as the conditioning protocol. Additionally, I was interested in the effect of contingency awareness. Results provided evidence, that eye blink conditioning is possible in the virtual environment and that it does not depend on contingency awareness. Evaluative conditioning, as measured by subjective ratings, was only present in the group of participants who explicitly learned the association between CS and US.
To examine acquisition and extinction of both fear associated cues and contexts, a novel cue-context generalization paradigm was applied in the second study. Besides the interplay of cues and contexts I was again interested in the effect of contingency awareness. Two different virtual offices served as fear and safety context, respectively. During acquisition, the CS+ was always followed by the US in the fear context. In the safety context, none of the lights had any consequences. During extinction, a additional (novel) context was introduced, no US was delivered in any of the contexts. Participants showed enhanced startle responses to the CS+ compared to the CS- in the fear context. Thus, discriminative learning took place regarding both cues and contexts during acquisition. This was confirmed by subjective ratings, although only for participants with explicit contingency awareness. Generalization of fear to the novel context after conditioning did not depend on awareness and was observable only on trend level.
In a third experiment I looked at neuronal correlates involved in extinction of fear memory by means of functional magnetic resonance imaging (fMRI). Of particular interest were differences between extinction of delay and trace fear conditioning. I applied the paradigm tested in the pilot study and additionally manipulated timing of the stimuli: In the delay conditioning group (DCG) the US was administered with offset of one light (CS+), in the trace conditioning group (TCG) the US was presented 4s after CS+ offset. Most importantly, prefrontal activation differed between the two groups. In line with existing evidence, the ventromedial prefrontal cortex (vmPFC) was activated in the DCG. In the TCG I found activation of the dorsolateral prefrontal cortex (dlPFC), which might be associated with modulation of working memory processes necessary for bridging the trace interval and holding information in short term memory.
Taken together, virtual reality proved to be an elegant tool for examining human fear conditioning in complex environments, and especially for manipulating contextual information. Results indicate that explicit knowledge of contingencies is necessary for attitude formation in fear conditioning, but not for a CR on an implicit level as measured by FPS responses. They provide evidence for a two level account of fear conditioning. Discriminative learning was successful regarding both cues and contexts. Imaging results speak for different extinction processes in delay and trace conditioning, hinting that higher working memory contribution is required for trace than for delay conditioning.
The integrity of our genome is continuously endangered by DNA damaging factors. Several cellular mechanisms have evolved to recognize and remove different types of DNA lesions. Despite the wealth of information on the three-dimensional structure and the catalytic mechanism of DNA repair enzymes, the essential process of target site search and identification remains more elusive. How can a small number of repair proteins find and detect the rare sites of damage rapidly and efficiently over an excess of millions of undamaged bases?
To address this pivotal question in DNA repair, I focused on the central players from the two DNA damage excision repair pathways in my studies: nucleotide excision repair (NER) and base excision repair (BER). As examples for completely different approaches of damage search, recognition and verification, I compared the NER protein Xeroderma pigmentosum group D (XPD) with the BER proteins human thymine DNA glycosylase (hTDG) and human 8-oxoguanine glycosylase (hOgg1).
In particular, the single molecule approach of atomic force microscopy (AFM) imaging and complementary biochemical and biophysical techniques were applied. I established a simple, optimized preparation approach, which yields homogeneous and pure samples of long (several hundreds to thousands of base pairs) DNA substrates suitable for the AFM studies with DNA repair proteins. Via this sample preparation, a single target site of interest can be introduced into DNA at a known position, which allows separate analysis of specific protein-DNA complexes bound to the lesion site and nonspecific complexes bound to non-damaged DNA.
The first part of the thesis investigates the XPD protein involved in eukaryotic NER. In general, the NER mechanism removes helix-distorting lesions – carcinogenic UV light induced photoproducts, such as cyclobutane pyrimidine dimers (CPDs) as well as bulky DNA adducts. The 5’-3’ helicase XPD has been proposed to be one of the key players in DNA damage verification in eukaryotic NER, which is still a matter of hot debate. In the studies, I focused on XPD from the archaeal species Thermoplasma acidophilum (taXPD), which shares a relatively high sequence homology with the sequence of the human protein and may serve as a good model for its eukaryotic counterpart. Based on AFM experiments and accompanying DNA binding affinity measurements with the biosensor technology Biolayer Interferometry (BLI), a clear role of XPD in damage verification was deciphered. Specifically, the data suggested that the ATP-dependent 5’-3’ helicase activity of XPD was blocked by the presence of damage leading to stalled XPD-DNA damage verification complexes at the lesion sites.
Successful damage verification led to ATP-dependent conformational changes visible by a significant transition in DNA bend angles from ~ 50° to ~ 65° at the site of the bound protein. Remarkably, this DNA bend angle shift was observed both in the presence of ATP and ATPγs (non-hydrolyzable ATP analog) indicating that ATP-binding instead of ATP hydrolysis was sufficient to induce repair competent conformational changes of XPD. Most importantly, detailed protein binding position and DNA bend angle analyses revealed for the first time that XPD preferably recognizes a bulky fluorescein lesion on the translocated strand, whereas a CPD lesion is preferentially detected on the opposite, non-translocated strand. Despite the different recognition strategies for both types of damages, they share a common verification complex conformation, which may serve as a signal for the recruitment of further NER factors.
In the second part of the thesis, AFM imaging and a 2-Aminopurine fluorescence-based base-flipping assay were combined to investigate damage search and recognition by DNA glycosylases in BER. Exemplarily, I chose to study hTDG as a representative of the vast glycosylase family. hTDG excises thymine and uracil from mutagenic G:T and G:U mispairs contributing to cancer and genetic disease. The AFM data suggested that hTDG uses the intrinsic flexibility of G:T and G:U wobble pairs for initial damage sensing, while scanning DNA as a search complex (SC, slightly bent DNA). Remarkably, hTDG has been indicated to continuously switch between the search and interrogation conformation (IC, stronger bent DNA) during damage search. In the IC, target bases are interrogated by extrahelical base flipping, which is facilitated by protein-induced DNA bending and enhanced DNA flexibility at mismatches. AFM and fluorescence analyses revealed that the flipped base is stabilized via hTDG’s arginine finger. Correct target bases are perfectly stabilized within the enzyme’s catalytic pocket resulting in prolonged residence time and enhanced excision probability. To test for the generalizability of the proposed hTDG damage search model to BER glycosylases, identical studies were performed with a second glycosylase, hOgg1. The data on hOgg1, which removes structurally more stable 8-oxoguanine lesions, supported the hypothesis developed for lesion recognition by hTDG as a common strategy employed by BER glycosylases
This thesis treats the thermopower and other thermal effects in single quantum dots (QD) and quantum dot systems. It contributes new experimental results to the broad and active field of research on thermoelectrics in low dimensional systems. The thermopower experiments discussed in this work focus on QDs which exhibit a net spin and on tunnel-coupled double QDs (DQD). Furthermore, experiments are presented which address the realization of a QD device which extracts thermal energy from a heat reservoir and converts it into a directed charge current in a novel way.
The samples used for these investigations have been fabricated from GaAs/AlGaAs heterostructures which contain a two dimensional electron gas. Using optical and electron beam lithography, the devices have been realized by means of the top-gate technology. All experiments have been performed at low temperature. In order to create a controllable temperature difference in the samples the current heating technique has been used. These experimental basics as well as fundamentals of electric and thermoelectric transport are introduced in Part I of this thesis.
The experiments on the thermopower of a single QD are described in Part II. Essentially, they deal with the problem of how a single spin situated on a QD influences the thermoelectric properties of the system. In this context, the Kondo-effect plays a crucial role. Generally, the Kondo effect is the result of a many-body state which arises from an antiferromagnetic coupling of a magnetic impurity with the surrounding conduction electrons. Here, the magnetic impurity is represented by a QD which is occupied with an odd number of electrons so that it exhibits a net spin. For the first time the thermopower of a Kondo-QD has been studied systematically as a function of two parameters, namely the QD coupling energy and the sample temperature. Both parameters are crucial quantities for Kondo-physics to be observed. Based on these data, it is shown that the thermopower line shape as a function of QD energy is mainly determined by two competing contributions: On the one hand by the enhanced density of states around the Fermi level due to Kondo-correlations and on the other hand by thermopower contributions from the Coulomb resonances. Furthermore, the experiments confirm theoretical predictions which claim that the spectral DOS arising from Kondo-correlations shifts away from the Fermi level for those QD level configurations which are not electron-hole symmetric. Comparison with model calculations by T. Costi and V. Zlatic [Phys. Rev. B 81, 235127 (2010)] shows qualitative and partly even quantitative agreement. A finite thermovoltage at the center of the Kondo-region, which occurred in previous investigations, is also observed in the experiments presented here. It is not covered by the current theory of the Kondo effect. The dependence of this signal on temperature, coupling energy and magnetic field, which differ from non-Kondo regions, is analyzed. In order to clarify the physics behind this phenomenon further studies are desirable.
Furthermore, it is shown by variation of the QD coupling energy over a wide range that Kondo-correlations can be detected in the thermopower even in the regime of very weak coupling. In contrast, no Kondo signatures are visible in the conductance in this energy range. It is found that in the limit of weak coupling the Kondo effect causes the thermopower to exhibit a diminished amplitude in close vicinity of a conductance resonance. Subsequent filling of spin-degenerate states then leads to a thermopower amplitude modulation (odd-even-effect). Although this effect had been observed in previous studies, no connection to Kondo physics had been established in order to explain the observations.
Hence, the experiments on a single QD presented in this thesis provide unique insight into the complex interplay of different transport mechanisms in a spin-correlated QD. Moreover, the results confirm the potential of thermopower measurements as a highly sensitive tool to probe Kondo-correlations.
In Part III thermal effects are investigated in systems which contain two coupled QDs.
Such QD-systems are particularly interesting with respect to thermoelectric applications: Many proposals utilize the extremely sharp energy filtering properties of such coupled QDs and also different kinds of inter dot coupling to construct novel and highly efficient thermoelectric devices. In the present work, thermopower characterizations are performed on a tunnel-coupled DQD for the first time. The key result of these investigations is the thermopower stability diagram. Here it is found, that in such a system maximal thermopower is generated in the vicinity of the so-called triple points (TP) at which three charge states of the DQD are degenerate. Along the axis of total energy, which connects two adjacent TP, a typical thermopower line shape is observed. It is explained and modeled within an intuitive picture that assumes two transport channels across the DQD, representing the TP. For those regions which are far away from the TP, the thermopower turns out to be very sensitive to the relative configuration of the QD energies. The conductance and thermopower data are well reproduced within a model that assumes transport via molecular states. Integration of both models into one then allows model calculations for a complete stability cell in conductance and thermopower to be done.
Furthermore, experiments on two capacitively coupled QDs are presented. In these studies the focus lies on testing the feasibility of such systems for the manipulation and generation of charge currents from thermal energy. In a series of experiments it is shown that such a system of QDs can be utilized to increase or decrease a current flowing between two electron reservoirs by varying the temperature in a third reservoir. This effect is based on the cross-correlation of occupation fluctuations of the individual QDs. These are positive for certain QD energy level configurations and negative for others, which increases or decreases the charge current in the experiments, respectively. In the stability diagram this is manifested in a characteristic clover leaf shaped structure of positive and negative current changes in vicinity of the TP. All main experimental results are reproduced qualitatively in simple model calculations. Due to the close analogy between electrical and thermal conductance of a QD, this effect of thermal switching can, in principle, also be used to built a thermal transistor.
Finally, it is shown that a system consisting of two Coulomb-coupled QDs, which couple a hot electron reservoir electrostatically to two cold electron reservoirs, can be utilized as a novel device which extracts heat from its environment and converts it into a directed charge current. The idea of this heat-to-current converter (HCC) was first proposed by R. Sánchez and M. Büttiker [Phys. Rev. B 83, 085428 (2011)]. It is not only characterized by the novelty of its working principle but also by the fact, that it decouples the directions of charge current and energy flow. In the experiments presented here, such HCC-currents are identified unambiguously: For certain QD-level configurations an electric current between the two cold reservoirs is observed if the temperature in the third reservoir is increased. The direction of this current is shown to be independent of an external voltage. In contrast, the direction of the current exhibits a characteristic dependence on the tunneling coefficients of the QDs, as predicted by theory: By adjusting the thickness and the shape of the respective tunnel junctions, a charge current can be generated between two cold reservoirs, and it can even be inverted. The experimental observations are quantitatively reproduced by model calculations by R. Sánchez and B. Sothmann. Thus, the results represent direct evidence for the existence of HCC-currents. Due to the novelty of the working principle of the HCC and its relevance from a fundamental scientific point of view, the results presented here are an important step towards energy harvesting devices at the nano scale.
In the course of this dissertation, we have presented the interest of using spectroscopic methods to unravel the physics of polymer semiconductors in photovoltaic applications. Applying photoluminescence and photoinduced absorption spectroscopy to the reference system P3HT:PCBM has enabled us to study the major steps of photocurrent generation in organic bulk heterojunctions, from excitons generation to charges extraction and loss mechanisms and thus to improve the understanding of those mechanisms.
The exciton binding energy, is the first obstacle to overcome for photocurrent generation in organic solar cell and the reason for the use of two materials, whose heterojunction act as a driving force for charge separation. We developed an original photoluminescence-detected field-induced exciton quenching method to investigate this energy. Absorption and photoluminescence spectra of pure P3HT show that, while both amorphous and crystalline domains participate in
absorption, the energy is then transferred to the crystalline domains, from where the photoluminescence is exclusively originating. The field dependence of this photoluminescence showed that an energy of no less than 420 meV is necessary to split excitons into non photon-emitting species. Comparing those results with energy levels obtained by absorption and photoelectron spectroscopies, confirmed that the formation of those species is only a first step toward dissociation into free charges. Indeed, photoemission spectroscopy and the onset
of photocurrent upon increasing the photon energy in a pure P3HT solar cell, concomitantly show that the energy level of a pair of free polarons is located 0.7 eV above the one of the exciton. The comprehensive analysis of those results originating from those different method enable us to draw a global picture of the states and energies involved in free polarons generation in pure material. This work has been widely acknowledged by the scientific community, published in Physical Review B in 2010 [1] and presented in national [2] and international [3] conferences.
The spectroscopy of excited states is used to detect the presence of wanted species (charges) and potentially unwanted neutral species upon photoexcitation. As such, it offers us the possibility to qualify the efficiency of charge generation and, if any, identify the competing processes and the generation of unwanted species. In the frame of the European Marie Curie Research Network SolarNType,[4] this possibility was used - in combination with morphological,
charge transport and devices characterizationsn - to study a number of new donor:acceptor blends. Thanks to those techniques, we were able to not only quantify the potential of those blends, but also to provide the chemist laboratories with a precious and detailed feedback on the strengths and weakness of the molecules, regarding charge generation, transport and extraction. The detailed study of terrylene-3,4:11,12-bis(dicarboximide) as electron acceptor for
solar cells application was published in the peer review journal Synthetic Metals and was chosen to illustrate the cover page of the issue [5].
Finally, in the last chapter, we have used time resolved photoinduced absorption to improve the understanding of the charge carrier loss mechanisms in P3HT:PCBM active layers. This comprehension is of prime importance because, the fact that this recombination is far weaker than expected from the Langevin theory, enable polarons to travel further without recombining and thus to build thicker and more efficient devices. A comprehensive analysis of steady-state
PIA spectra of pure P3HT, indicates that probing at 980 nm at a temperature between 140 and 250 K enables to monitor specifically polaron densities in both neat P3HT and P3HT:PCBM. Applying this finding to transient absorption enabled us to monitor, for the first time, the bimolecular recombination in pure P3HT, and to discover that - in sharp contrast with the blend - this recombination was in agreement with the Langevin theory. Moreover, it enables us to pinpoint the important role played by the existence of two materials and of energetical traps in the slow recombination and high recombination orders observed in the blend. This work has been published in the Journal of Applied Physics.[6]
Those new insights in the photophysics of polymer:fullerene photoactive layers could have a strong impact on the future developement of those materials. Consistent measurements of the binding energy of excitons and intermediate species, would enable to clarify the role played by excess thermal energy in interfacial states dissociation. Better understanding of blends
morphology and its influence on solar cells parameters and in particular on recombination could enable to reproduce the conditions of limited recombination on material systems offering some promising performances but with only limited active layer thicknesses. However, due to the number of parameters involved, further experimentation is required, before we can reach a quantitative modeling of bimolecular recombination.
[1] Deibel et al., Phys. Rev. B, 81:085202, 2010
[2] Gorenflot et al., Deutsche Physikalische Gesellschaft Frühjahrstagung 2010, CPP20:10, Regensburg, Germany, 2010
[3] Gorenflot et al., International Conference of Synthetic Metals, 7Ax:05, Kyoto, Japan, 2010
[4] Marie-Curie RTN "SolarNTyp" Contract No. MRTN-CT-2006-035533
[5] Gorenflot et al., Synth. Met., 161(23{24):2669-2676, 2012
[6] Gorenflot et al., J. Appl. Phys., 115(14):144502, 2014
Background and Aims: PMA is a recently described rare tumor entity occuring most often in young children. Due the worse outcome of PMA-patients as compared to children with pilocytic astrocytoma (PA), it has received a grade II assignment in the latest WHO classification. Nevertheless, increasing evidence suggests that the two tumor types are indeed pathologically and genetically related. The radiological differentiation of PMAs from PAs is challenging and the limited available data could not yet provide unequivocal distinguishing imaging features. Furthermore, it is not completely clarified whether PMA cases are associated with a higher rate of CSF dissemination compared to similarly young patients with PA. The aim of our study was firstly to compare MR/CT imaging features of these tumors, and secondly, to evaluate the occurrence of CSF dissemination.
Material and Methods: The study population included 15 children with PMA and 32 children with PA. A third group consisted of eight children with PAs with focal pilomyxoid features. All cases had been registered in the German multicenter SIOP/HIT-LGG trials. The initial MRIs (and CT scans, if available) at establishing the diagnosis were retrospectively analyzed according to standardized criteria and the findings compared between PMAs and PAs. Furthermore, we compared the occurrence of imaging evidences of CSF tumor dissemination between children with PMA and PA, respectively.
Results: The imaging appearance of PMAs and PAs was very similar. However, PAs tended to show more frequently cystic components (p=0.03). As opposed to PAs, PMAs did not have large tumor cysts. We did not find differences with respect to tumor size and tumor margin. Gadolinium enhancement of PMAs was significantly more frequently homogeneous (p=0.006). PMAs appeared to show more often intratumoral hemorrhages (p=0.047). Furthermore, suprasellar PMAs tended to have a more homogeneus texture on T2-weighted MR images (p=0.026). Within the subgroup < 6 years of age the PMA histology tended to have a larger effect on the occurrence of CSF dissemination than the age (p=0.05 vs.0.12).
Conclusions: Although the radiological appearance of PMAs and PAs is similar, some imaging features, like enhancement pattern or presence of cysts or hemorrhage may help differentiating these low-grade gliomas. Our results corroborate previous scarce data suggesting higher rate of CSF dissemination in PMAs, even in the youngest patient population. Thus, in young children with a chiasmatic-hypothalamic tumor suggestive of a PMA, an intensive search for CSF dissemination along the entire neuraxis should be performed.
In this thesis, we investigate aspects of the physics of heavy-fermion systems and correlated topological insulators.
We numerically solve the interacting Hamiltonians that model the physical systems using quantum Monte Carlo algorithms
to access both ground-state and finite-temperature observables.
Initially, we focus on the metamagnetic transition in the Kondo lattice model for heavy fermions.
On the basis of the dynamical mean-field theory and the dynamical cluster approximation,
our calculations point towards a continuous transition, where the signatures of metamagnetism are linked to a Lifshitz transition of heavy-fermion bands.
In the second part of the thesis, we study various aspects of magnetic pi fluxes in the Kane-Mele-Hubbard model of a correlated topological insulator.
We describe a numerical measurement of the topological index, based on the localized mid-gap states that are provided by pi flux insertions.
Furthermore, we take advantage of the intrinsic spin degree of freedom of a pi flux to devise instances of interacting quantum spin systems.
In the third part of the thesis, we introduce and characterize the Kane-Mele-Hubbard model on the pi flux honeycomb lattice.
We place particular emphasis on the correlations effects along the one-dimensional boundary of the lattice and
compare results from a bosonization study with finite-size quantum Monte Carlo simulations.
Stress has been shown to influence neuroplasticity and is suspected to increase the risk for psychiatric disorders such as major depression and anxiety disorders. Additionally, the short variant of the human serotonin transporter (5-HTT) length polymorphism (5-HTTLPR) is suggested to increase the risk for the development of such disorders. While stress as well as serotonergic signaling are not only discussed to be involved in the development of psychiatric disorders, they are also known to influence hippocampal adult neurogenesis (aN). Therefore, it has long been suspected that aN is involved in the etiology of these illnesses. The exact role of aN in this context however, still remains to be clarified.
In the present doctoral thesis, I am introducing two different studies, which had been carried out to assess possible changes in neuroplasticity and behavior as a result of 5-HTT genotype by stress interactions. In both studies, animals of the 5-HTT knock-out (5-HTT-/-) mouse line were used, which have been found to exhibit increased anxiety- and depression-related behavior, an altered stress response and decreased aggressive behavior. The aim of the first study, the so-called Spatial Learning study, had been to evaluate whether mice with altered levels of brain 5-HT as a consequence of lifelong 5-HTT deficiency perform differently in two spatial memory tests, the Morris Water Maze (WM) and the Barnes Maze (BM) test prospectively differing in aversiveness. Mice of the Spatial Learning study were of male sex and six months of age, and where subjected to a total of 10 (BM) or 15 (WM) trials. My particular interest was to elucidate if there are genotype by treatment interactions regarding blood plasma corticosterone levels and, if neurobiological equivalents in the brain to the found behavioral differences exist. For this purpose I carried out a quantitative immunohistochemistry study, investigating stem cell proliferation (via the marker Ki67) and aN (via the immature neuron marker NeuroD), as well as expression of the two immediate early genes (IEGs) Arc and cFos as a markers for neuronal activity in the hippocampus. The aim of the second study, the chronic mild stress (CMS) study had been to evaluate whether the innate divergent depression-like and anxiety-like behavior of mice with altered levels of brain 5-HT as a consequence of 5-HTT-deficiency is altered any further after being subjected to a CMS paradigm. Two cohorts of one-year-old female mice had been subjected to a variety of unpredictable stressors. In order to exclude possible interfering influences of behavioral testing on corticosterone levels and the outcome of the quantitative immunohistochemistry study the first cohort had been behaviorally tested after CMS while the second one had remained behaviorally untested. The objective of my part of the study was to find out about possible genotype by treatment interactions regarding blood plasma corticosterone as well as regarding aN in the hippocampus of the mice that had been subjected to CMS. For this purpose I performed a quantitative immunohistochemistry study in order to investigate the phenomenon of adult neurogenesis (via Ki67, NeuroD and the immature neuron marker DCX).
Both studies led to interesting results. In the CMS study, we could not replicate the increased innate anxiety- and depression-like behavior in 5-HTT-/- mice known from the literature. However, with regard to the also well documented reduced locomotor activity, as well as the increased body weight of 5-HTT-/- mice compared to their 5-HTT+/- and 5-HTT+/+ littermates, we could demonstrate that CMS leads to increased explorative behavior in the Open Field Test and the Light/Dark Box primarily in 5-HTT+/- und 5-HTT+/+ mice. The Spatial learning study revealed that increased stress sensitivity of 5-HTT-/- mice leads to a poorer performance in the WM test in relation to their 5-HTT+/+ and 5-HTT+/- littermates. As the performance of 5-HTT-/- mice in the less aversive BM was undistinguishable from both other genotypes, we concluded that the spatial learning ability of 5-HTT-/- mice is comparable to that of both other genotypes. As far as stress reactivity is concerned, the experience of a single trial of either the WM or the BM resulted in increased plasma corticosterone levels, irrespective of the 5-HTT genotype. After several trials 5-HTT-/- mice exhibited higher corticosterone concentrations compared with both other genotypes in both tests. Blood plasma corticosterone levels were highest in 5-HTT-/- mice tested in the WM indicating greater aversiveness of the WM and a greater stress sensitivity of 5-HTT deficient mice. In the CMS study, the corticosterone assessment of mice of cohort 1, which had undergone behavioral testing before sacrifice, resulted in significantly elevated corticosterone levels in 5-HTT-/- mice in relation to their 5-HTT+/+ controls. Contrary, corticosterone levels in mice of cohort 1, which had remained behaviorally untested, were shown to be elevated / increased after CMS experience regardless of the 5-HTT genotype. Regarding neuroplasticity, the Spatial Learning study revealed higher baseline levels of cFos- and Arc-ir cells as well as more proliferation (Ki67-ir cells) and higher numbers of neuronal progenitor cells (NeuroD-ir cells) in 5-HTT-/- compared to 5-HTT+/+ mice. Moreover, in 5-HTT-/- mice we could demonstrate that learning performance in the WM correlates with the extent of aN. The CMS study, in which aN (DCX-ir cells), has also been found to be increased in 5-HTT-/- mice compared to their 5-HTT+/+ littermates, yet only in control animals, did show hampered proliferation (Ki67-ir cells) in the hippocampus of all 5-HTT genotypes following CMS experience. Interestingly, the number of immature neurons (DCX-ir cells) was diminished exclusively in 5-HTT-/- mice in response to CMS.
From the Spatial Learning study we concluded, that increased IEG expression and aN levels observed in the hippocampus of 5-HTT deficient mice can be the neurobiological correlate of emotion circuit dysfunction and heightened anxiety of these mice and that 5-HTT-/- animals per se display a “stressed” phenotype as a consequence of long-life 5-HTT deficiency. Due to the different age and sex of the mice in the two studies, they cannot be compared easily. However, although the results of the CMS study seem to contradict the results of the Spatial Learning study at the first glance, they do support the conclusion of the Spatial Learning study by demonstrating that although CMS does have an impact on 5-HTT-/- mice on the neurobiological level (e.g. manifesting in a decrease of DXC-ir cells following CMS) CMS experience cannot add onto their heightened inborn stress-level and is almost ineffective regarding further changes of the behavior of 5-HTT-deficient mice. I thus propose, that 5-HTT-/- mice as a result of lifelong altered 5-HT signaling display a stressed phenotype which resembles a state of lethargy and is paralleled by baseline heightened IEG expression and aN. It cannot be altered or increased by CMS, but it becomes most visible in stressful situations such as repeated spatial learning tests like the WM in which locomotor activity is required.
Nano-antennas are an emerging concept for the manipulation and control of optical fields at the sub-wavelength scale. In analogy to their radio- and micro-wave counterparts they provide an efficient link between propagating and localized fields. Antennas operating at optical frequencies are typically on the order of a few hundred nanometer in size and are fabricated from noble metals. Upon excitation with an external field the electron gas inside the antenna can respond resonantly, if the dimensions of the antenna are chosen appropriate. Consequently, the resonance wavelength depends on the antenna dimensions. The electron-density oscillation is a hybrid state of electron and photon and is called a localized plasmon resonance. The oscillating currents within the antenna constitute a source for enhanced optical near-fields, which are strongly localized at the metal surface.
A particular interesting type of antennas are pairs of metal particles separated by a small insulating gap. For anti-symmetric gap modes charges of opposite sign reside across the gap. The dominating field-components are normal to the metal surface and due to the boundary conditions they are sizable only inside the gap. The attractive Coulomb interaction increases the surface-charge accumulation at the gap and enhanced optical fields occur within the insulating gap. The Coulomb interaction increases with decreasing gap size and extreme localization and strongest intensity enhancement is expected for small gap sizes.
In this thesis optical antennas with extremely small gaps, just slightly larger than inter-atomic distances, are investigated by means of optical and electrical excitation. In the case of electrical excitation electron tunneling across the antenna gap is exploited.
At the beginning of this thesis little was known about the optical properties of antennas with atomic scale gaps. Standard measurement techniques of field confinement and enhancement involving well-separated source, sample and detector are not applicable at atomic length-scales due to the interaction of the respective elements. Here, an elegant approach has been found. It is based on the fact that for closely-spaced metallic particles the energy splitting of a hybridized mode pair, consisting of symmetric and anti-symmetric mode, provides a direct measure for the Coulomb interaction over the gap. Gap antennas therefore possess an internal ruler which sensitively reports the size of the gap.
Upon self-assembly side-by-side aligned nanorods with gap sizes ranging from 2 to 0.5nm could be obtained. These antennas exhibit various symmetric and anti-symmetric modes in the visible range. In order to reveal optical modes of all symmetries a novel scattering setup has been developed and is successfully applied. Careful analysis of the optical spectra and comparison to numerical simulations suggests that extreme field confinement and localization can occur in gaps down to 0.5 nm. This is possibly the limit of plasmonic enhancement since for smaller gaps electron tunneling as well as non-locality of the dielectric function affect plasmonic resonances.
The strongly confined and intense optical fields provided by atomic-scale gaps are ideally suited for enhanced light-matter interaction. The interplay of intense optical-frequency fields and static electric fields or currents is of great interest for opto-electronic applications. In this thesis a concept has been developed, which allows for the electrical connection of optical antennas. By means of numerical simulations the concept was first verified for antennas with gap sizes on the order of 25 nm. It could be shown, that by attaching the leads at positions of a field minimum the resonant properties are nearly undisturbed. The resonance wavelengths shift only by a small amount with respect to isolated antennas and the numerically calculated near-field intensity enhancement is about 1000, which is just slightly lower than for an unconnected antenna.
The antennas are fabricated from single-crystalline gold and exhibit superior optical and electrical properties. In particular, the conductivity is a factor of 4 larger with respect to multi-crystalline material, the resistance of the gap is as large as 1 TOhm and electric fields of at least 10^8 V/m can be continuously applied without damage. Optical scattering spectra reveal well-pronounced and tunable antenna resonances, which demonstrates the concept of electrically-connected antennas also experimentally.
By combining atomic-scale gaps and electrically-connected optical antennas a novel sub-wavelength photon source has been realized. To this end an antenna featuring an atomic scale gap is electrically driven by quantum tunneling across the antenna gap. The optical frequency components of this fluctuating current are efficiently converted to photons by the antenna. Consequently, light generation and control are integrated into a planar single-material nano-structure. Tunneling junctions are realized by positioning gold nanoparticles into the antenna gap, using an atomic force microscope. The presence of a stable tunneling junction between antenna and particle is demonstrated by measuring its distinct current-voltage characteristic. A DC voltage is applied to the junction and photons are generated by inelastically tunneling electrons via the enhanced local density of photonic states provided by the antenna resonance. The polarization of the emitted light is found to be along the antenna axis and the directivity is given by the dipolar antenna mode. By comparing electroluminescence and scattering spectra of different antennas, it has been shown that the spectrum of the generated light is determined by the geometry of the antenna. Moreover, the light generation process is enhanced by two orders of magnitude with respect to a non-resonant structure.
The controlled fabrication of the presented single-crystalline structures has not only pushed the frontiers of nano-technology, but the extreme confinement and enhancement of optical fields as well as the light generation by tunneling electrons lays a groundwork for a variety of fundamental studies and applications.
Field localization down to the (sub-)nanometer scale is a prerequisite for optical spectroscopy with near-atomic resolution. Indeed, recently first pioneering experiments have achieved molecular resolution exploiting plasmon-enhanced Raman scattering. The small modal volume of antennas with atomic-scale gaps can lead to light-matter interaction in the strong coupling regime. Quantum electro-dynamical effects such as Rabi splitting or oscillations are likely when a single emitter is placed into resonant structures with atomic-scale gaps.
The concept of electrically-connected optical antennas is expected to be widely applied within the emerging field of electro-plasmonics. The sub-wavelength photon source developed during this thesis
will likely gain attention for future plasmonic nanocircuits. It is envisioned that in such a circuit the optical signal provided by the source is processed at ultrafast speed and nanometer-scales on the chip and is finally converted back into an electronic signal. An integrated optical transistor could be realized by means of photon-assisted tunneling. Moreover, it would be interesting to investigate, if it is possible to imprint the fermionic nature of electrons onto photons in order to realize an electrically-driven source of single photons. Non-classical light sources with the potential for on-chip integration could be built from electrically-connected antennas and are of great interest for quantum communication. To this end single emitters could be placed in the antenna gap or single electron tunneling could be achieved by means of a single-channel quantum point contact or the Coulomb-blockade effect.
MicroRNAs are endogenous ≈22 nt long non coding RNA molecules that modulate gene expression
at the post transcriptional level by targeting mRNAs for cleavage or translational repression.
MicroRNA-mRNA interaction involves a contiguous and perfect pairing within complementary
sites usually in the 3’ UTR of the target mRNA. Heart failure is associated with myocyte
hypertrophy and death, due to compensatory pathological remodeling and minimal functional repair
along with microRNA deregulation.
In this study, we identified candidate microRNAs based on their expression strength in
cardiomyocytes and by their ability to regulate hypertrophy. Expression profiling from early and
late stages of heart failure showed several deregulated microRNAs. Of these microRNAs, miR-378
emerged as a potentially interesting microRNA that was highly expressed in the mouse heart and
downregulated in the failing heart. Antihypertrophic activity of miR-378 was first observed by
screening a synthetic miR library for morphologic effects on cardiomyocytes, and validated in vitro proving the tight control of hypertrophy by this miR. We combined bioinformatic target prediction analysis and microarray analysis to identify the targets of miR-378. These analyses suggested that factors of the MAP kinase pathway were enriched among miR-378 targets, namely MAPK1 itself (also termed ERK2), the insulin-like growth factor receptor 1 (IGF1R), growth factor receptor bound protein 2 (GRB2) and kinase suppressor of ras 1 (KSR1). Regulation of these targets by miR-378 was then confirmed by mRNA and protein expression analysis. The use of luciferase reporter constructs with natural or mutated miR-378 binding sites further validated these four proteins as direct targets of miR-378. RNA interference with MAPK1 and the other three targets prevented the prohypertrophic effect of antimiR-378, suggesting that they functionally relate to miR-378. In vivo restoration of disease induced loss of miR-378 in a pressure overload mouse model of hypertrophy using adeno associated virus resulted in partial attenuation cardiac hypertrophy and significant improvement in cardiac function along with reduced expression of the four targets in heart.
We conclude from these findings that miR-378 is an antihypertrophic microRNA in cardiomyocytes, and the main mechanism underlying this effect is the suppression of the MAP kinase-signaling pathway on four distinct levels. Restoration of disease-associated loss of miR-378 through cardiomyocyte-targeted AAV-miR-378 may prove as an effective therapeutic strategy in myocardial disease.
Nature-based tourism and ecotourism experienced a dynamic development over the past decade. While originally often described as specialized post-Fordist niche markets for ecologically aware and affluent target groups, in many regions they are nowadays characterized by a heterogeneous structure and the presence of a wide product range, from individual travels to package tours.
The present dissertation analyzes the structure and economic importance of tourism in two highly frequented protected areas in middle income countries, the Sian Ka’an Biosphere Reserve (SKBR) in Mexico and the Souss-Massa National Park (SMNP) in Morocco. Both areas are situated in close proximity to the most important package tour destinations Cancún (Mexico) and Agadir (Morocco) and are subject to high touristic use and development pressure. So far, the planning of a more sustainable tourism development is hampered by the lack of reliable data.
Based on demand-side surveys and income multipliers calculated with the help of regionalized input-output models, the visitor structure and economic impact of tourism in both protected areas are described. With regional income effects of approximately 1 million USD (SKBR) and approximately 1.9 million USD (SMNP), and resulting income equivalents of 1,348 and 5,218 persons, both the SKBR and the SMNP play an important—and often undervalued—role for the regional economies in underdeveloped rural peripheral regions of the countries.
Detailed analyses of the visitor structures show marked differences with regard to criteria such as travel organization, nature/protected area affinity and expenditures. With regard to planning and marketing of nature-based tourism, protected area managers and political decision-takers are advised to focus on ecologically and economically attractive visitor groups. Based on the results of the two case studies as well as existing tourism typologies from the literature, a classification scheme is presented that may be used for a more target-oriented development and marketing of nature-based tourism products.
Theories of attention deficit hyperactivity disorder (ADHD) aetiology have placed a focus on impaired behavioural inhibition presumably leading to executive function (EF) deficits. Neuroimaging studies report neurophysiological findings consistent with these hypothesised impairments, and investigations of functional brain activation from a network perspective report hypoactivation in the frontoparietal network as well as hyperactivation in the dorsal attention network. Studies investigating the acute effects of stimulant medication on EF show an improvement on behavioural EF measures including working memory. In addition, methylphenidate (MPH) was shown to up-regulate the task-positive/ frontoparietal network in children and adolescents with ADHD. So far, there are only few studies investigating the impact of ADHD on behavioural and neurophysiological EF measures as well as the effect of several weeks of stimulant medication in adult patients.
The importance of the catechol-O-methyltransferase (COMT) enzyme for subcortical and cortical dopaminergic and noradrenergic functioning furthermore led to studies investigating a potential interactive impact of COMT genotype and ADHD on neuropsychological functioning, with a particular focus on working memory. The results of these studies were very heterogeneous. In addition, as none of the studies compared the results of ADHD patients to those of a healthy control group, possible differential effects of COMT in patients and healthy controls could not be examined.
The aim of this dissertation was to investigate selective attention properties of the central executive component during a working memory task and to transfer this task to fMRI. A third study then aimed to investigate the effects of adult ADHD (aADHD), MPH, and COMT genotype on working memory with a particular focus on activation of the task-positive network during the analysis of the fMRI data.
The first study (EEG) could replicate and extend the results from previous research. This study could furthermore connect the overall activation in frontal areas to suppression efficiency in posterior visual areas as well as establish the impact of hyperactive/ impulsive ADHD symptoms on task performance. The second study (fMRI) allowed the successful transfer of the paradigm to fMRI, and the further replication and extension of previous findings. In addition, this study showed the sensitivity of the task to the effects of the COMT genotype. The third study (fMRI) was one of the first studies that exploratorily investigated the effects COMT in a sample of aADHD patients and a comparable healthy control group. This study showed an interactive effect of these two factors on neuropsychological measures as well as on fMRI activation during a classic n-back working memory task. In addition, this task led to more activation in the task-positive network of the aADHD group compared to a healthy control group in the absence of performance differences, pointing towards compensatory activation in the aADHD group. Furthermore, activation in the frontal cortex was increased in patients taking MPH compared to a placebo. The fMRI data from the selective attention task moreover showed decreased activation in the right DLPFC of the patient group, which was associated with reduced suppression efficiency across all participants. The clinical effect of MPH in the third study was visible but did not reach significance, which is probably attributable to a lack of experimental power.
The studies in this dissertation could successfully replicate and extend previous findings. A goal for future studies should be the further investigation of the interactive effects of COMT genotype and aADHD on neuropsychological test results and fMRI activation, but also on medication response and adverse effects. In this context, the adaptation of a network perspective during the analysis of fMRI data seems to be the best way to detect existing between-group differences.
Mammalian haloacid dehalogenase (HAD)-type phosphatases are an emerging family of enzymes with important functions in physiology and disease. HAD phosphatases can target diverse metabolites, lipids, DNA, and serine/threonine or tyrosine phosphorylated proteins with often high specificity (Seifried et al., 2013). These enzymes thus markedly enlarge the repertoire and substrate spectrum of mammalian phosphatases. However, the basis of HAD phosphatase substrate specificity is still elusive and a number of mammalian HAD phosphatases remain uncharacterized to date. This study characterizes the biochemical and structural properties of AUM (aspartate-based, ubiquitous, Mg2+-dependent phosphatase), a previously unexplored mammalian HAD phosphatase.
In vitro phosphatase assays of purified, recombinant AUM showed phosphatase activity towards para-nitrophenyl phosphate and adenine and guanine nucleotide di- and triphosphates. Inhibitor studies indicated that similar to other HAD superfamily members, the AUM-catalyzed dephosphorylation reaction proceeds via a pentacovalent phosphoaspartate intermediate. In line with an aspartate-based catalytic mechanism, AUM was insensitive to inhibitors of serine/threonine phosphatases. The characterization of the purified recombinant murine enzyme also revealed that AUM exists in equilibrium between dimers and tetramers.
AUM was identified as the closest, yet functionally distinct relative of chronophin, a pyridoxal 5’-phosphate and serine/threonine-directed phosphatase. Phylogenetic analyses showed that AUM and chronophin evolved via duplication of an ancestral gene at the origin of the vertebrates. In contrast to chronophin, AUM acts as a tyrosine-specific HAD-type phosphatase in vitro and in cells. To elucidate how AUM and chronophin achieve these distinct substrate preferences, comparative evolutionary analyses, biochemical approaches and structural analyses were combined. Swapping experiments of less homologous regions between AUM and chronophin were performed. The mutational analysis revealed residues important for AUM catalysis and specificity. A single differently conserved residue in the cap domain of AUM or chronophin is crucial for phosphatase specificity (AUML204, chronophinH182). The X-ray crystal structure of the AUM cap fused to the catalytic core of chronophin (CAC, PDB: 4BKM) was solved to 2.65 Å resolution. It presents the first crystal structure of the murine AUM capping domain. The detailed view of the catalytic clefts of AUM and chronophin reveals the structural basis of the divergent substrate specificities. These presented findings provide insights into the design principles of capped HAD phosphatases and show that their substrate specificity can be encoded by a small number of predictable residues. In addition, the catalytic properties of AUM were investigated, identifying a mechanism of reversible oxidation regulating the activity of AUM in vitro. AUM phosphatase activity is inhibited by oxidation and can be recovered by reduction. The underlying molecular mechanism was revealed by mutational analyses. The cysteines C35, C104 and C243, located in the AUM core domain, are responsible for the inhibition of AUM by oxidation. C293 mediates the redox-dependent tetramerization of AUM in vitro. Based on the chronophin and CAC structure, a direct impact of the oxidation of C35 on the nucleophile D34 is proposed. In addition, a redox-dependent disulfide bridge (C104, C243), connecting the core and cap domain of AUM may be important for an open/close-mechanism. This hypothesis is supported by CD spectroscopy experiments that demonstrate a structural change in AUM upon reduction. These data present the first evidence for the regulation of AUM catalysis by reversible oxidation. This finding is so far unique in the field of HAD phosphatases.
In this context, the first cell-based AUM activity assay was developed. For this, the artificial substrate pNPP was combined with the reducing agent DTT to create a specific AUM activity readout. This fractionation-based assay is the first tool to differentiate between cell lines or tissues with different AUM concentrations or activities.
Taken together, the presented biochemical characterization reveals the specificity determinants and catalytic properties of AUM. General insights into structural determinants of mammalian HAD phosphatase substrate recognition are provided and reversible oxidation as possible regulatory mechanism for AUM is proposed. These findings constitute a framework for further functional analyses to elucidate the biomedical importance of AUM.
Malignant melanoma is the most severe form of all skin cancers with a particular poor prognosis once metastases have developed. Angiogenesis, the formation of new blood vessels, is a prominent feature of human melanoma, which have angiogenic activity already early in development. This is at least partly ascribed to the action of MAPK- and PI3K pathways which are hyperactivated in most melanoma. Animal models which combine in depth in vivo examinations with the opportunity to perform small molecular screens are well suited to gain a more detailed insight into how this type of cancer modulates its angiogenic program. Here, a first transgenic melanoma angiogenesis model was established in the fish species Oryzias latipes (Japanese medaka). In this model, tumors are generated by the pigment cell-specific expression of the oncogenic receptor tyrosine kinase Xmrk. Xmrk is a mutated version of the fish Egfp. Furthermore, to get an angiogenesis model, a medaka line with endothelial cell specific GFP expression was used. By using crosses between these Xmrk- and GFP transgenic fishes, it was shown that angiogenesis occurs in a reactive oxygen species- and NF-κB-dependent manner, but was hypoxia-independent. It was observed that blood vessel sprouting and branch point formation was elevated in this model and furthermore that sprouting could even be induced by single transformed cells. The mouse melanocytes expressing the oncogenic receptor tyrosine kinase Xmrk as well human melanoma cells, which display various oncogenic alterations, produced pro-angiogenic factors, most prominently angiogenin, via NF-κB signaling. Furthermore, inhibiting NF-κB action prevented tumor angiogenesis and even led to the regression of existing tumor blood vessels. In summary, the present medaka melanoma angiogenesis model displays a high sensitivity for angiogenesis detection and is perfectly suited as in vivo model for the testing of anti-angiogenesis inhibitors, as exemplified by the NF-kappaB inhibitor.
Furthermore, results indicate that it might be a promising anti-tumor strategy to target signaling pathways such as the NF-κB pathway which are able to induce angiogenesis-dependent as well as -independent pro-tumorigenic effects.
Considering its social, economic and natural conditions the Mediterranean Area is a highly vulnerable region by designated affections of climate change. Furthermore, its climatic characteristics are subordinated to high natural variability and are steered by various elements, leading to strong seasonal alterations. Additionally, General Circulation Models project compelling trends in specific climate variables within this region. These circumstances recommend this region for the scientific analyses conducted within this study. Based on the data of the CMIP3 database, the fundamental aim of this study is a detailed investigation of the total variability and the accompanied uncertainty, which superpose these trends, in the projections of temperature, precipitation and sea-level pressure by GCMs and their specific realizations. Special focus in the whole study is dedicated to the German model ECHAM5/MPI-OM. Following this ambition detailed trends and mean values are calculated and displayed for meaningful time periods and compared to reanalysis data of ERA40 and NCEP. To provide quantitative comparison the mentioned data are interpolated to a common 3x3° grid.
The total amount of variability is separated in its contributors by the application of an Analysis of Variance (ANOVA). For individual GCMs and their ensemble-members this is done with the application of a 1-way ANOVA, separating a treatment common to all ensemble-members and variability perturbating the signal given by different initial conditions. With the 2-way ANOVA the projections of numerous models and their realizations are analysed and the total amount of variability is separated into a common treatment effect, a linear bias between the models, an interaction coefficient and the residuals.
By doing this, the study is fulfilled in a very detailed approach, by considering yearly and seasonal variations in various reasonable time periods of 1961-2000 to match up with the reanalysis data, from 1961-2050 to provide a transient time period, 2001-2098 with exclusive regard on future simulations and 1901-2098 to comprise a time period of maximum length. The statistical analyses are conducted for regional-averages on the one hand and with respect to individual grid-cells on the other hand. For each of these applications the SRES scenarios of A1B, A2 and B1 are utilized. Furthermore, the spatial approach of the ANOVA is substituted by a temporal approach detecting the temporal development of individual variables. Additionally, an attempt is made to enlarge the signal by applying selected statistical methods.
In the detailed investigation it becomes evident, that the different parameters (i.e. length of temporal period, geographic location, climate variable, season, scenarios, models, etc…) have compelling impact on the results, either in enforcing or weakening them by different combinations. This holds on the one hand for the means and trends but also on the other hand for the contributions of the variabilities affecting the uncertainty and the signal. While temperature is a climate variable showing strong signals across these parameters, for precipitation mainly the noise comes to the fore, while for sea-level pressure a more differentiated result manifests. In turn, this recommends the distinguished consideration of the individual parameters in climate impact studies and processes in model generation, as the affecting parameters also provide information about the linkage within the system.
Finally, an investigation of extreme precipitation is conducted, implementing the variables of the total amount of heavy precipitation, the frequency of heavy-precipitation events, the percentage of this heavy precipitation to overall precipitation and the mean daily intensity from events of heavy precipitation. Each time heavy precipitation is defined to exceed the 95th percentile of overall precipitation. Consecutively mean values of these variables are displayed for ECHAM5/MPI-OM and the multi-model mean and climate sensitivities, by means of their difference between their average of the past period of 1981-2000 and the average of one of the future periods of 2046-2065 or 2081-2100. Following this investigation again an ANOVA is conducted providing a quantitative measurement of the severity of change of trends in heavy precipitation across several GCMs.
Besides it is a difficult task to account for extreme precipitation by GCMs, it is noteworthy that the investigated models differ highly in their projections, resulting partially in a more smoothed and meaningful multi-model mean. Seasonal alterations of the strength of this behaviour are quantitatively supported by the ANOVA.
Organic solar cells have great potential to become a low-cost and clean alternative to conventional photovoltaic technologies based on the inorganic bulk material silicon. As a highly promising concept in the field of organic photovoltaics, bulk heterojunction (BHJ) solar cells consist of a mixture of an electron donating and an electron withdrawing component. Their degree of intermixing crucially affects the generation of photocurrent. In this work, the effect of an altered blend morphology on polaron pair dissociation, charge carrier transport, and nongeminate recombination is analyzed by the charge extraction techniques time delayed collection field (TDCF) and open circuit corrected transient charge extraction (OTRACE). Different comparative studies cover a broad range of material systems, including polymer and small-molecule donors in combination with different fullerene acceptors. The field dependence of polaron pair dissociation is analyzed in blends based on the polymer pBTTT-C16, allowing a systematic tuning of the blend morphology by varying the acceptor type and fraction. The effect of both excess photon energy and intercalated phases are minor compared to the influence of excess fullerene, which reduces the field dependence of photogeneration. The study demonstrates that the presence of neat fullerene domains is the major driving force for efficient polaron pair dissociation that is linked to the delocalization of charge carriers. Furthermore, the influence of the processing additive diiodooctane (DIO) is analyzed using the photovoltaic blends PBDTTT-C:PC71BM and PTB7:PC71BM. The study reveals amulti-tiered alteration of the blend morphology of PBDTTT-C based blends upon a systematic increase of the amount of DIO. Domains on the hundred nanometers length scale in the DIO-free blend are identified as neat fullerene agglomerates embedded in an intermixed matrix. With the addition of the additive, 0.6% and 1% DIO already substantially reduces the size of these domains until reaching the optimum 3% DIO mixture, where a 7.1% power conversion efficiency is obtained. It is brought into connection with the formation of interpenetrating polymer and fullerene phases. Similar to PBDTTT-C, the morphology of DIO-free PTB7:PC71BM blends is characterized by large fullerene domains being decreased in size upon the addition of 3% DIO. OTRACE measurements reveal a reduced Langevin-type, super-second order recombination in both blends. It is demonstrated that the deviation from bimolecular recombination kinetics cannot be fully attributed to the carrier density dependence of the mobility but is rather related to trapping in segregated PC71BM domains. Finally, with regard to small-molecule donors, a higher yield of photogeneration and balanced transport properties are identified as the dominant factors enhancing the efficiency of vacuum deposited MD376:C60 relative to its solution processed counterpart MD376:PC61BM. The finding is explained by a higher degree of dimerization of the merocyanine dye MD376 and a stronger donor-acceptor interaction at the interface in the case of the vacuum deposited blend.
In this thesis, the broad band emission, especially in the gamma-ray and radio band, of the active galaxy IC 310 located in the Perseus cluster of galaxies was investigated. The main experimental methods were Cherenkov astronomy using the MAGIC telescopes and high resolution very
long baseline interferometry (VLBI) at radio frequencies (MOJAVE, EVN). Additionally, data
of the object in different energy bands were studied and a multi-wavelength campaign has been
organized and conducted. During the campaign, an exceptional bright gamma-ray flare at TeV
energies was found with the MAGIC telescopes. The results were compared to theoretical acceleration and emission models for explaining the high energy radiation of active galactic nuclei. Many open questions regarding the particle acceleration to very high energies in the jets of active galactic nuclei, the particle content of the jets, or how the jets are launched, were addressed in this thesis by investigating the variability of IC 310 in the very high energy band.
It is argued that IC310 was originally mis-classified as a head-tail radio galaxy. Instead,
it shows a variability behavior in the radio, X-ray, and gamma-ray band similar to the one
found for blazars. These are active galactic nuclei that are characterized by flux variability in all observed energy bands and at all observed time scales. They are viewed at a small angle between the jet axis and the line-of-sight. Thus, strong relativistic beaming influences the variability properties of blazars. Observations of IC 310 with the European VLBI Network helped to find limits for the angle between the jet axis and the line-of-sight, namely 10 deg - 20 deg. This places IC 310 at the borderline between radio galaxies (larger angles) and blazars (smaller angles).
During the gamma-ray outburst detected at the beginning of the multi-wavelength campaign, flux variability as short as minutes was measured. The spectrum during the flare can be described by a simple power-law function over two orders of magnitude in energy up to ~10 TeV. Compared to previous observations, no significant variability of the spectral shape was found. Together with the constraint on the viewing angle, this challenges the currently accepted models for particle acceleration at shock waves in the jets. Alternative models, such as stars moving through the jets, mini-jets in the jet caused, e.g., by reconnection events, or gap acceleration in a pulsar-like magnetosphere around the black hole were investigated. It was found that only the latter can explain all observational findings, which at least suggests that it could even be worthwhile to reconsider published investigations of AGN with this new knowledge in mind.
The first multi-wavelength campaign was successfully been conducted in 2012/2013, including
ground-based as well as space-based telescopes in the radio, optical, ultraviolet, X-ray, and
gamma-ray energy range. No pronounced variability was found after the TeV flare in any energy band. The X-ray data showed a slightly harder spectrum when the emission was brighter. The long-term radio light curve indicated a flickering flux variability, but no strong hint for a
new jet component was found from VLBI images of the radio jet. In any case, further analysis of the existing multi-wavelength data as well as complimentary measurements could provide further exciting insights, e.g., about the broad band spectral energy distribution.
Overall, it can be stated that IC 310 is a key object for research of active galactic nuclei in
the high-energy band due to its proximity and its peculiar properties regarding flux variability
and spectral behavior. Such objects are ideally suited for studying particle acceleration, jet
formation, and other physical effects and models which are far from being fully understood.
The Fanconi anemia (FA) pathway is a replication-dependent DNA repair mechanism which is essential for the removal of interstrand crosslink (ICL) DNA damages in higher eukaryotes (Moldovan and D’Andrea, 2009). Malfunctions in this highly regulated repair network lead to genome instability (Deans and West, 2011). Pathological phenotypes of the disease FA which is caused by mutations in the eponymous pathway are very heterogeneous, involving congenital abnormalities, bone-marrow failure, cancer predisposition and infertility (Auerbach, 2009). The FA pathway comprises a complex interaction network and to date 16 FA complementation groups and associated factors have been identified (Kottemann and Smogorzewska, 2013). Additionally, components of nucleotide excision repair (NER), homologous recombination repair (HRR), and translesion synthesis (TLS) are involved and coordinated by the FA proteins (Niedzwiedz et al., 2004; Knipscheer et al., 2009). One of the FA proteins is the DEAH helicase FANCM. In complex with its binding partners FAAP24 and MHF1/2 it binds the stalled replication fork and activates the FA damage response (Wang et al., 2013). However, the exact steps towards removal of the ICL damage still remain elusive.
To decipher the underlying process of FA initiation by FANCM, this thesis mainly focuses on the archaeal FANCM homolog helicase-associated endonuclease for fork-structured DNA (Hef). Hef from the archaeal organism Thermoplasma acidophilum (taHef) differs from other archaeal Hef proteins and exclusively comprises an N-terminal helicase entity with two RecA and a thumb-like domain while others additionally contain a nuclease portion at the C-terminus. I solved the crystal structure of full-length taHef at a resolution of 2.43 Å. In contrast to the crystal structure of the helicase domain of Hef from Pyrococcus furiosus (pfHef), taHef exhibits an extremely open conformation (Nishino et al., 2005b) which implies that a domain movement of the RecA-like helicase motor domains of 61° is possible thus highlighting the flexibility of helicases which is required to translocate along the DNA. However, small-angle x-ray scattering (SAXS) measurements confirm an intermediate conformation of taHef in solution indicating that both crystal structures represent rather edge states. Most
importantly, proliferating cell nuclear antigen (PCNA) was identified as an interaction partner of Hef. This interaction is mediated by a highly conserved canonical PCNA interacting peptide (PIP) motif. Intriguingly, the presence of PCNA does not alter the ATPase nor the helicase activity of taHef, thus suggesting that the interaction is entirely dedicated to recruit taHef to the replication fork to fulfill its function. Due to a high level of flexibility the taHef-taPCNA complex could not be crystallized and therefore SAXS was utilized to determine a low-resolution model of this quaternary structure.
This newly discovered PCNA interaction could also be validated for the eukaryotic FANCM homolog Mph1 from the thermophilic fungus Chaetomium thermophilum (ctMph1). As the first step towards the characterization of this interaction I solved the crystal structure of PCNA from Chaetomium thermophilum (ctPCNA).
Furthermore, it was possible to achieve preliminary results on the putative interaction between the human proteins FANCM and PCNA (hsFANCM, hsPCNA). In collaboration with Detlev Schindler (Human Genetics, Würzburg) and Weidong Wang (National Institute on Aging, Baltimore, USA) co-immunoprecipitation (CoIP) experiments were performed using hsFANCM and hsPCNA expressed in HEK293 cells. Although an interaction was reproducibly observed in hydroxyurea stimulated cells
further experiments and optimization procedures are required and ongoing.
Leishmaniasis is a neglected tropical disease that can be manifested through different clinical forms, ranging from cutaneous to visceral. The host response against Leishmania spp. is greatly dependent on T cell-mediated immunity, in which T helper 1 responses are associated with macrophage activation and elimination of the parasite, while regulatory T cells and T helper 2 responses are correlated with parasite survival and persistence of infection. Leishmania uses different virulence factors as strategies for evading the immune response of the host. One of them are cathepsin-like cysteine proteases, which are currently under extensive investigation as targets for drug development. Previous studies with inhibitors of cathepsins B and L in vivo revealed an outstanding modulation of the host T helper cell response. However, the mechanisms behind these observations were not further investigated. Given the urgent need for better treatments against leishmaniasis, the aim of this study was to investigate the effects that the lack of cathepsin B and L activity have on the signals that dendritic cells use to instruct T helper cell polarization in response to infection with Leishmania major.
The cathepsin inhibitors tested showed low or no cytotoxicity in bone marrow-derived dendritic cells, and dendritic cells and macrophages could be generated from cathepsin B and cathepsin L-deficient mice without apparent alterations in their phenotype in comparison to wild-type controls. Furthermore, lack of cathepsin B and L activity showed no impact in the rate of promastigote processing by dendritic cells. Cathepsin B and cathepsin L-deficient macrophages showed no differences in parasite proliferation and capacity to produce nitric oxide in comparison to wild-type macrophages. In response to the parasite, dendritic cells treated with a cathepsin B inhibitor and dendritic cells from cathepsin B-deficient mice showed higher levels of expression of major histocompatibility complex (MHC) class II molecules than dimethyl sulfoxide (DMSO) or wild-type controls, but it was not accompanied by changes in the expression of costimulatory molecules. Wild-type dendritic cells and macrophages are not able to express the pro-inflammatory cytokine interleukin (IL)-12 in response to promastigotes. However, cells treated with a cathepsin B inhibitor or cells deficient for cathepsin B were able to express IL-12, whilethe expression of other cytokines -including IL-6 and tumor necrosis factor (TNF)-alpha-remained unchanged. These characteristics point towards a more “pro-Th1” profile of dendritic cells in the absence of cathepsin B.
This data is the first report on IL-12 regulation depending on cathepsin B. The IL-12 up-regulation observed was already present at the transcriptional level. Furthermore, it was also present in macrophages and dendritic cells in response to LPS, and the latter had a higher capacity to induce T cell helper 1 polarization in vitro than wild-type dendritic cells. The activation of different signaling pathways was analyzed, but the up-regulation of IL-12 could not be attributed to modulation of nuclear factor-kappaB (NFkappaB), p38 mitogen activated protein kinase (MAPK) and extra-cellular signal-regulated kinase (ERK)1/2 pathways. Thus, the mechanism behind IL-12 regulation by cathepsin B remains to be elucidated, and the impact of these effects is yet to be confirmed in vivo. Altogether it is tempting to speculate that cathepsin B, in addition to its role in processing endocytosed material, is involved in the modulation of the pro-inflammatory cytokine IL-12.
In mammals, KSR1 functions as an essential scaffold that coordinates the assembly of RAF/MEK/ERK complexes and regulates intracellular signal transduction upon extracellular stimulation. Aberrant activation of the equivalent MAPK signaling pathway has been implicated in multiple human cancers and some developmental disorders. The mechanism of KSR1 regulation is highly complex and involves several phosphorylation/dephosphorylation steps. In the present study, a number of novel in vivo phosphorylation sites were detected in mKSR1 by use of mass spectrometry analysis. Among others, Tyr728 was identified as a unique regulatory residue phosphorylated by LCK, a Src kinase family member. To understand how phosphorylation of Tyr728 may regulate the function of KSR1 in signal transduction and cellular processes, structural modeling and biochemical studies were integrated in this work.
Computational modeling of the mKSR1(KD) protein structure revealed strong hydrogen bonding between phospho-Tyr728 and the residues surrounding Arg649. Remarkably, this pattern was altered when Tyr728 was non-phosphorylated or substituted. As confirmed by biochemical analysis, Arg649 may serve as a major anchor point for phospho-Tyr728 in order to stabilize internal structures of KSR1. In line with the protein modeling results, mutational studies revealed that substitution of Tyr728 by phenylalanine leads to a less compact interaction between KSR1 and MEK, a facilitated KSR1/B-RAF binding and an increased phosphorylation of MEK in complex with KSR1. From these findings it can be concluded that phospho-Tyr728 is involved in tightening the KSR1/MEK interaction interface and in regulating the phosphorylation of KSR1-bound MEK by either RAF or KSR1 kinases.
Beside the Tyr728, Ser722 was identified as a novel regulatory phosphorylation site. Amino acid exchanges at the relevant position demonstrated that Ser722 regulates KSR1-bound MEK phosphorylation without affecting KSR1/MEK binding per se. Due to its localization, Ser722 might consequently control the catalytic activity of KSR1 by interfering with the access of substrate (possibly MEK) to the active site of KSR1 kinase. Together with Ser722, phosphorylated Tyr728 may further positively affect the kinase activity of KSR1 as a consequence of its vicinity to the activation and catalytic loop in the KSR1(KD). As revealed by structural modeling, phospho-Tyr728 builds a hydrogen bond with the highly conserved Lys685. Consequently, phospho-Tyr728 has a stabilizing effect on internal structures involved in the catalytic reaction and possibly enhances the phosphate transfer within the catalytic cleft in KSR1. Considering these facts, it seems very likely that the LCK-dependent phosphorylation of Tyr728 plays a crucial role in the regulation of KSR1 catalytic activity.
Results of fractionation and morphology analyses revealed that KSR1 recruits LCK to cytoskeleton for its phosphorylation at Tyr728 suggesting that this residue may regulate cytoskeleton dynamics and, consequently, cell motility. Beside that, phosphorylation of Tyr728 is involved in the regulation of cell proliferation, as shown by a significantly reduced population doubling time of KSR1-Y728F cells compared to cells expressing wild type KSR1.
Taken together, tyrosine phosphorylation in KSR1 uncovers a new link between Src family kinases and MAPK signaling. Tyr728, the novel regulatory phosphorylation site in murine KSR1, may coordinate the transition between the scaffolding and the catalytic function of KSR1 serving as a control point used to fine-tune cellular responses.
Besides HIV and tuberculosis, malaria still is one of the most devastating infectious diseases especially in developing countries, with Plasmodium falciparum being responsible for the frequently lethal form of malaria tropica. It is a major cause of mortality as well as morbidity, whereby pregnant women and children under the age of five years are most severely affected. Rapidly emerging drug resistances and the lack of an effective and safe vaccine hamper the combat against malaria by chemical and pharmacological regimens, and moreover the poor socio-economic and healthcare conditions in malaria-endemic countries are compromising the extermination of this deadly tropical disease to a large extent. Malaria research is still questing for druggable targets in the parasitic protozoan which pledge to be refractory against evolving resistance-mediating mutations and yet constitute affordable and compliant antimalarial chemotherapeutics.
The parasite kinome consists of members that represent most eukaryotic protein kinase groups, but also contains several groups that can not be assigned to conservative ePK groups. Moreover, given the remarkable divergence of plasmodial kinases in respect to the human host kinome and the fact that several plasmodial kinases have been identified that are essential for the intraerythrocytic developmental cycle, these parasite enzymes represent auspicious targets for antimalarial regimens. Despite elaborate investigations on several other ePK groups, merely scant research has been conducted regarding the four identified members of the cyclin-dependent kinase-like kinase (CLK) family, PfCLK-1-4. In other eukaryotes, CLKs are involved in mRNA processing and splicing by means of phosphorylation of serine/arginine-rich (SR) proteins, which are crucial components of the splicing machinery in the alternative splicing pathway. All four PfCLKs are abundantly expressed in asexual parasites and gametocytes, and stage-specific expression profiles of PfCLK-1 and PfCLK-2 exhibited nucleus-associated localization and an association with phosphorylation activity. In the course of this study, PfCLK-3 and PfCLK-4 were functionally characterized by indirect immunofluorescence, Western blot analysis and kinase activity assays. These data confirm that the two kinases are primarily expressed in the nucleus of trophozoites and both kinases possess in vitro phosphorylation activity on physiological substrates. Likewise PfCLK-1 and PfCLK-2, reverse genetic studies exhibited the indispensability of both PfCLKs on the asexual life cycle of P. falciparum, rendering them as potential candidates for antiplasmodial strategies. Moreover, this study was conducted to identify putative SR proteins as substrates of all four PfCLKs. Previous alignments revealed a significant homology of the parasite CLKs to yeast SR protein kinase Sky1p. Kinase activity assays showed in vitro phosphorylation of the yeast Sky1p substrate and SR protein Npl3p by precipitated PfCLKs. In addition, four homologous plasmodial SR proteins were identified that are phosphorylated by PfCLKs in vitro: PfASF-1, PFSRSF12, PfSFRS4 and PfSR-1. All four parasite SR splicing factors are predominantly expressed in the nuclei of trophozoites. For PfCLK-1, a co-localization with the SR proteins was verified.
Finally, a library of human and microbial CLK inhibitors and the antiseptic chlorhexidine (CHX) was screened to determine their inhibitory effect on different parasite life cycle stages and on the PfCLKs specifically. Five inhibitors out of 63 compounds from the investigated library were selected that show a moderate inhibition on asexual life cycle stages with IC50 values ranging between approximately 4 and 8 µM. Noteworthy, these inhibitors belong to the substance classes of aminopyrimidines or oxo-β-carbolines. Actually, the antibiotic compound CHX demonstrated an IC50 in the low nanomolar range. Stage-of-inhibition assays revealed that CHX severely affects the formation of schizonts. All of the selected CLKs inhibitors also affect gametocytogenesis as well as gametogenesis, as scrutinized in gametocyte toxicity assays and exflagellation assays, respectively. Kinase activity assays confirm a specific inhibition of CLK-mediated phosphorylation of all four kinases, when the CLK inhibitors are applied on immunoprecipitated PfCLKs. These findings on PfCLK-inhibiting compounds are initial attempts to determine putative antimalarial compounds targeting the PfCLKs. Moreover, these results provide an effective means to generate chemical kinase KOs in order to phenotypically study the role of the PfCLKs especially in splicing events and mRNA metabolism. This approach of functionally characterizing the CLKs in P. falciparum is of particular interest since the malarial spliceosome is still poorly understood and will gain further insight into the parasite splicing machinery.
The cytokine Interleukin-4 (IL-4) plays a crucial role in the pathophysiology and progression of asthma and other atopic diseases. Its activities are signaled into the cells upon binding to and signaling through a shared receptor complex composed of the subunits IL-4Rα and common γc. Another cytokine, Interleukin-13 shares many functions with IL-4. This can be explained by the fact that both, IL-4 and IL-13, can signal via a shared receptor complex comprising the IL-4R and the IL-13R1 subunit.
Therefore, the IL-4Rα receptor subunit has become a highly promising drug target, since it mediates IL-4 and IL-13 responses and blocking IL-4Rα will abrogate IL-4 as well as IL-13 effector functions. Currently, an IL-4 based mutein (Pitrakinra), acting as a dual IL-4/IL-13 receptor antagonist is in clinical development.
This work describes the generation and production of biologically active IL-4 muteins, which contain a single additional engineered cysteine. The introduction of a free thiol group allows site-specific chemical modification. The muteins were expressed in E. coli in insoluble form, refolded and purified. The thiol group of the mutein was protected as mixed disulfide with the tripeptide glutathione.
A first attempt to chemically reduce the engineered cysteine residue failed, because the three native disulfide bonds of IL-4 exhibit a similar reactivity and chemical reduction of the native disulfide resulted in full deactivation and precipitation of the IL-4 protein. Therefore, an enzymatic approach was developed which specifically reduces the mixed disulfide bonds with an attached glutathion moiety and thus leaves the native structurally essential disulfide bonds unaltered. For optimization, four different IL-4 cysteine muteins with four cysteine residues introduced at positions close to the IL-4Rα binding site were tested and their reduction rates by glutaredoxin was determined. The enzymatic reduction occured at different rates for all four muteins indicating that accessibility is an important influence and must be determined individually for each mutant protein. After optimization of the pH value and particularly the reaction time, all muteins could be prepared with the engineered thiol group being released in reasonable yield. The proteins exhibiting the free thiol group were then modified by
N-ethylmaleimide (NEM) or maleimido-PEG. The effects of these modifications at different positions on binding to IL-4R were measured employing SPR biosensor technology.
In the second project of this study, foldamers, which represent a new class of stable, compactly folded biomolecules and can specifically interact with proteins and nucleic acids, were examined to identify their potential as new drugs to interfere with IL-4 activities.
Fragment-based drug discovery offers great promise for providing new starting points for drug discovery and facilitates the lead optimization. As foldamers equipped with a thiol-group for tethering could not to be produced; only the effect of foldamers present in a synthesized foldamer library on the binding to IL-4R could be tested. Two libraries containing different foldamers based on aromatic amide were synthesized by Michael Grotz and Dr. Michael Deligny and tested in our lab for their capability to disrupt the ligand-receptor interaction of IL-4 and its receptor IL-4Rα [ECD] using surface plasmon resonance technology. None of the studied foldamers could specifically inhibit the IL-4/IL-4Rα interaction. Some foldamers showed non-specific binding.
The study presented here shows the design and production of a potentially new type of IL-4 antagonists, which employ site-specific chemical modification to exert their antagonistic function.
In the framework of this thesis, the structural and electronic properties of bismuth and lead deposited on Ag(111) have been investigated by means of low-temperature scanning tunneling microscopy (LT-STM) and spectroscopy (STS).
Prior to spectroscopic investigations the growth characteristics have been investigated by means of STM and low energy electron diffraction (LEED) measurements. Submonolayer coverages as well as thick films have been investigated for both systems.
Subsequently the quantum well characteristics of thick Pb films on Ag(111) have been analyzed and the quantum well character could be proved up to layer thicknesses of N ≈ 100 ML. The observed characteristics in STS spectra were explained by a simple cosine Taylor expansion and an in-plane energy dispersion could be detected by means of quasi-particle interferences.
The main part of this work investigates the giant Rashba-type spin-split surface alloys of
(√3 × √3)Pb/Ag(111)R30◦ and (√3 × √3)Bi/Ag(111)R30◦. With STS experiments the band positions and splitting strengths of the unoccupied (√3 × √3)Pb/Ag(111)R30◦ band
dispersions could be resolved, which were unclear so far. The investigation by means of quasi-particle interferences resulted in the observation of several scattering events, which could be assigned as intra- and inter-band transitions.
The analysis of scattering channels within a simple spin-conservation–approach turned out to be incomplete and led to contradictions between experiment and theory. In this framework more sophisticated DFT calculations could resolve the apparent deviations by a complete treatment of scattering in spin-orbit–coupled materials, which allows for
constructive interferences in spin-flip scattering processes as long as the total momentum J_
is conserved.
In a similar way the band dispersion of (√3 × √3)Bi/Ag(111)R30◦ was investigated. The
STS spectra confirmed a hybridization gap opening between both Rashba-split bands and several intra- and inter-band scattering events could be observed in the complete energy range. The analysis within a spin-conservation–approach again turned out to be insufficient for explaining the observed scattering events in spin-orbit–coupled materials, which was confi by DFT calculations. Within these calculations an inter-band scattering event that has been identified as spin-conserving in the simple model could be assigned as a spin-flip scattering channel. This illustrates evidently how an incomplete description can lead to completely different indications.
The present work shows that different spectroscopic STM modes are able to shed light on Rashba-split surface states. Whereas STS allowed to determine band onsets and splitting strengths, quasi-particle interferences could shed light on the band dispersions. A very important finding of this work is that spin-flip scattering events may result in constructive interferences, an eff which has so far been overlooked in related publications. Additionally it has been found that STM measurements can not distinguish between spin-conserving scattering events or spin-flip scattering events, which prevents to give a definite conclusion on the spin polarization for systems with mixed orbital symmetries just from the observed scattering events.
Studies on receptor signaling and regulation in platelets and T cells from genetically modified mice
(2014)
Receptors with tyrosine-based signaling motifs control essential functions of hematopoietic cells, including lymphocytes and platelets. Downstream of the platelet receptor glycoprotein (GP) VI and the T cell receptor (TCR) the immunoreceptor tyrosine-based activation motif (ITAM) initiates a signaling cascade that involves kinases, adapter and effector proteins and finally leads to cellular activation. This thesis summarizes the results of three studies investigating different aspects of receptor signaling and regulation in platelets and T cells.
In the first part, the impact of constitutive Ca2+ influx on TCR signaling and T cell physiology was investigated using a transgenic mouse line with a mutation in the Ca2+ sensor stromal interaction molecule 1 (STIM1). The elevated cytoplasmic Ca2+ level resulted in an altered phosphorylation pattern of the key enzyme phospholipase (PL) Cγ1 in response to TCR stimulation, but without affecting its enzymatic activity. Withdrawal of extracellular Ca2+ or inhibition of the phosphatase calcineurin restored the normal phosphorylation pattern. In addition, there was a decrease in the release of Th2-type cytokines interleukin 4, 5 and 13 upon stimulation in vitro.
The second part of the thesis deals with the role of the adapter protein growth factor receptor-bound protein 2 (Grb2) in platelets using a megakaryocyte/platelet-specific knockout mouse line. Loss of Grb2 severely impaired signaling of GPVI and C-type lectin-like receptor 2 (CLEC-2), a related hemITAM receptor. This was attributed to defective stabilization of the linker for activation of T cells (LAT) signalosome and resulted in reduced adhesion, aggregation, Ca2+ mobilization and procoagulant activity downstream of (hem)ITAM-coupled receptors in vitro. In contrast, the signaling pathways of G protein-coupled receptors (GPCRs) and the integrin αIIbβ3, which do not utilize the LAT signalosome, were unaffected. In vivo, the defective (hem)ITAM signaling caused prolonged bleeding times, however, thrombus formation was only affected under conditions where GPCR signaling was impaired (upon acetylsalicylic acid treatment). These results establish Grb2 as an important adapter protein in the propagation of GPVI- and CLEC-2-induced signals.
Finally, the proteolytic regulation of the immunoreceptor tyrosine-based switch motif (ITSM)-bearing receptor CD84 in platelets was investigated. This study demonstrated that in mice CD84 is cleaved by two distinct and independent proteolytic mechanisms upon platelet activation: shedding of the extracellular part, which is exclusively mediated by a disintegrin and metalloproteinase (ADAM) 10 and cleavage of the intracellular C-terminus by the protease calpain. Finally, the analysis of soluble CD84 levels in the plasma of transgenic mice revealed that shedding of CD84 by ADAM10 occurs constitutively in vivo.
Evolution of Vγ9Vδ2 T-cells
(2014)
Human Vγ9Vδ2 T cells are the major subset of blood γδ T cells and account for 1-5% of blood T cells. Pyrophosphorylated metabolites of isoprenoid biosynthesis are recognized by human Vγ9Vδ2 T cells and are called as phosphoantigens (PAg). Isopentenyl pyrophosphate (IPP) and (E)-4-Hydroxy-3-methyl-but-2-enyl pyrophosphate (HMBPP) are among the few well studied PAg. IPP is found in all organisms while HMBPP is a precursor of IPP found only in eubacteria, plants and apicomplexaen parasite. Interestingly, the PAg reactive Vγ9Vδ2 T cells are so far identified only in human and higher primates but not in rodents. Hence, Vγ9Vδ2 T cells are believed to be restricted to primates. With regard to PAg recognition, a Vγ9JP recombined TCRγ chain and certain CDR3 motifs of the TCR chain are mandatory. The BTN3A1 molecule is essential for a response to PAg. BTN3 is a trans-membrane protein belonging to butyrophilin family of proteins. Though BTN3A1 was found to be essential for PAg presentation, the exact molecular basis of PAg presentation still remains unclear.
This thesis presents new data on the evolution of Vγ9Vδ2 TCR and its ligands (BTN3) as well as the genetic basis of PAg presentation to Vγ9Vδ2 TCR.
The comprehensive analysis of genomic database sequences at NCBI and other public domain databases revealed for the first time that Vγ9, Vδ2 and BTN3 genes emerged and co-evolved along with the placental mammals. Vγ9, Vδ2 and BTN3 genes are scattered across mammalian species and not restricted to primates. But interestingly, all three genes are highly conserved between phylogenetically distinct species. Moreover, the distribution pattern of Vγ9, Vδ2 TCR genes and BTN3 genes suggests a functional association between these genes representing the TCR - ligand relationship. Alpaca (Vicugna pacos), a member of the camelid family, is one among the 6 candidate non-primate species which were found to possess functional Vγ9, Vδ2 and BTN3 genes.
From peripheral lymphocytes of alpaca, Vγ9 chain transcripts with a characteristic JP rearrangement and transcripts of Vδ2 chains with a CDR3 typical for PAg-reactive TCR were identified. The transduction of αβ TCR negative mouse thymoma BW cells with alpaca Vγ9 and Vδ2 TCR chains resulted in surface expression of the TCR complex as it was deduced from detection of cell surface expression of mouse CD3. Cross-linking of alpaca Vγ9Vδ2 TCR transductants with anti-CD3ε led to IL-2 production which confirmed that alpaca Vγ9 and Vδ2 TCR chains pair to form a functional TCR. Besides the conservation of human like Vγ9 and Vδ2 TCR chains, alpaca has conserved an orthologue for human BTN33A1 as well. Interestingly, the predicted PAg binding sites of human BTN3A1 was 100% conserved in deduced amino acid sequence of alpaca BTN3A1. All together alpaca is a promising candidate for further studies as it might have preserved Vγ9Vδ2 T cells to function in surveillance of stress and infections.
This thesis also provides the sequence of Vγ9Vδ2 TCR of African green monkey (Chlorocebus aethiops), which was previously unknown. Moreover, our data indicates the lack of any species specific barrier which could hinder the PAg presentation by African monkey derived COS cells to human Vγ9Vδ2 TCR and vice versa of human cells to African green monkey Vγ9Vδ2 TCR which was in contradiction to previously reported findings.
Apart from the above, the thesis also presents new data on the genetic basis of PAg presentation to Vγ9Vδ2 T cells, which revealed that human chromosome 6 is sufficient for the presentation of exogenous and endogenous PAg. By employing human/mouse somatic hybrids, we identified the role of human chromosome 6 in PAg presentation and in addition, we observed the lack of capacity of human chromosome 6 positive hybrids to activate Vγ9Vδ2 TCR transductants in the presence of the alkylamine sec-butylamine (SBA). Investigation of Chinese hamster ovary (CHO) cells containing the human chromosome 6 also yielded similar results. This suggests that aminobisphosphonates (zoledronate) and alkylamines employ different mechanisms for activation of Vγ9Vδ2 T cells although both have been described to act by inhibition of farnesyl pyrophosphate synthase activity which is known to increase intracellular levels of the IPP.
In conclusion, this thesis suggests that Vγ9, Vδ2 and BTN3 genes controlling Vγ9Vδ2 TCR- ligand relationship emerged and co-evolved along with placental mammals; and also identified candidate non-primate species which could possess Vγ9Vδ2 T cells. Furthermore, it suggests alpaca as a promising non-primate species to investigate the physiological function of Vγ9Vδ2 T cells. With respect to PAg antigen presentation it was shown that chromosome 6 is essential and sufficient for exogenous and endogenous PAg presentation. Moreover, the alkylamine SBA and aminobisphosphonate zoledronate may engage different cellular mechanism to exert inhibition over IPP consumption. The thesis raises interesting questions which need to be addressed in future: 1) What are the environmental and evolutionary factors involved in preservation of Vγ9Vδ2 T cells only by few species? 2) What could be the functional nature and antigen recognition properties of such a conserved T cell subset? 3) What is the genetic and molecular basis of the differential capacity of human chromosome 6 bearing rodent-human hybridoma cells in activating Vγ9Vδ2 T cells in presence of SBA and aminobisphosphonates?
Organisms use different resources in different habitat types during their life cycle. Thereby, they connect habitats and provide ecosystem services or disservices in several habitat types. In agricultural landscapes, the spillover of organisms, i.e. movement of an organism and its function from one habitat to another, especially from semi-natural to managed habitats, is one of the most important processes that influence population dynamics and community composition. Importantly, spillover connects habitats not only spatially, but also on different temporal scales, because availability of resources changes over time in agricultural landscapes, e.g. by mass-flowering events of crops, harvesting or crop rotation. Most often, semi-natural habitats are seen as beneficial source of organisms, but also managed habitats can provide valuable resources, and thereby initiate spillover to other habitats. Mass-flowering crops, like oil-seed rape, are such valuable feeding resources for pollinators, and pollinators might spillover from oil-seed rape to other habitats which provide alternative foraging resources. The focus of this dissertation was to evaluate the influence of oil-seed rape on pollinators in agricultural landscapes by studying effects (1) on different temporal scales (from effects during the flowering period of oil-seed rape, Chapter II & IV, to intermediate effects on a second mass-flowering crop, Chapter III, to spillover effects to the flowering period in the next year, Chapter IV), (2) semi-natural (Chapter II) and crop (Chapter III, IV) habitats, and (3) on various pollinator groups which differ in their life cycle (Chapter II, III, IV).
In this dissertation effects from oil-seed rape on all temporal scales – in the short term during mass-flowering and in the long term on a late-flowering crop and even in the next year on oil-seed rape fields ─ were found. These effects might be important for crop and wild plant pollination, and pollinator conservation. Importantly, the effects on different temporal scales depend on the considered habitat (managed or different semi-natural habitats) and on the investigated pollinator group. The more pollinators match the flowering period of oil-seed rape in their activity period and the more dependent they are on flowering resources in their life cycle, the more pronounced are their responses. Effects were found for wild bees, but not for hoverflies and honey bees. Moreover, the availability of semi-natural habitats in the landscape is important and may modulate effects from oil-seed rape. The longevity of effects of oil-seed rape shows the importance of including several temporal scales into ecosystem-service studies, not only for pollinators, but also for other ecosystem-service providing species groups.
Chlamydia trachomatis is an obligate intracellular pathogen that replicates inside a vacuole, the so-called inclusion. During replication by a biphasic life-cycle Chlamydia secrete via their type 3 secretion system various effector proteins into the inclusion lumen, the inclusion membrane or the host cell cytosol to form their favored replication niche. Chlamydia-infected cells are highly resistant against apoptosis since the replicative form of Chlamydia is non-infectious and premature cell death would cause complete loss of one Chlamydia generation. The bacteria block apoptosis by preventing mitochondrial outer membrane permeabilization. Various proteins with anti-apoptotic function are enriched in Chlamydia-infected cells such as Mcl-1, cIAP2, Survivin or HIF1α. The accumulation of these proteins is a result of increased gene expression and direct protein stabilization. However, the molecular mechanisms and involved bacterial effector proteins are mostly unknown.
With this work the molecular mechanisms of Mcl-1 stabilization and the participation of chlamydial factors were investigated. Mcl-1 is a member of the Bcl-2 protein family and has an extremely short half-life causing its permanent ubiquitination and subsequent degradation by the 26S proteasome under normal homeostasis whilst Mcl-1 accumulation results in apoptosis inhibition. It was shown that during C. trachomatis infection Mcl-1 ubiquitination is reduced causing its stabilization albeit no cellular ubiquitin-proteasome-system components are involved in this process. However, C. trachomatis express the two deubiquitinases ChlaDUB1 and ChlaDUB2 which are mostly uncharacterized. With this work the expression profile, subcellular localization, substrates and function of the deubiquitinases were investigated. It was shown that ChlaDUB1 is secreted to the surface of the inclusion where it interacts with Mcl-1 which is accumulated in the proximity of this compartment. By utilization of infection experiments, heterologous expression systems and in vitro experiments a direct interaction of ChlaDUB1 and Mcl-1 was demonstrated. Furthermore, it was shown that Mcl-1 is deubiquitinated by ChlaDUB1 causing its stabilization. During replicative phase of infection, ChlaDUB2 seems to be accumulated in the chlamydial particles. However, ChlaDUB2 substrates could not be identified which would give an indication for the physiological role of ChlaDUB2.
Since 2011, a protocol to transform C. trachomatis with artificial plasmid DNA is available. As part of this work the transformation of C. trachomatis with plasmid DNA suitable for the permanent or inducible protein overexpression on a routinely basis was established. In addition, the first targeted homologous recombination into the chlamydial genome to replace the ChlaDUB1 gene by a modified one was performed and validated. The targeted homologous recombination was also used to create a ChlaDUB1 knock-out mutant; however deletion of ChlaDUB1 seems to be lethal for C. trachomatis. Due to the fact that ChlaDUB1-lacking Chlamydia could not be obtained an inhibitor screen was performed and identified CYN312 as a potential ChlaDUB1 inhibitor. Application of CYN312 during infection interfered with chlamydial growth and reduced Mcl-1 quantity in infected cells. Furthermore, CYN312 treated Ctr-infected cells were significantly sensitized for apoptosis.
Taken together, C. trachomatis secretes the deubiquitinase ChlaDUB1 to the surface of the inclusion where it deubiquitinates Mcl-1 causing its accumulation in infected cells resulting in apoptosis resistance. Application of the ChlaDUB1 inhibitor CYN312 interferes with Mcl-1 stabilization sensitizing infected cells for apoptosis.
The haloacid dehalogenase (HAD) family of phosphatases is an ancient, ubiquitous group of enzymes, and their emerging role in human health and disease make them attractive targets for detailed analyses.
This thesis comprises the biochemical and structural characterization of chronophin, an HAD-type
phosphatase, which has been shown to act on Ser3-phosphorylated cofiln-1, a key regulator of actin dynamics, and on the Ser/Thr-phosphorylated steroid receptor co-activator 3 (SRC-3). Besides being a specific phosphoprotein phosphatase, chronophin also acts on the small molecule pyridoxal 5'-phosphate (PLP, vitamin B6), implying that chronophin serves as a regulator of a variety important physiological pathways. The analysis of chronophin was performed on different levels, ranging from intrinsic regulatory mechanisms, such as the allosteric regulation via dimerization or the characterization of specificity determinants, to modes of extrinsic modulation, including the association with putative interacting proteins or the generation of chronophin-specific inhibitors.
The association of the previously identified putative chronophin interactors calcium- and integrinbinding protein 1 (CIB1) and calmodulin was investigated using recombinantly expressed and purified proteins. These studies revealed that the interaction of chronophin with CIB1 or calmodulin is mutually exclusive and regulated by calcium. Neither CIB1 nor calmodulin had an effect on the in vitro chronophin phosphatase activity towards PLP or phospho-cofilin-1, but might regulate other functions of this important phosphatase.
The role of chronophin dimerization was studied by generating a constitutively monomeric variant,
which showed reduced PLP hydrolyzing activity. X-ray crystallographic studies revealed that dimerization is essential for the positioning of the substrate specificity loop in chronophin, unraveling a previously unknown mechanism of allosteric regulation through a homophilic interaction. This mechanism potentially applies to other enzymes of the C2a subfamily of HAD-type phosphatases, as all structurally characterized members show a conserved mode of dimerization.
The general determinants of substrate specificity in the C2a subfamily of HAD phosphatases were
investigated by performing domain swapping experiments with chronophin and its paralog AUM and
subsequent biochemical analyses of the hybrid proteins. The X-ray crystallographic structure
determination of the chronophin catalytic domain equipped with the AUM capping domain revealed the first partial structure of AUM. This structural information was then used in subsequent studies that analyzed the divergent substrate specificities of AUM and chronophin in an evolutionary context.
Finally, a set of four chronophin inhibitors were generated based on the structure of PLP and
characterized biochemically, showing moderate inhibitory effects with IC50-values in the micromolar range. These compounds nevertheless constitute valuable tools for future in vitro experiments, such as studies concerning the structure-function relationship of chronophin as a PLP phosphatase. In addition, the crystal structure of one inhibitor bound to chronophin could be solved. These results provide the basis for the further development of competitive chronophin inhibitors with increased specificity and potency.
The present thesis “Hot spin carriers in cold semiconductors” investigates hot carrier effects in low-temperature photoinduced magneto-optical Kerr effect (MOKE) microscopy of electron spins in semiconductor heterostructures. Our studies reveal that the influence of hot photocarriers in magneto-optical pump-probe experiments is twofold.
First, it is commonly assumed that a measurement of the local Kerr rotation using an arbitrary probe wavelength maps the local electron spin polarization. This is the fundamental assumption that underlies the widely used two-color MOKE microscopy technique. Our continuous-wave (cw) spectroscopy experiments demonstrate that this assumption is not correct.
At low lattice temperatures the nonresonant spin excitation by the focused pump laser inevitably leads to a strong heating of the electron system. This heating, in turn, locally modifies the magneto-optical coefficient which links the experimentally observed Kerr rotation to the electron spin polarization. As a consequence, the spin-induced local Kerr rotation is augmented by spin-unrelated changes in the magneto-optical coefficient. A spatially resolved measurement of the Kerr rotation then does not correctly map the electron spin polarization profile.
We demonstrate different ways to overcome this limitation and to correctly measure the electron spin profile. For cw spectroscopy we show how the true local electron spin polarization can be obtained from a quantitative analysis of the full excitonic Kerr rotation spectrum. Alternatively, picosecond MOKE microscopy using a spectrally broad probe laser pulse mitigates hot-carrier effects on the magneto-optical spin detection and allows to directly observe the time-resolved expansion of optically excited electron spin packets in real-space.
Second, we show that hot photocarriers strongly modify the spin diffusion process. Owing to their high kinetic energy, hot carriers greatly enhance the electron spin diffusion coefficient with respect to the intrinsic value of the undisturbed system. Therefore, for steady-state excitation the spin diffusivity is strongly enhanced close to the pump spot center where hot electrons are present. Similarly, for short delays following pulsed excitation the high initial temperature of the electrons leads to a very fast initial expansion of the spin packet which gradually slows as the electrons cool down to the lattice temperature.
While few previous publications have recognized the possible influence of hot carriers on the electron spin transport properties, the present work is the first to directly observe and quantify such hot carrier contributions. We develop models which for steady-state and pulsed excitation quantitatively describe the experimentally observed electron spin diffusion. These models are capable of separating the intrinsic spin diffusivity from the hot electron contribution, and allow to obtain spin transport parameters of the undisturbed system.
We perform extensive cw and time-resolved spectroscopy studies of the lattice temperature dependence of the electron spin diffusion in bulk GaAs. Using our models we obtain a consistent set of parameters for the intrinsic temperature dependence of the electron spin diffusion coefficient and spin relaxation time and the hot carrier contributions which quantitatively describes all experimental observations. Our analysis unequivocally demonstrates that we have, as we believe for the first time, arrived at a coherent understanding of photoinduced low-temperature electron spin diffusion in bulk semiconductors.
Calcium ions can activate intracellular signalling cascades that control key functions in all types of neurons. These functions include neuronal excitability and excitation, synaptic plasticity, cell migration, transmitter release, gene transcription, and apoptosis. The major intracellular neuronal store for calcium is the endoplasmic reticulum (ER), a continuous and dynamic, membranous organelle that extends through all parts of neurons, from axons to dendrites. The calcium concentration in the ER is appr. one thousand fold higher than in the cytosol and this calcium gradient is built up by the sarco-/endoplasmic reticulum calcium ATPase (SERCA) pump that pumps calcium from the cytosol into the ER.
Despite detailed knowledge about various induced calcium signals within neurons, it was still elusive, how resting neurons maintain their ER calcium content at rest. In order to shed light on the calcium homeostasis at rest, the targeted-esterase induced dye loading (TED) technique was improved. TED allows the direct and non-disruptive visualization of ER calcium in presence of extracellular calcium, thus enabling to visualize the dynamic flow of ER calcium. TED is based on the overexpression of an ER-targeted mouse carboxylesterase. Inside the ER the carboxylesterase cleaves the acetoxymethyl ester calcium dye Fluo5N, AM, thereby converting this dye into a calcium sensitive, low-affinity, cell membrane impermeable calcium indicator that is trapped in the ER. When bound to calcium ions and excited by fluorescent light, its fluorescence intensity increases one hundredfold compared to the calcium-free state.
It was observed that calcium withdrawal from resting neurons led to a rapid loss of calcium from both the ER and the cytosol, which recovered upon calcium re-addition. It was concluded that a strong calcium influx and efflux must exist under resting conditions that maintain a constant calcium concentration in neurons at rest. TED calcium imaging could visualize this resting calcium influx event. When the inhibitor of store-operated calcium entry (SOCE), SKF-96365, was acutely added to neurons an immediate decline in ER calcium levels was observed, whereas cytosolic calcium levels remained constant. Based on these findings, a novel calcium homeostasis model is proposed in which a strong SOCE-like calcium influx and a corresponding calcium efflux maintain the ER calcium levels at rest. These fluxes are adapted to disturbances in order to maintain a constant calcium level in resting neurons.
This study visualizes for the first time the resting calcium flow into the ER. The calcium enters the neurons via a store-operated calcium entry-like mechanism, a form of calcium influx that was thought to be induced by signalling events.
Remote sensing for disease risk profiling: a spatial analysis of schistosomiasis in West Africa
(2014)
Global environmental change leads to the emergence of new human health risks. As a consequence, transmission opportunities of environment-related diseases are transformed and human infection with new emerging pathogens increase. The main motivation for this study is the considerable demand for disease surveillance and monitoring in relation to dynamic environmental drivers. Remote sensing (RS) data belong to the key data sources for environmental modelling due to their capabilities to deliver spatially continuous information repeatedly for large areas with an ecologically adequate spatial resolution.
A major research gap as identified by this study is the disregard of the spatial mismatch inherent in current modelling approaches of profiling disease risk using remote sensing data. Typically, epidemiological data are aggregated at school or village level. However, these point data do neither represent the spatial distribution of habitats, where disease-related species find their suitable environmental conditions, nor the place, where infection has occurred. As a consequence, the prevalence data and remotely sensed environmental variables, which aim to characterise the habitat of disease-related species, are spatially disjunct.
The main objective of this study is to improve RS-based disease risk models by incorporating the ecological and spatial context of disease transmission. Exemplified by the analysis of the human schistosomiasis disease in West Africa, this objective includes the quantification of the impact of scales and ecological regions on model performance.
In this study, the conditions that modify the transmission of schistosomiasis are reviewed in detail. A conceptual underpinning of the linkages between geographical RS measures, disease transmission ecology, and epidemiological survey data is developed. During a field-based analysis, environmental suitability for schistosomiasis transmission was assessed on the ground, which is then quantified by a habitat suitability index (HSI) and applied to RS data. This conceptual model of environmental suitability is refined by the development of a hierarchical model approach that statistically links school-based disease prevalence with the ecologically relevant measurements of RS data. The statistical models of schistosomiasis risk are derived from two different algorithms; the Random Forest and the partial least squares regression (PLSR). Scale impact is analysed based on different spatial resolutions of RS data. Furthermore, varying buffer extents are analysed around school-based measurements. Three distinctive sites of Burkina Faso and Côte d’Ivoire are specifically modelled to represent a gradient of ecozones from dry savannah to tropical rainforest including flat and mountainous regions.
The model results reveal the applicability of RS data to spatially delineate and quantitatively evaluate environmental suitability for the transmission of schistosomiasis. In specific, the multi-temporal derivation of water bodies and the assessment of their riparian vegetation coverage based on high-resolution RapidEye and Landsat data proofed relevant. In contrast, elevation data and water surface temperature are constraint in their ability to characterise habitat conditions for disease-related parasites and freshwater snail species. With increasing buffer extent observed around the school location, the performance of statistical models increases, improving the prediction of transmission risk. The most important RS variables identified to model schistosomiasis risk are the measure of distance to water bodies, topographic variables, and land surface temperature (LST). However, each ecological region requires a different set of RS variables to optimise the modelling of schistosomiasis risk. A key result of the hierarchical model approach is its superior performance to explain the spatial risk of schistosomiasis.
Overall, this study stresses the key importance of considering the ecological and spatial context for disease risk profiling and demonstrates the potential of RS data. The methodological approach of this study contributes substantially to provide more accurate and relevant geoinformation, which supports an efficient planning and decision-making within the public health sector.
The present dissertation analyzes whether bank debt lending influences certain managerial decisions of borrowers, and if so, how. More precisely, the thesis investigates the influence of bank debt lending on the cost of debt and capital structure of firms, and on the accounting behavior of borrowers prior to borrowing new bank debt. The major aim of the dissertation is to deliver empirical evidence that central managerial decisions of companies are not only made by managers and equity owners but also driven by important debt investors. The objects of discussion are German small and medium-sized enterprises (SMEs). These firms are particularly suitable for this analysis, as they commonly have high bank debt proportions.
The dissertation comprises three separate empirical analyses, which investigate selected aspects in the above mentioned context. Section 3.1 inspects the impact of the Basel II Capital Accord and the financial crisis on the cost of debt of German SMEs. Basel II formalized the credit assessment of debtors. This might have led to higher costs and a higher risk awareness of banks. Banks might have tried to refinance those additional costs by imposing tighter credit terms on debtors. Especially SMEs might face a higher cost of debt, as they tend to have comparably high proportions of bank debt, low equity ratios, and consecutively lower ratings than big companies. The results presented in Section 3.1 indicate a significant rise of the cost of debt since 2007. Unfortunately, the amendment of Basel II was followed by the financial crisis. It is difficult to separate the effect of the reform and the one of the crisis on the costs of debt capital of German SMEs. The presented analysis controls for several possible interdependencies be-tween credit costs, credit shortage and the insolvency risk of companies. However, none of the analyzed facts indicates a significant change in the extent of bank credit granting to SMEs during the financial crisis that would justify higher costs of debt capital. The results might point out that banks made use of the special situation of the financial crisis and raised credit standards for SME loans.
Section 3.2 examines whether bank debt financing drives certain accounting choices of Ger-man SMEs. At least since Basel II, banks have to base their credit assessments on objective, quantitative ratings, which commonly rely on financial statement data. As loan interest rates account for a significant proportion of the cost of capital of SMEs, their incentive to optimize loan conditions is obvious. Under the assumption that SMEs are aware of the importance of financial statements data in credit assessments, they might have an incentive to direct their financial statements at banks. More precisely, SMEs might strive to exploit their asymmetric information advantage over banks by manipulating earnings with the intention to achieve decent credit terms. The results presented in Section 3.2 show that SMEs have significantly higher total accruals in the period prior to borrowing new bank debt than in other periods. Moreover, a higher bank debt proportion is accompanied by higher total accruals. Hence, particularly bank-dependent firms seem to alter their accounting behavior prior to the important corporate financing event of bor-rowing new bank debt. Finally, the study investigates whether earnings manipulation is detected by banks or whether it is effective and influences the cost of debt of German SMEs. Empirical results in Section 3.2 indicate that SMEs, which report positive discretionary accruals are re-warded in terms of a lower cost of debt. This might imply that banks do not see through earnings manipulation.
Section 3.3 contains results of a comprehensive survey of German SMEs, which intends to further analyze the research questions posed in Section 3.1 and 3.2. First, the survey aims to verify or falsify the results concerning the impact of Basel II on the cost of debt and the re-quirements to obtain a loan for SMEs since 2007. A large proportion of survey respondents complained about a higher effort needed to obtain a new bank loan since 2007. Moreover, for the majority of survey participants both the collateral demanded by banks and the strictness of covenants increased since Basel II. In addition, almost half of surveyed SMEs experience higher costs of bank debt since the amendment of the reform. The second part of the survey aims to investigate whether SMEs apply measures of earnings manipulation in the period prior to bor-rowing new bank debt. The majority of SMEs admit that they would use both certain means of real activities and accrual manipulation in order to achieve decent credit terms in the subsequent debt contract negotiation.
Taking these empirical results into consideration, the dissertation shows that certain manage-rial decisions of German SMEs are influenced by debt holders. Results in Sections 3.1 and 3.3 indicate that SME bank lending was affected by Basel II and the financial crisis. The cost of debt of German SMEs is significantly higher since Basel II, even after controlling for potential influences of the financial crisis. These higher costs of debt might have additional side effects on further corporate financing and/or investment decisions. Furthermore, results in Sections 3.2 and 3.3 indicate that bank debt lending influences accounting choices of German SMEs, particu-larly in the period before borrowing new bank debt. SME use both means of real activities and accrual management in order to achieve decent credit terms. This change of accounting behavior might be accompanied by effort, additional effects on other corporate contracts, and notable economic costs.
Cardiac healing after myocardial infarction (MI) represents the cardinal prerequisite for proper replacement of the irreversibly injured myocardium. In contrast to innate immunity, the functional role of adaptive immunity in postinfarction healing has not been systematically addressed. The present study focused on the influence of CD4+ T lymphocytes on wound healing and cardiac remodeling after experimental myocardial infarction in mice. Both conventional and Foxp3+ regulatory CD4+ T cells (Treg cells) became activated in heart draining lymph nodes after MI and accumulated in the infarcted myocardium. T cell activation was strictly antigen-dependant as T cell receptor-transgenic OT-II mice in which CD4+ T cells exhibit a highly limited T cell
receptor repertoire did not expand in heart-draining lymph nodes post-MI. Both OT-II and major histocompatibility complex class II-deficient mice lacking a CD4+ T cell compartment showed a fatal clinical postinfarction outcome characterized by disturbed scar tissue construction that resulted in impaired survival due to a prevalence of left-ventricular ruptures. To assess the contribution of anti-inflammatory Treg cells on wound healing after MI, the Treg cell compartment was depleted using DEREG mice that specifically express the human diphtheria toxin receptor in Foxp3-positive cells, resulting in Treg cell ablation after diphtheria toxin administration. In a parallel line of experiments, a second model of anti-CD25 antibody-mediated Treg cell immuno-depletion was used. Treg cell ablation prior to MI resulted in adverse postinfarction left-ventricular dilatation associated with cardiac deterioration. Mechanistically, Treg cell depletion resulted in an increased recruitment of pro-inflammatory neutrophils and Ly-6Chigh monocytes into the healing myocardium. Furthermore, Treg cell-ablated mice exhibited an adverse activation of conventional non-regulatory CD4+ and CD8+ T cells that
showed a reinforced infiltration into the infarct zone. Increased synthesis of TNFα and IFNγ by conventional CD4+ and CD8+ T cells in hearts of Treg cell-depleted mice provoked an M1-like macrophage polarization characterized by heightened expression of healing-compromising induced NO synthase, in line with a reduced synthesis of healing-promoting transglutaminase factor XIII (FXIII), osteopontin (OPN) and transforming growth factor beta 1 (TGFβ1).
Therapeutic Treg cell activation by a superagonistic anti-CD28 monoclonal antibody stimulated Treg cell accumulation in the infarct zone and led to an increased expression of mediators inducing an M2-like macrophage polarization state, i.e. interleukin-10, interleukin-13 and TGFβ1. M2-like macrophage differentiation in the healing infarct was associated with heightened expression of scar-forming procollagens as well as scar-stabilizing FXIII and OPN, resulting in improved survival due to a reduced incidence of left-ventricular ruptures. Therapeutic Treg cell activation and the induction of a beneficial M2-like macrophage polarization was further achieved by employing a treatment modality of high clinical potential, i.e. by therapeutic administration of IL-2/ anti-IL-2 monoclonal antibody complexes. The findings of the present study suggest that therapeutic Treg cell activation and the resulting improvement of healing may represent a suitable strategy to attenuate adverse infarct expansion, left-ventricular remodeling, or infarct ruptures in patients with MI.
SPRED proteins are inhibitors of the Ras/ERK/MAPK signaling pathway, an evolutionary highly conserved and very widespread signaling cascade regulating cell proliferation, differentiation, and growth. To elucidate physiological consequences of SPRED2 deficiency, SPRED2 KO mice were generated by a gene trap approach. An initial phenotypical characterization of KO mice aged up to five months identified SPRED2 as a regulator of chondrocyte differentiation and bone growth. Here, the loss of SPRED2 leads to an augmented FGFR-dependent ERK activity, which in turn causes hypochondroplasia-like dwarfism. However, long term observations of older KO mice revealed a generally bad state of health and manifold further symptoms, including excessive grooming associated with severe self-inflicted wounds, an abnormally high water uptake, clear morphological signs of kidney deterioration, and a reduced survival due to sudden death. Based on these observations, the aim of this study was to discover an elicitor of this complex and versatile phenotype.
The observed kidney degeneration in our SPRED2 KO mice was ascribed to hydronephrosis characterized by severe kidney atrophy and apoptosis of renal tubular cells. Kidney damage prompted us to analyze drinking behavior and routine serum parameters. Despite polydipsia, which was characterized by a nearly doubled daily water uptake, the significantly elevated Na+ and Cl- levels and the resulting serum hyperosmolality could not be compensated in SPRED2 KOs. Since salt and water balance is primarily under hormonal control of aldosterone and AVP, we analyzed both hormone levels. While serum AVP was similar in WTs and KOs, even after experimental water deprivation and an extreme loss of body fluid, serum aldosterone was doubled in SPRED2 KO mice. Systematic investigation of contributing upstream hormone axes demonstrated that hyperaldosteronism developed independently of an overactivated Renin-Angiotensin system as indicated by halved serum Ang II levels in KO mice. However, aldosterone synthase expression in the adrenal gland was substantially augmented. Serum corticosterone, which is like aldosterone released from the adrenal cortex, was more than doubled in SPRED2 KOs, too. Similar to corticosterone, the production of aldosterone is at least in part under control of pituitary ACTH, which is further regulated by upstream hypothalamic CRH release. In fact, stress hormone secretion from this complete hypothalamic-pituitary-adrenal axis was upregulated because serum ACTH, the mid acting pituitary hormone, and hypothalamic CRH, the upstream hormonal inductor of HPA axis activity, were also elevated by 30% in SPRED2 KO mice. This was accompanied by an upregulated ERK activity in paraventricular nucleus-containing hypothalamic brain regions and by augmented hypothalamic CRH mRNA levels in our SPRED2 KO mice. In vitro studies using the hypothalamic cell line mHypoE-44 further demonstrated that both SPRED1 and SPRED2 were able to downregulate CRH promoter activity, CRH secretion, and Ets factor-dependent CRH transcription. This was in line with the presence of various Ets factor binding sites in the CRH promoter region, especially for Ets1.
Thus, this study shows for the first time that SPRED2-dependent inhibition of Ras/ERK/MAPK signaling by suppression of ERK activity leads to a downregulation of Ets1 factor-dependent transcription, which further results in inhibition of CRH promoter activity, CRH transcription, and CRH release from the hypothalamus. The consecutive hyperactivity of the complete HPA axis in our SPRED2 KO mice reflects an elevated endogenous stress response becoming manifest by excessive grooming behavior and self-inflicted skin lesions on the one hand; on the other hand, in combination with elevated aldosterone synthase expression, this upregulated HPA hormone release explains hyperaldosteronism and the associated salt and water imbalances. Both hyperaldosteronism and polydipsia very likely contribute further to the observed kidney damage.
Taken together, this study initially demonstrates that SPRED2 is essential for the appropriate regulation of HPA axis activity and of body homeostasis.
To further enlighten and compare consequences of SPRED2 deficiency in mice and particularly in humans, two follow-up studies investigating SPRED2 function especially in heart and brain, and a genetic screen to identify human SPRED2 loss-of-function mutations are already in progress.
Information on the state of the terrestrial vegetation cover is important for several ecological, economical, and planning issues. In this regard, vegetation properties such as the type, vitality, or density can be described by means of continuous biophysical parameters. One of these parameters is the leaf area index (LAI), which is defined as half the total leaf area per unit ground surface area. As leaves constitute the interface between the biosphere and the atmosphere, the LAI is used to model exchange processes between plants and their environment. However, to account for the variability of ecosystems, spatially and temporally explicit information on LAI is needed both for monitoring and modeling applications.
Remote sensing aims at providing such information. LAI is commonly derived from remote sensing data by empirical-statistical or physical models. In the first approach, an empirical relationship between LAI measured in situ and the corresponding canopy spectral signature is established. Although this method achieves accurate LAI estimates, these relationships are only valid for the place and time at which the field data were sampled, which hampers automated LAI derivation. The physical approach uses a radiation transfer model to simulate canopy reflectance as a function of the scene’s geometry and of leaf and canopy parameters, from which LAI is derived through model inversion based on remote sensing data. However, this model inversion is not stable, as it is an under-determined and ill-posed problem.
Until now, LAI research focused either on the use of coarse resolution remote sensing data for global applications, or on LAI modeling over a confined area, mostly in forest and crop ecosystems, using medium to high spatial resolution data. This is why to date no study is available in which high spatial resolution data are used for LAI mapping in a heterogeneous, natural landscape such as alpine grasslands, although a growing amount of high spatial and temporal resolution remote sensing data would allow for an improved environmental monitoring. Therefore, issues related to model parameterization and inversion regularization techniques improving its stability have not yet been investigated for this ecosystem.
This research gap was taken up by this thesis, in which the potential of high spatial resolution remote sensing data for grassland LAI estimation based on statistical and radiation transfer modeling is analyzed, and the achieved accuracy and robustness of the two approaches is compared. The objectives were an ecosystem-adapted radiation transfer model set-up and an optimized LAI derivation in mountainous grassland areas. Multi-temporal LAI in situ measurements as well as time series of RapidEye data from 2011 and 2012 over the catchment of the River Ammer in the Bavarian alpine upland were used. In order to obtain accurate in situ data, a comparison of the LAI derivation algorithms implemented in the LAI-2000 PCA instrument with destructively measured LAI was performed first. For optimizing the empirical-statistical approach, it was then analyzed how the selection of vegetation indices and regression models impacts LAI modeling, and how well these models can be transferred to other dates. It was shown that LAI can be derived
with a mean accuracy of 80 % using contemporaneous field data, but that the accuracy decreases to on average 51 % when using these models on remote sensing data from other dates. The combined use of several data sets to create a regression which is used for LAI derivation at different points in time increased the LAI estimation accuracy to on average 65 %. Thus, reduced field measurement labor comes at the cost of LAI error rates being increased by 10 - 30 % as long as at least two campaigns are conducted. Further, it was shown that the use of RapidEye’s red edge channel improves the LAI derivation by on average 5.4 %.
With regard to physical LAI modeling, special interest lay in assessing the accuracy improvements that can be achieved through model set-up and inversion regularization techniques. First, a global sensitivity analysis was applied to the radiation transfer model in order to identify the most important model parameters and most sensitive spectral features. After model parameterization, several inversion regularizations, namely the use of a multiple sample solution, the additional use of vegetation indices, and the addition of noise, were analyzed. Further, an approach to include the local scene’s geometry in the retrieval process was introduced to account for the mountainous topography. LAI modeling accuracies of in average 70 % were achieved using the best combination of regularization techniques, which is in the upper range of accuracies that were achieved in the few existing other grassland studies based on in situ or air-borne measured hyperspectral data. Finally, further physically derived vegetation parameters and inversion uncertainty measures were evaluated in detail to identify challenging modeling conditions, which was mostly neglected in other studies. An increased modeling uncertainty for extremely high and low LAI values was observed. This indicates an insufficiently wide model parameterization and a canopy deviation from model assumptions on some fields. Further, the LAI modeling accuracies varied strongly between the different scenes. From this observation it can be deduced that the radiometric quality of the remote sensing data, which might be reduced by atmospheric effects or unexpected surface reflectances, exerts a high influence on the LAI modeling accuracy.
The major findings of the comparison between the empirical-statistical and physical LAI modeling approaches are the higher accuracies achieved by the empirical-statistical approach as long as contemporaneous field data are available, and the computationally efficiency of the statistical approach. However, when no or temporally unfitting in situ measurements are available, the physical approach achieves comparable or even higher accuracies. Furthermore, radiation transfer modeling enables the derivation of other leaf and canopy variables useful for ecological monitoring and modeling applications, as well as of pixel-wise uncertainty measures indicating the robustness and reliability of the model inversion and LAI derivation procedure. The established look-up tables can be used for further LAI derivation in Central European grassland also in other years.
The use of high spatial resolution remote sensing data for LAI derivation enables a reliable land cover classification and thus a reduced LAI mapping error due to misclassifications. Furthermore, the RapidEye pixels being smaller than individual fields allow for a radiation transfer model inversion over homogeneous canopies in most cases, as canopy gaps or field parcels can be clearly distinguished. However, in case of unexpected local surface conditions such as blooming, litter, or canopy gaps, high spatial resolution data show corresponding strong deviations in reflectance values and hence LAI estimation, which would be reduced using coarser resolution data through the balancing effect of the surrounding surface reflectances. An optimal pixel size with regard to modeling accuracy hence depends on the canopy and landscape structure. Furthermore, a reduced spatial resolution would enable a considerable acceleration of the LAI map derivation.
This illustration of the potential of RapidEye data and of the challenges associated to LAI derivation in heterogeneous grassland areas contributes to the development of robust LAI estimation procedures based on new and upcoming, spatially and temporally high resolution remote sensing imagery such as Landsat 8 and Sentinel-2.
Background: Food craving refers to an intense desire to consume a specific kind of food of which chocolate is the most often craved one. It is this intensity and specificity that differentiates food craving from feelings of hunger. Although food craving and hunger often co-occur, an energy deficit is not a prerequisite for experiencing food craving, that is, it can also occur without being hungry. Food craving often precedes and predicts over- or binge eating which makes it a reasonable target in the treatment of eating disorders or obesity. One of the arguably most extensively validated measures for the assessment of food craving are the Food Cravings Questionnaires (FCQs), which measure food craving on a state (FCQ-S) and trait (FCQ-T) level. Specifically, the FCQ-S measures the intensity of current food craving whereas the FCQ-T measures the frequency of food craving experiences in general. The aims of the present thesis were to provide a German measure for the assessment of food craving and to investigate cognitive, behavioral, and physiological correlates of food craving. For this purpose, a German version of the FCQs was presented and its reliability and validity was evaluated. Using self-reports, relationships between trait food craving and dieting were examined. Cognitive-behavioral correlates of food craving were investigated using food-related tasks assessing executive functions. Psychophysiological correlates of food craving were investigated using event-related potentials (ERPs) in the electroencephalogram and heart rate variability (HRV). Possible intervention approaches to reduce food craving were derived from results of those studies.
Methods: The FCQs were translated into German and their psychometric properties and correlates were investigated in a questionnaire-based study (articles #1 & #2). The relationship between state and trait food craving with executive functioning was examined with behavioral tasks measuring working memory performance and behavioral inhibition which involved highly palatable food-cues (articles #3 & #4). Electrophysiological correlates of food craving were tested with ERPs during a craving regulation task (article #5). Finally, a pilot study on the effects of HRV-biofeedback for reducing food craving was conducted (article #6).
Results: The FCQs demonstrated high internal consistency while their factorial structure could only partially be replicated. The FCQ-T also had high retest-reliability which, expectedly, was lower for the FCQ-S. Validity of the FCQ-S was shown by positive relationships with current food deprivation and negative affect. Validity of the FCQ-T was shown by positive correlations with related constructs. Importantly, scores on the subscales of the FCQ-T were able to discriminate between non-dieters and successful and unsuccessful dieters (article #1). Furthermore, scores on the FCQ-T mediated the relationship between rigid dietary control strategies and low dieting success (article #2). With regard to executive functioning, high-calorie food-cues impaired working memory performance, yet this was independent of trait food craving and rarely related to state food craving (article #3). Behavioral disinhibition in response to high-calorie food-cues was predicted by trait food craving, particularly when participants were also impulsive (article #4). Downregulation of food craving by cognitive strategies in response to high-calorie food-cues increased early, but not later, segments of the Late Positive Potential (LPP) (article #5). Few sessions of HRV-biofeedback reduced self-reported food cravings and eating and weight concerns in high trait food cravers (article #6).
Conclusions: The German FCQs represent sound measures with good psychometric properties for the assessment of state and trait food craving. Although state food craving increases during cognitive tasks involving highly palatable food-cues, impairment of task performance does not appear to be mediated by current food craving experiences. Instead, trait food craving is associated with low behavioral inhibition in response to high-calorie food-cues, but not with impaired working memory performance. Future studies need to examine if trait food craving and, subsequently, food-cue affected behavioral inhibition can be reduced by using food-related inhibition tasks as a training. Current food craving and ERPs in response to food-cues can easily be modulated by cognitive strategies, yet the LPP probably does not represent a direct index of food craving. Finally, HRV-biofeedback may be a useful add-on element in the treatment of disorders in which food cravings are elevated. To conclude, the current thesis provided measures for the assessment of food craving in German and showed differential relationships between state and trait food craving with self-reported dieting behavior, food-cue affected executive functioning, ERPs and HRV-biofeedback. These results provide promising starting points for interventions to reduce food craving based on (1) food-cue-related behavioral trainings of executive functions, (2) cognitive craving regulation strategies, and (3) physiological parameters such as HRV-biofeedback.
Motivation and Aim:
Cardiovascular disease has been the leading cause of mortality and morbidity throughout the world. In developed countries, cardiovascular diseases are already responsible for a majority of deaths and will become the pre-eminent health problem worldwide (1,2). Rupture of atherosclerotic plaque accounts for approximately 70% of fatal acute myocardial infarction and sudden heart deaths. Conventional criterias for the diagnosis of “vulnerable plaques” are calcified nodules, yellow appearance of plaque, a thin cap, a large lipid core, severe luminal stenosis, intraplaque hemorrhage, inflammation, thrombogenicity, and plaque injury (3-5).
Noninvasive diagnosis of vulnerable plaque still remains a great challenge and a huge research prospect, which triggered us to investigate the feasibility of PET imaging on the evaluation of atherosclerosis. Nuclear imaging of atherosclerosis, especially co-registered imaging modalities, could provide a promising diagnostic tool including both anatomy and activities to identify vulnerable atherosclerotic plaque or early detection of inflammatory endothelium at risk. Furthermore, the development of specific imaging tracers for clinical applications is also a challenging task. The aim of this work was to assess the potential of novel PET imaging probes associated with intra-plaque inflammation on animal models and in human respectively.
Methods
In this work, several molecular imaging modalities were employed for evaluation of atherosclerosis. They included Positron emission tomography / Computed tomography (PET/CT) for human studies, and micro-PET, autoradiography and high-resolution magnetic resonance imaging (MRI) for animal studies. Radiotracers for PET imaging included the glucose analogue 18F-Fluorodeoxyglucose (18F-FDG), the somatostatin receptor avide tracer 68Ga-DOTATATE, and the Gallium-68 labeled fucoidan (68Ga-Fucoidan), which was developed as a PET tracer to detect endothelial P-selectin, which overexpressed at early stage of atherosclerosis and endothelial overlying activated plaque. Tracer’s capabilities were firstly assessed on cellular level in vitro. Subsequently, Animal studies were conducted in two animal models: 1, Apolipoprotein E (ApoE-/-) mice having severe atherosclerotic plaque; 2, Lipopolysaccharide (LPS) -induced mice for receiving acute vascular inflammation. Corresponding analyses on protein and histological level were conducted as well to confirm our results.
In human study, 16 patients with neuroendocrine tumors (NETs) were investigated on imaging vascular inflammation. These patients had undergone both 68Ga-DOTATATE PET/CT and 18F-FDG PET/CT for staging or restaging within 6 weeks. 16 patients were randomized into two groups: high-risk group and low-risk group. Uptake ratio of both tracers from two groups were compared and correlated with common cardiovascular risk factors.
Results and Conclusion
In murine study, the expression of somatostatin receptor 2, which is the main bio-target of 68Ga-DOTATATE on macrophage/monocyte was confirmed by flow cytometry and immunohistochemistry. Prospectively, high specific accumulation of 68Ga-DOTATATE to the macrophage within the plaques was observed in aorta lesions by autoradiography and by micro-PET. In study with 68Ga-fucoidan, a strong expression of P-selectin on active endothelium overlying on inflamed plaque but weaker on inactive plaques was confirmed. Specific focal uptake of 68Ga-fucoidan were detected at aorta segments by micro-PET, and correlated with high-resolution magnetic resonance imaging (MRI), which was used to characterize the morphology of plaques. 68Ga-fucoidan also showed a greater affinity to active inflamed plaque in comparison of inactive fibrous plaque, which was assessed by autoradiography. Specificity of 68Ga-DOTATATE and 68Ga-fucoidan were confirmed by ex-vivo blocking autoradiography and in vivo blocking PET imaging respectively.
In human study, focal uptake of both 18F-FDG and 68Ga-DOTATATE was detected. Analyzing concordance of two tracers’ uptake ratio, Out of the 37 sites with highest focal 68Ga-DOTATATE uptake, 16 (43.2%) also had focal 18F-FDG uptake. Of 39 sites with highest 18F-FDG uptake, only 11 (28.2%) had a colocalized 68Ga-DOTATATE accumulation. Correlated tracers’ uptake and calcium burden and risk factors, Mean target-to-background ratio (TBR) of 68Ga-DOTATATE correlated significantly with the presence of calcified plaques (r=0.52), hypertension (r=0.60), age (r=0.56) and uptake of 18F-FDG (r=0.64). TBRmean of 18F-FDG correlated significantly only with hypertension (r=0.58; p<0.05). Additionally, TBRmean of 68Ga-DOTATATE is significant higher in the high risk group while TBRmean of 18F-FDG is not.
In conclusion, we evaluated vascular inflammation of atherosclerosis non-invasively using the two PET tracers: 68Ga-DOTATATE and 68Ga-Fucoidan. 68Ga-DOTATATE show specific affinity to infiltrated macrophage within the plaques. 68Ga-Fucoidan may hold the potential to discriminate between active and inactive atherosclerotic plaques in terms of variant accumulation on different-types of plaques. PET as leading molecular imaging technique provides superiority in assessing cellular activity, which is pivotal for understanding internal activity of atherosclerotic plaques. Since diagnosis of atherosclerosis is a complex and multi-dimensional task. More integrated imaging technology such as PET/MRI, faster imaging algorithm, more efficient radiotracer are required for further development of atherosclerosis imaging,
Each year millions of plastic and reconstructive procedures are performed to regenerate soft tissue defects after, for example, traumata, deep burns or tumor resections. Tissue engineered adipose tissue grafts are a promising alternative to autologous fat transfer or synthetic implants to meet this demand for adipose tissue. Strategies of tissue engineering, especially the use of cell carriers, provide an environment for better cell survival, an easier positioning and supplemented with the appropriate conditions a faster vascularization in vivo. To successfully engineer an adipose tissue substitute for clinical use, it is crucial to know the actual intended application. In some areas, like the upper and lower extremities, only a thin subcutaneous fat layer is needed and in others, large volumes of vascularized fat grafts are more desirable. The use and interplay of stem cells and selected scaffolds were investigated and provide now a basis for the generation of fitted and suitable substitutes in two different application areas.
Complex injuries of the upper and lower extremities, in many cases, lead to excessive scarring. Due to severe damage to the subcutaneous fat layer, a common sequela is adhesion formation to mobile structures like tendons, nerves, and blood vessels resulting in restricted motion and disabling pain [Moor 1996, McHugh 1997]. In order to generate a subcutaneous fat layer to cushion scarred tissue after substantial burns or injuries, different collagen matrices were tested for clinical handling and the ability to support adipogenesis. When testing five different collagen matrices, PermacolTM and StratticeTM showed promising characteristics; additionally both possess the clinical approval. Under culture conditions, only PermacolTM, a cross-linked collagen matrix, exhibited an excellent long-term stability. Ranking nearly on the same level was StratticeTM, a non-cross-linked dermal scaffold; it only exhibited a slight shrinkage. All other scaffolds tested were severely compromised in stability under culture conditions. Engineering a subcutaneous fat layer, a construct would be desirable with a thin layer of emerging fat for cushioning on one side, and a non-seeded other side for cell migration and host integration. With PermacolTM and StratticeTM, it was possible to produce constructs with ASC (adipose derived stem cells) seeded on one side, which could be adipogenically differentiated. Additionally, the thickness of the cell layer could be varied. Thereby, it becomes possible to adjust the thickness of the construct to the surrounding tissue. In order to reduce the pre-implantation time ex vivo and the costs, the culture time was varied by testing different induction protocols. An adipogenic induction period of only four days was demonstrated to be sufficient to obtain a substantial adipogenic differentiation of the applied ASC. Thus, seeded with ASC, PermacolTM and StratticeTM are suitable scaffolds to engineer subcutaneous fat layers for reconstruction of the upper and lower extremities, as they support adipogenesis and are appropriately thin, and therefore would not compromise the cosmesis.
For the engineering of large-volume adipose tissue, adequate vascularization still represents a major challenge. With the objective to engineer vascularized fat pads, it is important to consider the slow kinetics of revascularization in vivo. Therefore, a decellularized porcine jejunum with pre-existing vascular structures and pedicles to connect to the host vasculature or the circulation of a bioreactor system was used. In a first step, the ability of a small decellularized jejunal section was tested for cell adhesion and for supporting adipogenic differentiation of hASC mono-cultures. Cell adhesion and adipogenic maturation of ASC seeded on the jejunal material was verified through histological and molecular analysis. After the successful mono-culture, the goal was to establish a MVEC (microvascular endothelial cells) and ASC co-culture; suitable culture conditions had to be found, which support the viability of both cell types and do not interfere with the adipogenic differentiation. After the elimination of EGF (epidermal growth factor) from the co-culture medium, substantial adipogenic maturation was observed. In the next step, a large jejunal segment (length 8 cm), with its pre-existing vascular structures and arterial/venous pedicles, was connected to the supply system of a custom-made bioreactor. After successful reseeding the vascular structure with endothelial cells, the lumen was seeded with ASC which were then adipogenically induced. Histological and molecular examinations confirmed adipogenic maturation and the existence of seeded vessels within the engineered construct. Noteworthily, a co-localization of adipogenically differentiating ASC and endothelial cells in vascular networks could be observed. So, for the first time a vascularized fat construct was developed in vitro, based on the use of a decellularized porcine jejunum. As this engineered construct can be connected to a supply system or even to a patient vasculature, it is versatile in use, for example, as transplant in plastic and reconstruction surgery, as model in basic research or as an in vitro drug testing system.
To summarize, in this work a promising substitute for subcutaneous fat layer reconstruction, in the upper and lower extremities, was developed, and the first, as far as reported, in vitro generated adipose tissue construct with integrated vascular networks was successfully engineered.
Novel manganese(I) tricarbonyl complexes based on the tridentate bis(pyrazolyl)ethylamine (bpea) ligand with pendant functionalized phenyl groups were synthesized and conjugated to biological carrier systems like peptides and dendrimers. Their dark stability establishes them as CORM prodrugs. The monomers show a faster CO-release compared to the peptide and dendrimer conjugates. However, both monomers and peptide conjugates release two equivalents of CO upon photoactivation at 365 nm. The dendrimer conjugates can deliver up to seven equivalents of CO due to the higher number of Mn(CO)3 moieties per molecular unit. In the future, the biological activity of the conjugates needs to be further explored to establish the targeted delivery of CO to cells and tissues.
Today knowledge base authoring for the engineering of intelligent systems is performed mainly by using tools with graphical user interfaces. An alternative human-computer interaction para- digm is the maintenance and manipulation of electronic documents, which provides several ad- vantages with respect to the social aspects of knowledge acquisition. Until today it hardly has found any attention as a method for knowledge engineering.
This thesis provides a comprehensive discussion of document-centered knowledge acquisition with knowledge markup languages. There, electronic documents are edited by the knowledge authors and the executable knowledge base entities are captured by markup language expressions within the documents. The analysis of this approach reveals significant advantages as well as new challenges when compared to the use of traditional GUI-based tools.
Some advantages of the approach are the low barriers for domain expert participation, the simple integration of informal descriptions, and the possibility of incremental knowledge for- malization. It therefore provides good conditions for building up a knowledge acquisition pro- cess based on the mixed-initiative strategy, being a flexible combination of direct and indirect knowledge acquisition. Further it turns out that document-centered knowledge acquisition with knowledge markup languages provides high potential for creating customized knowledge au- thoring environments, tailored to the needs of the current knowledge engineering project and its participants. The thesis derives a process model to optimally exploit this customization po- tential, evolving a project specific authoring environment by an agile process on the meta level. This meta-engineering process continuously refines the three aspects of the document space: The employed markup languages, the scope of the informal knowledge, and the structuring and organization of the documents. The evolution of the first aspect, the markup languages, plays a key role, implying the design of project specific markup languages that are easily understood by the knowledge authors and that are suitable to capture the required formal knowledge precisely. The goal of the meta-engineering process is to create a knowledge authoring environment, where structure and presentation of the domain knowledge comply well to the users’ mental model of the domain. In that way, the approach can help to ease major issues of knowledge-based system development, such as high initial development costs and long-term maintenance problems.
In practice, the application of the meta-engineering approach for document-centered knowl- edge acquisition poses several technical challenges that need to be coped with by appropriate tool support. In this thesis KnowWE, an extensible document-centered knowledge acquisition environment is presented. The system is designed to support the technical tasks implied by the meta-engineering approach, as for instance design and implementation of new markup lan- guages, content refactoring, and authoring support. It is used to evaluate the approach in several real-world case-studies from different domains, such as medicine or engineering for instance.
We end the thesis by a summary and point out further interesting research questions consid- ering the document-centered knowledge acquisition approach.
The number of fungal infections is rising in Germany and worldwide. These infections are mainly caused by the opportunistic fungal pathogen C. albicans, which especially harms immunocompromised people. With increasing numbers of fungal infections, more frequent and longer lasting treatments are necessary and lead to an increase of drug resistances, for example against the clinically applied therapeutic fluconazole. Drug resistance in C. albicans can be mediated by the Multidrug resistance pump 1 (Mdr1), a membrane transporter belonging to the major facilitator family. However, Mdr1-mediated fluconazole drug resistance is caused by the pump’s regulator, the transcription factor Mrr1 (Multidrug resistance regulator 1). It was shown that Mrr1 is hyperactive without stimulation or further activation in resistant strains which is due to so called gain of function mutations in the MRR1 gene.
To understand the mechanism that lays behind this constitutive activity of Mrr1, the transcription factor should be structurally and functionally (in vitro) characterized which could provide a basis for successful drug development to target Mdr1-mediated drug resistance caused by Mrr1. Therefore, the entire 1108 amino acid protein was successfully expressed in Escherichia coli. However, further purification was compromised as the protein tended to form aggregates, unsuitable for crystallization trials or further characterization experiments. Expression trials in the eukaryote Pichia pastoris neither yielded full length nor truncated Mrr1 protein. In order to overcome the aggregation problem, a shortened variant, missing the N-terminal 249 amino acids named Mrr1 ‘250’, was successfully expressed in E. coli and could be purified without aggregation. Similar to the wild type Mrr1 ‘250’, selected gain of function variants were successfully cloned, expressed and purified with varying yields and with varying purity. The Mrr1 `250’ construct contains most of the described regulatory domains of Mrr1. It was used for crystallization and an initial comparative analysis between the wild type protein and the variants. The proposed dimeric form of the transcription factor, necessary for DNA binding, could be verified for both, the wild type and the mutant proteins. Secondary structure analysis by circular dichroism measurements revealed no significant differences in the overall fold of the wild type and variant proteins. In vitro, the gain of function variants seem to be less stable compared to the wild type protein, as they were more prone to degradation. Whether this observation holds true for the full length protein’s stability in vitro and in vivo remains to be determined. The crystallization experiments, performed with the Mrr1 ‘250’ constructs, led to few small needle shaped or cubic crystals, which did not diffract very well and were hardly reproducible. Therefore no structural information of the transcription factor could be gained so far.
Infections with M. tuberculosis, the causative agent of tuberculosis, are the leading cause of mortality among bacterial diseases. Especially long treatment times, an increasing number of resistant strains and the prevalence of for decades persisting bacteria create the necessity for new drugs against this disease. The cholesterol import and metabolism pathways were discovered as promising new targets and interestingly they seem to play an important role for the chronic stage of the tuberculosis infection and for persisting bacteria.
In this thesis, the 3-ketoacyl-CoA thiolase FadA5 from M. tuberculosis was characterized and the potential for specifically targeting this enzyme was investigated. FadA5 catalyzes the last step of the β-oxidation reaction in the side-chain degradation pathway of cholesterol. We solved the three dimensional structure of this enzyme by X-ray crystallography and obtained two different apo structures and three structures in complex with acetyl-CoA, CoA and a hydrolyzed steroid-CoA, which is the natural product of FadA5. Analysis of the FadA5 apo structures revealed a typical thiolase fold as it is common for biosynthetic and degradative enzymes of this class for one of the structures. The second apo structure showed deviations from the typical thiolase fold. All obtained structures show the enzyme as a dimer, which is consistent with the observed dimer formation in solution. Thus the dimer is likely to be the catalytically active form of the enzyme. Besides the characteristic structural fold, the catalytic triad, comprising two cysteines and one histidine, as well as the typical coenzyme A binding site of enzymes belonging to the thiolase class could be identified. The two obtained apo structures differed significantly from each other. One apo structure is in agreement with the characteristic thiolase fold and the well-known dimer interface could be identified in our structure. The same characteristics were observed in all complex structures. In contrast, the second apo structure followed the thiolase fold only partially. One subdomain, spanning 30 amino acids, was in a different orientation. This reorientation was caused by the formation of two disulfide bonds, including the active site cysteines, which rendered the enzyme inactive. The disulfide bonds together with the resulting domain swap still permitted dimer formation, yet with a significantly shifted dimer interface. The comparison of the apo structures together with the preliminary activity analysis performed by our collaborator suggest, that FadA5 can be inactivated by oxidation and reactivated by reduction. If this redox switch is of biological importance requires further evaluation, however, this would be the first reported example of a bacterial thiolase employing redox regulation.
Our obtained complex structures represent different stages of the thiolase reaction cycle. In some complex structures, FadA5 was found to be acetylated at the catalytic cysteine and it was in complex with acetyl-CoA or CoA. These structures, together with the FadA5 structure in complex with a hydrolyzed steroid-CoA, revealed important insights into enzyme dynamics upon ligand binding and release. The steroid-bound structure is as yet a unique example of a thiolase enzyme interacting with a complex ligand. The characterized enzyme was used as platform for modeling studies and for comparison with human thiolases. These studies permitted initial conclusions regarding the specific targetability of FadA5 as a drug target against M. tuberculosis infection, taking the closely related human enzymes into account. Additional analyses led to the proposal of a specific lead compound based on the steroid and ligand interactions within the active site of FadA5.
The topic of the present study focuses on landslide susceptibility assessment in the Northern Vienna Forest by GIS-based, statistic-probabilistic and deterministic modelling. The study is based on two complementary approaches for integrated landslide susceptibility assessment, which is not limited to one single methodology and its inherent assumptions.
A statistic-probabilistic method is applied to the whole region of the Northern Vienna Forest. This regional model investigates the basic disposition for landslides under consideration of controlling factors, which are persistent and more or less constant over time. A deterministic method is applied on a larger scale in a sub-study site of the Hagenbach Valley. These detailed models aim to investigate the variable disposition as a function of substrate wetness, which is in turn dependent on meteorological conditions. A main aspect of the work is the development of various wetness scenarios, which consider short-term weather phenomena, like heavy or long-lasting rainfall, but which also investigate the influence of meteorological and climate conditions on slope stability, which may vary in mid-term and long-term.
Furthermore, the assessment of the effects of climate change on the disposition for landslides is a major aspect of the study. Hence, average changes in air temperature and precipitation as predicted by Regional Climate Models are incorporated into modelling. In this context, it is tested whether changes in substrate wetness and thus in slope stability can be identified and quantified as a consequence of changed climate conditions.
As further objective shallow slope movements are incorporated into disposition modelling. According to geomorphological and sedimentological studies, these quaternary sediments are essential for slope formation in the Vienna Forest. In general, it is assumed that landslides primarily occur in weathered flysch sandstones rich in marl. Field-based surveys, however, identified shallow landslide activity in the quaternary sediments covering the flysch bedrock in wide areas. Therefore, the influence of these sediments on slope dynamics is studied in the present work within GIS-based slope stability models.
The results of the statistic-probabilistic landslide susceptibility assessment provide information on the basic disposition of the Northern Vienna Forest for landslides. The resulting regional susceptibility map reveals that the Northern Zone, a tectonic unit in the north of the study area, has extensive areas with the highest degree of landslide susceptibility. In this overthrust area in transition to the Molasse Zone there are geological units which are highly susceptible to landslides. The “Wolfpassing Formation” and the “Calcareous Klippen” of the Northern Zone show significant landslide densities. These geological zones start in the north near St. Andrä-Wördern and continue in south-western direction along the ridges of Tulbinger Kogel, Klosterberg, Frauenberg, and Eichberg.
Statistical weighting carried out in the course of regional landslide susceptibility assessment provides information on the spatial relation between landslide processes and specific controlling factors. The modelling highlights the relevance of zones rich in clay within the flysch formations as controlling geofactor. The highest landslide susceptibility is calculated for the geological units, which contain layers of Gaultflysch rich in clay and shale. Furthermore, a close correlation between the distribution of landslides on the one hand and the spatial distribution of the fault system and nappe boundaries on the other hand is ascertained. Hence, the tectonic conditions can be seen as crucial controlling geofactor for landslide activity in the study area. In the proximity of drainage lines an increased landslide frequency is revealed. In combination with heavy rainfall, torrential discharge can occur in creeks and may cause instabilities in adjacent hillslopes. In addition, the model documents an enhancement of landslide susceptibility on north-west facing slopes. In comparison to meteorological data it is obvious that the north-west exposition corresponds to the prevailing wind direction of the study area. Therefore, north-west facing slopes might be exposed to enhanced advective rainfall amounts, which can increase substrate wetness and thus landslide susceptibility. The latter geofactors indicate the significance of meteorological and hydrological conditions for the occurrence of landslides in the study area.
As described above, the regional assessment is based on controlling factors that are persistent over a long period of time and can therefore be considered as constant. On the contrary, the large-scale, physically based deterministic modelling investigates the disposition for landslides under variable humidity conditions in the substrate. In conclusion it can be stated that the disposition for slope instability is strongly varying in dependence of the humidity conditions in the substrate. A heavy rainfall event causes a drastic reduction of stable areas by 23% compared to monthly average wetness conditions in summer (July). In summary the wetness scenarios demonstrate, that apart from short-term weather conditions, like long-lasting or heavy rainfall, the long-term-development of substrate moisture has impact on slope stability. The more persistent, seasonally fluctuating wetness conditions show measureable influence on slope stability: As a consequence of increased topographic wetness in the winter month February there is an increase of instable areas by 5% in comparison with the summer month July. The modelling further revealed that quaternary sediments are more moisture sensitive and the influence of changing wetness conditions is stronger in these layers than in the bedrock.
The results of modelling, which are based on climate change, indicate that a moderate change of slope stability on a monthly average is possible in comparison to the conditions of the climate normal period. An assumed average monthly temperature increase of 2°C in combination with a precipitation increase of 30% in the winter months lead to an augmentation of recharge of 7% in the model in comparison with the long-term average conditions. Due to this increased recharge, there is a slight increase of topographic wetness in the model. This wetness augmentation results in an extension of instable slope areas by 3% and a reduction of the stable slope areas proportional to this extension. This slightly increased instability reduces critical triggering thresholds for single rainfall events meaning that even lower precipitation amounts or intensities can cause instabilities.
In contrast to the winter months, the incorporation of forecasted climate change into the modelling reveals a reduction of instable slope areas in favour of stable areas in the summer scenario. The forecasted average air temperature increase of 2.5°C in combination with a reduction of the average monthly precipitation amount of 15% drastically decreases substrate moisture. Consequently, instable slope areas are reduced by 11% of the study area. This effect on slope stability in the model mainly results from the reduced monthly rainfall amounts, but also from increased evapotranspiration as a consequence of the increased air temperature causing reduced recharge amounts. However, in spite of the monthly decrease of precipitation amounts, precipitation intensities are probable to rise according to climate studies. In this context the results of the modelling indicate, that a drastic, short-term increase of landslide disposition due to heavy rainfall events has to be expected more frequently in summer.
The results of the complementary methods are then assembled. Based on this synthesis the following conclusion can be drawn: The regional landslide susceptibility assessment yields that hillslopes with an inclination of 26° to 31° are highly landslide prone. The physically based models indicate that in this slope gradient range the presence of quaternary sediments is of major importance for landslides. Therefore, it can be concluded that a considerable portion of known landslides mapped in flysch actually occurred in quaternary sediments.
Burkitt lymphoma (BL) is a highly aggressive B cell malignancy. Rituximab, a humanized antibody against CD20, in a combination with chemotherapy is a current treatment of choice for B-cell lymphomas including BL. However, certain group of BL patients are resistant to Rituximab therapy. Therefore, alternative treatments targeting survival pathways of BL are needed.
In BL deregulation of MYC expression, together with additional mutations, inhibits differentiation of germinal centre (GC) B cells and drives proliferation of tumor cells. Pro-apoptotic properties of MYC are counteracted through the B-cell receptor (BCR) and phosphoinositide-3-kinase (PI3K) pathway to ensure survival of BL cells. In normal B-cells BCR triggering activates both NF-κB and NFAT-dependent survival signals. Since BL cells do not exhibit constitutive NF-κB activity, we hypothesized that anti-apoptotic NFATc1A isoform might provide a major survival signal for BL cells.
We show that NFATc1 is constitutively expressed in nuclei of BL, in BL cell lines and in Eµ-Myc–induced B cell lymphoma (BCL) cells. Nuclear residence of NFATc1 in these entities depends on intracellular Ca2+ levels but is largely insensitive to cyclosporine A (CsA) treatment and therefore independent from calcineurine (CN) activity. The protein/protein interaction between the regulatory domain of NFATc1 and DNA binding domain of BCL6 likely contributes to sustained nuclear residence of NFATc1 and to the regulation of proposed NFATc1-MYC-BCL6-PRDM1 network in B-cell lymphomas.
Our data revealed lack of strict correlation between the expression of six NFATc1 isoforms in different BL-related entities suggesting that both NFATc1/alphaA and -betaA isoforms provide survival functions and that NFATc1alpha/betaB and -alpha/betaC isoforms either do not possess pro-apoptotic properties in BL cells or these properties are counterbalanced. In addition, we show that in BL entities expression of NFATc1 protein is largely regulated at post-transcriptional level, including MYC dependent increase of protein stability.
Functionally we show that conditional inactivation of Nfatc1 gene in Eµ-Myc mice prevents development of BCL tumors with mature B cell immunophenotype (IgD+). Loss of NFATc1 expression in BCL cells ex vivo results in apoptosis of tumor cells.
Together our results identify NFATc1 as an important survival factor in BL cells and, hence, as a promising target for alternative therapeutic strategies for BL.
Due to the rotation of the earth in the solar system all inhabitants of our planet are exposed to regular environmental changes since more than 3.5 billion years. In order to anticipate these predictable changes in the environment, evolutionarily conserved biological rhythms have evolved in most organisms – ranging from ancient cyanobacteria up to human beings – and also at different levels of organization – from single cells up to behavior. These rhythms are endogenously generated by so called circadian clocks in our body and entrained to the 24 h cycle by external timing cues. In multi-cellular organisms the majority of the cells in the body is equipped with such an oscillator. In mammals, the circadian system is structured in a hierarchical fashion: A central pacemaker resides in the bilateral suprachiasmatic nucleus (SCN) of the hypothalamus, while subsidiary peripheral clocks exist in nearly every tissue and organ.
In contrast to the aforementioned recurrent environmental changes most organisms are also exposed to unpredictable changes in the environment. In order to adapt to these sudden alterations the acute activation of the stress response system, involving the hypothalamic-pituitary-adrenal (HPA) axis and the sympathetic nervous system, displays a fundamental survival mechanism. However, if activation of the stress system becomes chronic, devastating somatic and affective disorders might be the consequence.
At first glance, the circadian and the stress system seem to represent two separate bodily control systems that are involved in adaptation to predictable and unpredictable stimuli, respectively. However, both systems are fundamental for survival, and thus, communicate with each other at various levels. Early studies already demonstrated that stressor exposure at different times of the diurnal cycle generates different stress effects, whereupon the type of stressor plays a pivotal role. Moreover, alterations in the SCN and peripheral circadian clocks could be shown following stressor exposure.
In cooperation with various co-workers, I investigated whether the stress responsiveness is modulated by the endogenous clock in a diurnal fashion and whether repeated psychosocial stress impacts the circadian clock depending on the time of day of stressor exposure. Therefore, male C57BL/6 mice were repeatedly exposed to a psychosocial stressor, either at the beginning of the inactive/light phase (SDL mice) or active/dark phase (SDD mice).
Subsequently, different behavioral, physiological/endocrine and immunological/ inflammatory consequences were assessed. It could be shown that the effects of repeated psychosocial stressor exposure strongly depend on the time of day of stressor exposure. The present results demonstrate that repeated daily stressor exposure has a more negative outcome when applied during the active/dark phase compared to the inactive/light phase. Stressor exposure during the active phase resulted in a loss of general activity, decreased interest in an unfamiliar conspecific, a shift towards a more pro-inflammatory body milieu, and rhythm disturbances in plasma hormones, all representing well-accepted hallmarks of depression. In contrast, C57BL/6 mice exposed to the stressor in their inactive phase exhibited minor physiological alterations that might prevent the formation of the maladaptive consequences mentioned above, thus representing beneficial adaptations.
The second focus of this thesis was put on the investigation of the effects of repeated psychosocial stressor exposure at different times of the light-dark cycle on various levels of the circadian system. An increased expression of the PERIOD2 (PER2) protein, which represents an essential core clock component, could be found in the SCN of mice repeatedly exposed to the stressor during their active phase. In consistence with the alterations in the central circadian pacemaker, the daily rhythm of different hormones and the activity rhythm were considerably affected by SDD. Mice exposed to the psychosocial stressor in their active phase showed a shifted, or absent, rhythm of the hormones corticosterone and leptin. Moreover, their activity was found to be phase-delayed, which seems to be attributable to the Period (Per) gene since Per1/Per2 double-mutants still exhibited their normal activity rhythm following 19 days of stressor exposure during the active phase. In contrast, a phase-advance in the peripheral adrenal gland clock could be seen in C57BL/6 mice subjected to the stressor during their inactive phase. This phase-shift might be required for maintaining the normal rhythmicity in hormonal release and activity.
It has previously been suggested that activation of the HPA axis upon stressor exposure at different times of the light-dark cycle is depending on whether the stressor is of physical or psychological nature. Data from the HPA axis analysis now refine previous findings, indicating that psychosocial stressors also modulate HPA axis responses based on the time of day of stressor presentation. The present results demonstrate that HPA axis activity was reduced following repeated stressor exposure during the active phase. It is reasonable to speculate that this reduced basal activity of the stress system represents a failure in HPA axis adjustment, which could contribute to the negative consequences of repeated psychosocial stressor exposure during the dark phase.
Taken together, it can be concluded that the endogenous clock in mice modulates the stress responsiveness in a circadian fashion and that repeated psychosocial stressor exposure affects the biological clock depending on the time of day of stressor presentation. Thereby, stressor exposure during the active phase results in a more negative outcome as compared to stressor experience during the inactive phase. It is assumed that the interaction between the circadian clock and the stress system is a complex issue that might ensure that the endogenous clock does not get out of synchrony in any order.
Development and validation of LC-MS/MS methods to determine PK/PD parameters of anti-infectives
(2014)
In the present thesis the development and validation of bioanalytical LC-MS/MS methods for the quantification of erythromycin A, erythromycin ethylsuccinate, roxithromycin, clarithromycin, 14 hydroxy clarithromycin, flucloxacillin, piperacillin and moxifloxacin in human plasma and human urine (piperacillin) is introduced. All methods were applied to analyze human plasma and urine samples from clinical trials and therefore, have been validated according to international guidelines. The methods were reliable in these studies and fulfilled all regulatory requirements known at the time of the study conduct.
Moreover, the validation data of the macrolides were compared on three different mass spectrometers (API III Plus, API 3000™, API 5000™). The new innovations in the ion source (horizontal versus vertical electrospray), the ionpath (skimmer, QJet) and the diameter of the orifice resulted in better sensitivity and a larger linearity range for the majority of the analytes. Sensitivity was improved up to a factor of 12 (for clarithromycin) between API III Plus to API 3000™ and up to a factor of 8 (for erythromycin and roxithromycin) between API 3000™ and API 5000™, keeping the accuracy and precision data at about the same level. The high sensitivity was a benefit for example for the flucloxacillin study, because concentrations from all subject samples were detectable up to approximately eight half-lives, i.e. no concentrations needed to be reported below the quantification limit. Also the linearity range were extended from two orders of magnitude to up to four orders of magnitude, which increases the likelihood to allow to analyze all samples from a pharmacokinetic study in the same run.
This is especially useful if a large concentration range needs to be analysed, for example, if the method shall be applied in an ascending dose study. Then, all low concentrations from the beginning of the study can be determined, as well as all high concentrations, without the need to dilute and analyse single samples repeatedly.
The pharmacokinetic data were compared to previously reported literature data and correlated graphically with MIC values of popular microorganisms which might be a starting point for further PK/PD investigations.
The PK/PD theory is a very helpful tool for prediction of the efficacy of given drugs against certain micro-organisms. Depending on the pharmacodynamic processes, e. g. the mode of action, three classes of drugs have been identified.
In the same way this applies to adverse effects, which need to be minimised by reducing plasma concentrations. These coherences are not well-investigated, yet, and are not discussed further in this thesis.
Still, a lot of research has to be done in this interdisciplinary field to minimise uncertainty in single values, like an AUC/MIC. These include:
Improve accuracy and precision of bioanalytical methods determining total and free concentration data in biological matrices for calculation of AUC and Cmax
These parameters are related to the MIC in pharmacodynamic considerations. Since the determination of the MIC often underlies significant variations and also differences between microbiological laboratories, the determination of concentrations of anti-infectives is particular important, being achievable by scientific exact techniques. Finally, from the volume of distribution of antibiotics can be used to derive information about intracellular concentrations and effectivity of antiinfectives.
Abstract
Glioblastomas, primary brain tumors, represent a tumor entity with a dismal prognosis and a median survival of only about one year. Invasion into the healthy brain parenchyma contributes substantially to the malignancy of this type of brain tumor. Therefore, a better understanding of the mechanisms promoting the invasive behavior of these brain tumors is needed to identify new therapeutic targets.
Cofilin, an actin regulatory protein, has been shown to be an important regulator of the invasive behavior of tumor cells in other types of cancer and the actin cytoskeleton is involved in the formation of a variety of cellular structures important for cell migration and invasion. Cofilin is regulated by phosphorylation on a single residue, serine 3. The aim of this thesis was to examine the role of the cofilin regulatory phosphatase chronophin for glioma cell migration and invasion.
First, it was established that chronophin depletion in the cell line GBM6840 leads to an increase in the ratio of phosphorylated cofilin to total cofilin. Higher chronophin levels were correlated with a decrease in F-actin in the cell lines GBM6840 and U87 as measured in an actin spin down assay and in a flow cytometry based assay.
Furthermore, it was shown that knockdown of chronophin in two different cell lines, GBM6840 and DBTRG-05-MG, strongly increased their invasiveness in vitro. Expression of human chronophin in the cell line U87 decreased its invasiveness substantially. There was no difference in cell proliferation between GBM6840 and DBTRG-05-MG cells expressing a chronophin targeting shRNA or a control shRNA and U87 cells transfected with an empty vector or a human chronophin encoding plasmid. The increase in invasiveness after chronophin depletion could be correlated with an increase in directionality in cell migration under 2D culture conditions in the cell lines U87 and GBM6840. Moreover, treatment with the ROCK inhibitor Y-27632 decreased directionality in GBM6840 cells under 2D culture conditions and reduced the invasiveness of GBM6840 chronophin shRNA cells back to control levels.
Expression of a non-phosphorylatable cofilin mutant, the S3A mutant, was able to reduce invasiveness and to reduce directionality under 2D culture conditions back to control levels in GBM6840 chronophin shRNA cells.
This provides important evidence for the involvement of cofilin phosphoregulation in the phenotypes described above.
In vivo, when injected into NOD-SCID mice, chronophin depleted cells showed a dramatic growth reduction as compared to control and rescue cells.
Transciptomic characterization of GBM6840 cells by microarray analysis and subsequent comparison of the data with microarray profiles of normal brain tissues and different glioma entities identified two specifically chronophin regulated transcripts potentially involved in tumor progression and invasion, MXI1 and EDIL3. Moreover, c-myc was identified as a significantly altered transcription factor after chronophin deregulation based on the number of c-myc target molecules in the microarray dataset.
MXI1 is a potential negative regulator of c-myc dependent transcription, and was strongly downregulated after chronophin knockdown in GBM6840. In line with this, the activity of a c-myc reporter plasmid was increased after chronophin depletion in GBM6840 and reduced after chronophin expression in U87 cells.
However, the protein level of the c-myc protein was reduced after chronophin depletion in GBM6840.
Finally, anaylsis of the expression of proteases known to be important for glioblastoma pathogenesis revealed no major changes in protease expression between chronophin depleted and control cells.
Therefore, a comprehensive analysis of chronophin in the context of glioma pathogenesis has been performed in this thesis. It has been shown that chronophin depletion strongly enhanced invasiveness of glioma cells and that it induced transcriptomic changes potentially involved in tumor progression. The proteins regulating cofilin phosphorylation are therefore valuable therapeutic targets for anti-invasive therapy in glioblastomas. Inhibitors for kinases upstream of cofilin, e.g. LIMKs and ROCKs, are available, and might be promising agents for anti-invasive therapy.
The female sex hormone 17beta-estradiol, produced naturally in the body, seems to play an important role in the development of breast cancer, since (i) it can be activated to reactive metabolites, which are known to damage DNA and (ii) the stimulation of the estrogen receptor alpha by 17beta-estradiol enhances cell proliferation. Both processes together increase mutation frequency and subsequently lead to transformation of epithelial cells. Therefore, the aim of this work was to characterize the influence of polymorphisms and lifestyle factors on 17beta-estradiol metabolism in normal mammary gland tissue. [...]
In sum, the tissue specific 17beta-estradiol metabolism was described in mammary gland tissue homogenate, whereas differences in proliferation of epithelial cells were only reflected in isolated epithelial cells. Factors associated with breast cancer risk (age, BMI and age-related changes in mammary gland morphology) were shown to affect 17beta-estradiol tissue levels.
The 17beta-estradiol mediated genotoxicity was evaluated using bioinformatically calculated
DNA adduct fluxes, which were predominately influenced by individual mRNA patterns rather than individual genotypes and (DNA adduct fluxes) were correlated with known breast cancer risk factors (age, parity, BMI and polymorphism of glutathione-S-transferase theta 1).
Sustainability has become a critical topic in all areas of supply chain management. As discussed earlier, drivers for this development can be identified as both internal and external phenomena. Since customers are one of the key stakeholders in supply chain management, special attention is paid to the impact of costumers´ behavior on sustainable supply chain design decisions. In this context, two main research questions were analyzed:
1.What is the appropriate way to design a supply chain according to environmentally-oriented requirements of customers?
2.What is the impact of customer´s behavior regarding both usage and return of products on supply chain design decisions in an environmentally conscious closed-loop supply chain environment?
Therefore, three different optimization models with various main aspects are developed. To illustrate how the presented models can be applied in practical problem cases, guidelines for implementing an environmentally supply chain design project are presented.
This thesis reviews the fundamentals of three-dimensional super-resolution localization imaging. In order to infer the axial coordinate of the emission of single fluorophores, the point spread function is engineered following a technique usually referred to as astigmatic imaging by the introduction of a cylindrical lens to the detection path of a microscope.
After giving a short introduction to optics and localization microscopy, I outline sources of aberrations as frequently encountered in 3D-localization microscopy and will discuss their respective impact on the precision and accuracy of the localization process. With the knowledge from these considerations, experiments were designed and conducted to verify the validity of the conclusions and to demonstrate the abilities of the proposed microscope to resolve biological structures in the three spatial dimensions. Additionally, it is demonstrated that measurements of huge volumes with virtually no aberrations is in principle feasible.
During the course of this thesis, a new method was introduced for inferring axial coordinates. This interpolation method based on cubic B-splines shows superior performance in the calibration of a microscope and the evaluation of subsequent measurement and will therefore be used and explained in this work.
Finally, this work is also meant to give future students some guidance for entering the field of 3D localization microscopy and therefore, detailed protocols are provided covering the specific aspects of two color 3D localization imaging.
This thesis consists of two parts of original experimental work, its evaluation, and in- terpretation. Its final goal is to investigate dynamical charge transfer (CT) at a hetero- molecular interface with resonant photoelectron spectroscopy (RPES). In order to achieve this goal preliminary studies have been necessary. First two hetero-molecular inter- faces that exhibit adequate structural properties as well as an appropriate photoelec- tron spectroscopy (PES) spectrum of the valence regime have been identified. The de- sired CT analysis with RPES of these hetero-molecular systems is then conducted on the basis of the knowledge gained by previous RPES studies of homo-molecular sys- tems.
The characterization of hetero-molecular films on single crystal Ag surfaces in the first part of this thesis is performed with high resolution core level PES and valence PES. The reproduction of the core level PES data with reference spectra of homo-molecular films allows me to determine which molecule is in direct contact to the Ag surface and which one is situated in higher layers (not the first one). Due to the direct correspon- dence of core level and valence PES the assignment of features in the spectra of the latter technique can be achieved with the identification of the contributions extracted from the evaluation of the data of the former technique. It is found that the systems PTCDA on one monolayer (ML) of SnPc on Ag(111) and CuPc/1 ML PTCDA/Ag(111) are stable at 300 K which means that no significant layer exchange occurs for these systems. In contrast a vertical exchange of CuPc and PTCDA molecules is observed for PTCDA de- posited on top of 1 ML CuPc/Ag(111). Up to a coverage of approximately 0.5 ML of PTCDA molecules these diffuse into the first layer, replace CuPc molecules, and con- sequently force them into higher layers. Above a coverage of approximately 0.5 ML of PTCDA molecules these are also found in higher layers. The search for a promising system for the intended RPES study then leads to an investigation of hetero-molecular films with a combination of F4TCNQ and PTCDA molecules on Ag(110) within the same approach. Depositing F4TCNQ molecules onto a 1 ML PTCDA/Ag(110) film in the herringbone phase at 300 K results in an instable hetero-organic system which un- dergoes a layer exchange. Hereby PTCDA molecules in the first layer are replaced by F4TCNQ molecules similar to the behavior of the system PTCDA/1 ML CuPc/Ag(111). Switching the order of the preparation steps leads to a stable film of PTCDA/1.0 ML F4TCNQ/Ag(110) at 300 K. Among the stable hetero-molecular films only the system CuPc/1 ML PTCDA/Ag(111) exhibits the required wetting growth of the first two layers at 300 K and a valence PES spectrum with energetically separable molecular orbital signals in the same intensity range. Thus this system is identified to be appropriate for a detailed analysis with RPES.
The unexpected findings of vertical exchanges in the hetero-molecular films at 300 K motivate a study of the behavior at elevated temperatures for all systems investigated before. Therein it is revealed that annealing 1.5 ML SnPc/1 ML PTCDA/Ag(111) and
1.0 ML PTCDA/1 ML SnPc/Ag(111) to a temperature above the desorption temperature of molecules not in direct contact to the Ag(111) surface results in a 1 ML SnPc/Ag(111) film in both cases. Hence at elevated temperatures (approximately above 420 K) SnPc molecules replace PTCDA molecules in the first layer on Ag(111). At higher temper- atures (approximately above 470 K) PTCDA molecules and SnPc molecules situated above the first layer then desorb from the 1 ML SnPc/Ag(111) sample. Annealing all hetero-molecular films with CuPc and PTCDA molecules on Ag(111) to 570 K leads to a sample with CuPc and PTCDA molecules in the first and only layer. Depending on the initial CuPc coverage different ratios of both molecules are obtained. With a CuPc coverage of exactly 1 ML, or above, films with PTCDA coverages of approxi- mately 0.1–0.2 ML are produced. So at elevated temperatures CuPc molecules replace PTCDA molecules in the first layer of the system CuPc/1 ML PTCDA/Ag(111). Anal- ogously the layer exchange at 300 K for the system PTCDA/1 ML CuPc/Ag(111) is reversed at elevated temperatures. In the case of SnPc and CuPc coverages below 1 ML annealing vertical hetero-molecular systems with PTCDA on Ag(111) up to 570 K re- sults in a single layer of mixed hetero-molecular films with lateral long range order. In this way the system CuPc + PTCDA/Ag(111) is prepared and then characterized as a proper system for a detailed analysis with RPES. Additional annealing experiments of hetero-organic films consisting of F4TCNQ and PTCDA molecules on Ag(110) with an F4TCNQ coverage of 1.0 ML (and above) end in a submonolayer (sub-ML) film of F4TCNQ/Ag(110) that exhibits a contribution of amorphous carbon. Consequently, it can be concluded that at elevated temperatures part of the F4TCNQ molecules decom- pose.
In the second part of this thesis homo-molecular multilayer samples and (sub-)ML films on single crystalline metal surfaces are investigated with RPES in order to enable the final RPES study of vertical and lateral hetero-molecular interface systems. First a pho- ton energy (hν) dependent intensity variation of (groups of) molecular orbital signals of exemplary multilayer films (NTCDA and coronene) is studied and explained on the basis of the local character of the electronic transitions in near edge x-ray absorption fine structure (NEXAFS) spectroscopy in combination with the real space probability den- sity of the contributing molecular orbitals. This simple approach is found to be able to correctly describe relative intensity variations by orders of magnitude while it fails for hν dependent relative intensity changes in the same order of magnitude. After that the hν dependent line-shape evolution of an energetically separated molecular orbital signal of a CuPc multilayer is discussed in relation to small molecules in the gas phase and explained with an effect of electron vibration coupling. Through a comparison of the hν dependent line-shape evolution of the highest occupied molecular orbital (HOMO) of a CuPc with a SnPc multilayer the molecule specific character of this effect is identified. Then the same effect with either two (or more) electronic transitions or multiple coupling vibrational modes is observed for a coronene multilayer. Thereafter the influence of the adsorption on metal surfaces on this effect is studied and discussed with special emphasis on a possible contribution by features which are related to dynamical interface CT. For a sub-ML of SnPc/Au(111) no variation with respect to a SnPc multilayer film is detected while for a sub-ML of CuPc/Au(111) less intensity is distributed into the high binding energy (EB) part of the HOMO signal with respect to the corresponding multilayer film. In the RPES data of a sub-ML of coronene/Ag(111) a resonance specific variation of the hν dependent line-shape evolution of the HOMO signal is found by the revelation of a change of this effect with respect to the coronene multilayer data in only one of the two NEXAFS resonances. All these findings are consistently explained within one effect and a common set of parameters, namely all quantities that characterize the potential energy surfaces involved in the RPES process. Through that an alternative explanation that re- lies on dynamical CT can be excluded which influences the following CT analysis with RPES.
Three criteria for such an analysis of dynamical interface CT with RPES are identified. In the system coronene on Ag(111) a low EB feature is related to metal-molecule inter- face CT through the assignment of a particular final state and hence named CT state. In the EB region of the frontier molecular orbital signals of the molecule-metal inter- face systems with a signal from the lowest unoccupied molecular orbital (LUMO) in direct valence PES a broad line-shape is measured in RPES. This finding is related to interface CT by a possible explanation that emerges through the comparison to the line- shape of the CT state. The constant kinetic energy (EK ) features detected for several molecule-metal interfaces constitute the third criterion for a CT analysis with RPES. For the molecule-metal interface systems without a LUMO signal in direct valence PES the energy of these features can be calculated with the assignment of the responsible decay channel in combination with explicitly given simplifying assumptions. Through that the involvement of metal-molecule interface CT in the generation of these constant EK fea- tures is demonstrated. The RPES data of the lateral and the vertical hetero-molecular interface, identified in the first part, is then scanned for these three CT criteria. Thereby neither for the lateral hetero-molecular system CuPc + PTCDA/Ag(111) nor for the verti- cal hetero-molecular system CuPc/1 ML PTCDA/Ag(111) dynamical hetero-molecular interface CT can be confirmed. In the former system the molecule-metal interface in- teraction is found to dominate the physics of the system in RPES while in the latter system no hints for a significant hybridization at the CuPc-PTCDA interface can be revealed
Cord blood hematopoietic stem cells (CB-HSCs) are an outstanding source for the treatment of a variety of malignant and non-malignant disorders. However, the low amount of cells collected per donor is often insufficient for treatment of adult patients. In order to make sufficient numbers of CB-HSCs available for adults, expansion is required. Different approaches were described for HSC expansion, however these approaches are impeded by the loss of engrafting potential during ex vivo culture. Little is known about the underlying molecular mechanisms. Epigenetic mechanisms play essential roles in controlling stem cell potential and fate decisions and epigenetic strategies are considered for HSC expansion. Therefore, this study aimed to characterize global and local epigenotypes during the expansion of human CB-CD34+, a well established CB progenitor cell type, to better understand the molecular mechanisms leading to the culture-associated loss of engrafting potential. Human CB-CD34+ cells were cultured using 2 different cytokine cocktails: the STF cocktail containing SCF, TPO, FGF-1 and the STFIA cocktail, which combines STF with Angiopoietin-like 5 (Angptl5) and Insulin-like growth factor-binding protein 2 (IGFBP2). The latter expands CB-HSCs ex vivo. Subsequently, the NOD-scid gamma (NSG) mouse model was used to study the engraftment potential of expanded cells. Engraftment potential achieved by fresh CB-CD34+ cells was maintained when CB-CD34+ cells were expanded under STFIA but not under STF conditions. To explore global chromatin changes in freshly isolated and expanded CB-CD34+ cells, levels of the activating H3K4me3 and the repressive H3K27me3 histone marks were determined by chromatin flow cytometry and Western blot analyses. For analysis of genome-wide chromatin changes following ex vivo expansion, transcriptome profiling by microarray and chromatin immunoprecipitation combined with deep sequencing (ChIP-seq) were performed. Additionally, local chromatin transitions were monitored by ChIP analyses on promoter regions of developmental and self-renewal factors. On a global level, freshly isolated CD34+ and CD34- cells differed in H3K4me3 and H3K27me3 levels. After 7 days of expansion, CD34+ and CD34- cells adopted similar levels of active and repressive marks. Expanding the cells without IGFBP2 and Angptl5 led to a higher global H3K27me3 level. ChIP-seq analyses revealed a cytokine cocktail-dependent redistribution of H3K27me3 profiles. Chemical inhibition of the H3K27 methyltransferase EZH2 counteracted the culture-associated loss of NSG engraftment potential. Collectively, the data presented in this study revealed that by adding epigeneticly active compounds in the culture media we observed changes on a chromatin level which counteracted the loss of engraftment potential. H3K27me3 rather than H3K4me3 may be critical to establish a specific engraftment supporting transcriptional program. Furthermore, I identified a critical function for the Polycomb repressive complex 2-component EZH2 in the loss of engraftment potential during the in vitro expansion of HPSCs. Taken together this thesis provides a better molecular understanding of chromatin changes upon expansion of CB-HSPCs and opens up new perspectives for epigenetic ex vivo expansion strategies.
Magnetic Resonance Imaging (MRI) is a non-invasive medical imaging technique, that is rou- tinely used in clinical practice for detection and diagnosis of a wide range of different diseases. In MRI, no ionizing radiation is used, making even repeated application unproblematic. This is an important advantage over other common imaging methods such as X-rays and Computer To- mography. One major drawback of MRI, however, are long acquisition times and associated high costs of experiments. Since the introduction of MRI, several important technical developments have been made to successfully reduce acquisition times. In this work, novel approaches were developed to increase the efficiency of MRI acquisitions.
In Chapter 4, an improved radial turbo spin-echo (TSE) combined acquisition and reconstruction strategy was introduced. Cartesian turbo spin-echo sequences [3] are widely used especially for the detection and diagnosis of neurological pathologies, as they provide high SNR images with both clinically important proton density and T2 contrasts. TSE acquisitions combined with radial sampling are very efficient, since it is possible to obtain a number of ETL images with different contrasts from a single radial TSE measurement [56–58]. Conventionally, images with a particular contrast are obtained from both radial and Cartesian TSE acquisitions by combining data from different echo times into a single image. In the radial case, this can be achieved by employing k-space weighted image contrast (KWIC) reconstruction. In KWIC, the center region of k-space is filled exclusively with data belonging to the desired contrast while outer regions also are assembled with data acquired at other echo times. However, this data sharing leads to mixed contrast contributions to both Cartesian and radial TSE images. This is true especially for proton density weighted images and therefore may reduce their diagnostic value.
In the proposed method, an adapted golden angle reordering scheme is introduced for radial TSE acquisitions, that allows a free choice of the echo train length and provides high flexibility in image reconstruction. Unwanted contrast contaminations are greatly reduced by employing a narrow-band KWIC filter, that restricts data sharing to a small temporal window around the de- sired echo time. This corresponds to using fewer data than required for fully sampled images and consequently leads to images exhibiting aliasing artifacts. In a second step, aliasing-free images are obtained using parallel imaging. In the neurological examples presented, the CG-SENSE algorithm [42] was chosen due to its stable convergence properties and its ability to reconstruct arbitrarily sampled data. In simulations as well as in different in vivo neurological applications, no unwanted contrast contributions could be observed in radial TSE images reconstructed with the proposed method. Since this novel approach is easy to implement on today’s scanners and requires low computational power, it might be valuable for the clinical breakthrough of radial TSE acquisitions.
In Chapter 5, an auto-calibrating method was introduced to correct for stimulated echo contribu- tions to T2 estimates from a mono-exponential fit of multi spin-echo (MSE) data. Quantification of T2 is a useful tool in clinical routine for the detection and diagnosis of diseases as well as for tis- sue characterization. Due to technical imperfections, refocusing flip angles in a MSE acquisition deviate from the ideal value of 180○. This gives rise to significant stimulated echo contributions to the overall signal evolution. Therefore, T2 estimates obtained from MSE acquisitions typically are notably higher than the reference. To obtain accurate T2 estimates from MSE acquisitions, MSE signal amplitudes can be predicted using the extended phase graph (EPG, [23, 24]) algo- rithm. Subsequently, a correction factor can be obtained from the simulated EPG T2 value and applied to the MSE T2 estimates. However, EPG calculations require knowledge about refocus- ing pulse amplitudes, T2 and T1 values and the temporal spacing of subsequent echoes. While the echo spacing is known and, as shown in simulations, an approximate T1 value can be assumed for high ratios of T1/T2 without compromising accuracy of the results, the remaining two parameters are estimated from the data themselves. An estimate for the refocusing flip angle can be obtained from the signal intensity ratio of the second to the first echo using EPG. A conventional mono- exponential fit of the MSE data yields a first estimate for T2. The T2 correction is then obtained iteratively by updating the T2 value used for EPG calculations in each step. For all examples pre- sented, two iterations proved to be sufficient for convergence. In the proposed method, a mean flip angle is extracted across the slice. As shown in simulations, this assumption leads to greatly reduced deviations even for more inhomogeneous slice profiles. The accuracy of corrected T2 values was shown in experiments using a phantom consisting of bottles filled with liquids with a wide range of different T2 values. While T2 MSE estimates were shown to deviate significantly from the spin-echo reference values, this is not the case for corrected T2 values. Furthermore, applicability was demonstrated for in vivo neurological experiments.
In Chapter 6, a new auto-calibrating parallel imaging method called iterative GROG was pre- sented for the reconstruction of non-Cartesian data. A wide range of different non-Cartesian schemes have been proposed for data acquisition in MRI, that present various advantages over conventional Cartesian sampling such as faster acquisitions, improved dynamic imaging and in- trinsic motion correction. However, one drawback of non-Cartesian data is the more complicated reconstruction, which is ever more problematic for non-Cartesian parallel imaging techniques. Iterative GROG uses Calibrationless Parallel Imaging by Structured Low-Rank Matrix Completion (CPI) for data reconstruction. Since CPI requires points on a Cartesian grid, it cannot be used to directly reconstruct non-Cartesian data. Instead, Grappa Operator Gridding (GROG) is employed in a first step to move the non-Cartesian points to the nearest Cartesian grid locations. However, GROG requires a fully sampled center region of k-space for calibration. Combining both methods in an iterative scheme, accurate GROG weights can be obtained even from highly undersampled non-Cartesian data. Subsequently, CPI can be used to reconstruct either full k- space or a calibration area of arbitrary size, which can then be employed for data reconstruction with conventional parallel imaging methods.
In Chapter 7, a new 2D sampling scheme was introduced consisting of multiple oscillating effi- cient trajectories (MOET), that is optimized for Compressed Sensing (CS) reconstructions. For successful CS reconstruction of a particular data set, some requirements have to be met. First, ev- ery data sample has to carry information about the whole object, which is automatically fulfilled for the Fourier sampling employed in MRI. Additionally, the image to be reconstructed has to be sparse in an arbitrary domain, which is true for a number of different applications. Last, data sam- pling has to be performed in an incoherent fashion. For 2D imaging, this important requirement of CS is difficult to achieve with conventional Cartesian and non-Cartesian sampling schemes. Ra- dial sampling is often used for CS reconstructions of dynamic data despite the streaking present in undersampled images. To obtain incoherent aliasing artifacts in undersampled images while at the same time preserving the advantages of radial sampling for dynamic imaging, MOET com- bines radial spokes with oscillating gradients of varying amplitude and alternating orientation orthogonal to the readout direction. The advantage of MOET over radial sampling in CS re- constructions was demonstrated in simulations and in in vivo cardiac imaging. MOET provides superior results especially when used in CS reconstructions with a sparsity constraint directly in image space. Here, accurate results could be obtained even from few MOET projections, while the coherent streaking artifacts present in the case of radial sampling prevent image recovery even for smaller acceleration factors. For CS reconstructions of dynamic data with sparsity constraint in xf-space, the advantage of MOET is smaller since the temporal reordering is responsible for an important part of incoherency. However, as was shown in simulations of a moving phantom and in the reconstruction of ungated cardiac data, the additional spatial incoherency provided by MOET still leads to improved results with higher accuracy and may allow reconstructions with higher acceleration factors.
Localization microscopy is a class of super-resolution fluorescence microscopy techniques. Localization microscopy methods are characterized by stochastic temporal isolation of fluorophore emission, i.e., making the fluorophores blink so rapidly that no two are
likely to be photoactive at the same time close to each other. Well-known localization microscopy methods include dSTORM}, STORM, PALM, FPALM, or GSDIM. The biological community has taken great interest in localization microscopy, since it can enhance the resolution of common fluorescence microscopy by an order of magnitude at little experimental cost.
However, localization microscopy has considerable computational cost since millions of individual stochastic emissions must be located with nanometer precision. The computational cost of this evaluation, and the organizational cost of implementing the complex algorithms, has impeded adoption of super-resolution microscopy for a long time.
In this work, I describe my algorithmic framework for evaluating localization microscopy data.
I demonstrate how my novel open-source software achieves real-time data evaluation, i.e., can evaluate data faster than the common experimental setups can capture them.
I show how this speed is attained on standard consumer-grade CPUs, removing the need for computing on expensive clusters or deploying graphics processing units.
The evaluation is performed with the widely accepted Gaussian PSF model and a Poissonian maximum-likelihood noise model.
I extend the computational model to show how robust, optimal two-color evaluation is realized, allowing correlative microscopy between multiple proteins or structures. By employing cubic B-splines, I show how the evaluation of three-dimensional samples can be made simple and robust, taking an important step towards precise imaging of micrometer-thick samples.
I uncover the behavior and limits of localization algorithms in the face of increasing emission densities.
Finally, I show up algorithms to extend localization microscopy to common biological problems.
I investigate cellular movement and motility by considering the in vitro movement of myosin-actin filaments. I show how SNAP-tag fusion proteins enable imaging with bright and stable organic fluorophores in live cells. By analyzing the internal structure of protein clusters, I show how localization microscopy can provide new quantitative approaches beyond pure imaging.
This thesis explores the influence of social and environmental cues on the nest building behavior of leaf-cutting ants. Especially, the investigations are aimed at evaluating the mechanisms of nest building and how the nest environment can spatially guide building responses that lead to an adaptive nest architecture. The emergence of nest chambers in the nest of the leaf-cutting ant Acromyrmex lundi were evaluated. Rather than excavating nest chambers in advance, at places where workers encounter suitable environmental conditions for brood and fungus rearing, these items have to be present at a site. When presented in the laboratory with a choice between two otherwise identical digging sites, offering suitable environmental conditions, but one containing brood, the workers displayed a higher excavation activity at the site where they encountered the putative content of a chamber. The shape of the excavated cavity was also more round and chamber-like. It is concluded that leaf-cutting ants respond to social cues during nest building. Excavation is a costly process and colonies have to spend a part of their energy stores on nest building, so that regulatory responses for the control of nest excavation are expected to occur. Worker density at the beginning of the digging process influenced digging activity while the presence of in-nest stores did not. Stored brood and fungus did however influence the architecture of the excavated nest, leading to the excavation of larger chambers and smaller tunnels. While self-organized mechanisms appear to be involved in the nest building process, the social cues of the ants’ environment during building clearly influence the nest architecture and lead to an adjustment of the nest size to the current space needs of the colony. Workers secondarily regulated nest size by the opportunistic refilling of unused space with excavated soil pellets. As the ants should provide suitable conditions for brood and fungus rearing, they should show a behavioral response to CO2 concentrations, as the gas is known to hinder fungus respiration. Workers of A. lundi did indeed avoid high CO2-levels for fungus rearing but actually preferred CO2-values in the range encountered close to the soil surface, where this species excavates their nests. However, different CO2-levels did not affect their excavation behavior. While fungus chambers make up part of a leaf-cutting ant nest, most leaf-cutting ants of the genus Atta also spent part of the colony’s energy on excavating large, voluminous chambers for waste disposal, rather than scattering the material aboveground. It is expected that leaf-cutting ants also show environmental preferences for waste management. In experiments Atta laevigata workers preferred deposition in a warm and dry environment and showed no preference for specific CO2-levels. The continued accumulation of waste particles in a waste chamber seems to be based on the use of volatiles. These originate from the waste itself, and seem to be used as an orientation cue by workers relocating the material. The ensuing large accumulation of waste at one site should result in the emergence of more voluminous chambers for waste disposal.
The intracellular pathogen Chlamydia is the causative agent of millions of new infections per year transmitting diseases like trachoma, pelvic inflammatory disease or lymphogranuloma venereum. Undetected or recurrent infections caused by chlamydial persistence are especially likely to provoke severe pathologies. To ensure host cell survival and to facilitate long term infections Chlamydia induces anti-apoptotic pathways, mainly at the level of mitochondria, and restrains activity of pro-apoptotic proteins. Additionally, the pathogen seizes host energy, carbohydrates, amino acids, lipids and nucleotides to facilitate propagation of bacterial progeny and growth of the chlamydial inclusion.
At the beginning of this study, Chlamydia-mediated apoptosis resistance to DNA damage induced by the topoisomerase inhibitor etoposide was investigated. In the course of this, a central cellular protein crucial for etoposide-mediated apoptosis, the tumour suppressor p53, was found to be downregulated during Chlamydia infections. Subsequently, different chlamydial strains and serovars were examined and p53 downregulation was ascertained to be a general feature during Chlamydia infections of human cells. Reduction of p53 protein level was established to be mediated by the PI3K-Akt signalling pathway, activation of the E3-ubiquitin ligase HDM2 and final degradation by the proteasome. Additionally, an intriguing discrepancy between infections of human and mouse cells was detected. Both activation of the PI3K-Akt pathway as well as degradation of p53 could not be observed in Chlamydia-infected mouse cells. Recently, production of reactive oxygen species (ROS) and damage to host cell DNA was reported to occur during Chlamydia infection. Thus, degradation of p53 strongly contributes to the anti-apoptotic environment crucial for chlamydial infection.
To verify the importance of p53 degradation for chlamydial growth and development, p53 was stabilised and activated by the HDM2-inhibiting drug nutlin-3 and the DNA damage-inducing compound etoposide. Unexpectedly, chlamydial development was severely impaired and inclusion formation was defective. Completion of the chlamydial developmental cycle was prevented resulting in loss of infectivity. Intriguingly, removal of the p53 activating stimulus allowed formation of the bacterial inclusion and recovery of infectivity. A similar observation of growth recovery was made in infected cell lines deficient for p53.
As bacterial growth and inclusion formation was strongly delayed in the presence of activated p53, p53-mediated inhibitory regulation of cellular metabolism was suspected to contribute to chlamydial growth defects. To verify this, glycolytic and pentose phosphate pathways were analysed revealing the importance of a functioning PPP for chlamydial growth. In addition, increased expression of glucose-6-phosphate dehydrogenase rescued chlamydial growth inhibition induced by activated p53. The rescuing effect was even more pronounced in p53-deficient cells treated with etoposide or nutlin-3 revealing additional p53-independent aspects of Chlamydia inhibition. Removal of ROS by anti-oxidant compounds was not sufficient to rescue chlamydial infectivity. Apparently, not only the anti-oxidant capacities of the PPP but also provision of precursors for nucleotide synthesis as well as contribution to DNA repair are important for successful chlamydial growth.
Modulation of host cell signalling was previously reported for a number of pathogens. As formation of ROS and DNA damage are likely to occur during infections of intracellular bacteria, several strategies to manipulate the host and to inhibit induction of apoptosis were invented. Downregulation of the tumour suppressor p53 is a crucial point during development of Chlamydia, ensuring both host cell survival and metabolic support conducive to chlamydial growth.
Rapid population growth in West Africa has led to expansion in croplands due to the need to grow more food to meet the rising food demand of the burgeoning population. These expansions negatively impact the sub-region's ecosystem, with implications for water and soil quality, biodiversity and climate. In order to appropriately monitor the changes in croplands and assess its impact on the ecosystem and other environmental processes, accurate and up-to-date information on agricultural land use is required. But agricultural land use mapping (i.e. mapping the spatial distribution of crops and croplands) in West Africa has been challenging due to the unavailability of adequate satellite images (as a result of excessive cloud cover), small agricultural fields and a heterogeneous landscape. This study, therefore, investigated the possibilities of improving agricultural land use mapping by utilizing optical satellite images with higher spatial and temporal resolution as well as images from Synthetic Aperture Radar (SAR) systems which are near-independent of weather conditions. The study was conducted at both watershed and regional scales.
At watershed scale, classification of different crop types in three watersheds in Ghana, Burkina Faso and Benin was conducted using multi-temporal: (1) only optical images (RapidEye) and (2) optical plus dual polarimetric (VV/VH) SAR images (TerraSAR-X). In addition, inter-annual or short term (2-3 years) changes in cropland area in the past ten years were investigated using historical Landsat images. Results obtained indicate that the use of only optical images to map different crop types in West Africa can achieve moderate classification accuracies (57% to 71%). Overlaps between the cropping calendars of most crops types and certain inter-croppings pose a challenge to optical images in achieving an adequate separation between those crop classes. Integration of SAR images, however, can improve classification accuracies by between 8 and 15%, depending on the number of available images and their acquisition dates. The sensitivity of SAR systems to different crop canopy architectures and land surface characteristics improved the separation between certain crop types. The VV polarization of TerraSAR-X was found to better discrimination between crop types than the VH. Images acquired between August and October were found to be very useful for crop mapping in the sub-region due to structural differences in some crop types during this period.
At the regional scale, inter-annual or short term changes in cropland area in the Sudanian Savanna agro-ecological zone in West Africa were assessed by upscaling historical cropland information derived at the watershed scale (using Landsat imagery) unto a coarse spatial resolution, but geographically large, satellite imagery (MODIS) using regression based modeling. The possibility of using such regional scale cropland information to improve government-derived agricultural statistics was investigated by comparing extracted cropland area from the fractional cover maps with district-level agricultural statistics from Ghana The accuracy of the fractional cover maps (MAE between 14.2% and 19.1%) indicate that the heterogeneous agricultural landscape of West Africa can be suitably represented at the regional or continental scales by estimating fractional cropland cover on low resolution Analysis of the results revealed that cropland area in the Sudanian Savanna zone has experienced inter-annual or short term fluctuations in the past ten years due to a variety of factors including climate factors (e.g. floods and droughts), declining soil fertility, population increases and agricultural policies such as fertilizer subsidies. Comparison of extracted cropland area from the fractional cover maps with government's agricultural statistics (MoFA) for seventeen districts (second administrative units) in Ghana revealed high inconsistencies in the government statistics, and highlighted the potential of satellite derived cropland information at regional scales to improve national/sub-national agricultural statistics in West Africa.
The results obtained in this study is promising for West Africa, considering the recent launch of optical (Landsat 8) and SAR sensors (Sentinel-1) that will provide free data for crop mapping in the sub-region. This will improve chances of obtaining adequate satellite images acquired during the cropping season for agricultural land use mapping and bolster opportunities of operationalizing agricultural land use mapping in West Africa. This can benefit a wide range of biophysical and economic models and improve decision making based on their results.
In this thesis we study smoothness properties of primal and dual gap functions for generalized Nash equilibrium problems (GNEPs) and finite-dimensional quasi-variational inequalities (QVIs). These gap functions are optimal value functions of primal and dual reformulations of a corresponding GNEP or QVI as a constrained or unconstrained optimization problem. Depending on the problem type, the primal reformulation uses regularized Nikaido-Isoda or regularized gap function approaches. For player convex GNEPs and QVIs of the so-called generalized `moving set' type the respective primal gap functions are continuously differentiable. In general, however, these primal gap functions are nonsmooth for both problems. Hence, we investigate their continuity and differentiability properties under suitable assumptions. Here, our main result states that, apart from special cases, all locally minimal points of the primal reformulations are points of differentiability of the corresponding primal gap function.
Furthermore, we develop dual gap functions for a class of GNEPs and QVIs and ensuing unconstrained optimization reformulations of these problems based on an idea by Dietrich (``A smooth dual gap function solution to a class of quasivariational inequalities'', Journal of Mathematical Analysis and Applications 235, 1999, pp. 380--393). For this purpose we rewrite the primal gap functions as a difference of two strongly convex functions and employ the Toland-Singer duality theory. The resulting dual gap functions are continuously differentiable and, under suitable assumptions, have piecewise smooth gradients. Our theoretical analysis is complemented by numerical experiments. The solution methods employed make use of the first-order information established by the aforementioned theoretical investigations.
The thesis ’Hurwitz’s Complex Continued Fractions - A Historical Approach and Modern Perspectives.’ deals with two branches of mathematics: Number Theory and History of Mathematics. On the first glimpse this might be unexpected, however, on the second view this is a very fruitful combination. Doing research in mathematics, it turns out to be very helpful to be aware of the beginnings and development of the corresponding subject.
In the case of Complex Continued Fractions the origins can easily be traced back to the end of the 19th century (see [Perron, 1954, vl. 1, Ch. 46]). One of their godfathers had been the famous mathematician Adolf Hurwitz. During the study of his transformation from real to complex continued fraction theory [Hurwitz, 1888], our attention was arrested by the article ’Ueber eine besondere Art der Kettenbruch-Entwicklung complexer Grössen’ [Hurwitz, 1895] from 1895 of an author called J. Hurwitz. We were not only surprised when we found out that he was the elder unknown brother Julius, furthermore, Julius Hurwitz introduced a complex continued fraction that also appeared (unmentioned) in an ergodic theoretical work from 1985 [Tanaka, 1985]. Those observations formed the Basis of our main research questions:
What is the historical background of Adolf and Julius Hurwitz and their mathematical studies? and What modern perspectives are provided by their complex continued fraction expansions?
In this work we examine complex continued fractions from various viewpoints. After a brief introduction on real continued fractions, we firstly devote ourselves to the lives of the brothers Adolf and Julius Hurwitz. Two excursions on selected historical aspects in respect to their work complete this historical chapter. In the sequel we shed light on Hurwitz’s, Adolf’s as well as Julius’, approaches to complex continued fraction expansions.
Correspondingly, in the following chapter we take a more modern perspective. Highlights are an ergodic theoretical result, namely a variation on the Döblin-Lenstra Conjecture [Bosma et al., 1983], as well as a result on transcendental numbers in tradition of Roth’s theorem [Roth, 1955]. In two subsequent chapters we are concernced with arithmetical properties of complex continued fractions. Firstly, an analogue to Marshall Hall’s Theorem from 1947 [Hall, 1947] on sums of continued fractions is derived. Secondly, a general approach on new types of continued fractions is presented building on the structural properties of lattices. Finally, in the last chapter we take up this approach and obtain an upper bound for the approximation quality of diophantine approximations by quotients of lattice points in the complex plane generalizing a method of Hermann Minkowski, improved by Hilde Gintner [Gintner, 1936], based on ideas from geometry of numbers.
Cell growth and cell division are two interconnected yet distinct processes. Initiation of proliferation of central brain progenitor cells (neuroblasts) after the late embryonic quiescence stage requires cell growth, and maintenance of proper cell size is an important prerequisite for continuous larval neuroblast proliferation. Beside extrinsic nutrition signals, cell growth requires constant supply with functional ribosomes to maintain protein synthesis.
Mutations in the mushroom body miniature (mbm) gene were previously identified in a screen for structural brain mutants. This study focused on the function of the Mbm protein as a new nucleolar protein, which is the site of ribosome biogenesis. The comparison of the relative expression levels of Mbm and other nucleolar proteins in different cell types showed a pronounced expression of Mbm in neuroblasts, particularly in the fibrillar component of the nucleolus, suggesting that in addition to nucleolar components generally required for ribosome biogenesis, more neuroblast specific nucleolar factors exist. Mutations in mbm cause neuroblast proliferation defects but do not interfere with cell polarity, spindle orientation or asymmetry of cell division of neuroblasts. Instead a reduction in cell size was observed, which correlates with an impairment of ribosome biogenesis. In particular, loss of Mbm leads to the retention of the small ribosomal subunit in the nucleolus resulting in decreased protein synthesis. Interestingly, the defect in ribosome biogenesis was only observed in neuroblasts. Moreover, Mbm is apparently not required for cell size and proliferation control in wing imaginal disc and S2 cells supporting the idea of a neuroblast-specific function of Mbm.
Furthermore, the transcriptional regulation of the mbm gene and the functional relevance of posttranslational modifications were analyzed. Mbm is a transcriptional target of dMyc. A common feature of dMyc target genes is the presence of a conserved E-box sequence in their promoter regions. Two E-box motifs are found in the vicinity of the transcriptional start site of mbm. Gene reporter assays verified that only one of them mediates dMyc-dependent transcription. Complementary studies in flies showed that removal of dMyc function in neuroblasts resulted in reduced Mbm expression levels.
At the posttranslational level, Mbm becomes phosphorylated by protein kinase CK2. Six serine and threonine residues located in two acidic amino acid rich clusters in the C-terminal half of the Mbm protein were identified as CK2 phosphorylation sites.
Mutational analysis of these sites verified their importance for Mbm function in vivo and indicated that Mbm localization is controlled by CK2-mediated phosphorylation.
Although the molecular function of Mbm in ribosome biogenesis remains to be determined, the results of this study emphasize the specific role of Mbm in neuroblast ribosome biogenesis to control cell growth and proliferation.
Several aspects of the control of large-scale systems communicating over digital channels are considered.
In particular, the issue of delay, quantization, and packet loss is addressed with the help of dynamic quantization.
New small-gain results suitable for networked control systems are introduced and it is shown that many of the known small-gain conditions are equivalent.
The issue of bandwidth limitations is addressed with the help of event-triggered control.
A novel approach termed parsimonious triggering is introduced, which helps to rule out the occurrence of an infinite number of triggering events within finite time.
Moreover, the feasibility of the presented approaches is demonstrated by numerical examples.
Galectin-1 (hGal-1) is overexpressed by numerous cancer types and previously conducted studies confirmed that the β-galactoside-binding protein mediates various molecular interactions associated with tumor growth, spread and survival. Upon interaction with carbohydrate-based binding epitopes of glycan structures on human cell surfaces galectin-1 induces proliferative, angiogenetic and migratory signals and modulates negative T cell regulation which essentially helps the tumor to evade the immune response. These findings attributed galectin-1 a pivotal role in tumor physiology and strongly suggest the protein as target for diagnostic and therapeutic applications.
Within the scope of this work a strategy was elaborated for designing tailor-made galectin-1 ligands by functionalizing selected hydroxyl groups of the natural binding partner N-acetyllactosamine (LacNAc) that are not involved in the sophisticated interplay between the disaccharide and the protein. Synthetic modifications intended to introduce chemical groups i) to address a potential binding site adjacent to the carbohydrate recognition domain (CRD) with extended hGal-1-ligand interactions, ii) to implement a tracer isotope for diagnostic detection and iii) to install a linker unit for immobilization on microarrays.
Resulting structures were investigated regarding their targeting ability towards galectin-1 by cocrystallization experiments, SPR and ITC studies. Potent binders were further probed for their diagnostic potential to trace elevated galectin-1 levels in microarray experiments and for an application in positron emission tomography (PET).
The transport of optically excited states, called excitons, as well as their conversion into charges define the two major steps allowing for the operation of organic photovoltaic (OPV) devices. Hence, a deep understanding of these processes, the involved mechanisms as well as possible loss channels is crucial for further improving the efficiency of organic solar cells. For studying the aforementioned processes spectroscopic methods like absorption and emission measurements are useful tools. As many of the processes take place on a sub-nanosecond (ns) timescale ultrafast spectroscopic methods are required. Due to this reason two experiments based on a femtosecond laser system were built and employed in this work, namely picosecond (ps) time-resolved photoluminescence (PL) and transient absorption (TA) spectroscopy.
By analyzing the PL decay dynamics in the prototypical organic semiconductor rubrene, the feasibility of a new approach for improving the efficiency of organic solar cells by harvesting triplet excitons generated by singlet fission was examined. Singlet fission describes a process where two triplet excitons are generated via a photoexcited singlet exciton precursor state if the energy of the two triplets is comparable with the energy of the singlet. For this purpose the influence of characteristic length scales on the exciton dynamics in different rubrene morphologies exhibiting an increasing degree of confinement was analyzed. The results show that the quenching at interfacial states efficiently suppresses the desired fission process if these states are reached by excitons during migration. Since interfacial states are expected to play a significant role in thin film solar cells and are easily accessible for the migrating excitons, the results have to be considered for triplet-based OPV.
While the aforementioned approach is only investigated for model systems so far, the efficiency of disordered organic bulk heterojunction (BHJ) solar cells could be significantly enhanced in the last couple of years by employing new and more complex copolymer donor materials. However, little is known about the photophysics and in particular the excitation dynamics of these systems. By carrying out a systematic optical study on the prominent copolymer PCDTBT and its building blocks we were able to identify the nature of the two characteristic absorption bands and the coupling mechanism between these levels. The latter mechanism is based on an intrachain partial charge transfer between two functional subunits and our time-resolved measurements indicate that this coupling governs the photophysical properties of solar cells based on these copolymers. The efficient coupling of functional subunits can be seen as a key aspect that guarantees for the success of the copolymer approach.
Another important issue concerns the optimization of the morphology of BHJ solar cells. It arises from the discrepancy between the exciton diffusion length \mbox{($\approx$ 10 nm)} and the absorption length of solar irradiation ($\approx$ 100 nm). Due to this reason, even for devices based on new copolymer materials, processing parameters affecting the morphology like annealing or employing processing additives are of major importance. In our combined optical, electrical and morphological study for solar cells based on the high-efficient copolymer PBDTTT-C we find a direct correlation between additive content and intermixing of the active layer. The observed maximum in device efficiency can be attributed to a morphology guaranteeing for an optimized balance between charge generation and transport. Our results highlight the importance of understanding the influence of processing parameters on the morphology of the BHJ and thus on the efficiency of the device.
In this work the synthesis, the spectroscopic and electrochemical investigation as well as some applications of a broad diversity of indolenine squaraine dyes were presented. This diversity was based on two parent squaraine dyes, one standard trans-configured compound (M1) and one in which one central oxygen atom was replaced by a dicyanomethylene moiety (M2), which increased the acceptor strength and induced a cis-configuration. The variety of synthesised dyes included functionalised squaraine monomers, donor- and acceptor-substituted monomeric model squaraines, donor- and acceptor-squaraine copolymers, pure squaraine homopolymers, a squaraine-squaraine copolymer, as well as some conjugated cyclic oligomers.
In order to be able to synthesise all these different kinds of dyes, several bromine and boronic ester derivatives were synthesised, which enabled the use of the Suzuki cross coupling reaction, to generate model dyes and copolymers. In addition, the bromine derivatives were used to carry out the Yamamoto homocoupling reaction to the respective homopolymers and macrocycles.
The absorption maximum of unsubstituted reference dye M1 was found at ~ 15500 cm–1, while that of M2 was red-shifted to ~ 14300 cm–1 due to the increased acceptor strength of the central unit. The extinction coefficients were in the order of ~ 300000 M–1 cm–1 and ~ 200000 M–1 cm–1, respectively. It was found that the implementation of functional groups (M3–M9), additional electron donors (M10–M19) or acceptors (M20–M22) at the periphery lead to bathochromic shifts of the absorption depending on the strength of either - and/or -donating properties of the substituents.
For the bis- and triarylamine substituted dyes M10–M13 and the dibrominated dyes M5 and M7 the electronic structure of the mono- and diradical (di)cations was explored using the interplay of cyclic voltammetry, spectroelectrochemistry, and DFT calculations. It was demonstrated that the monoradical cations still show a cyanine-like character and are delocalised Robin-Day class III species due to the low redox potential of the squaraine bridge between the additional amine redox centres. To the best of my knowledge, this made M13+∙, with an N-N-distance of 26 bonds between the additional redox centres to the longest bis(triarylamine) radical cation that is completely delocalised. For the diradical dications, the situation was of larger complexity. The computed most stable energetic state of the dianisylamine-substituted dyes turned out to be a broken-symmetry state with almost equal contributions of an open-shell singlet and triplet state. In addition, it was shown that the HOMO–1→HOMO transition dominated the absorption spectra of the diradical dications where the trans-/cis-configuration of the squaraines had a direct impact due to symmetry reasons.
Based on the donor–squaraine model compounds M10–M19, a series of donor–squaraine copolymers was synthesised (P7–P12) in order to further red shift and broaden the low energy absorption band. However, these effects were only of marginal extent. Both the optical and the electrochemical derived band gaps were barely lowered compared to the respective monomeric model dyes. This was assigned to an increased squaraine-squaraine distance and resulting lower exciton coupling between the squaraine chromophores due to the bridging units. In addition, according to semiempirical calculations the bridges were twisted out of the squaraine plane what reduced conjugational effects between the chromophores. To sum up, the idea to insert additional electron rich bridging units in order to create copolymers with broad and red-shifted absorption did not fully work out for the presented systems.
The addition of strong electron accepting NDI units at the periphery resulted in M21, the most unique monomeric model squaraine in this work. The common picture of a sharp low energy squaraine absorption completely altered due to the addition of the NDIs and a rather broad and solvent dependent low energy absorption was found. Spectroelectrochemical experiments and semiempirical calculations showed that this band is a superposition of the common squaraine HOMO→LUMO transition and a partial squaraine→NDI charge transfer transition. The latter was lost upon oxidation of the squaraine and the absorption spectrum of the monocation of M21 was found to be nearly a 1:1 image of a pure squaraine monocation. Both the monomeric model M21 and the respective copolymer P13 showed low electrochemically obtained band gaps of 1.05–1.20 eV, which were the lowest of all squaraines in this work. For both dyes, transient absorption measurements in the fs-time regime revealed the ultrafast formation of a CS state via an intermediate CT state within a few ps. Besides, charge recombination to the ground state also occured within a few ps. In the polymer, there was barely any further energy or charge transfer within the excited state lifetime and therefore the CS state was confined on adjacent squaraine-NDI pairs and did not further travel along the polymer strand.
The Ni-mediated Yamamoto homocoupling reaction was applied for the synthesis of the homopolymers (P1–P5). In contrast to the donor–squaraine copolymers, those polymers revealed strongly red-shifted and broad absorption in the red to NIR region in addition to a sharp fluorescence. These features could be explained to originate mainly from the exciton coupling of localised excited states and the presence of different superstructures in solution. For the polymers P1 and P2, an elongated J-type polymer chain caused the strong lowest energy absorption band whereas a zig-zag type arrangement of the single chromophores lead to transitions into both low and high energy excited states of the excitonic manifold. For the polymers P3 and P4, several polymer fractions of different size were investigated. Here, also an elongated chain with J-type character induced the lowest energy absorption band whereas a helical H-type arrangement caused transitions to higher energies of the excitonic manifold. The fractions to which these structures were formed depended on the chain length and the solvent. In thin film measurements, it was shown that the initially in solution formed superstructures were partly retained in the thin film but could be altered by annealing procedures. A control of the superstructures should enable the controlled tuning of the optical properties. Despite the strong interaction of the chromophores in the excited state, the redox potentials of the homopolymers barely differed to those of the respective reference dyes, indicating negligible electronic interaction in the ground state.
In addition squaraine-squaraine copolymer P6, consisting of alternating parent dyes M1 and M2, was synthesised. Likewise to the homopolymers, a broad and red-shifted absorption was observed. This was explained by exciton coupling theory, which was extended to also suit alternating copolymers. In toluene, an extraordinary narrow and intense lowest energy absorption band was observed. This exchange narrowing might be a result of a highly ordered J-type structure of the polymer especially in this solvent because it was not found in others. The features of the polymer may be compared to typical J-aggregates formed from monomeric cyanine molecules for example and the polymer used as model for excitonic interactions in an alternating copolymer. Transient absorption measurements revealed a strong energy dependence of the decay traces of the copolymer, most strikingly at early decay times. This was assigned to the occurrence of multiple excitations of one polymer strand (due to the large extinction coefficients of the polymer) and resulting exciton-exciton annihilation. Due to the large exciton diffusion constants that were estimated, the static exciton-exciton annihilation was the rate limiting process of the decay, in contrast to other conjugated polymers, where in thin film measurements the decay was diffusion controlled.
To sum up, for the polymers consisting of exclusively squaraine chromophores, it was shown that the exciton coupling of single chromophores with strong transition dipole moments was a fruitful way to tune the absorption spectra.
As a side product of some of the polycondensation reactions, unprecedented cyclic conjugated oligomers such as the triarylamine-bridged dimer Dim1, the cyclic homotrimers Tri1–Tri3, and the tetramer Tet1 were obtained by recycling GPC in low yields. Especially the cyclic trimers showed unusual absorption and even more extraordinary fluorescence properties. They showed multiple fluorescence bands in the NIR that covered a range from ~ 8000–12500 cm–1 (800–1250 nm). First hints from theoretical calculations indicated that the trimer was not fully planar but comprised a mixture of both planar and bent single squaraine chromophores. However, final results of the calculations were still missing at the time of writing.
In the last part of this work, the application of some monomeric and polymeric squaraines in binary and ternary bulk heterojunction solar cells was demonstrated. Also the utilisation as a dopant in a polymer matrix in an OLED device was shown. The homopolymers P1–P4 were tested in the binary BHJ solar cells revealing poor performances and especially very low short circuit currents. The utilisation of the polymers P3 and P4 that carried the dicyanomethylene group resulted in higher open circuit voltages due to the lower LUMO energy levels but still an overall poor performance. Neither for the different alkyl chains nor for the size of the polymers was a trend observed. In the ternary BHJ solar cells, small amounts of either monomer M14 or polymers P1A, P4–1 or P13 were added to a P3HT/PCBM system in order to generate an additional pathway for charge or energy transfer that should result in a better device performance. However, for none of the tested squaraines, improved solar cells could be built. In similarity to the binary solar cells, the short circuit currents were lower compared to a P3HT/PCBM reference device. These low short circuit currents indicated that the morphology of the squaraine dyes was the major limitation in those devices. It is possible that the dimethyl groups at the indolenine hindered a favoured alignment of the compounds that would allow decent charge transport. In the squaraine doped OLED the squaraine M6 worked rather well as an NIR emitter. Already at low dye loads the fluorescence of the host polymer SY-PPV was completely quenchend and emission from the squaraine was observed. For electroluminescence measurements, a lower dye load (0.5 wt.%) compared to the photoluminescence measurements was sufficient, indicating that apart from FRET additional quenching mechanisms were at work in the electrically driven devices such as charge carrier dynamics.
Malaria is a challenging infection with increasing and wide-spread treatment failure risk due to resistance. With a estimated death toll of 1-3 Million per year, most cases of Malaria affect children under the age of five years in Sub-Saharan Africa. In this thesis, I analyse the current status of malaria control (focussing on diagnosis and therapy) in Burkina Faso to show how this disease burdens public health in endemic countries and to identify possible approaches to improvement. MB is discussed as a therapeutic option under these circumstances.
Burkina Faso is used as a representative example for a country in Sub-Saharan Africa with high endemicity for malaria and is here portrayed, its health system characterised and discussed under socioeconomic aspects.
More than half of this country’s population live in absolute poverty. The burden that malaria, especially treatment cost, poses on these people cannot be under-estimated.
A retrospective study of case files from the university pediatric hospital in Burkina Faso’s capital, Ouagadougou, shows that the case load is huge, and especially the specific diagnosis of severe malaria is difficult to apply in the hospital’s daily routine. Treatment policy as proposed by WHO is not satisfactorily implemented neither in home treatment nor in health services, as data for pretreatment clearly show.
In the face of growing resistance in malaria parasites, pharmacological combination therapies are important. Artemisinins currently are the last resort of malaria therapy. As I show with homology models, even this golden bullet is not beyond resistance development. Inconsidered mass use has rendered other drugs virtually useless before. Artemisinins should thus be protected similar to reserve antibiotics against multi-resistant bacteria.
There is accumulating evidence that MB is an effective drug against malaria. Here the biological effects of both MB alone and in combination therapy is explored via modeling and experimental data. Several different lines of MB attack on Plasmodium redox defense were identified by analysis of the network effects. Next, CQ resistance based on Pfmdr1 and PfCRT transporters as well as SP resistance were modeled in silico. Further modeling shows that MB has a favorable synergism on antimalarial network effects with these commonly used antimalarial drugs, given their correct application.
Also from the economic point of view MB shows great potential: in terms of production price, it can be compared to CQ, which could help to diminuish the costs of malaria treatment to affordable ranges for those most affected and struk by poverty.
Malaria control is feasible, but suboptimal diagnosis and treatment are often hindering the achievment of this goal. In order to achieve malaria control, more effort has to be made to implement better adjusted and available primary treatment strategies for uncomplicated malaria that are highly standardised. Unfortunately, campaigns against malaria are chronically underfinanced. In order to maximize the effect of available funds, a cheap treatment option is most important, especially as pharmaceuticals represent the biggest single matter of expense in the fight against malaria.