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- Arabidopsis thaliana (2)
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The Transforming Growth Factor (TGF) superfamily of cytokines and their serine/threonine kinase receptors play an important role in the regulation of cell division, differentiation, adhesion, migration, organization, and death. Smad proteins are the major intracellular signal transducers for the TGF receptor superfamily that mediate the signal from the membrane into the nucleus. Bone Morphogenetic Protein-4 (BMP-4) is a representative of the TGF superfamily, which regulates the formation of teeth, limbs and bone, and also plays a role in fracture repair. Binding of BMP-4 to its receptor stimulates phosphorylation of Smad1, which subsequently recruits Smad4. A hetero-oligomeric complex consisting of Smad1 and Smad4 then translocates into the nucleus and regulates transcription of target genes by interacting with transcription factors. Although the individual steps of the signaling cascade from the receptor to the nucleus have been identified, the exact kinetics and the rate limiting step(s) have remained elusive. Standard biochemical techniques are not suitable for resolving these issues, as they do not offer sufficiently high sensitivity and temporal resolution. In this study, advanced optical techniques were used for direct visualization of Smad signaling in live mammalian cells. Novel fluorescent biosensors were developed by fusing cyan and yellow fluorescent proteins to the signaling molecules Smad1 and Smad4. By measuring Fluorescence Resonance Energy Transfer (FRET) between the two fluorescent proteins, the kinetics of BMP/Smad signaling was unraveled. A rate-limiting delay of 2 - 5 minutes occurred between BMP receptor stimulation and Smad1 activation. A similar delay was observed in the complex formation between Smad1 and Smad4. Further experimentation indicated that the delay is dependent on the Mad homology 1 (MH1) domain of Smad1. These results give new insights into the dynamics of the BMP receptor – Smad1/4 signaling process and provide a new tool for studying Smads and for testing inhibitory drugs.
Bacteriosponges contain large amounts of morphologically and phylogenetically diverse microorganisms in their mesohyl. The association is permanent, stable and highly specific, however, little is known about the establishment and maintenance of this association. The first aim of this Ph.D. thesis was to examine cospeciation between eight Aplysina species from the Mediterranean and Caribbean and their cyanobacterial associates. Host phylogeny was constructed with 18S rDNA and ITS-2 sequences using an alignment based on the secondary structure of the molecular markers and five different algorithms each. The genus Aplysina appeared as monophyletic. Aplysina sponges could be distinguished into a Caribbean and a Mediterranean cluster and a possible Tethyan origin is suggested. Comparison of the host phylogeny to the 16S rDNA phylogeny of the cyanobacterial strains revealed the lack of a congruent pattern. Therefore it is proposed that Aplysina sponges have not cospeciated with their cyanobacterial phylotypes and probably also not with other sponge specific microbes. The second aim of this Ph.D. thesis was to examine vertical transmission of microorganisms through reproductive stages of sponges. A general transmission electron microscopy (TEM) suvey revealed a clear correlation in that bacteriosponges always contained many microorganisms in their reproductive stages whereas non-bacteriosponges were always devoid of microbes in their reproductive stages. The transmission of the microbial community via sponge reproductive stages is concluded. Based on the previous results Ircinia felix was chosen for a detailed documentation of vertical transmission. I. felix larvae contained large amounts of microorganisms extracellularly in the central region whereas the outer region was almost free of microbes as shown by TEM. In I. felix juveniles microorganisms were located between densely packed sponge cells. The microbial profiles of I. felix adult, larvae, and juveniles were compared using denaturing gradient gel electrophoresis (DGGE). Similar microbial community patterns were found in adult and the respective larvae indicating that a large subset of the adult microbial community was vertically transmitted. In contrast, microbial communities of larvae pools released by different adult individuals seemed to be more variable. Juvenile banding patterns were a mixture of sponge specific and seawater microbes due to DNA extraction artefacts but demonstrated that at least half of the adult microbial community is present in the next generation. Finally, a comprehensive phylogenetic analysis was conducted by sequencing excised DGGE bands from adult and offspring of the bacteriosponges Agelas wiedenmayeri, I. felix, and Smenospongia aurea and by taking additional 16S rDNA sequences of Ectyoplasia ferox and Xestospongia muta (unpublished data of the laboratory). The identification of 24 vertical transmission clusters in at least 8 eubacterial phyla demonstrates that a complex and uniform microbial community is transferred via sponge reproductive stages. Vertical transmission is specific in that the microorganisms of bacteriosponges, but not those from seawater, are passed on, but unselective in that there appears to be no differentiation between individual sponge-specific lineages. In conclusion, vertical transmission points to a mutualistic and long-term association of bacteriosponges and complex microbial consortia.
In this work, the laser control of molecules was investigated theoretically. In doing so, emphasis was layed on entering vectorial properties and in particular the orientation in the laboratory frame. Therefore, the rotational degree of freedom had to be included in the quantum mechanical description. The coupled vibrational and rotational dynamics was examined, which is usually not done in coherent control theory. Local control theory was applied, where the field is determined from the dynamics of a system, which reacts with an instantaneous response to the perturbation and, in turn, determines the field again. Thus, the field is entangled with the quantum mechanical motion and the presented examples document, that this leads to an intuitive interpretation of the fields in terms of the underlying molecular dynamics. The limiting case of a classical treatment was shown to give similar results and hence, eases to understand the complicated structure of the control fields. In a different approach, the phase- and amplitude shaping of laser fields was systematically studied in the context of controlling population transfer in molecules.
Integrins are transmembrane receptors transmitting mechanical signals from the extracellular matrix (ECM) to the cytoskeleton (outside-in-signaling). Many molecular defects in the link between cytoskeleton and ECM are known to induce cardiomyopathies. alpha v integrin appears to play a major role in several processes relevant to remodeling, such as binding and activation of matrix metalloproteinases as well as regulation of cell proliferation, migration, and differentiation. We hypothesized that alpha v integrin-mediated signaling is required for the compensatory hypertrophy after aortic banding (AB) and associated with the modulation of ECM protein expression. Mice were treated in vivo with a specific integrin alpha v inhibitor or vehicle via osmotic minipumps starting 1 day prior to aortic banding (AB). At day 2 and day 7 following AB or sham-operation, the mice were examined by echocardiography and hemodynamic analyses were performed. Treatment of alpha v Integrin inhibitor led to a dilated cardiomyopathy and congestive heart failure in AB mice (dilated left ventricle, depressed LV function, and pulmonary congestion), but not to hypertrophy as observed in mice without inhibitor treatment. Investigation of downstream signaling revealed significant activation of the p38 Mitogen-Activated Protein Kinase (MAPK), the Extracellular signal-Regulated Kinases 1 and 2 (Erk 1/2), Focal Adhesion Kinase (FAK) and tyrosine-phosphorylation of c-Src in mice 7 days after AB. This response was blunted in mice treated with integrin alpha v inhibitor. Microarrays probing for a total of 96 cell adhesion and ECM genes identified various genomic targets of integrin alpha v mediated signalling. 7 days after AB 18 ECM genes were up-regulated more than 2-fold (n=6), e.g. collagen (8.11 ± 2.2), fibronectin (2.32 ± 0.94), secreted protein, acidic and rich in cysteine (SPARC, 3.78 ± 0.12), A disintegrin-like and metalloprotease (reprolysin type) with trombospondin type 1 (Adamts-1, 3.51 ± 0.81) and Tissue inhibitor of metalloproteinase 2 (TIMP2, 2.23 ± 0.98), whereas this up-regulation was abolished in mice that were treatd by integrin alpha v inhibitor via mini pumps. We conclude that signaling downstream of integrin alpha v is mediated by the MAPK, FAK and c-Src pathways leading to an up-regulation of extracelluar matrix components necessary for the compensatory response of the heart under a condition of pressure overload.
With ageing, the loss of bone mass correlates with the expansion of adipose tissue in human bone marrow thus facilitating bone-related diseases like osteopenia and osteoporosis. The molecular mechanisms underlying these events are still largely unknown. Reduced osteogenesis and concurrently enhanced adipogenesis might not only occur due to the impairment of conventional osteogenic differentiation originating from mesenchymal stem cells (MSCs). Additionally, transdifferentiation of (pre-)osteoblasts into adipocytes could contribute to the fatty conversion. Therefore, the aim of the present study was to prove the existence of transdifferentiation between the adipogenic and osteogenic lineage and to elucidate molecular mechanisms underlying this phenomenon. At first, a cell culture system of primary human MSCs was established that allowed for differentiation into the adipogenic and osteogenic lineage and proved that the MSC-derived adipocytes and pre-osteoblasts were capable of transdifferentiation (reprogramming) from one into the other lineage. Thereby, lineage-specific markers were completely reversed after reprogramming of pre-osteoblasts into adipocytes. The osteogenic transdifferentiation of adipocytes was slightly less efficient since osteogenic markers were present but the adipogenic ones partly persisted. Hence, plasticity also reached into the differentiation pathways of both lineages and the better performance of adipogenic reprogramming further supported the assumption of its occurrence in vivo. The subsequent examination of gene expression changes by microarray analyses that compared transdifferentiated cells with conventionally differentiated ones revealed high numbers of reproducibly regulated genes shortly after initiation of adipogenic and osteogenic reprogramming. Thereof, many genes were correlated with metabolism, transcription, and signal transduction as FGF, IGF, and Wnt signalling, but only few of the established adipogenesis- and none of the osteogenesis-associated marker genes were detected within 24 h after initiation of transdifferentiation. To find possible key control factors of transdifferentiation amongst the huge amount of regulated genes, a novel bioinformatic scoring scheme was developed that ranked genes due to their potential relevance for reprogramming. Besides the reproducibility and level of their regulation, also the possible reciprocity between the adipogenic and osteogenic transdifferentiation pathway was taken into account. Fibroblast growth factor 1 (FGF1) that ranked as one of the leading candidates to govern reprogramming was proven to inhibit adipogenic differentiation as well as adipogenic transdifferentiation in our cell culture system. Further examination of the FGF signalling pathway and other highly ranked genes could help to better understand the age-related fatty degeneration at the molecular level and therefore provide target molecules for therapeutic modulation of the plasticity of both lineages in order to inhibit adipogenic degeneration and to enhance osteogenesis.
The Nuclear Factors of Activated T cells (NFATs) are critical transcription factors that direct gene expression in immune and non-immune cells. Interaction of T cells with Ag-presenting cells results in the clustering of T-cell antigen receptor (TCR), co-receptors and integrins. Subsequent signal transduction resulting in NFAT activation leads to cytokine gene expression. Among the NFATs expressed in T cells, NFATc1 shows a unique induction property, which is essential for T cell differentiation and activation. It was revealed before that 3 major isoforms of NFATc1 are generated in activated T cells – the inducible short NFATc1/A, and the longer isoforms NFATc1/B and C. However, due to alternative splicing events and the existence of two different promoters and two alternative polyadenylation, we show here that 6 isoforms are synthesized in T cells which differ in their N-terminal and C-terminal peptides. In these experiments, we have identified these 6 isoforms by semi-quantitative long distance RT-PCR in several T cells subsets, and the inducible properties of 6 isoforms were investigated in those cells. The short NFATc1/A which is under control of the P1 promoter and the proximal pA1 polyadenylation site was the most prominent and inducible isoform in T effector cells. The transcription of the longer NFATc1/B and C isoforms is constitutive and even reduced in activated T lymphocytes. In addition to NFATc1 autoregulation, we tried to understand the NFATc1 gene regulation under the control of PKC pathways by microarray analysis. Compared to treatment of T cells with ionomycin alone (which enhances Ca++ flux), treatment of cells with the phorbolester TPA (leading to PKC activation) enhanced the induction of NFATc1. Microarray analysis revealed that PKC activation increased the transcription of NF-B1, Fos and JunB, which are important transcription factors binding to the regulatory regions of the NFATc1 gene. Besides the promoting effect of these transcription factors, we provided evidence that p53 and its targeting gene, Gadd45, exerted a negative effect on NFATc1 gene transcription. Summarizing all these results, we drew novel conclusions on NFATc1 expression, which provide a more detailed view on the regulatory mechanisms of NFATc1 transcription. Considering the high transcription and strong expression of NFATc1 in various human lymphomas, we propose that similar to NF-B, NFATc1/A plays a pivotal role in lymphomagenesis.
Processes of the Earth’s surface occur at different scales of time and intensity. Climate in particular determines the activity and seasonal development of vegetation. These dynamics are predominantly driven by temperature in the humid mid-latitudes and by the availability of water in semi-arid regions. Human activities are a modifying parameter for many ecosystems and can become the prime force in well-developed regions with an intensively managed environment. Accounting for these dynamics, i.e. seasonal dynamics of ecosystems and short- to long-term changes in land-cover composition, requires multiple measurements in time. With respect to the characterization of the Earth surface and its transformation due to global warming and human-induced global change, there is a need for appropriate data and methods to determine the activity of vegetation and the change of land cover. Space-borne remote sensing is capable of monitoring the activity and development of vegetation as well as changes of the land surface. In many instances, satellite images are the only means to comprehensively assess the surface characteristics of large areas. A high temporal frequency of image acquisition, forming a time series of satellite data, can be employed for mapping the development of vegetation in space and time. Time series allow for detecting and assessing changes and multi-year transformation processes of high and low intensity, or even abrupt events such as fire and flooding. The operational processing of satellite data and automated information-extraction techniques are the basis for consistent and continuous long-term product generation. This provides the potential for directly using remote-sensing data and products for analyzing the land surface in relation to global warming and global change, including deforestation and land transformation. This study aims at the development of an advanced approach to time-series generation using data-quality indicators. A second goal focuses on the application of time series for automated land-cover classification and update, using fractional cover estimates to accommodate for the comparatively coarse spatial resolution. Requirements of this study are the robustness and high accuracy of the approaches as well as the full transferability to other regions and datasets. In this respect, the developments of this study form a methodological framework, which can be filled with appropriate modules for a specific sensor and application. In order to attain the first goal, time-series compilation, a stand-alone software application called TiSeG (Time Series Generator) has been developed. TiSeG evaluates the pixel-level quality indicators provided with each MODIS land product. It computes two important data-availability indicators, the number of invalid pixels and the maximum gap length. Both indices are visualized in time and space, indicating the feasibility of temporal interpolation. The level of desired data quality can be modified spatially and temporally to account for distinct environments in a larger study area and for seasonal differences. Pixels regarded as invalid are either masked or interpolated with spatial or temporal techniques.
This thesis presents an experimental study of the thermoelectrical properties of semiconductor quantum dots (QD). The measurements give information about the interplay between first order tunneling and macroscopic quantum tunneling transport effects in the presence of thermal gradients by the direct comparison of the thermoelectric response and the energy spectrum of the QD. The aim of the thesis is to contribute to the understanding of the charge and spin transport in few-electron quantum dots with respect to potential applications in future quantum computing devices. It also gives new insight into the field of low temperature thermoelectricity. The investigated QDs were defined electrostatically in a two dimensional electron gas (2DEG) formed with a GaAs/(Al,Ga)As heterostructure by means of metallic gate electrodes on top of the heterostructure. Negative voltages with respect to the potential of the 2DEG applied to the gate electrodes were used to deplete the electron gas below them and to form an isolated island of electron gas in the 2DEG which contains a few ten electrons. This QD was electrically connected to the 2DEG via two tunneling barriers. A special electron heating technique was used to create a temperature difference between the two connecting reservoirs across the QD. The resulting thermoelectric voltage was used to study the charge and spin transport processes with respect to the discrete energy spectrum and the magnetic properties of the QD. Such a two dimensional island usually exhibits a discrete energy spectrum, which is comparable to that of atoms. At temperatures below a few degrees Kelvin, the electrostatic charging energy of the QDs exceeds the thermal activation energy of the electrons in the leads, and the transport of electrons through the QD is dominated by electron-electron interaction effects. The measurements clarify the overall line shape of thermopower oscillations and the observed fine structure as well as additional spin effects in the thermoelectrical transport. The observations demonstrate that it is possible to control and optimize the strength and direction of the electronic heat flow on the scale of a single impurity and create spin-correlated thermoelectric transport in nanostructures, where the experimenter has a close control of the exact transport conditions. The results support the assumption that the performance of thermoelectric devices can be enhanced by the adjustment of the QD energy levels and by exploiting the properties of the spin-correlated charge transport via localized, spin-degenerate impurity states. Within this context, spin entropy has been identified as a driving force for the thermoelectric transport in the spin-correlated transport regime in addition to the kinetic contributions. Fundamental considerations, which are based on simple model assumptions, suggest that spin entropy plays an important role in the presence of charge valence fluctuations in the QD. The presented model gives an adequate starting point for future quantitative analysis of the thermoelectricity in the spin-correlated transport regime. These future studies might cover the physics in the limit of single electron QDs or the physics of more complex structures such as QD molecules as well as QD chains. In particular, it should be noted that the experimental investigations of the thermopower of few-electron QDs address questions concerning the entropy transport and entropy production with respect to single-bit information processing operations. These questions are of fundamental physical interest due to their close connection to the problem of minimal energy requirements in communication, and thus ultimately to the so called "Maxwell's demon" with respect to the second law of thermodynamics.
Oxygen-centered radicals are important intermediates in photobiological, mechanistic and synthetic studies. The majority of precursors of reactive oxyl radicals are labile and thus delicate to handle. Therefore N-(alkoxy)-pyridinethiones and N-(Alkoxy)-thiazolethiones have attracted attention as "mild'' photochemical source of alkoxyl radicals, in the last few years. A disadvantage of the pyridine compounds, is their sensibility to daylight. Despite of their similarities, both molecules behave surprisingly different, if photolyzed in the absence of trapping reagents. The pyridinethione compounds undergo highly efficient radical chain reactions under such conditions while the corresponding thiazolethiones react surprisingly sluggish and give rise to several unwanted side products. The properties of both compounds should be understood and optimized in the frame of this work. Additionally new compounds should be suggested that can also be applied in the photochemical alkoxyl radical generation. Some background information about the generation and application of alkoxyl radicals is provided in chapter 2. Electronic excitations and UV/vis spectroscopy together with a description of quantum chemical approaches that are able to calculate such phenomena are outlined in chapter 3. Chapter 4 deals with the description of the vertical excitation spectra. During the validation CASSCF, CASPT2, TD-DFT and RI-CC2 were tested with respect to their ability to describe the vertical excitations in both compounds. The CASPT2 approach gives accurate descriptions of the electronic excitation spectra of all compounds. The time-dependent DFT results are very sensitive on the choice of the functional and a validation of the results should be always done. On the basis of these computations the spectroscopic visible absorption bands of both compounds were assigned to a pi-->pi* transition in the thiohydroxamic acid functionality. In chapter 5 the mechanism of the thermally and the photochemically induced N,O homolysis in both compounds is unveiled. The near UV-induced N,O homolysis will start from the S2 state. The expected relaxation from the S2- to the S1-state and the dissociation process is expected to be very fast in the case of the thiazolethione compound. The potential surfaces of the pyridine compound in contrast point to a slower N,O bond dissociation. Due to the resulting faster dissociation process the excess energy which results from the photochemical activation is quenched only to small amounts. The maximal possible excess energy of the fragments is lower and a quenching is much more likely in the case of the pyridinethione compounds. This explaines the different reactivities of both compounds. For the also already successfully applied precursor system N-(alkoxy)-pyridineones the computed dissociation paths show courses that clearly predict a slow bond dissociation process. Chapter 6 deals with the tuning of the initial excitation wave length of the known pyridinethiones und thiazolethiones. In the first part the effects of substituents on the thiazolethione heterocycle was examined. The UV/vis spectra of 4 and 5 substituted thiazolethiones can be interpreted like the spectrum of the parent compound. The second part of chapter 6 deals with the identification of a substitution pattern on the pyridine heterocycle which induces a blue shift of the photo active band. The computations showed that electron rich and electron poor substituents result the same effects on the electronic excitation spectra. These substituent effects are additive, but the steric orientation of the substituents has to be taken into account. Chapter 7 describes a computer aided design of new alkoxyl radical precursors. Combining the advantages of both compounds the radical formation should be initiated by an irradiation with light at about 350 nm, and the amount of side products during the radical formation process should be small. To achieve this 18 test candidates were obtained by a systematic variation of the parent compound of the thiazolethione precursor. To identify the promising new precursor systems a screening of the lower electronic excitations of all resulting 18 systems was performed with TD-DFT. For promising systems the N,O or P,O dissociation paths, respectively, were analyzed according to the developed model. N-(methoxy)-azaphospholethione and N-(methoxy)-pyrrolethione seem to be the most promising candidates. The computations predict a strong absorption at about 350 nm respectively 320 nm. Due to the amounts of maximal excess energy and the shapes of the potential surfaces of the N,O bond dissociation paths their reactivity should resemble more the behavior of the pyridinethiones.
Since the fruit fly Drosophila melanogaster entered the laboratories as a model organism, new genetic, physiological, molecular and behavioral techniques for the functional analysis of the brain rapidly accumulated. Nowadays this concerted assault obtains its main thrust form Gal4 expression patterns that can be visualized and provide the means for manipulating -in unrestrained animals- groups of neurons of the brain. To take advantage of these patterns one needs to know their anatomy. This thesis describes the Virtual Insect Brain (VIB) protocol, a software package for the quantitative assessment, comparison, and presentation of neuroanatomical data. It is based on the 3D-reconstruction and visualization software Amira (Mercury Inc.). Its main part is a standardization procedure which aligns individual 3D images (series of virtual sections obtained by confocal microscopy) to a common coordinate system and computes average intensities for each voxel (volume pixel). The VIB protocol facilitates direct comparison of gene expression patterns and describes their interindividual variability. It provides volumetry of brain regions and helps to characterize the phenotypes of brain structure mutants. Using the VIB protocol does not require any programming skills since all operations are carried out at a (near to) self-explanatory graphical user interface. Although the VIB protocol has been developed for the standardization of Drosophila neuroanatomy, the program structure can be used for the standardization of other 3D structures as well. Standardizing brains and gene expression patterns is a new approach to biological shape and its variability. Using the VIB protocol consequently may help to integrate knowledge on the correlation of form and function of the insect brain. The VIB protocol provides a first set of tools supporting this endeavor in Drosophila. The software is freely available at http://www.neurofly.de.
Brassicaceae and a few related plant families are characterized by possession of the glucosinolate-myrosinase system. Glucosinolates are amino-acid derived allelochemicals which are hydrolysed upon tissue damage by myrosinase enzymes to produce various degradation products which can be toxic for generalist insects. The larvae of the crucifer-specialist Athalia rosae, the turnip sawfly, sequester glucosinolates into their haemolymph. The role of the glucosinolate-myrosinase system for the interaction of the turnip sawfly with Brassicaceae was examined in this study from two different perspectives: variation within individual plants and between plant species. The plant responses to the feeding by herbivores and the short-term effects this induction had on insect behaviour were investigated in white mustard. Furthermore, plants can use multiple defences. Hence correlations of glucosinolates and myrosinase activities with other defences and nutritional quality and their long-term effects on the development of the insects were investigated in seven different plant species.
In this thesis we have investigated the effect of NFAT (Nuclear Factor of Activated T Cell) transcription factors on the expression of Rag-(Recombination Activating Genes) genes in murine thymus. The protein products of Rag genes, RAG1 and RAG2, are critical for the recombination and generation of the TCR (T Cell Receptor) repertoire during thymocyte development, and their expression can be suppressed by the activity of NFAT factors. In thymus, the expression of Rag1 and Rag2 genes is induced at the double-negative (DN, CD4-8-) 3 stage, down-regulated at the DN4 stage, re-induced at the double-positive (DP, CD4+8+) stage, and suppressed again at the single-positive (SP, CD4+8- or CD4-8+) stage. Although it is known that TCR signaling suppresses the expression of Rag1 and Rag2 at the SP stage, the signals that mediate the Rag gene down-reulation remain elusive. Here we report that both the calcineurin-NFAT-signaling and MAPKinase signaling pathways, which are activated by TCR signaling during positive selection, mediate the Rag gene down-regulation in DP thymocytes. The calcineurin-NFAT pathway suppresses both the Rag1 and the Rag2 gene expression. This pathway has a stronger suppressive effect on the Rag1 than the Rag2 gene. A synergistic activity between the two NFAT factors NFATc2 and NFATc3 is essential for calcineurin-NFAT signaling to efficiently suppress the Rag gene expression in DP thymocytes. It is likely that the calcineurin-NFAT signaling down-regulates Rag gene expression by suppressing both the Rag anti-silencer element (ASE) activity and the Rag promoter activity. Similarly, MEK-ERK signaling of MAPK signaling pathway mediates the Rag gene suppression in DP thymocytes although the mechanism through which MEK-ERK mediates the Rag gene down-regulation has to be elucidated. In DN thymocytes, it appears that neither the calcineurin-NFAT signaling nor MAPK signaling is involved in the Rag gene down-regulation. However, a role for these two signaling pathways in the Rag gene up-regulation in DN thymocytes is not excluded. In DN thymocytes, pre-TCR signaling stimulates the expression both Nfatc1 and Nfatc2 genes but has no effect on Nfatc3 gene expression. In DN thymocytes, pre-TCR signaling activates Nfatc1α expression but not Nfatc1ß expression, i.e. the two promoters controling Nfatc1 gene xpression are differently controled by pre-TCR signals. Nfatc1α gene expression in DN thymocytes is mainly regulated by the MAPK signaling pathway because activation of Nfatc1α is mediated by MEK-ERK signaling but opposed by JNK signaling. Calcineuirn-NFAT and p38 signaling pathways are not involved in Nfatc1α promoter regulation in DN thymocytes. In DP thymocytes, TCR signaling up-regulates Nfatc1 and Nfatc2 expression but down-regulates Nfatc3 expression. In DP thymocytes, TCR signaling activates Nfatc1α expression. The activation of Nfatc1α in DP thymocytes is mediated by NFATc1, but not or to a less degree by NFATc2 and NFATc3. MEK-ERK, JNK, and p38 signaling pathways are involved in Nfatc1α gene activation in DP thymocytes, probably by activating NFAT trans-activation activity. All these findings illustrate that in thymocytes the expression of NFAT transcription factors – which are essential for thymic development - is controled at multiple levels.
Introduction: This study investigates the role of Wolbachia bacteria in the pathogenesis of O. volvulus keratitis in a mouse model. Wolbachia bacteria are essential symbionts of most filarial nematodes of importance for mankind. Methods: Using a mouse model for river blindness in which soluble extracts of filarial nematodes are injected in the corneal stroma, changes in stromal thickness and haze of the cornea are observed by in vivo confocal microscopy, followed by immunohistochemical staining for neutrophils and PECAM-1, as well as ELISA of corneal chemokines. Reactions to filarial extracts containing Wolbachia are compared to those without the endosymbiont. Results: The approach of characterizing Wolbachia’s role in river blindness in this study is threefold. Firstly, Wolbachia-depleted extracts from doxycycline treated onchocerciasis patients led to a diminished inflammatory response in corneas of C57BL/6 mice compared to untreated, i.e. Wolbachia containing antigen. The decreased cell recruitment observed with doxycycline treated extracts involved neutrophils, but not eosinophils. This finding demonstrated that the presence of Wolbachia increases neutrophil recruitment. Secondly, extracts from Wolbachia-containing B. malayi revealed markedly more pathology than endosymbiont-free A. viteae antigen. This again pointed at the role of Wolbachia in development of disease. Thirdly, Toll-like Receptor 4 (TLR4) dependence was shown to exist for the inflammatory response to Wolbachia harboring O. volvulus antigen by looking at the corneal pathology in TLR4-mutant C3H/HeJ mice, compared to the wild-type C3H/HeN strain. Investigating further Wolbachia mediated mechanisms of neutrophil recruitment to the cornea, this study also showed that expression of the adhesion molecule PECAM-1 in limbal vessels, as well as upregulation of the CXC chemokines KC and MIP-2 were dependent on the presence of functional TLR4 and Wolbachia respectively. Conclusions: This study indicates that the innate immune system and Wolbachia endobacteria play an important role in the inflammatory response associated with the pathogenesis of onchocerca keratitis, suggesting a complete alteration in our understanding of the immunopathology of filariasis.
Cutaneous leishmaniasis is an infectious disease that is endemic especially in tropical and desert regions with an incidence of 1.5 million cases per year and a prevalence of 12 million people infected worldwide. The infection can be caused by the intracellular parasite Leishmania major. The disease has been studied extensively in the murine model. It has become apparent that the induction of a class of interferon (IFN)--producing CD4+ T helper cells (TH1 cells) that activate macrophages to kill the parasites they harbor is desicive for the establishment of immunity. The redirection of the host’s immune response towards a protective TH1 phenotype will also be the key to an effective vaccine. Dendritic cells (DC) loaded with leishmanial antigens ex vivo were lately described as vaccines against L. major infections. One single recombinant Leishmania antigen, LeIF (Leishmania homologue of eukaryotic ribosomal initiation factor 4a), which was identified as a protein that stimulates DC to secrete interleukin (IL)-12 and discussed as a pattern-associated molecular pattern (PAMP), was found to mediate a protective TH1-dependent effect when used for pulsing of DC. The application of recombinant proteins is tied to many disadvantages, which is why other methods of antigen administration have been developed. RNA electroporation of DC has recently emerged from tumor research as a safe and versatile method of antigen delivery, by which a large number of RNA molecules encoding a specific antigen gains access to the cytosol of DC by an electrical impulse. The present study describes, for the first time, transfection of DC with RNA encoding a molecularly defined parasite antigen. Initially, a standardized protocol for RNA transfection was established, using the enhanced green fluorescent protein (EGFP) as reporter antigen. EGFP-RNA was well translatable in an in vitro translation system, and both a DC cell line (fetal skin-derived DC; FSDC) and murine primary bone marrow-derived DC (BMDC) could be transfected efficiently, with a yield of up to 90% and 75%, respectively. In both cell types, maximal transfection efficiency was attained with 20 µg RNA and could not be further increased with larger amounts of RNA. The level of antigen expression, measured as the mean fluorescence intensity (MFI) by flow cytometry, was directly proportional to the amount of RNA used for transfection. In FSDC, transfection efficiency and MFI were generally higher than in BMDC when the same amounts of RNA were used. Furthermore, the kinetics was shown to be sensitive to treatment with lipopolysaccharide (LPS): the expression peak was higher and was reached sooner, followed by a more rapid decline. In transfection experiments with LeIF, two variants of LeIF-RNA were used: LeIF(fl)-RNA, encoding the complete LeIF sequence, and LeIF(226)-RNA, encoding only the aminoterminal half of the LeIF sequence (226 amino acids), the immunogenic part of LeIF. Only LeIF(fl) was detectable by Western Blot in whole cell lysates of BMDC after LeIF(fl)-RNA transfection, whereas LeIF(226) could never be detected in LeIF(226)-transfected BMDC. However, as both constructs were well translatable in a cell-free system, the failure to detect LeIF(226) in BMDC lysates did not represent a failure in RNA translation, but rather a rapid antigen degradation. It was therefore expected that LeIF(226)-transfected BMDC should nevertheless be able to present LeIF(226)-derived antigenic peptides to T cells from BALB/c mice primed with recombinant LeIF (rLeIF). This hypothesis was confirmed by measuring IFN- production in BMDC-T cell co-incubation assays, showing that rLeIF-pulsed, LeIF(226)- and LeIF(fl)-transfected day 7 BMDC did indeed activate T cells from LeIF-immunized mice in an antigen-specific manner. In contrast, IL-4 was not produced, which was consistent with the fact that T cells found in lymph nodes from LeIF-primed mice are primarily of the TH1 type. In the supernatants of LeIF-transfected BMDC cultures, in contrast to rLeIF-pulsed BMDC, the proinflammatory cytokines IL-1β, IL-6, IL-10 and IL-12 were not detected. This effect was not due to the electroporation procedure, as cytokine production by BMDC electroporated with rLeIF was only partially impaired. Also, the expression levels of CD86 were lower upon LeIF transfection than after pulsing with rLeIF. Thus, LeIF transfection did not induce maturation of DC. In conclusion, LeIF-transfected BMDC may have acted as semi-mature antigen-specific tolerance inducers, with regulatory T cells as responders. The effect of LeIF transfection on the immunostimulatory capacity of BMDC was not significantly increased when day 8 or 9 BMDC were used. However, day 8, and even more day 9 BMDC pulsed with rLeIF mounted a vigorous T cell response. Day 9 BMDC were able to activate naïve T cells. In conclusion, before a strong T cell response against LeIF can be induced, DC need to – besides presenting antigen and expressing co-stimulatory molecules – exhibit a susceptibility to the innate signaling molecule LeIF which is linked to their maturation age. This third signal is provided by extracellular rLeIF, but it is not conveyed – or is suppressed – by intracellular LeIF after LeIF-RNA transfection. Furthermore, electroporation of rLeIF abrogated IL-12 production by BMDC completely, the production of IL-1 was reduced with higher antigen doses, and the production of IL-10 was partially increased. The IL-6 production was unaffected. This altered cytokine profile suggests that LeIF as a PAMP might have a bipartite nature: besides exhibiting the capacity to stimulate IL-12 production upon extracellular presence, thereby enhancing host resistance against L. major, LeIF could also contribute to parasitic host evasion mechanisms from intracellular compartments of DC, possibly by interfering with mitogen-activated protein (MAP) kinase signaling pathways. Thus, the adjuvant properties of LeIF depend both on its mode of delivery (transfection with RNA vs. pulsing with the recombinant protein) and the targeted compartment (extra- vs. intracellular). From this work, it can be summarized that BMDC are well transfectable with a parasite antigen. The antigen is processed and presented, but it is not recognized as a PAMP by DC. Hence, transfection with antigen-encoding mRNA by itself does not convey all necessary signals for the elicitation of a potent immune response.
Questions: What are the relative contributions of kin selection and individual selection to the evolution of dispersal rates in fragmented landscapes? How do environmental parameters influence the relative contributions of both evolutionary forces? Features of the model: Individual-based simulation model of a metapopulation. Logistic local growth dynamics and density-dependent dispersal. An optional shuffling algorithm allows the continuous destruction of any genetic structure in the metapopulation. Ranges of key variables: Depending on dispersal mortality (0.05-0.4) and the strength of environmental fluctuations, mean dispersal probability varied between 0.05 and 0.5. Conclusions: For local population sizes of 100 individuals, kin selection alone could account for dispersal probabilities of up to 0.1. It may result in a ten-fold increase of optimal dispersal rates compared with those predicted on the basis of individual selection alone. Such a substantial contribution of kin selection to dispersal is restricted to cases where the overall dispersal probabilities are small (textless 0.1). In the latter case, as much as 30% of the total fitness of dispersing individuals could arise from the increased reproduction of kin left in the natal patch.
Despite its precise agreement with the experiment, the validity of the standard model (SM) of elementary particle physics is ensured only up to a scale of several hundred GeV so far. Even more, the inclusion of gravity into an unifying theory poses a problem which cannot be solved by ordinary quantum field theory (QFT). String theory, which is the most popular ansatz for a unified theory, predicts QFT on noncommutative space-time as a low energy limit. Nevertheless, independently of the motivation given by string theory, the nonlocality inherent to noncommutative QFT opens up the possibility for the inclusion of gravity. There are no theoretical predictions for the energy scale Lambda_NC at which noncommutative effects arise and it can be assumed to lie in the TeV range, which is the energy range probed by the next generation of colliders. Within this work we study the phenomenological consequences of a possible realization of QFT on noncommutative space-time relying on this assumption. The motivation for this thesis was given by the gap in the range of phenomenological studies of noncommutative effects in collider experiments, due to the absence in the literature of Large Hadron Collider (LHC) studies regarding noncommutative QFTs. In the first part we thus performed a phenomenological analysis of the hadronic process pp -> Z gamma -> l^+l^- gamma at the LHC and of electron-positron pair annihilation into a Z boson and a photon at the International Linear Collider (ILC). The noncommutative extension of the SM considered within this work relies on two building blocks: the Moyal-Weyl star-product of functions on ordinary space-time and the Seiberg-Witten maps. The latter relate the ordinary fields and parameters to their noncommutative counterparts such that ordinary gauge transformations induce noncommutative gauge transformations. This requirement is expressed by a set of inhomogeneous differential equations (the gauge equivalence equations) which are solved by the Seiberg-Witten maps order by order in the noncommutative parameter Theta. Thus, by means of the Moyal-Weyl star-product and the Seiberg-Witten maps a noncommutative extension of the SM as an effective theory as expansion in powers of Theta can be achieved, providing the framework of our phenomenological studies. A consequence of the noncommutativity of space-time is the violation of rotational invariance with respect to the beam axis. This effect shows up in the azimuthal dependence of cross sections, which is absent in the SM as well as in other models beyond the SM. Thus, the azimuthal dependence of the cross section is a typical signature of noncommutativity and can be used in order to discriminate it against other new physics effects. We have found this dependence to be best suited for deriving the sensitivity bounds on the noncommutative scale Lambda_NC. By studying pp -> Z gamma -> l^+l^- gamma to first order in the noncommutative parameter Theta, we show in the first part of this work that measurements at the LHC are sensitive to noncommutative effects only in certain cases, giving bounds on the noncommutative scale of Lambda_NC > 1.2 TeV. Our result improved the bounds present in the literature coming from past and present collider experiments by one order of magnitude. In order to explore the whole parameter range of the noncommutativity, ILC studies are required. By means of e^+e^- -> Z gamma -> l^+l^- gamma to first order in Theta we have shown that ILC measurements are complementary to LHC measurements of the noncommutative parameters. In addition, the bounds on Lambda_NC derived from the ILC are significantly higher and reach Lambda_NC > 6 TeV. The second part of this work arose from the necessity to enlarge the range of validity of our model towards higher energies. Thus, we expand the neutral current sector of the noncommutative SM to second order in $\theta$. We found that, against the general expectation, the theory must be enlarged by additional parameters. The new parameters enter the theory as ambiguities of the Seiberg-Witten maps. The latter are not uniquely determined and differ by homogeneous solutions of the gauge equivalence equations. The expectation was that the ambiguities correspond to field redefinitions and therefore should vanish in scattering matrix elements. However, we proved that this is not the case, and the ambiguities do affect physical observables. Our conjecture is, that every order in Theta will introduce new parameters to the theory. However, only the experiment can decide to what extent efforts with still higher orders in Theta are reasonable and will also give directions for the development of theoretical models of noncommutative QFTs.
The internal transcribed spacer 2 (ITS2) of the ribosomal gene repeat is an increasingly important phylogenetic marker whose RNA secondary structure is widely conserved across eukaryotic organisms. The ITS2 database aims to be a comprehensive resource on ITS2 sequence and secondary structure, based on direct thermodynamic as well as homology modelled RNA folds. Results: (a) A rebuild of the original ITS2 database generation scripts applied to a current NCBI dataset reveal more than 60,000 ITS2 structures. This more than doubles the contents of the original database and triples it when including partial structures. (b) The end-user interface was rewritten, extended and now features user-defined homology modelling. (c) Other possible RNA structure discovery methods (namely suboptimal and shape folding) prove helpful but are not able to replace homology modelling. (d) A use case of the ITS2 database in conjunction with other tools developed at the department gave insight into molecular phylogenetic analysis with ITS2.
Maize seedlings contain high amounts of glucosidically bound 2,4-dihydroxy-7-methoxy-1,4-benzoxazin-3-one (DIMBOA). The effects of DIMBOA on the feeding behaviour and performance of two noctuids, Spodoptera exigua Hübner and S. frugiperda Smith, were compared. The question was raised whether S. frugiperda, preferring maize and other Poaceae, is better adapted to DIMBOA than S. exigua. In addition, the effects of DIMBOA on the mycelial growth of the plant pathogen Setosphaeria turcica Leonard et Suggs (causal agent of northern corn leaf blight) was assessed in vitro. DIMBOA had an antifeedant effect on S. exigua but stimulated feeding in S. frugiperda in dual-choice experiments. In a no-choice setup, larvae of S. exigua gained less biomass and had a prolonged development when feeding on an artificial diet containing DIMBOA. However, pupal weight was not significantly different between treatments. In contrast, larvae of S. frugiperda were not affected by DIMBOA. Strong detrimental effects of DIMBOA were found on the mycelial growth of the pathogen S. turcica.
A small percentage (1-5%) of the blood lymphocytes expresses alternative T-cell antigen receptor that uses g and d TCR rearranging genes. A subset of them expresses the Vg9Vd2 TCR. Those cells respond to self-nonpeptide and foreign antigens presented by unknown antigen-presenting molecules. Vg9Vd2 T cells also express Toll-like receptors and natural killer receptors that allow them to respond to other nonpeptide microbial components or to alterations in the expression of stress cell surface ligands such as NKG2D ligands. Vg9Vd2 T cells frequently are regulated by the expression of activating and/or inhibitory NKRs (iNKRs) that can fine-tune their activation threshold and the activating NKG2D receptor is one of the most studied until now. NKG2D, a C-type lectin receptor directed against MICA/MICB and UL16-binding protein (ULBP) molecules, have been reported a powerful co-stimulus for Ag-mediated activation of CD8 and Vg9Vd2 T cells. Indeed, NKG2D is recruited within the Vg9Vd2 TCR immunological synapse and enhances recognition by Vg9Vd2 T cells of Mycobacteria-infected DCs and various MICA/MICB or ULBP hemopoietic and non-hemopoietic tumors. The level of NKG2D is upregulated by inflammatory cytokines (e.g. IL-15), and NKG2D ligands are induced after a physical or genotoxic stress and/or along infection by intracellular pathogens. Therefore, NKG2D is a key stress sensor that strongly enhances recognition of altered or infected self by human gd T cells. Recent progress in the field supports the idea that gd T cells fulfill a role in the innate and adaptative immune response in different way of the conventional ab T cells. We demonstrated direct activation of Vg9Vd2 T cells by NKG2D ligation through the association with DAP10 adapter molecules and independently of TCR-Ag recognition, similar to the NKG2D-mediated activation of NK cells. Culture of peripherical blood mononuclear cells with immobilized NKG2D mAb or NKG2D ligand MICA induces up-regulation of CD69 and CD25 in NK and Vg9Vd2 T cells but not in CD8 T cells. Additionally, the ligation of NKG2D induces in Vg9Vd2 T cells the up-regulation of molecules typical for antigenpresenting cells, such as co-stimulator molecules (CD86) antigen presenting molecules (CD1a, HLA-DR), adhesion molecules (CD54), and activation molecules (CD69). Furthermore, NKG2D ligation in Vg9Vd2 T cells induces the production of cytokines such as TNF-a and chemokines such as, MIP-1a, but cannot induce the production of cytokines such as IL-6 or IFN-g and chemokines such as RANTES, MCP-1 and GM-CSF. In addition, NKG2D triggers the activation of the cytolytic machinery as efficient as CD3 stimulation as shown by measurement of the release of granules with esterase activity (BLT assay), perforin and the up-regulation of CD107a on the surface of Vg9Vd2 T cells. This NKG2D dependent cytolysis has been confirmed using purified Vg9Vd2 T cells, which kill MICA-transduced RMA cells but not the control cells. The TCR independence and NKG2D dependence of this killing is supported by mAb inhibition experiment. Finally, DAP 10, which mediates NKG2D signaling of human NK cells, is found in resting and activated Vg9Vd2 T cells. Moreover, data of intracellular signaling studies suggest an important role of Scr kinases in the NKG2D mediated killing and involvement of DAP-10-PI3K and PLCg 1 pathways as mayor proteins implicated in target cell lysis, and shows remarkable difference with the TCR signaling. The identification of these similarities in NKG2D function between NK and Vg9Vd2 T cells may be of interest for development of new strategies for Vg9Vd2 T cell-based immunotherapy in certain types of cancer and help to understand Vg9Vd2 T cell function in general.
In radiation accidents biological methods are used in dosimetry, if the radiation dose could not be measured by physical methods. The knowledge of individual dose is a prerequisite for planning a medical treatment and for health risk evaluations. In the present work two biodosimetrical assays were calibrated in young patients who were treated with radioiodine for thyroid cancer. Patients were from Belarus. They suffered from radiation induced thyroid cancer as a consequence of the Chernobyl reactor accident. In radioiodine therapy (RIT) bone marrow and lymphatic organs are exposed to ionizing radiation at doses of 0.1 to 0.75 Sv within about 2 days. Since several RIT have to be applied with interval between each of them from 6 months up to approximately 1 year, total dose can be up to 2 Sv within 2 to 3 years. The dose for thyroid tissue is approximately 1000 times higher. The dose-response relationship was measured by the T-cell receptor test (TCR test) in T4 lymphocytes with and without in vitro incubation or by the micronucleus assay in transferrin receptor positive reticulocytes (MN-Tf-Ret test). In all these assays, the frequency of radiation-induced mutants of blood cells is measured using flow cytometry. The TCR test is a cumulative biodosimeter, which measures the total radiation dose within the last 5 to 10 years, whereas the result of the MN-Tf-Ret test reflects the radiation dose of approximately 24 hours interval. It takes 8 hours and 3 days to perform TCR and MN-Tf-Ret tests respectively. Calibration curves based on radioiodine treated patients can be used for dose estimation in humans, if the radiation conditions correspond to those in RIT. This limits their applicability to low dose-rate β- and γ-irradiation and to doses per session not higher than about 0.5 Sv. If higher doses or dose-rates as well as the other types of ionizing radiation are involved, calibration curves in animals are indispensable. In the case MN-Tf-Ret test mouse models are established and may be used. The TCR assay was performed in 72 thyroid cancer patients aged between 14 and 25. T-cell mutant frequency (Mf) reaches its maximum only after half a year following the RIT. Then it declines exponentially. This decline could be described by the 3 parameter single exponential decay function. Based on this equation, the radiation dose could be calculated when the Mf and the time interval since exposure are known. Furthermore, the experimentally measured Mf value, which significantly exceeds the corresponding calculated Mf value would indicate an individual with higher radiosensitivity. However, among our patients there were none. The reticulocytes micronuclei test (MN-Tf-Ret) was performed in 46 radioiodine treated patients. When measuring the MN frequency (f(MN-Tf-Ret)) the measured cell fraction should be limited only to the youngest cohort of reticulocytes, because all the micronucleated erythrocytes are quickly removed from the peripheral blood by spleen. Thus, the MN test was performed only in CD71 positive (having transferring receptor) reticulocytes. These reticulocytes just entered the peripheral blood flow from red marrow. The MN frequency was measured before the therapy and then every day after the irradiation until day 7. MN frequency curve has typical shape with latent period for days 0 to 3. Then there is a sharp increase in MN frequency which lasts for 24 hours and could start between days 3 and 4. In the following days the MN frequency is dropping to its base level that equals the one before the treatment. The decay of MN frequency is depending on the half-life of radioiodine in the patient organism. If the half-life is low, then the increased f(MN-Tf-Ret) lasts shorter and vice versa. It was shown that the MN frequency curve could be described by the model where all the micronuclei arise only through the last mitosis of erythroblasts in the red marrow and the MN frequency is proportional to the radiation dose in the last cell cycle. The shape of this curve depends on the cell kinetics of erythropoiesis on one side and the exponential decay of radioiodine activity on the other. To the best of our knowledge, the MN-Tf-Ret test was applied in the present study for the first time in biological dosimetry.
Sumoylation of transcription factors modulate their activity (either upregulating or downregulating) by altering protein-protein interactions as well as subcelluar/subnuclear localization. The transcription factor family of NFAT (Nuclear Factor of Activated T cells) plays an important role in cytokine gene regulation in T cells. Due to alternative usage of two promoters (P1 & P2), two polyadenylation sites (pA1 and pA2) and alternative splicing events, NFATc1 is expressed in six isoforms which are NFATc1/alphaA, betaA, alphaB, betaB, alphaC and betaC, where alpha and beta refer to two different 1st exons and A, B, C to the differentially spliced and extended C-termini. The short isoforms of NFATc1 (NF-ATc1/A) contain a relatively short C terminus whereas, the longer isoforms, B and C, span the extra C-terminal peptides of 128 and 246 aa, respectively. To analyze the specific biological effects of NFATc1 isoform, a yeast two hybrid screening of a human spleen cDNA library with extra C-terminal peptide of NFATc1 as a bait, was performed. At the end of the assay, the proteins involved in the sumoylation pathway such as Ubc9, PIAS1 were detected with highest frequencies and subsequently were were able to demonstrate that NFATc1 is sumoylated. The extent of sumoylation is isoform specific. While NFATc1/A, harboring only one sumoylation site, shows very weak sumoylation, the two additional sites within NFATc1/C lead to efficient sumoylation. This modification directs NFATc1/C into SUMO-1 bodies, which in turn colocalize with PML-nbs. Furthermore, sumoylated NFATc1/C recruits the transcriptional co-repressors HDAC (both class I as well as class II HDACs) which results in a significant decrease of the level of histone acetylation on the IL-2 promoter, an important NFATc1 target gene. As a consequence of this, a decrease of IL-2 production was observed, while NFATc1/C, which can no longer be sumoylated due to mutating the target lysines, exhibited dramatic elevated transcriptional potential on the IL2 promoter. This supports our finding from IL-2 promoter-driven reporter gene assay, which shows downregulation of NFATc1/C transactivation upon sumoylation. Hence, sumoylation exerts a negative effect on NFATc1 transcriptioanl activity. Immunofluorescence studies showed SUMO modification to relocate NFATc1/C also into transcriptionally inactive heterochromatin regions, demonstrated by H3K9 m3 (tri-methylated histone lysine 9) colocalization studies. Interestingly, in the absence of sumoylation, NFATc1 was partially colocalized with transcriptional hotspots in the nucleus, which might contribute to the higher transcription potentiality of the non-sumoylated NFATc1. It is important to note that, the transcriptional activity of other NFATc1 target genes (IL-13, IFN-gamma etc.) was positively upregulated upon sumoylation of NFATc1, suggesting a non-universal effect of sumoylation on NFATc1/C function. In conclusion, sumoylation directs NFATc1 into nuclear bodies where it interacts with transcriptional co-repressors and relocalize itself with heterochromatin, leading to repression of NFATc1/C-mediated transcription. Most importantly, the effect of NFATc1/C sumoylation is promoter specific. Taken together, SUMO modification alters the function of NFATc1 from an activator to a site-specific transcriptional repressor. This study unraveled a novel regulatory mechanism, which controls isoform specific NFATc1 function.
This volume brings together several authors from different areas of psychology and the neighbouring social sciences. Each one contributes their own perspective on the growing interest topic of subjective well-being. The aim of the volume is to present these divergent perspectives and to foster communication between the different areas. Split into three parts, this volume initially discusses the general perspectives of subjective well-being and addresses fundamental questions, secondly it discusses the dynamics of subjective well-being and more specific research issues to give a better understanding of the general phenomenon, and thirdly the book emphasizes the social context in which people experience and report their happiness and satisfaction. The book will be of great interest to social and clinical psychologists, students of psychology and sociology and health professionals.
The main focus of this work was to get a deeper understanding of the relationship between the structure of sol-gel films, their densification and their macroscopic cracking. First of all titania was chosen as model system. Therefore a synthesis route starting from the preparation of long-term stable amorphous redissoluble precursor powders based on acetylacetone as chelate ligand was utilized. The solubility and stability of the powders in various solvents can be determined by chemical synthesis and technological parameters. When dissolved in a solvent mixture of ethanol and 1,5-pentanediol, thin films can be easily prepared by dip-coating technique. Thereby the quality of the titania films enormously depends on the calcinations temperature and the solvent mixture is used. In order to investigate the influence of different solvents and solvent mixtures on the microstructure and densification of the precursors, the coating solutions were stripped off (sol powder) and analyzed as function of annealing temperature. It was pointed out that a high densification rate caused by the addition of 1,5-pentanediol, results in dense microstructure with trapped residual carbon. These impurities can retard the phase transformation of anatase to rutile. The analysis of so-called “film powders” scraped off multiple dip-coated substrates provides valuable information on the effect of air moisture and unidirectional densification during drying and aging on the structure of thin films. The high surface-to-volume ratio and access to air moisture determine the chemical composition of the as-prepared film, which controls shrinkage, crystallization and defect structure of the coatings. Further it was shown, that drying as a thin film results in the formation of closed pores and much denser microstructure than the respective sol powder. Without the addition of 1,5-pentanediol all –OEt moieties undergo hydrolysis reactions, which causes the formation of a rigid network. The presence of 1,5-pentanediol retards this hydrolysis reactions and provides some network plasticity. Generally the microstructure of thin films is comparatively close to the microstructure of the film powders. The addition of 1,5-pentandiol prevents hydrolysis and condensation reactions as like in the film powders. However even at 700 °C, thin films never transform to rutile, which was attributed to the tensile stresses in thin films. In thin films and in film powders as well a comparable amount of closed pores are formed during annealing. Further it was shown that most of the thin sol-gel films investigated form a dense crust on their tops during annealing. This explains why crack free films exhibit only closed pores. However, when cracks appear during thin film shrinkage in the coating, this crust is burst, which generates open porosity. The defect density in the coatings was determined by an automated analysis of surface images. The crack formation and quantity can be directly referred to tensile stresses in the coatings, which arise from hydrolysis and condensation during thin film drying and aging. Therefore when 1,5-pentanediol is added to the sol, thin film cracking was avoided, because hydrolysis and condensation reactions are retarded, which preserves a higher network flexibility. Furthermore the crack formation was significantly influenced by the atmospheric humidity that was used during the coating process, which was explained by different drying and condensation rates. Under certain chemical starting conditions water soluble precursor powders can be also obtained. In general the observations made with the water based coating solutions are mostly in agreement with the former results based on ethanol based coating solutions. For example the high surface-to-volume ratio of film powders compared to sol powders also significantly enhances film drying and densification. The addition of 1,5-pentanediol also clearly contributes to their densification behavior and phase evolution. As seen before in the case of ethanol based coatings, 1,5-pentanediol enhances the stability towards hydrolysis and condensation reactions and preserves some network plasticity. Therefore coatings prepared without the addition of 1,5-pentanediol already form cracks during film drying and aging because of tensile stresses. Thus, the addition of 1,5-pentanediol results in a reduction/prevention of crack formation. Nevertheless some differences were observed, i.e. the critical single coating film thickness of ethanol based coatings is nearly twice that of water based coatings. This was explained by the different surface tensions of the basis solvents, which during thin film drying causes significantly higher capillary forces and tensile stresses in water based coatings. When acetylacetone is replaced by triethanolamine as chelating ligand for titanium also re-dissolvable precursor powders can be synthesized. The film powders combine a high hydrolytic stability of the precursor with sufficient intermediate network flexibility. The different type of organics changes the drying and densification behavior: i.e. in contrast to film powders obtained from acetylacetone based precursor powders the structure of triethanolamine based film powders is unaffected by the thin film drying process. This high hydrolytic stability and plasticity of this precursor allows the preparation of defect free coatings up to single film thickness of 300 nm. However triethanolamine based thin films present at intermediary annealing temperatures a distinctively different microstructure compared to acetylacetone based films. The general validity of the conclusions was proved on the basis of zirconia coatings that were also prepared by the use of re-dissolvable precursor powders. In principle all conclusions concerning the interconnection of precursor chemistry, film formation, densification and structure were transferable to the respective zirconia coatings. Differences mainly arise only from differential material properties i.e. bulk density. Finally, it has been pointed out that the findings obtained on the densification behavior of thinsol-gel films are also a valuable tool for improved explanations of other important scientific questions concerning sol-gel films, i.e. scratch resistance of sol-gel coatings, fiber -bridging and – degradation of sol-gel coated fibers.
This thesis is devoted to the study of computational complexity theory, a branch of theoretical computer science. Computational complexity theory investigates the inherent difficulty in designing efficient algorithms for computational problems. By doing so, it analyses the scalability of computational problems and algorithms and places practical limits on what computers can actually accomplish. Computational problems are categorised into complexity classes. Among the most important complexity classes are the class NP and the subclass of NP-complete problems, which comprises many important optimisation problems in the field of operations research. Moreover, with the P-NP-problem, the class NP represents the most important unsolved question in computer science. The first part of this thesis is devoted to the study of NP-complete-, and more generally, NP-hard problems. It aims at improving our understanding of this important complexity class by systematically studying how altering NP-hard sets affects their NP-hardness. This research is related to longstanding open questions concerning the complexity of unions of disjoint NP-complete sets, and the existence of sparse NP-hard sets. The second part of the thesis is also dedicated to complexity classes but takes a different perspective: In a sense, after investigating the interior of complexity classes in the first part, the focus shifts to the description of complexity classes and thereby to the exterior in the second part. It deals with the description of complexity classes through leaf languages, a uniform framework which allows us to characterise a great variety of important complexity classes. The known concepts are complemented by a new leaf-language model. To a certain extent, this new approach combines the advantages of the known models. The presented results give evidence that the connection between the theory of formal languages and computational complexity theory might be closer than formerly known.
Within the scope of this thesis, spin related transport phenomena have been investigated in HgTe/HgCdTe quantum well structures. This material exhibits peculiar band structure properties, which result in a strong spin-orbit interaction of the Rashba type. An inverted band structure, i.e., a reversed ordering of the energy states in comparison to common semiconductors, is obtained for quantum well layers above a critical thickness. Furthermore, the band structure properties can be controlled in the experiments by moderate gate voltages. Most prominently, the type of carriers in HgTe quantum wells can be changed from n to p due to the narrow energy gap. Along with the inverted band structure, this unique transition is the basis for the demonstration of the Quantum Spin Hall state, which is characterized by the existence of two one-dimensional spin-polarized edge states propagating in opposite directions, while the Fermi level in the bulk is in the energy gap. Since elastic scattering is suppressed by time reversal symmetry, a quantized conductance for charge and spin transport is predicted. Our experiments provide the first experimental demonstration of the QSH state. For samples with characteristic dimensions below the inelastic mean free path, charge conductance close to the expected value of 2e^2/h has been observed. Strong indication for the edge state transport was found in the experiments as well. For large samples, potential fluctuations lead to the appearance of local n-conducting regions which are considered to be the dominant source of backscattering. When time reversal symmetry is broken in a magnetic field, elastic scattering becomes possible and conductance is significantly suppressed. The suppression relies on a dominant orbital effect in a perpendicular field and a smaller Zeeman-like effect present for any field direction. For large perpendicular fields, a re-entrant quantum Hall state appears. This unique property is directly related to the non-trivial QSH insulator state. While clear evidence for the properties of charge transport was provided, the spin properties could not be addressed. This might be the goal of future experiments. In another set of experiments, the intrinsic spin Hall effect was studied. Its investigation was motivated by the possibility to create and to detect pure spin currents and spin accumulation. A non-local charging attributed to the SHE has been observed in a p-type H-shaped structure with large SO interaction, providing the first purely electrical demonstration of the SHE in a semiconductor system. A possibly more direct way to study the spin Hall effects opens up when the spin properties of the QSH edge states are taken into account. Then, the QSH edge states can be used either as an injector or a detector of spin polarization, depending on the actual configuration of the device. The experimental results indicate the existence of both intrinsic SHE and the inverse SHE independently of each other. If a spin-polarized current is injected from the QSH states into a region with Rashba SO interaction, the precession of the spin can been observed via the SHE. Both the spin injection and precession might be used for the realization of a spin-FET similar to the one proposed by Datta and Das. Another approach for the realization of a spin-based FET relies on a spin-interference device, in which the transmission is controlled via the Aharonov-Casher phase and the Berry phase, both due to the SO interaction. In the presented experiments, ring structures with tuneable SO coupling were studied. A complex interference pattern is observed as a function of external magnetic field and gate voltage. The dependence on the Rashba splitting is attributed to the Aharonov-Casher phase, whereas effects due to the Berry phase remain unresolved. This interpretation is confirmed by theoretical calculations, where multi-channel transport through the device has been assumed in agreement with the experimental results. Thus, our experiments provide the first direct observation of the AC effect in semiconductor structures. In conclusion, HgTe quantum well structures have proven to be an excellent template for studying spin-related transport phenomena: The QSHE relies on the peculiar band structure of the material and the existence of both the SHE and the AC effect is a consequence of the substantial spin-orbit interaction. While convincing results have been obtained for the various effects, several questions can not be fully answered yet. Some of them may be addressed by more extensive studies on devices already available. Other issues, however, ask, e.g., for further advances in sample fabrication or new approaches by different measurements techniques. Thus, future experiments may provide new, compelling insights for both the effects discussed in this thesis and, more generally, other spin-orbit related transport properties.
In a nice assay published in Nature in 1993 the physicist Richard God III started from a human observer and made a number of witty conclusions about our future prospects giving estimates for the existence of the Berlin Wall, the human race and all the rest of the universe. In the same spirit, we derive implications for "the meaning of life, the universe and all the rest" from few principles. Adams´ absurd answer "42" tells the lesson "garbage in / garbage out" - or suggests that the question is non calculable. We show that experience of "meaning" and to decide fundamental questions which can not be decided by formal systems imply central properties of life: Ever higher levels of internal representation of the world and an escalating tendency to become more complex. An observer, "collecting observations" and three measures for complexity are examined. A theory on living systems is derived focussing on their internal representation of information. Living systems are more complex than Kolmogorov complexity ("life is NOT simple") and overcome decision limits (Gödel theorem) for formal systems as illustrated for cell cycle. Only a world with very fine tuned environments allows life. Such a world is itself rather complex and hence excessive large in its space of different states – a living observer has thus a high probability to reside in a complex and fine tuned universe.
A series of experiments was conducted in order to investigate motor contributions to learning highly skilled action sequences in contrast to sensory contributions. Experiments 1–4 made use of a bimanual-bisequential variant of the serial reaction time task: Presentation of imperative stimuli was arranged such that participants’ left-hand and right-hand responses followed different sequences independently of one another, thus establishing a compound sequence spanning both hands. At least partly independent learning of the two concurrently implemented hand-related sequences was demonstrated after extensive practice under condi-tions of both simultaneous (Experiments 1 & 2) and alternating (Experiments 3 & 4) stimulus presentation and responding. It persisted when there was only one imperative stimulus for presenting both hand-related sequences (Experiments 2–4) instead of two separate imperative stimuli (Experiments 1 & 2), one for each sequence, even when the hand-related sequences were correlated and massive integrated learning of the compound sequence occurred (Ex-periment 4). As for the nature of the independently acquired sequence representations, trans-ferable sequence knowledge was acquired only when there was a separate imperative stimulus for each sequence (Experiments 1 & 2) but not otherwise (Experiments 2–4). The most likely stimulus-based representations which allow for intermanual transfer can be regarded as sen-sory components of highly skilled action sequences, whereas motor components can be con-sidered as being reflected in effector-specific, non-transferable sequence knowledge. The same decomposition logic applies to transferable and non-transferable sequence knowledge observed under conditions of unimanual practice of a single sequence (Experiments 6 & 7). The advantage of practicing a key press sequence with fingers of one hand as opposed to practicing it with fingers of both hands (Experiment 5) also implicates a motor component as the two assignments were equivalent in all other respects. Moreover, Experiments 6 and 7 showed that hand-specific sequence knowledge can develop after relatively little practice (as little as approximately 120 sequence repetitions). Presumably, this occurs especially in tasks with particularly pronounced requirements for coarticulation between consecutive finger movements. In sum, the present series of experiments provides compelling evidence for an effector-specific component of sequence learning. Albeit relatively small in size, it emerged consistently under various conditions. By contributing to the refinement of sequential action execution it can play a role in attaining high levels of performance.
Microtubules are a fascinating component of the cellular scaffold protein network, the cytoskeleton. These hollow tubular structures are assembled of laterally associated proto-filaments containing ab-tubulin heterodimers in a head to tail arrangement. Accordingly microtubules have a defined polarity, which sets the base for the polarity of the cell. The microtubule lattice can be arranged in two conformations: In the more abundant B-lattice conformation, where the protofilaments interact laterally through a- to a- and b- to b-tubulin contacts and in the less stable A-lattice conformation, where a-tubulin interacts laterally with b-tubulin. In cells the microtubules generally contain 13 protofilaments of which usually one pair interacts in the A-lattice conformation, forming the so-called lattice seam. Microtubule dynamics and interactions are strongly regulated by micro-tubule associate proteins (MAPs). Structural investigations on MAPs and microtubule associated motor proteins in complex with microtubules have become possible in combination with modern electron microscopy (EM) and image processing. We have used biochemistry and different advanced EM techniques to study the interaction between microtubules and the MAP Mal3p in vitro. Mal3p is the sole member of the end-binding protein 1 (EB1) protein family in the fission yeast Schizosaccharomyces pombe. Previous in vivo studies have shown that Mal3p promotes microtubule growth. Our studies with high-resolution unidirectional shadowing EM revealed that Mal3p interacts with the microtubule lattice in a novel way, using binding sites on the microtubule that are different from those reported for other MAPs or motor proteins. Full-length Mal3p preferentially binds between two protofilaments on the microtubule lattice, leaving the rest of the lattice free. A case where Mal3p was found in two adjacent protofilament, revealed an A-lattice conformation on the microtubules, surprisingly indicating specific binding of Mal3p to the microtubule seam. With a lattice enhancer, in form of a b-tubulin binding kinesin motor domain, it was demonstrated that Mal3p stabilizes the seam which is thought to be the weakest part of a microtubule. Further, the presence of Mal3p during microtubule polymerization enhances the closure of protofilament sheets into a tubular organization. Cryo-EM and 3-D helical reconstruction on a monomeric microtubule binding domain of Mal3p, confirm the localization in between the protofilament and result in an accurate localization on the microtubule lattice. The results also indicate Mal3p’s capacity to influence the microtubule lattice conformation. Together, studies approached in vitro demonstrate that an EB1-family homolog not only interacts with the microtubule plus end, but also with the microtubule lattice. The structure of Mal3p interacting with microtubules reveals a new mechanism for microtubule stabilization and further insight on how plus end binding proteins are able promote microtubule growth. These findings further suggest that microtubules exhibit two distinct reaction platforms on their surface that can independently interact with selected MAPs or motors.
The continuously increase in resistance of human pathogenic microorganisms to the known antibiotics leads to the necessity for searching new sources for production of new active antimicrobial compounds from different natural sources especially plants, since many plants have been found to be able to produce antimicrobial compounds as a defense phenomenon against invading microorganisms. The aim of this work is to screen cultures for production of antimicrobial activity against representative of human pathogenic microorganisms and selection the most active cell culture producing antimicrobial protein(s) which are active against these pathogenic microorganisms and also isolation ,purification of the active protein(s) and cloning of its/their genes. Ten different plant suspension cultures have been screened in presence of nine elicitors for their antimicrobial activity against five selected human pathogenic microorganisms, and it has been found that the heterotrophic cultures are more active against the tester isolates than the autotrophic ones. The intracellular fraction of the mixotrophic Arabidopsis thaliana culture elicited with salicylic acid showed the highest antimicrobial activity against the tester isolates. The presence of proteinous antimicrobial activity has been elucidated by testing the activity of ammonium sulphate precipitate against Candida maltosa. High speed centrifugation technique has been used for partial purification of the active protein. The proteinous nature of the isolated compound has been confirmed by using bioautography technique and its molecular weight could be estimated to be around 26KDa. The active protein has been purified using gel filtration, and using mass spectrometry technique, for microsequencing of the active protein, it has been found that the function of the protein is unknown and we have termed it as AtPDP1 according to Arabidopsis thaliana Plat-Domain Protein1, since it contains a plant stress domain termed PLAT domain. It has been found that a second protein from the same plant with high homology level to AtPDP1 with the same domain, we termed it as AtPDP2. Genes for AtPDP1 and AtPDP2 have been cloned in E. coli using PGEM-T easy vector. The expression of both genes have been tested using Digital Northern program, and it has been observed that both genes are induced by different pathogens, chemicals known to induce defense in plant cells and also different hormones. We tried to clone the gene for AtPDP1 in PBI121 binary vector under the control of an elicitor inducible promoter of a proteinase inhibitor gene, to test its function in plant by overexpression, but we did not succeeded. Also the work aims to cloning the different known thaumatin genes from Arabidopsis thaliana for future work which represented by testing their expression under different stimuli, since most thaumatins have antimicrobial activity and some of them are active against Candida spp..Thirteen genes of known thaumatins from Arabidopsis thaliana have been cloned in PGEM-Teasy vector in DH5-alpha cells. coli cells. The expression of the thirteen genes has been done using Digital Northern program and it has been found that different genes show different expressions under different stimuli and the expression of At1g75800 gene was the maximum under all stimuli. The minimum expression of genes was for At1g75050. The rest of thaumatin genes showed moderate expressions under different stimuli.
The Ras/RAF/MEK/ERK cascade is a central cellular signal transduction pathway involved in cell proliferation, differentiation, and survival where RAF kinases are pivotal kinases implicated in cancer. The development of specific irreversible kinase inhibitors is a rewarding but difficult aim. CI-1033 was developed to irreversibly inhibit erbB receptor tyrosine kinases by reacting to the Cys113 residue (p38alpha MAP kinase numbering) of the kinase domain. In this study we tried a similar approach to target the RAF oncoproteins which posses a similar cysteine at position 108 in the hinge region between the small n-lobe and the large c-lobe of the kinase domain. A novel synthetic approach including a lyophilization step allowed us the synthesis of a diphenyl urea compound with an epoxide moiety (compound 1). Compound 1 possessed inhibitory activity in vitro. However our time kinetics experiments and mass spectroscopic studies clearly indicate that compound 1 does not react covalently with the cysteine residue in the hinge region. Moreover, in cell culture experiments, a strong activation of the RAF signaling pathway was observed, an effect which is known from several other RAF kinase inhibitors and is here reported for the first time for a diphenyl urea compound, to which the clinically used unspecific kinase inhibitor BAY 43-9006 (Sorafinib, Nexavar) belongs. Although activation was apparently independent on B- and C-RAF hetero-oligomerization in vitro, in vivo experiments support such a mechanism as the activation did not occur in starved knockout cells lacking either B-RAF or C-RAF. Furthermore, we developed a mathematical model of the Ras/RAF/MEK/ERK cascade demonstrating how stimuli induce different signal patterns and thereby different cellular responses, depending on cell type and the ratio between B-RAF and C-RAF. Based on biochemical data for activation and dephosphorylation, we set up differential equations for a dynamical model of the Ras/RAF/MEK/ERK cascade. We find a different signaling pattern and response result for B-RAF (strong activation, sustained signal) and C-RAF (steep activation, transient signal). We further support the significance of such differential modulatory signaling by showing different RAF isoform expression in various cell lines and experimental testing of the predicted kinase activities in B-RAF, C-RAF as well as mutated versions. Additionally the effect of the tumor suppressor DiRas3 (also known as Noey2 or ARHI) on RAF signaling was studied. I could show that DiRas3 down-regulates the mitogenic pathway by inhibition of MEK, a basis for a refined model of the Ras/RAF/MEK/ERK cascade.
The effective binding of anions like carboxylates and phosphates in aqueous solutions is of particular interest for various reasons. The natural archetypes of effective anion receptors are enzymes that contain often arginine as relevant amino acid in the binding pocket. For this reason, one class of artificial anion receptors that emerged more than two decades ago mimics the anion binding with the guanidinium group present in the amino acid side chain. In 1999, Schmuck and coworkers developed a new class of guanidinium-based oxo anion receptor that binds carboxylates even in aqueous media. The binding modes of the 2-(guanidiniocarbonyl)-1H-pyrroles are based on individually weak non-covalent interaction between artificial host and substrate like ion pairing and multiple hydrogen bonds. The zwitterionic derivative with substitution of a carboxylate group in position 5 of the pyrrole ring system shows a strong self-assembly to discrete dimers (dimer 1) with an estimated association constant of 170 M-1 even in water. In order to further improve the structure motif for an effective oxo anion binding it is therefore of great interest to quantify the different intermolecular interactions between two monomeric units of 1. Against this background several theoretical ab initio studies were conducted in order to elucidate the influences of intrinsic properties as well as solvent effects on the stability of self-assembled dimers. In chapter 4.1 the molecular interactions in dimer 1 were investigated by comparison to various “knock-out” analogues. In these analogues single hydrogen bonds were switched off by substitution of hydrogen donor atoms with either methylene groups or ether bridges. The calculations were done for vacuum and solvation, as represented by a conductor-like polarizable continuum. It could be shown that the application of a simple continuum solvent model fails to predict the absolute energies of the knock-out analogues in strongly polar solvents. However, the calculated trends can explain the relative stabilities. In chapter 4.2 the structural similarity of arginine with structure 1 was used in order to examine the dependence of self-assembly from the flexibility of the molecular structure. In chapter 4.2.1 new global minimum structures of the canonical and zwitterionic arginine in gas phase were found by means of exhaustive force field based conformational searches in conjunction with ab initio structure optimizations of the lowest energy conformers. Most of the newly identified minimum conformers of both the zwitterionic and canonical tautomer revealed geometrical arrangements with hitherto unreported stacked orientations of the terminal groups. Finally a novel global minimum structure was detected that is more than 8 kJ mol-1 lower in energy than the previously published conformers. The same strategy for finding minimum energy conformers of the arginine monomer has also been employed for the arginine dimer structures. While previous theoretical studies favoured directed hydrogen bonds the new global minimum structure MMFF1 is about 60 kJ mol-1 more stable and exhibits a stacked orientation of the guanidinium and carboxylate groups. The importance of rigidity on the dimer stability was proven by calculations of an artificially stiffened arginine dimer system. The high binding affinity dimer 1 results by about 50% from the rigidity of the monomers which prevents any intramolecular stabilization. In chapter 4.3 novel structure motifs with varying ring systems have been examined on a DFT level of theory in order to make proposals for an improved carboxylate binding motif. The direct dependency of the dimerization energy on an increasing dipole moment was demonstrated by various anellated ring structures. The influence of the delocalization in the monomer on the dimerization energy was examined by variation of the electronic structure of electronically decoupled biphenylenes. With the aid of various substituted 7-guanidinioindole-2-carboxylate derivatives we could show that the carbonyl function is mainly responsible for the advantageous preorganisation, whereas the effect on the acidity seems to be only of minor importance. In the last chapter cooperativity effects in supramolecular assemblies have been investigated. This was achieved by NMR shift calculations of adenosine-carboxylic acid complexes as model systems and comparison to experimental low-temperature NMR studies. We could demonstrate that only by applying vibrational averaged NMR shifts the experimental proton shifts obtained at very low temperatures in the hydrogen bond exchange regime could be reproduced.
In the first part of this work a new approach to measure transient absorption spectra of fluorescent compounds by means of laser flash photolysis technique was presented. Generally, the recorded transient absorption signal consists of transient absorption, fluorescence and ground state bleaching. Thus, for fluorescent chromophores a fluorescence correction is indispensable in order to obtain undisturbed absorption decay curves as well as accurate transient absorption spectra. Due to time response characteristics of the PMT detector the fluorescence contribution cannot be corrected by recording the fluorescence separately. Measuring two transient absorption signals with probe light differing in intensity, compounds with quantum yields up to ~ 35 % can be investigated. This is a major improvement because transient absorption spectroscopy is a powerful method to gain insight into the kinetics and the energy of excited states and information in the time domain of fluorescence are no longer lost. In the second part the synthesis and the photophysical characterisation of redox cascades were reported. These cascades consist of an acridine acceptor and up to three triarylamine donor subunits. The redox potentials of the triarylamines were tuned by adequate substituents in the para-position of the phenyl ring to ensure a directed redox gradient. Upon photoexcitation a locally excited state or a CT state is populated which then injects a hole onto the adjacent donor and consequently results in a CS state. Fluorescence and transient absorption measurements revealed that HT depends strongly on donor strength and solvent polarity. Formation of a CS state was only observed in case of strong terminal donors or polar solvents. A low lying localised triplet state acts as an energy trap and quenches all CS states even in case of the cascade with the strongest terminal donor in very polar solvents. Furthermore, population of a CS state catalyses the formation of this triplet states which results in a shorter lifetime of the CS state compared to the lifetime of the CT state of the corresponding reference compound. Compared to redox cascades already reported in literature, the electronic coupling between the redox centres was decreased by sterical as well as electronic effects. To prolong the lifetime of the CS state saturated spacers on the one hand and a perpendicular orientation of the acceptor and the adjacent donor on the other hand were selected. The twisting of the subunits forming the CT state results in a higher degree of charge separation but its contribution to increase the lifetimes of the CS states is of minor importance. The longer lifetime of the CS states can be ascribed to the saturated spacers. Experimental data in combination with calculated values indicate that charge recombination takes place in the Marcus normal region by a superexchange mechanisms. Although charge recombination of the known cascades is located in the Marcus inverted region, these CS states decay faster than the CS states of the compounds investigated in this work.
Clonidine is an agonist at alpha2-adrenergic receptors that mediate a wide variety of the physiological responses to epinephrine and norepinephrine, such as inhibition of neurotransmitter release as well as sedation and analgesia. As with other therapeutically used alpha2-agonists such as moxonidine and rilmenidine, clonidine possesses an imidazoline structure and is believed to lower blood pressure not only via central and peripheral alpha2-receptors, but perhaps even more so by acting on central “imidazoline I1 receptors” in the brain stem. The molecular structure of these hypothetical “imidazoline I1 receptors” has not yet been identified. In order to test whether ligands with an imidazoline structure elicit pharmacological effects via alpha2-adrenergic receptors or via “imidazoline receptors”, mice were generated with a targeted deletion of all three alpha2-adrenergic receptor subtypes (alpha2ABC-KO). These alpha2ABC-KO mice were an ideal model in which to examine the pharmacological effects of the centrally acting antihypertensives clonidine, moxonidine and rilmenidine in the absence of alpha2-adrenergic receptors. As expected, sedative and analgesic actions of clonidine were completely absent in alpha2ABC-KO mice, confirming the sole role of alpha2-receptors in these properties of clonidine. Clonidine significantly lowered heart rate in anesthetized alpha2ABC-KO and wild-type mice by up to 150 beats/min. A similar bradycardic effect of clonidine was observed in isolated spontaneously beating right atria from alpha2ABC-KO mice. After treatment with the specific If inhibitor ZD 7288, clonidine was no longer able to lower spontaneous beating frequency, suggesting a common site of action. Furthermore, in HEK293 cells stably transfected with HCN2 and HCN4, it could be shown that clonidine inhibits the If current via blockade of pacemaker channels with similar affinity as in isolated alpha2ABC-KO and wild-type atria. This inhibition was demonstrated again in isolated sinoatrial node (SAN) cells from alpha2ABC-KO mice and was identical in potency and efficacy to clonidine inhibition observed in isolated wild-type SAN cells, confirming that inhibition of atrial HCN channels constitutes the alpha2-independent bradycardic action of clonidine. Direct inhibition of cardiac HCN pacemaker channels contributes to the bradycardic effects of clonidine in gene-targeted mice. Thus clonidine-like drugs represent novel structures for future HCN channel inhibitors.
The covalent linkage of the aryloxy-substituents through macrocyclisation was applied for the synthesis of perylene bisimide atropo-enantiomers. The synthesis of macrocyclic perylene bisimides was achieved by using a tetra(3-hydroxyphenoxy)-functionalized perylene bisimide with achiral 2,6-diisopropylphenyl as imide substituent through Williamson´s etherfication which could be realized for four different oligoethylene glycol bridging units. Two regioisomeric macrocycles, namely the diagonally bridged (1,7- and 6,12- linkage) and the laterally bridged (1,12- and 6,7-linkage) isomers, were obtained for each bridging unit. The structural assignment of the isolated regioisomeric macrocycles was unambiguously accomplished by X-ray analysis of two macrocycles and by 1H NMR spectroscopy for all isomers. The conformational influence of the aryloxy-substituents on the functional properties of this class of chromophores could be derived by comparison of the optical and electrochemical properties of all isolated macrocylces with those of an open-chained reference compound. It was shown that the aryloxy-substituents prefer a lateral conformation in solution. Furthermore, solvent dependent fluorescence studies indicated that a photoinduced electron transfer process is of importance for the fluorescence quenching of electron-rich aryloxy-substituted perylene bisimides. The resolution of the atropo-diastereomers of diagonally bridged macrocyclic perylene bisimides with chiral 2-(R)-octylamine as imide substituent and diethylene glycol bridging units could be accomplished by semi-preparative HPLC on a chiral column. The chiroptical properties of the isolated epimerically pure macrocycles were determined by CD spectroscopy. Based on the experimental CD spectra, the stereochemical assignment of the isolated epimers was accomplished by application of the excition chirality method and confirmed by quantum chemical calculation of the CD spectra. The synthetical concept was extended successfully to 1,7-diaryloxy-substituted perylene bisimides. The structure of the diagonally bridged macrocycle was unambiguously confirmed by X-ray analysis and NMR spectroscopy. The atropo-enantiomers of this macrocycle could be resolved by semi-preparative HPLC on a chiral column and the assignment of the absolute configuration was achieved by comparison of the CD spectra of the resolved enantiomers with those of epimerically pure bis(macrocycles) reported before. By comparison of the X-ray structures obtained for the racemic mixture as well as one enantiomer important information could be extracted for the formation of p-dimers of perylene bisimides. The dependence of the interconversion barrier on the bulkiness of the bay-substituents was investigated for four halogen-substituted perylene bisimides. The dynamic properties were investigated by temperature-dependent NMR spectroscopy and kinectic measurements using CD spectroscopy. By applying the concept of the “apparent overlap” a convincing linear relationship between the size of the substituents and the free enthalpy of activation could be derived. Furthermore, the resolution of the atropo-diastereomers or enantiomers of the tetrachloro and tetrabromo-substituted derivates was accomplished, whereupon especially the 1,6,7,12-tetrabromosubstituted perylene bisimide provided at room temperature stable enantiomers. Additionally, the derived structure-property relationship allows the design of conformationally stable perylene bisimide enantiomers by proper choice of the bay substituents. In order to utilize the reversibility of self-assembly for the quantitative formation of macrocyclic perylene bisimides, a tetrazinc porphyrin-functionalized perylene bisimide was synthesized. The self-assembly of the zinc porphyrin perylene bisimide bichromophoric building block and diazabicyclo-[2.2.2]-undecane into the desired 1:2 sandwich complex was investigated by UV/Vis and 1H NMR spectroscopy and the macrocyclic structure was unequivocally proven by diffusion-ordered NMR spectroscopy (DOSY NMR). Furthermore, the controlled deposition of these well-defined macrocycles on highly ordered pyrolitic graphite (HOPG) was demonstrated by atomic force microscopy (AFM) investigations. The alignment of a linear amino functionalised p-conjugated polymers upon addition of the bichromphoric tetrazinc porphyrin-perylene bisimide was investigated by UV/Vis spectroscopy and AFM measurement. The surface analysis by AFM investigations revealed that the bichromophoric system composed of perylene bisimide and zinc porphyrin is able to cross-link the linear p-conjugated polymer over a wide range of the graphite surface which provided a defined arrangement of three different functional p-systems.
Performance Evaluation of Efficient Resource Management Concepts for Next Generation IP Networks
(2007)
Next generation networks (NGNs) must integrate the services of current circuit-switched telephone networks and packet-switched data networks. This convergence towards a unified communication infrastructure necessitates from the high capital expenditures (CAPEX) and operational expenditures (OPEX) due to the coexistence of separate networks for voice and data. In the end, NGNs must offer the same services as these legacy networks and, therefore, they must provide a low-cost packet-switched solution with real-time transport capabilities for telephony and multimedia applications. In addition, NGNs must be fault-tolerant to guarantee user satisfaction and to support business-critical processes also in case of network failures. A key technology for the operation of NGNs is the Internet Protocol (IP) which evolved to a common and well accepted standard for networking in the Internet during the last 25 years. There are two basically different approaches to achieve QoS in IP networks. With capacity overprovisioning (CO), an IP network is equipped with sufficient bandwidth such that network congestion becomes very unlikely and QoS is maintained most of the time. The second option to achieve QoS in IP networks is admission control (AC). AC represents a network-inherent intelligence that admits real-time traffic flows to a single link or an entire network only if enough resources are available such that the requirements on packet loss and delay can be met. Otherwise, the request of a new flow is blocked. This work focuses on resource management and control mechanisms for NGNs, in particular on AC and associated bandwidth allocation methods. The first contribution consists of a new link-oriented AC method called experience-based admission control (EBAC) which is a hybrid approach dealing with the problems inherent to conventional AC mechanisms like parameter-based or measurement-based AC (PBAC/MBAC). PBAC provides good QoS but suffers from poor resource utilization and, vice versa, MBAC uses resources efficiently but is susceptible to QoS violations. Hence, EBAC aims at increasing the resource efficiency while maintaining the QoS which increases the revenues of ISPs and postpones their CAPEX for infrastructure upgrades. To show the advantages of EBAC, we first review today’s AC approaches and then develop the concept of EBAC. EBAC is a simple mechanism that safely overbooks the capacity of a single link to increase its resource utilization. We evaluate the performance of EBAC by its simulation under various traffic conditions. The second contribution concerns dynamic resource allocation in transport networks which implement a specific network admission control (NAC) architecture. In general, the performance of different NAC systems may be evaluated by conventional methods such as call blocking analysis which has often been applied in the context of multi-service asynchronous transfer mode (ATM) networks. However, to yield more practical results than abstract blocking probabilities, we propose a new method to compare different AC approaches by their respective bandwidth requirements. To present our new method for comparing different AC systems, we first give an overview of network resource management (NRM) in general. Then we present the concept of adaptive bandwidth allocation (ABA) in capacity tunnels and illustrate the analytical performance evaluation framework to compare different AC systems by their capacity requirements. Different network characteristics influence the performance of ABA. Therefore, the impact of various traffic demand models and tunnel implementations, and the influence of resilience requirements is investigated. In conclusion, the resources in NGNs must be exclusively dedicated to admitted traffic to guarantee QoS. For that purpose, robust and efficient concepts for NRM are required to control the requested bandwidth with regard to the available transmission capacity. Sophisticated AC will be a key function for NRM in NGNs and, therefore, efficient resource management concepts like experience-based admission control and adaptive bandwidth allocation for admission-controlled capacity tunnels, as presented in this work are appealing for NGN solutions.
Overlay networks establish logical connections between users on top of the physical network. While randomly connected overlay networks provide only a best effort service, a new generation of structured overlay systems based on Distributed Hash Tables (DHTs) was proposed by the research community. However, there is still a lack of understanding the performance of such DHTs. Additionally, those architectures are highly distributed and therefore appear as a black box to the operator. Yet an operator does not want to lose control over his system and needs to be able to continuously observe and examine its current state at runtime. This work addresses both problems and shows how the solutions can be combined into a more self-organizing overlay concept. At first, we evaluate the performance of structured overlay networks under different aspects and thereby illuminate in how far such architectures are able to support carrier-grade applications. Secondly, to enable operators to monitor and understand their deployed system in more detail, we introduce both active as well as passive methods to gather information about the current state of the overlay network.
Pathogenic relevance of autoantibodies to type XVII collagen from pemphigoid gestationis patients
(2007)
Pemphigoid gestationis (PG) and bullous pemphigoid (BP) are subepidermal autoimmune blistering diseases characterized by self-reactive T and B cells specific for the transmembrane hemidesmosomal protein type XVII collagen/BP180. Major T and B cell epitopes are located within the immunodominant 16th non-collagenous domain A (NC16A) of type XVII collagen. It has been suggested that pathogenically relevant autoantibodies also bind to this immunodominant region. The aim of this study was to map the epitopes targeted by blister-inducing human autoantibodies. For this purpose, we used an in vitro model of autoantibody-induced leucocyte-dependent dermal-epidermal separation. In contrast to the majority of patients with BP (7 of 10), preadsorption against a recombinant form of the NC16A region abolished the blister-inducing potential of autoantibodies from all PG patients tested (n=5). Using overlapping synthetic peptides, we demonstrate that PG autoantibodies bind to 2 defined epitopes within the NC16A region (aa 500-514 and aa 511-523). Preadsorption using an affinity matrix containing these two epitopes completely abolished dermal-epidermal separation induced by PG autoantibodies (in 8 of 9 patients). These findings provide new insights into the pathogenesis of pemphigoid diseases and should prove helpful for the development of an antigen-specific immunoadsorption therapy in PG.
In 2001 the 433 m deep Messel 2001 borehole was drilled in the centre of the Messel Pit, 25 km south of Frankfurt (Germany). Geoscientific results from this drilling clarified the origin of the circular-shaped basin as a maar-diatreme-structure. Recovered deposits consist of lacustrine sediments (0-240 m) and volcaniclastic rocks such as lapilli tuffs (240-373 m) as well as rocks of the underlying diatreme breccia (373 433 m). The lapilli tuffs, as main interest here, show little differentiation on a macro- and microscopic scale and appear as a massive and unsorted volcaniclastic body with dominating juvenile lapilli and accidental clasts mostly in the range of (sub)millimetres to centimetres in diameter. This study presents rock magnetic properties measured on core samples of the volcaniclastic units and explains the origin of downhole magnetic anomalies detected during the drilling project in 2001. Magnetic behaviour of the erupted material is related to fine-grained, Fe-rich (titano)-magnetites, which are dispersed within the juvenile lapilli. Temperature-dependent susceptibility experiments, isothermal remanent magnetisation and hysteresis investigations demonstrate similar ferrimagnetic properties throughout the volcaniclastic material, in terms of composition, coercivity and grain size (pseudo-single-domain particles) of the ferrimagnetic minerals. Thus, during emplacement of the erupted material, the ferrimagnetic minerals had the same remanence acquisition potential. However, demagnetisation experiments show different magnetic stability behaviour of the acquired natural remanent magnetisation (NRM). Heating experiments prove the acquisition of thermal remanent magnetisation (TRM) dominated by temperature effects which could have been occurred during eruption and deposition of volcanic material, forming the Messel maar-diatreme. It is assumed that the upper half of the lapilli tuffs was deposited at relatively low depositional temperatures (<300 °C), whereas the material of the lower half took advantage of higher temperatures (>>300 °C). To understand the rock magnetic character within the Messel maar-diatreme-facies, particle grain sizes, the degree of the relative fraction dominance and the shape of the juvenile fragments have been studied in more detail. Image analytical methods as well as major and trace element analyses on the juvenile fraction support the clear subdivision of the lapilli tuffs. These findings in combination with rockmagnetic data indicate a separation into a relatively hot, geochemically undifferentiated eruption phase and a colder, differentiated phase. A two-condition eruption stage at the end of the Messel volcanic activity is suggested. The juvenile particles account for the temperature evolution and heat conditions during deposition of the Messel tuffs and contribute to the origin of magnetic field anomalies. Based on gravity parameters and the results of magnetisation properties, the potential field 3D-model of the Messel subsurface explains the negative ground anomalies, calculates the mass and volume parameters of the drilled lithozones and shows the asymmetric appearance of the diatreme-structure.
The importance of olfactory versus contact cues for host plant recognition was investigated in the tortoise beetle Cassida canaliculata Laich. (Coleoptera: Chrysomelidae), which is strictly monophagous on meadow sage. The reaction of adult beetles to olfactory and contact host cues was tested using three bioassays (locomotion compensator, six-chamber-olfactometer, stem arena') to account for different behavioral contexts. Bioassay-guided fractionation of plant extracts was elaborated to characterize the nature of contact stimuli. The beetles were only slightly attracted to odors from small amounts of leaf material. However, when contact cues were provided additionally, the beetles showed strong preferences for samples of their host plant over controls. Bioassay-guided fractionation led to isolation of at least two non-polar contact stimuli acting in concert that are sufficient for host plant identification in C. canaliculata.
In a first part the bilayer Heisenberg Model and the 2D Kondo necklace model are studied. Both models exhibit a quantum phase transition between an ordered and disordered phase. The question is addressed to the coupling of a single doped hole to the critical fluctuations. A self-consistent Born approximation predicts that the doped hole couples to the magnons such that the quasiparticle residue vanishes at the quantum critical point. In this work the delicate question about the fate of the quasiparticle residue across the quantum phase transition is also tackled by means of large scale quantum Monte Carlo simulations. Furthermore the dynamics of a single hole doped in the magnetic background is investigated. In the second part an analysis of the spiral staircase Heisenberg ladder is presented. The ladder consists of two ferromagnetic coupled spin-1/2 chains, where the coupling within the second chain can be tuned by twisting the ladder. Within this model the crossover between an ungapped spin-1/2 system and a gapped spin-1 system can be studied. In this work the emphasis is on the opening of the spin gap with respect to the ferromagnetic rung coupling. It is shown that there are essential differences in the scaling behavior of the spin gap depending on the twist of the model. Moreover, by means of the string order parameter it is shown, that the system remains in the Haldane phase within the whole parameter range although the spin gap scales differently. The tools which are used for the analyses are mainly large scale quantum Monte Carlo methods, but also exact diagonalization techniques as well as mean field approaches.
The basic question which drove our whole work was to find a meaningful noncommutative gauge theory even for the time-like case ($\theta^{0 i} \neq 0$). In order to be able to tackle questions regarding unitarity, it is not sufficient to consider theories which include the noncommutative parameter only up to a finite order. The reason is that in order to investigate tree-level unitarity or the optical theorem in loops one has to know the behavior of the noncommutative theory for center-of-mass energies much greater than the noncommutative scale. Therefore an effective theory, that is by construction only valid up to the noncommutative scale, isn't sufficient for our purpose. Our model is based on two fundamental assumptions. The first assumption is given by the commutation relations \eqref{eq:ncalg}. This led to the Moyal-Weyl star-product \eqref{eq:astproduct2} which replaces all point-like products between two fields. The second assumption is to assume that the model built this way is not only invariant under the noncommutative gauge transformation but also under the commutative one. In order to obtain an action of such a model one has to replace the fields by their appropriate \swms. We chose the gauge fixed action \eqref{eq:actioncgf} as the fundamental action of our model. After having constructed the action of the NCQED including the {\swms} we were confronted with the problem of calculating the {\swms} to all orders in $\tMN$. By means of \cite{bbg} we could calculate the {\swms} order by order in the gauge field, where each order in the gauge field contains all orders in the noncommutative parameter (\cf chapter \ref{chapter:swms}). By comparing the maps with the result we obtained from an alternative ansatz \cite{bcpvz}, we realized that already the simplest {\swm} for the gauge field is not unique. In chapter \ref{chapter:ambiguities} we examined this ambiguity, which we could parametrised by an arbitrary function $\astf$. The next step was to derive the Feynman rules for our NCQED. One finds that the propagators remain unchanged so that the free theory is equal to the commutative QED. The fermion-fermion-photon vertex contains not only a phase factor coming from the Moyal-Weyl star-product but also two additional terms which have their origin in the \swms. Beside the 3-photon vertex which is already present in NCQED without {\swms} and which has also additional terms coming from the \swms, too, one has a contact vertex which couples two fermions with two photons. After having derived all the vertices we calculated the pair annihilation scattering process $e^+ e^- \rightarrow \gamma \gamma$ at Born level. By choosing the parameter $\kggg = 1$ (\cf section \ref{sec:represent}), we found that the amplitude of the pair annihilation process becomes equal to the amplitude of the NCQED without \swms. This means that, at least for this process, the NCQED excluding {\swms} is only a special case of NCQED including \swms. On the basis of the pair annihilation process, we afterwards investigated tree-level unitarity. In order to satisfy the tree-level unitarity we had to constrain the arbitrary function $\astf$. We found that the series expansion of $\astf$ has to start with unity. In addition, the even part of the function must not increase faster than $s^{-1/2} \log(s)$ for $s \rightarrow \infty$, whereas the odd part of the $\astf$-function can't be constrained, at least by the process we considered. By assuming these constrains for the $\astf$-function, we could show that tree-level unitarity is satisfied if one incorporates the uncertainties present in the energy and the momenta of the scattered particles, \ie the uncertainties of the center-of-mass energy and the scattering angles. This uncertainties are not exclusively present due to the finite experimental resolution. A delta-like center-of-mass energy as well as delta-like momenta are in general not possible because the scattered particles are never exact plane waves.
In physiological conditions platelets have a major role in maintaining haemostasis. Platelets prevent bleeding from wounds by distinguishing normal endothelial cells in vasculature from areas with lesions to which they adhere. Interaction of platelet agonists and their receptors is controlled by intracellular signaling molecules that regulate the activation state of platelets. Very important intracellular signaling molecules are cyclic nucleotides (cGMP and cAMP), both involved in inhibition of platelet activation. Formation of cGMP and cAMP in platelets is stimulated by endothelial-derived NO and prostacyclin (PGI2), which then mediate inhibition of platelets by activating protein kinase G (PKG) and protein kinase A (PKA). Recently, it has been suggested that reactive oxygen species (ROS) represent new modulators of cell signaling within different cell types. The work summarized here describes the involvement of platelet ROS production in platelet activation, the relation of NO/cGMP/PKG I pathway to ROS and to mitogen-activated protein kinases (MAP kinase) signaling, and the involvement of cyclic nucleotides in megakaryocyte and platelet development. Platelets activated with different agonists produce intracellular but not extracellular ROS by activation of NAD(P)H oxidase. In addition, ROS produced in platelets significantly affects αIIbβ3 integrin activation but not alpha/dense granule secretion and platelet shape change. Thrombin induced integrin αIIbβ3 activation is significantly decreased after pretreatment of platelets with NAD(P)H oxidase inhibitors and superoxide scavengers. These inhibitors also reduce platelet aggregation and thrombus formation on collagen under high shear and achieve their effects independently of the NO/cGMP pathway. ADP secreted from platelet dense granules with subsequent activation of P2Y12 receptors as well as thromboxane A2 release are found to be important upstream mediators of p38 MAP kinase activation by thrombin. However, p38 MAP kinase activation does not significantly contribute to calcium mobilization, P-selectin expression, αIIbβ3 integrin activation and aggregation of human platelets in response to thrombin. Finally, PKG activation does not stimulate, but rather inhibit, p38 and ERK MAP kinases in human platelets. Further study revealed that cyclic nucleotides not only inhibit platelet activation, but are also involved, albeit differentially, in megakaryocyte and platelet development. cAMP is engaged in haematopoietic stem cell differentiation to megakaryocytes, and cGMP has no impact on this process. While PKA is already present in stem cells, expression of proteins involved in cGMP signaling (soluble guanylyl cyclase, sGC; PKG) increases with maturation of megakaryocytes. In the final step of megakaryocyte maturation that includes release of platelets, cGMP and cAMP have mild but opposing effects: cGMP increases platelet production while cAMP decreases it indicating a finely regulated process that could depend on stimulus coming from adjacent endothelial cells of sinusoids in bone marrow. The results of this thesis contribute to a better understanding of platelet regulation and of the possible molecular mechanisms involved in megakaryocyte maturation in bone marrow vascular microenvironment.
During the last few years an increasing number of physiological processes in plants have been shown to be regulated by NO. NO plays important roles in growth and development, plant disease resistance, abiotic stress, and in above and underground plant organs. In recent years several enzymatic pathways and few non-enzymatic pathways were proposed for nitric oxide production in plants. The major goal of this work was to quantify NO production by plants and especially by roots, and to identify the enzymes responsible for NO production. As a major method, NO production by roots was followed through on-line measurement of NO emission into the gas phase by chemiluminescence (= direct chemiluminescence), and also by indirect chemiluminescence where trace amounts of oxidized products like NO2- and NO3- can be easily measured. Plants used were tobacco wild-type (N. tabacum cv Xanthi or cv Gatersleben), NR-free mutants grown on ammonium in order to prevent NR induction, plants grown on tungstate to inhibit synthesis of functional MoCo-enzymes, and a NO-overproducing nitrite reductase (NiR)-deficient transformant as well as barley, rice and pea. Induction of a hypersensitive response (HR) in tobacco leaves was achieved by using avirulent Pseudomonas syringae pv phaseolicola. At oxygen concentrations of <1%, even completely nitrate reductase (NR)-free root tissues reduced added nitrite to NO, indicating that in roots, NR was not the only source for nitrite-dependent NO formation. By contrast, NR-free leaf slices were not able to reduce nitrite to NO. Root NO formation was blocked by inhibitors of mitochondrial electron transport (Myxothiazol and SHAM), whereas NO formation by NR containing leaf slices was insensitive to the inhibitors. Consistent with that, mitochondria purified from roots, but not those from leaves, reduced nitrite to NO at the expense of NADH. The inhibitor studies suggest that, in root mitochondria, both terminal oxidases participate in NO formation, and they also suggest that even in NR-containing roots, a large part of the reduction of nitrite to NO was catalysed by mitochondria, and less by NR. The differential capacity of root and leaf mitochondria to reduce nitrite to NO appears to be common among higher plants, since it was observed with Arabidopsis, barley, pea, and tobacco. Nitrite and NADH consumption by mitochondria were also measured. Anaerobic, nitrite-dependent NO emission was exclusively associated with the membrane fraction, without participation of matrix components. It was also examined whether root mitochondria and mitochondrial membranes produce nitric oxide (NO) exclusively by reduction of nitrite or also via a nitric oxide synthase (NOS),- and to what extent direct NO measurements could be falsified by NO oxidation. In addition to chemiluminescence, Diaminofluoresceins (DAF) were used as an NO indicators for comparison. In air, mitochondria apparently produced no nitrite-dependent NO, and no NOS activity was detected by direct or indirect chemiluminescence. In contrast, with DAF-2 and DAR-4M an L-arginine-dependent fluorescence increase took place. However, the response of this apparent NOS activity to inhibitors, substrates and cofactors was untypical when compared with commercial iNOS and is considered an artefact. With iNOS, about 2/3 of the NO were oxidized to (nitrite + nitrate). Mitochondria also appear to consume NO without increasing oxidation to (nitrite+ nitrate). We therefore assume formation of NO to a volatile intermediate (eventually N2O3). It was recently shown that the hypersensitive response (HR) of tobacco triggered by the fungal elicitor cryptogein occurred independent of the presence or absence of nitrate reductase (NR). One conclusion was that NR-dependent NO formation played no role in the HR. Here we present evidence that the described scenario may be specific for cryptogein. Pseudomonas syringae pv. phaseolicola was infiltrated into tobacco leaves from WT plant and from the NiR-deficient NO-overproducing clone 271, grown either on nitrate or ammonium. Lesion development as well as bacterial growth and sugar concentrations in leaves and in the leaf apoplast was monitored. Lesion development was positively and bacterial growth was negatively correlated with nitrate nutrition and eventually with NO formation. Bacterial growth was positively correlated with ammonium nutrition and apoplastic sugar concentrations. Total (free and conjugated) SA content were always drastically increased by bacterial infection, but there was no clear correlation with NO production. In the presence of cryptogein, Pseudomonas growth was drastically reduced. This shows that the assumed interdependence of bacterial growth, NO production and the HR is complex and not unifactorial.
Aggression is a strikingly multi-faceted phenomenon occurring in vertebrates as well as in invertebrates. Despite its omnipresence, the neuronal basis of aggressive behaviours is yet barely understood. Many studies however, imply a role for biogenic amines in aggression. This PhD project aimed at contributing to the understanding of the neuronal correlates of aggression, with a main focus on the biogenic amine octopamine, using Drosophila melanogaster as the model system. In Drosophila, agonistic encounters of males and females are composed of a variety of both offensive and defensive components, some of which are displayed more often in one sex than in the other. To simplify analysis and to standardize evaluation, I chose to focus on a single indicator of aggression: the lunge, a striking feature unique to Drosophila male aggression. By evaluating the lunge I developed in cooperation with Andreas Eckart for the first time an automated, video-based analysis of Drosophila male aggression. The present software program gives the number of lunges for each fly in a certain time interval. In addition, it provides information such as the distance the fly walked and his size among others. In combination with a second software program that we developed, aggressive interactions between two male Drosophila melanogaster of a genotype of choice can now be registered either completely automatically or if preferred semi-automatically. Using these softwares, I demonstrate that (1) body size differences of 8% and higher influence the outcome of a fight in favour of the larger male; (2) walking activity alters lunge frequency with more lunges performed by more active pairs of males; (3) flies mutant for the white gene, one member of the ABC transporter family in Drosophila, are profoundly impaired in aggression, an effect that is partially due to reduced visual performance. (4) Either knocking-down white in various brain regions or chemically ablating the mushroom body located in the central brain by deleting its neuroblast precursors diminishes aggression, indicating that integrity of various neural circuits/brain regions is required for wild-type aggression to occur. Furthermore, I show that (5) flies lacking octopamine signalling but having altered tyramine signalling display hardly any lunge. A quantitative high-speed analysis revealed that lunge execution is almost indistinguishable from wild-type males. The results from the experiments in which octopamine levels and/or tyramine levels were restored suggest that an elaborate pattern of octopamine levels in time and space is required to enable flies to express wild-type aggressive behaviour.
This thesis deals with the isolation and structural elucidation of bioactive naphthylisoquinoline alkaloids and related analogs. The mode of action of the antiplasmodial activity exhibited by the naphthylisoquinoline alkaloids was explored and compared to that of the antimalarial drug chloroquine. Furthermore, the phase 1 and 2 metabolism of dioncophyllines A and C and dioncopeltine A were investigated. In detail the following results have been obtained: • From the leaves of the recently discovered East African liana A. tanzaniensis six naphthylisoquinoline alkaloids were isolated. • The leaves of a botanical yet undescribed Ancistrocladus species, collected by Prof. Dr. V. Mudogo in the Democratic Republic of Congo in the habitat Yeteto near the town Ikela, were analyzed for naphthylisoquinoline alkaloids for the first time. The isolation work led to the first identification of an N,C-coupled naphthyldihydroisoquinoline alkaloid; ancistrocladinium B. Phytochemical investigation of the roots of the Congolese Ancistrocladus species (habitat Yeteto), , afforded five new derivatives of known naphthylisoquinoline alkaloids, namely 5'-O-demethylhamatine, 5'-O-demethylhamatinine, 6-O-demethylancistroealaine A, 6,5'-O,O-didemethylancistroealaine A, and 5-epi-6-O-methylancistrobertsonine A, along with six known naphthylisoquinoline alkaloids. • The antiplasmodial activity guided purification of 60Co irradiated samples containing commercially available naphthylisoquinoline related substances, afforded the isolation of the irradiation products 3,4-dihydro-1-isoquinolinone, 3,4-dihydro-1-isoquinolineamine, and 1,2,3,4-tetrahydro-1,2-diazirino-isoquinoline. The compounds were found to be more active than the starting material, although only exhibiting weak antiplasmodial activity against P. falciparum. • The effect on the absorption spectrum of FPIX due to complex formation with the naphthylisoquinoline alkaloids dioncophyllines A and C, dioncopeltine A korupensamine A, and ancistrocladine was examined by a titration study. Job's plot analyses by UV-spectroscopy determined the stoichiometry for the complex formation of FPIX and naphthylisoquinoline alkaloids to be 2:1. Furthermore, the dissociation constants for the complexation with FPIX were determined for each of the naphthylisoquinoline alkaloids investigated. Dioncophylline C and dioncopeltine A were found to possess dissociation constants, which are comparable to the one reported for the antimalarial drug chloroquine. The ability of ESI to transfer noncovalent solution-phase assemblies intact into the gas phase, was conducted on solution mixtures of naphthylisoquinoline alkaloid and FPIX, as well as on mixtures of chloroquine and FPIX. The mass spectrometry analyses revealed several peaks, which corresponded to the complex formation of FPIX to the respective ligands investigated. The most interesting results obtained were the detection of peaks corresponding to the complex formation between a chelated dimer of FPIX and dioncophylline Cand of peaks corresponding to a double protonated tetramer of FPIX – consisting of two chelated -oxo dimers of FPIX – in complex formation with two molecules of chloroquine. • Two phase 1 metabolism products of dioncophylline A were identified. Coelution in combination with HPLC-MS/MS, NMR, and CD investigations assigned the major metabolic product as 5'-O-demethyldioncophylline A. The minor metabolic product was only present in small amounts, which disabled an unambiguous structural characterization of the compound. However, as deduced from the mass spectrometry analyses and exclusion of a possible metabolic oxidation product by coelution with authentic reference material, the metabolite should possess a 4-hydroxylated isoquinoline portion and is assumed to be represented by structure. Dioncophylline C and dioncopeltine A were found to be stable to phase 1 metabolism reactions caused by rat liver microsomes.
The present work deals with the synthesis and the investigation of the photophysical properties of covalently constructed calix[4]arene–perylene bisimide dye arrays containing various PBI units. The obtained conjugates are characterized with respect towards their application in a new, zigzag-type architecture of artificial light-harvesting systems. For this purpose, orange (core-unsubstituted), red (6,7,11,12-tert-butylphenoxy-functionalized) and green (1,7-pyrrolidino-substituted) perylene bisimide building blocks have been attached to the calix[4]arene scaffold. First, the monochromophoric reference systems have been studied, and second, the photophysical properties of a comprehensive series of newly synthesized, multichromophoric calix[4]arene–perylene bisimide conjugates showing efficient energy transfer processes between the individual dye subunits have been investigated. Furthermore, a series of bichromophoric compounds containing identical chromophoric units has been obtained. Towards this goal, a variety of spectroscopic techniques such as UV/vis absorption, steady state and time-resolved fluorescence emission, and femtosecond transient absorption spectroscopy as well as a spectrotemporal analysis of the obtained data has been applied. This work presents a new concept for an artificial light-harvesting system positioning the dye units by means of calix[4]arene spacers along a zigzag chain. The investigations start with the syntheses and optical properties of the monochromophoric building blocks and result in an elaborate study on the energy and electron transfer processes occurring after photoexcitation in a comprehensive series of multichromophoric calix[4]arene–perylene bisimide conjugates. Finally, the photophysical properties of a series of compounds containing each two identical PBI units are discussed.
In the context of this thesis, I investigated the molecular causes and functional consequences of genetic instability using a human inherited disease, Fanconi anemia. FA patients display a highly variable clinical phenotype, including congenital abnormalities, progressive bone marrow failure and a high cancer risk. The FA cellular phenotype is characterized by spontaneous and inducible chromosomal instability, and a typical S/G2 phase arrest after exposure to DNA-damaging agents. So far, 13 genes have been identified, whose biallelic (or, in the case of X-linked FANCB, hemizygous) mutations cause this multisystem disorder. The FA proteins interact in a multiprotein network, instrumental and essential in the cellular response to DNA damage. A more comprehensive summary of Fanconi anemia and its myriad clinical, cellular and molecular manifestations is provided in the introduction section of this thesis. The results of my experimental work are presented as published papers and manuscripts ready to be submitted. In the first publication, I investigated the connection between FA genes and bladder tumors. The question I tried to answer was whether a disruption of the FA/BRCA pathway may be a frequent and possibly causal event in bladder cancer, explaining the hypersensitivity of these cells to DNA-crosslinking agents. On the basis of my experimental data I arrived at the conclusion that disruption of the FA/BRCA pathway might be detrimental rather than advantageous for the majority tumor types by rendering them vulnerable towards DNA damaging agents and oxidative stress. The second publication deals with the gene coding for the core complex protein FANCE and tries to answer the question why FANCE is so rarely affected among FA-patients. The conclusion from these studies is that like FANCF, FANCE functions as a probable adaptor protein with a high tolerance towards amino acid substitutions which would explain the relative rareness of FA-E patients. I have also investigated the FANCL gene whose product functions as the catalytic subunit of the E3 ligase. The third publication addresses this issue by providing the first comprehensive description of genetic alterations and phenotypic manifestations in a series of three FA-L patients. The results of my study show that genetic alterations of FANCL are compatible with survival, these alterations may include large deletions such as so far common only in the FANCA gene, FA-L phenotypes can be mild to severe, and FANCL belongs to the group of FA genes that may undergo somatic reversion. The central protein of the FA/BRCA network, FANCD2, is the subject of the fourth publication presented in this thesis. Most importantly, we were able to show that there are no biallelic null mutations in FANCD2. Correspondingly, residual protein of both FANCD2-isotypes (FANCD2-S and FANCD2-L) was present in all available patient cell lines. This suggests that complete abrogation of the FANCD2 protein cannot be tolerated and causes early embryonic lethality. There are at least three FA proteins that are not required for the posttranslational modification of FANCD2. One of these proteins is the 5’-3’ helicase BRIP1 (BRCA1-interacting protein 1), a protein that interacts directly with the breast cancer susceptibility protein BRCA1. I participated in the identification of BRIP1 as the FA protein FANCJ. This discovery is described in the fifth publication of this thesis. The newly discovered protein BRIP1/FANCJ seems to act as one of the mediators of genomic maintenance downstream of FANCD2. Another protein identified downstream of FANCD2 is PALB2. PALB2 was originally discovered as “partner and localizer of BRCA2”. In a candidate gene approach we tested patients with early childhood cancers but without mutations in BRCA2 for mutations in PALB2 (publication 6). PALB2 was identified as a novel FA gene and designated FANCN. FA-N patients are very severely affected. The last publication included in my thesis describes the identification of the FA gene FANCI as the second monoubiquitinated member of the FA/BRCA pathway (publication 7). We identified biallelic mutations in KIAA1794 in four FA patients, thus proving the genuine FA-nature of this candidate sequence. The general discussion provides a synopsis of the results and conclusions of my work with the state of art of FA research.
The insulin receptor ortholog EmIR of the fox-tapeworm Echinococcus multilocularis displays significant structural homology to the human insulin receptor (HIR) and has been suggested to be involved in insulin sensing mechanisms of the parasite’s metacestode larval stage. In the present work, the effects of host insulin on Echinococcus metacestode vesicles and the proposed interaction between EmIR and mammalian insulin have been studied using biochemical and cell-biological approaches. Human insulin, exogenously added to in vitro cultivated parasite larvae, (i) significantly stimulated parasite survival and growth, (ii) induced DNA de novo synthesis in Echinococcus, (iii) affected overall protein phosphorylation in the parasite, and (iv) specifically induced the phosphorylation of the parasite’s Erk-like MAP kinase orthologue EmMPK1. These results clearly indicated that Echinococcus metacestode vesicles are able to sense exogenous host insulin which induces a mitogenic response. To investigate whether EmIR mediates these effects, anti-EmIR antibodies were produced and utilized in biochemical assays and immunohistochemical analyses. EmIR was shown to be expressed in the germinal layer of the parasite both on the surface of glycogen storing cells and undifferentiated germinal cells. Upon addition of exogenous insulin to metacestode vesicles, the phosphorylation of EmIR was significantly induced, an effect which was suppressed in the presence of specific inhibitors of insulin receptor-like tyrosine kinases. Furthermore, upon expression of EmIR/HIR receptor chimera containing the extracellular ligand binding domain of EmIR in HEK 293 cells, a specific autophosphorylation of the chimera could be induced through the addition of exogenous insulin. These results indicated the capability of EmIR to sense and to transmit host insulin signals to the Echinococcus signaling machinery. The importance of insulin signaling mechanisms for parasite survival and growth were underscored by in vitro cultivation experiments in which the addition of an inhibitor of insulin receptor tyrosine kinases led to vesicle degradation and death. Based on the above outlined molecular data on the interaction between EmIR and mammalian insulin, the parasite’s insulin receptor orthologue most probably mediates the insulin effects on parasite growth and is, therefore, a potential candidate factor for host-parasite communication via evolutionary conserved pathways. In a final set of experiments, signaling mechanisms that act downstream of EmIR have been analyzed. These studies revealed significant differences between insulin signaling in Echinococcus and the related cestode parasite Taenia solium. These differences could be associated with differences in the organo-tropism of both species.
The process of sex-determination can be better understood through examinations of developing organs and cells, which are involved in the formation of undifferentiated gonad. This mechanisms show in fish a broad variety, ranging from hermaphroditism to gonochorism and environmental to genetic sex determination. Hormones and abiotic factors such as temperature and pH can influence teleost development and reproductive traits. These factors are vulnerable to pollutants and climate changes. Therefore, it is important to examine gonad development and sex-determination/differentiation in teleost fish. Teleost fish are the largest known group of vertebrates with approximately 25,000 species and are used for such kind of examinations as model organisms. Recently, in Oryzias latipes (medaka), dmrt1bY (or dmy), a member of the Dmrt gene family, has been described as testis-determining gene. However, this gene is not the universal master sex-determining gene in teleost fish. Although dmrt1bY is present in the most closely related species of the genus, namely Oryzias curvinotous, it is absent from other Oryzias species, like Oryzias celebensis, and other fish. During my thesis, I studied gonad development in medaka and in the closely related species Oryzias celebensis. Germ cell specification in medaka seems to be dependent on maternally provided cytoplasmatic determinants, so called germ plasm. Nanos and vasa are such germ cell specific genes. In zebrafish they are asymmetrically localized in the early embryo. I have shown that nanos mRNA is evenly distributed in the early embryo of medaka. A similar pattern has been already described for the medaka vasa homolog, olvas. This suggests differences in PGC specification in zebrafish and medaka. Further, the vasa homolog was isolated and the expression pattern examined in O. celebensis. The results show that it can be used as a germ cell specific marker. Additionally, the primordial germ cell migration in O. celebensis was followed, which is similar to medaka PGC migration. Primordial germ cell migration in vertebrates is dependent on the chemokine stromal cell-derived factor 1 (Sdf-1). Medaka has two different sdf-1 genes, sdf-1a and sdf-1b. Both genes are expressed in the lateral plate mesoderm (LPM). During late embryonic development, I could show that sdf-1a is expressed in newly formed somites and not longer in the LPM. Sdf-1b expression persisted in the posterior part of the lateral plate mesoderm in the developing gonad. In terms of early and late functions, this suggests subfunctionalization of sdf-1a and sdf-1b. In “higher” vertebrates, genes that are involved in the process of gonad development have been studied in detail, e.g. Wt1, Sox9, and Amh. I have analyzed the expression pattern of wt1 and sox9 co-orthologs and amh. In both, the medaka and O. celebensis, wt1a transcripts were localized in the LPM and its expression was similar to sdf-1a gene expression in medaka. Wt1b expression was restricted to the developing pronephric region. During later embryonic development, wt1a is specifically expressed in the somatic cells of the gonad primordium in both sexes. This is the first time that in fish wt1 gene expression in developing gonads has been described. Therefore, this result suggests that wt1a is involved in the formation of the bipotential gonad. Furthermore, I have analyzed the gonad specific function of the wt1 co-orthologs in medaka. I could show that a conditional co-regulation mechanism between Wt1a and Wt1b ensures PGC maintenance and/or survival. The expression of sox9 genes in medaka and sox9b in O. celebensis were detected in the somatic cells of the gonad primordium of both sexes. Additionally, I have shown that amh and amhrII in medaka are expressed in somatic cells of the gonad primordium of both sexes. This suggests that sox9b, amh and amhrII are involved in gonad development and have specific functions in the adult gonad. In O. celebensis I could detect an expression of dmrt1 already six days after fertilization in half of the embryos, which is similar to the dmrt1bY expression in medaka. Whether the expression of dmrt1 is male specific in O. celebensis is currently under investigation. Altogether, the obtained results provide new insights into gene expression patterns during the processes of gonad development. Furthermore, no differences in the expression pattern of wt1a and sox9b during gonad development between the medaka and O. celebensis could be detected. This might indicate that the genetic mechanisms during gonad development are similar in both species.
NO has been described as an important component involved in the development of the hypersensitive reaction (Delledonne et.al., 1998). Furthermore, NO induces expression of a set of defence gene, such as PR-1, PAL1 and chalcone synthase (CHS), and accumulation of SA (Durner et al., 1998). In this study, transgenic plants with altered NO levels were used to study the role of NO in plant defence. Arabidopsis plants which, due to expression of a bacterial NO dioxygenase, exhibit lower levels of NO than wild-type plants, show several weakened defence response, including the oxidative burst and expression of phenylpropanoid pathway genes. By contrast, constitutive expression of a bacterial NO synthase in Arabisopsis results in increased levels of endogenous NO. However, these plants do not show constitutively activated defence responses, but suffer from increased susceptibility to various strains of P. syringae. This might indicate that a gradient in NO production rather than constitutive elevation of NO is necessary to trigger plant defence responses. Nevertheless, NO seems to be important for regulation of the oxidative state in plant cells. This function of NO is important during leaf senescence. The data of the present work indicate that NO acts as senescence-delaying factor during plant development. The molecular action of NO in plants and signalling cascades in which NO is involved as second messenger are still poorly understood. Experiments addressing the selective quantification of NO in intact plant tissue, the identification of NO-target proteins as well as the function of NO-modified biomolecules might help to understand the role of NO in plants. Non-host resistance consists of several layers of defence that include preformed compounds existing in plants before pathogen infection and induced defences which the plant activates after recognition of a pathogen. The role of inducible defences in preventing multiplication of non-adapted bacteria is not clear. Our experiments suggest that to restrict non-adapted bacterial growth, pre-formed antimicrobial compounds and an early inducible cell wall-based defence might play an important role in Arabidopsis leaves. Upon inoculation with non-adapted bacteria, we have observed early, TTSS-independent up-regulation of PAL1 and BCB, two lignin biosynthesis genes which might be involved in papilla formation or other kinds of cell wall fortification. Moreover, Arabidopsis pal1 knockout lines permit significantly higher survival of non-adapted bacteria in leaves than wild-type plants, suggesting a functional importance of PAL1 up-regulation. Although non-host bacteria, like host bacteria, induce accumulation of SA and PR gene expression in a TTSS-dependent manner, SA-dependent or JA/ET-dependent defences do not directly contribute to non-host resistance. Moreover, non-adapted bacteria activate similar defence signalling pathways as do host bacteria. However, because of varieties in effector protein composition between different non-adapted bacterial strains, the activated signalling pathways might also include different compounds. The Arabidopsis ecotype Ler 0 is more susceptible to a non-adapted strain of P. syringae than ecotype Col-0. Although differences in glucosinolate content and composition between those ecotypes exist, they are probably not a major reason for the observed difference in non-host resistance. To further understand the mechanisms underlying non-host resistance, the generation of double or triple mutants with deficits in both cell wall-based defences and SA-dependent signal cascades is necessary. Moreover, the study of genome polymorphism and composition of secondary metabolites between Ler-0 and Col-0 can shed new light into the mechanisms of non-host resistance against bacterial pathogens. Additionally, experiments addressing papilla formation and callose biosynthesis in Ler-0 and Col-0 could help to further elucidate bacterial non-host resistance. Our data indicate that localized contact of Arabidopsis leaves with non-adapted bacteria, type III secretion-defective P. syringae strains and bacterial pathogen-associated molecular patterns (PAMPs) induce systemic acquired resistance (SAR) at the whole plant level. This finding contrasts the general belief that an HR or other leaf necroses are required for SAR induction. The observed symptomless systemic response was abolished in all SAR-deficient mutants tested in this study, but was intact in the jar1 mutant, which is compromised in induction of ISR, indicating that non-host bacteria and PAMPs induce SAR in a mechanistically similar way than host bacteria. In addition, our data show that the extent of SA accumulation or PR gene expression induced at sites of virulent or avirulent P. syringae inoculation rather than the amount of tissue necroses or jasmonate accumulation determine the magnitude of SAR. The fact that systemic responses were also triggered after local treatment with type III secretion-defective P. syringae strains and bacterial PAMPs indicate that induction of SAR is TTSS-independent. Instead, recognition of general elicitors like flagellin and LPS play an important role in activation of the SAR process. To broaden the concept of PAMP-based SAR initiation, further general elicitors from bacteria and fungal pathogens should be tested for their capability to induce SAR. Screens for mutants with deficiency in SAR activation by individual PAMPs can help to identify new components involved in the SAR signalling cascade. Possible functions of PAMPs as mobile systemic signals should be tested in future experiments. By selection of candidate genes whose expression is up-regulated in Arabidopsis leaves infected with avirulent and virulent P. syringae and pathophysiological analyses of corresponding T-DNA knockout lines, FLAVIN-DEPENDENT MONOOXYGENASE1 (FMO1) was identified as a key SAR regulator. SAR triggered by P. syringae is completely abolished in fmo1 mutant plants, and pathogen-induced expression of FMO1 in systemic leaves is closely correlated with the capability of different Arabidopsis lines to develop SAR. According to our findings, we have proposed that the FMO1 acts in signal amplification in non-inoculated, systemic leaves to trigger SAR. Experimental verification of the postulated potential amplification cycle underlying SAR should be tested in future experiments. The generation of transgenic lines expressing FMO1::GFP will provide useful information about the cellular localization of the FMO1 protein. Moreover, a comparative metabolomic analysis using SAR-induced wild-type, fmo1 knockout and FMO1 overexpressing lines can be used to identify substrates and reaction products of the FMO1 monooxygenase. As the single yeast FMO (yFMO) provides oxidizing equivalents at the ER for correct protein folding, expression of FMO1 in yfmo mutant yeast combined with protein activity assays might indicate whether FMO1 exhibits functional similarities with yeast FMO, e.g. in assuring proper folding of ER-targeted proteins essential for SAR establishment. Identification of further genes involved in activation of systemic resistance and biochemical characterization of the corresponding proteins can help to understand the SAR process in more detail.
Inhibition of Nuclear Import of Calcineurin Prevents the Development of Myocardial Hypertrophy
(2007)
The Calcineurin/NFAT signaling cascade is a crucial transducer of cellular function. It has recently been emerged that in addition to the transcription factor NFAT, the phosphatase Calcineurin is also translocated to the nucleus. Our traditional understanding of Calcineurin activation via sustained high Ca2+-levels was also advanced by recent findings from this working group (AG Ritter), which showed that Calcineurin is activated by proteolysis of the C-terminal autoinhibitory domain. This leads to the constitutive activation and nuclear translocation of Calcineurin. Therefore, Calcineurin is not only responsible for dephosphorylating of NFAT in the cytosol thus enabling its nuclear import, its presence in the nucleus is also significant in ensuring the full transcriptional activity of NFAT. Formation of complexes between transcription factors and DNA regulates the transcriptional process. Therefore, the time that transcription factors remain nuclear is a major determinant of transcriptional activity. The movement of proteins over ~40 kDa into and out of the nucleus is governed by the nuclear pore complex (NPC). Transcription factors and enzymes that regulate the activity of these proteins are shuttled across the nuclear envelope by proteins that recognize nuclear localization signals (NLS) and nuclear export signals (NES) within the amino acid sequence of these transcription factors. In this study, the precise mechanisms of Calcineurin nuclear import and export were identified. Additionally to the nuclear localization sequence (NLS) and the nuclear export sequence (NES) within the sequence of Calcineurin, the respective nuclear cargo proteins, responsible for nuclear import, Importinβ1, and for nuclear export, CRM1, were identified. Inhibition of the Calcineurin/importin interaction by a competitive peptide, called Import Blocking Peptide (IBP), which mimicked the Calcineurin NLS, prevented nuclear entry of Calcineurin. A non-inhibitory control peptide showed no effect. Using this approach, it was able to prevent the development of myocardial hypertrophy. In Angiotensin II stimulated cardiomyocytes, both the transcriptional and the translational level was suppressed. Additionally, cell size and expression of Brain natriuretic peptide (as molecular marker for hypertrophy) were significantly reduced compared untreated controls. IBP worked dose-dependent, but did not affect the Calcineurin phosphatase activity. In conclusion, Calcineurin is not only capable of dephosphorylating NFAT, thus enabling its nuclear import, its presence in the nucleus is also important for full NFAT transcriptional activity. Using IBP to prevent the nuclear import of Calcineurin is a completely new approach to prevent the development of myocardial hypertrophy.
Infrared photodissociation spectroscopy of ionic hydrocarbons : microsolvation and protonation sites
(2007)
This work has presented a spectroscopic analysis of three types of hydrocarbon cations: two ionized aromatic hydrocarbons, two protonated aromatic hydrocarbons and the cation of a fundamental radical hydrocarbon. The experiments were centered on the proton stretch vibrations of mass-selected complexes of these systems and polar (H2O) and non polar (Ar, N2, CO2) ligands. The experiments have been done in a tandem mass spectrometer coupled with an electron impact ionization ion source; an OPO laser system was used as tunable IR light source. All the proposed dimer structures have been also modeled using quantum chemical calculations (QCC). These calculations have consistently been matched with the experimental results and have enabled clear identification of the spectral features observed. This has enabled the evaluation of thermochemical properties which could not be extracted directly from experiment. The experiments done on complexes of 1-Np+ and Im+ have allowed for the acidity of their various groups to be probed: the shifts in the frequency as well as the enhancement in the intensity of the OH and NH stretch vibrations resulting from the complexation have yielded dependences on both the species (L) and the number (n) of the ligands. OH bound 1-Np+···Ar has been detected for the first time, showing that the REMPI-IRPD method is severely limited with respect to the production of the most stable isomer of a given cationic complex. The detection of c-1-Np+···(N2)n corresponds to the first observation of c-1-Np+ complexes and enables thus direct comparison of both 1-Np+ rotamers. The shift of the NH vibration of Im+···N2(H) yielded the first experimental estimate for the PA of the imidazyl radical. It was also found that the most stable 1-Np+···Ar and Im+···Ar structures differ qualitatively from that of the corresponding neutral dimers (H-bound vs pi-bound), emphasizing the large impact of ionization on the interaction potential and the preferred recognition motif between acidic aromatic molecules (A) and nonpolar ligands. The IRPD spectra of 1-Np+···Ln and Im+···Ln yielded spectroscopic information about the CH, NH and OH stretch vibrations of bare 1-Np+ and Im+. The dependence of the shifts in the frequency of the OH and NH stretch vibrations allows for creating microsolvation models. The spectroscopic results obtained on size-selected 1-NpH+···Ln show that, in the output of the presently used ion source, three classes of 1-NpH+ isomers can be identified: oxonium ions (1-Np protonated at the O atom); carbenium ions obtained by protonation in the para and ortho positions with respect to the OH functional group; carbenium ions obtained by the addition of a proton to well-defined sites on the second naphthalene ring. The spectral identification of these three classes of protonation sites is supported by their different photofragmentation patterns. It was demonstrated that the spectroscopic monitoring of the microsolvation of ImH+ in Ar and N2 together with the QCCs paint a very detailed picture of the microsolvation process, evidencing clear differences between the microsolvation models as function of the PA of the ligands. Important differences have also been identified between the various binding sites, enabling the creation of a clear scale of priorities for occupation of the binding sites during microsolvation. The application of IRPD to the study of microhydrated ImH+ provided for the first time direct spectroscopic information on the properties of the N-H bonds of this biomolecular building block under controlled microhydration. It was demonstrated that, as protonation enhances the acidity of the NH groups, the ability for proton conductivity of ImH+ increases. A very important result is derived from the IRPD spectroscopy of C2H5+···L (L = Ar, N2, CO2, CH4) dimers. The equilibrium geometry of the C2H5+ has long been debated. Now, IRPD spectra were recorded over the range of the CH stretch fundamentals (covering possible sp3 and sp2 hybridization of C). Depending on the ligand species, the spectra are found to be dominated by the fingerprint of two largely different dimer geometries. Using the experimental C2H5+···Ar spectrum and the corresponding QCCs, the structure of the (weakly perturbed) C2H5+ was found to be the nonclassical one, with one proton straddling across the C=C bond of the H2C=CH2. On the other hand, ligands like N2 and CH4 are strongly influencing the geometry, as seen in the spectral signatures of the C2H5+···N2 and C2H5+···CH4, which correspond to the classical [H2CCH3]+. It was thus demonstrated that while the nonclassical C2H5+ is the global minimum on the PES of the free [C2,H5]+, the structure of the C2H5+ can be strongly influenced by the chemical properties of the environment.
B cells play diverse roles in the immunopathogensis of autoimmune diseases several approaches targeting B cell directly or indirectly are in clinical practice in the treatment of autoimmunity. In this regard, temporal B cell depletion by rituximab (anti CD20 antibody) is being appreciated and gaining more importance in recent years. To date, little is known about the regeneration profile of B cells following B cell depletion. We wanted to investigate the early replenishing B cells and examine the dynamic changes in the repertoire. we studied the immunoglobulin receptor (IgR) modulation of Ig-VH4 genes as representative of the heavy chain family. Five patients were included in the study and therapy induced alterations were assessed. Three time points namely before therapy, early regeneration phase (ERP- the early time point during regeneration where just above 1% B cells were found in the peripheral lymphocyte pool) and later regeneration phase (LRP- which commenced 2-3 months following ERP) were chosen. In three patients (A-C), Ig-VH4 genes were amplified from total genomic DNA during the above-mentioned all time points and in another two patients (D and E), Ig genes during ERP were studied by single cell amplification technique. Firstly, B cell regeneration followed the characteristic regeneration pattern as reported by several groups, with a predominant circulation of CD38hi expressing plasma cells and immature B cells in the ERP. During LRP, the proportion of these cells reduced relatively and the levels of naïve B cells rose gradually. On a molecular level, Ig-VH4 variable gene usage prior and post B cell depletion was determined and it was noticed that a diverse set of Ig-VH4 genes were employed in the repertoire before and after therapy. Mini gene segments such as VH4-34 and VH-4-39, which were reported to be connected with autoimmunity, were over expressed in the B cell repertoire before therapy. Profound changes were noticed in the early reemerging repertoire with a relatively increased population of intensely mutated B cells. These B cells acquired >=9 mutations in the Ig genes. Immunophenotyping with specific surface markers revealed that these highly mutated B cells evolve from the isotype-switched memory compartment especially the plasma cells. To support the hypothesis that the highly mutated B cells observed during ERP were plasma cells we carried out single cell amplification of individual plasma cells in another two patients during ERP and compared the mutational load, which remained similar. Actually plasma cells do not express CD20 on their surface and are not eliminated by rituximab therapy. However they were not observed in the peripheral blood following B cell depletion. The earliest time point when plasma cells are found again in peripheral circulation is the early recovery period (ERP). Therefore, it was intriguing to ascertain if the plasma cells were also modulated by rituximab therapy although they were not directly targeted by the therapy. We investigated if there is a therapy mediated mutational modulation of the plasma cells though these are not directly targeted by the therapy. We examined the confinement of mutations to the pre-defined RGYW/WRCY hotspot motifs (R=purine, Y=pyrimidine, W=A/T) in the plasma cells, which provides information on the involvement of T cells in B cell somatic hypermutation (SHM). Plasma cells before rituximab manifested the characteristics of active disease, which was revealed by restricted mutational targeting to the RGYW/WRCY motifs. The reemerging plasma cells during ERP had an increased targeting of the RGYW/WRCY motifs which indicated for a more pronounced T cell mediated B cell mutations which is the scenario observed in the healthy subjects. To further support the hypothesis of rituximab-mediated plasma cell modulation, we delineated the replacement to silent mutations ratio (R/S) in the hypervariable regions (CDRs) of the plasma cell Ig sequences. Within our study, the mean R/S ratio in the plasma cell CDRs of the patient group was relatively low (1.87) before rituximab treatment and interestingly this ratio increased significantly in the recirculating plasma cells to values of 2.67 and 3.60 in ERP and LRP status respectively. The increase in R/S ratios in reemerging plasma cells can be interpreted as a shaping of the Ig-repertoire by positive antigen selection as seen in healthy individuals. To conclude, our study demonstrates temporal B cell depletion by rituximab therapy seems to modulate also the plasma cell compartment, which is not directly targeted by the therapy. Modulation of plasma cells in RA could be also used as a potential biomarker in studying the effective response in RA treatment. This needs to be further explored to gain deeper insights into the underlying processes, which may be influenced by future therapies.
CYR61 and WISP3 belong to the family of CCN-proteins. These proteins are characterised by 10% cysteine residues whose positions are strictly conserved. The proteins are extracellular signalling molecules that can be associated with the extracellular matrix. CCN-proteins function in a cell- and tissue specific overlapping yet distinct manner. CCN-proteins are expressed and function in several cells and tissues of the musculoskeletal system. In this study the impact of the angiogenic inducer cysteine-rich protein 61 (CYR61/CCN1) on endothelial progenitor cells (EPCs) and mesenchymal stem cells (MSCs) as well as the wnt1 inducible signalling pathway protein 3 (WISP3/CCN6) on MSCs were elucidated. EPCs are promising cells to induce neovascularisation in ischemic regions as tissue engineered constructs. A major drawback is the small amount of cells that can be obtained from patients; therefore a stimulating factor to induce in vitro propagation of EPCs is urgently needed. In this study, mononuclear cells obtained from peripheral blood were treated with 0.5 µg/ml CYR61, resulting in an up to 7-fold increased cell number within one week compared to untreated control cells. To characterise if EPCs treated with CYR61 display altered or maintained EPC phenotype, the expression of the established markers CD34, CD133 and KDR as well as the uptake of acLDL and concurrent staining for ulex lectin was analysed. Both CYR61 treated and untreated control cells displayed EPCs characteristics, indicating that CYR61 treatment induces EPC number without altering their phenotype. Further studies revealed that the stimulating effect of CYR61 on EPCs is due to enhanced adhesion, rather than improved proliferation. Usage of mutated CYR61-proteins showed that the adhesive effect is mediated, at least partly, by the integrin α6β1, while the integrin αυβ3 has no influence. Endogenous expression of CYR61 was not detectable in EPCs, which indicated that control cells are not influenced by endogenous secretion of CYR61 and also could explain the dose-dependent effect of CYR61 that is measured at a low concentration of 0.05 µg/ml. MSCs were treated with 0.5 µg/ml CYR61, a combination of growth factors including VEGF, both together and compared to untreated control cells. Matrigel angiogenesis assay revealed an induction of angiogenesis, detected by induced sprouting of the cells, after CYR61 treatment of the MSC. Induced sprouting and vessel like structure formation after CYR61 treatment was similar to the results obtained after treatment with growth factors including the established angiogenesis inducer VEGF. This result clearly demonstrates the angiogenic potential of CYR61 on MSCs. Further studies revealed a migrative and proliferative effect of CYR61 on MSCs. Both properties are crucial for the induction of angiogenesis thus further strengthening the view of CYR61 as an angiogenic inducer. MSCs and EPCs are promising cells for tissue engineering applications in bone remodelling and reconstruction. MSCs due to their potential to differentiate into other lineages; EPCs induce neovascularisation within the construct. Both cell types respond to CYR61 treatment. Furthermore EPCs home to sides were CYR61 expression is detectable and both are induced by similar stimulators. Therefore CYR61 is a promising factor for tissue engineered bone reconstruction applications. WISP3 is expressed in cartilage in vivo and in chondrocytes in vitro. Loss of function mutations in the WISP3 gene are associated to the inherited human disease progressive pseudorheumatoid dysplasia (PPD), that is characterised by cartilage loss and bone and joint destruction. Since MSCs also express the protein, the aim of this study was to elucidate if recombinant protein targets MSCs. A migratory effect of WISP3 treatment on MSCs and osteogenic differentiated MSCs has been proven in this study. To elucidate if global gene expression patterns are influenced by WISP3, cells were treated with 0.5 µg/ml WISP3 and compared to untreated control MSCs. Gene expression study by using affymetrix technology revealed an induction of interferon inducible genes including CXCL chemokines and members of the TNFSF family. Reevaluation by RT-PCR on identical RNA and an additional time series confirmed the results. Although no established cartilage associated genes were detected as regulated genes within this 24h treatment, anti-angiogenic and immunosuppressive genes indicate a protective role of WISP3 for the cartilage, which is sensitive to inflammatory processes. Both CCN-proteins CYR61 and WISP3 are valuable for the musculoskeletal system. This and previous studies revealed the role of CYR61 for osteogenesis and angiogenesis of tissue engineered applications. WISP3 is responsible for development, protection and maintenance of cartilage. Therefore further studies with the proteins in the musculoskeletal system are of high relevance.
Transmissible spongiform encephalopathies (TSEs) or prion diseases are a group of infectious neurodegenerative diseases that are associated with misfolding of the cellular form of the cellular prion protein (PrPC) into a disease associated conformer (PrPSc). No therapy for prion diseases is available at present. So far, anti-PrPC vaccination is hampered by immunological tolerance of the mammalian immune system to endogenous PrPC. The aim of this thesis was to set up a new vaccination strategy based on virus-like particles (VLP) to induce anti-PrPC antibody responses in PrPC-competent mice. In a first step it was assessed whether VLP have the capacity to induce antibody responses that are protective against conventional pathogens. For this purpose, VLP displaying the vesicular stomatitis virus-gylcoprotein (VLP-VSV) were generated and tested for their immunogenicity. Similarly to live vesicular stomatitis virus (VSV), replication deficient VLP-VSV induced T help-independent VSV neutralizing IgM responses that switched to the IgG subclass in a T help-dependent manner. Furthermore, type I IFN receptor (IFNAR) triggering only marginally affected VLP-VSV induced neutralizing IgM responses, whereas it was critically required to promote the IgG switch. The analysis of conditional knockout mice with a lymphocyte-specific IFNAR deletion revealed that IFNAR triggering of lymphocytes did not play a crucial role, neither upon VLP-VSV nor VSV immunization. Collectively, these data verified the high immunogenicity of VLP. Therefore, in a next step VLP were generated displaying the C-terminal half of PrP (residues 121-231aa) fused to the platelet derived growth factor receptor (PDGFR) transmembrane region (VLP-PrPD111) for anti-PrPC immunization. On the surface of such retroparticles, PrPC was expressed at high levels as determined by electron microscopy. VLP-PrPD111 immunization of Prnp-deficient (Prnp0/0) mice resulted in antibody response specifically binding the cellular form of PrPC. Upon intravenous injection of wild-type mice, high PrPC-specific IgM responses were induced, whereas the T cell-dependent switch from the IgM to the IgG subclass was less pronounced. As a consequence, anti-PrPC titers were rather short-lived. The impaired subclass switch was probably related with host T cell tolerance to endogenous PrPC. Attempts to increase anti-PrPC IgG responses in wild-type mice via administration of VLP-PrPD111 emulsified in various different adjuvants failed. Nevertheless, in single individuals low IgG antibodies were induced after immunization of VLP-PrPD111 emulsified in CFA. To circumvent T cell tolerance in wild-type mice, a multitude of different immunization strategies was tested, including priming and boosting protocols with different types of VLP or VLP expressing PrPC together with foreign T helper epitopes. Overall, those efforts did not improve anti-PrPC IgG responses in wild-type mice. Interestingly, anti-PrPC antibodies induced in Prnp0/0 mice reduced PrPSc levels in prion infected cell cultures, whereas serum of vaccinated wild-type mice did not. To assess the protective capacity of VLP-PrPD111 induced immune responses, vaccinated wild-type mice were infected with scrapie (RML 5.0). Unfortunately, vaccinated mice did not show a significant delay in the onset of scrapie. In a last part of the thesis it was studied whether in the absence of T cell help activated “memory” B cells were able to produce anti-PrPC specific antibodies. To address this question, PrPC-specific memory B cells were sorted from vaccinated Prnp0/0 mice and adoptively transferred into wild-type recipient mice. Upon VLP-PrPD111 challenge, no PrPC-specific IgG titers were induced in the recipients. Nevertheless, several VLP-PrPD111 challenged recipient mice were protected against scrapie infection. In conclusion, VLP were characterized as highly immunogenic vaccines that were used to elucidate various questions concerning adaptive immune response and basic mechanisms of PrPC-specific tolerance vs. immunity. Remarkably, VLP-PrPD111 was able to induce native PrPC-specific antibodies in wild-type mice but major difficulties associated with PrPC-specific tolerance made efficacious scrapie vaccination impossible. New vaccination approaches are being tested to overcome these limitations.
The RS1 protein, a 67 kDa protein, encoded by an intronless single copy gene that was only detected in mammals, mediates transcriptional and post-transcriptional down-regulation of the sodium-D-glucose co-transporter SGLT1. The short-term post-transcriptional down-regulation of SGTL1 by RS1 has been shown to occur at the trans-Golgi network (TGN). In the present study, two tripeptides from the human RS1 protein (hRS1), GlnCysPro and GlnSerPro, that induce the post-transcriptional down-regulation of SGLT1 at the TGN, were identified. The application of the tripeptides led to 40-50% reduction of the amount of the SGLT1 protein in the plasma membrane, which correlated to the degree of decrease in SGLT1-mediated glucose transport. For the short-term down-regulation of SGLT1 by the tripeptides, the effective intracellular concentrations IC50 values of 2.0 nM (GlnCysPro, QCP) and 0.16 nM (GlnSerPro, QSP) were estimated. The observed down-regulation of SGLT1 by the tripeptides QCP and QSP, similar to hRS1 protein, was attenuated by different intracellular monosaccharides including nonmetabolized methyl-α-D-glucopyranoside and 2-deoxyglucose. On the contrary, the short-term inhibition of the hOCT2 by QCP could only be observed after rising of intracellular concentration of AMG. QCP and QSP are transported by H+-peptide cotransporter PEPT1 that is co-located with SGLT1 in the small intestinal enterocytes and thereafter effectively down-regulate hSGLT1-mediated transport of AMG. The data indicates that orally applied tripeptides QCP or QSP can be used to down-regulate D-glucose absorption in small intestine and used for treatment of obesity and diabetes mellitus.
Frustration has been investigated since the early beginnings of psychological research. Yet, it is still unclear how frustration influences the two main parameters of motivation, i.e., orientation (approach-avoidance) and intensity. Some theories propose that controllable frustration increases approach motivation, thereby maintaining motivational intensity. In contrast, other theories propose that the perception of obstacles immediately elicits an avoidance orientation because of the negative valence of the perceptual input. Yet, the latter theories can not explain how motivational intensity is maintained upon encountering obstacles. The aim of the present thesis is to integrate previous contradicting assumptions by describing the influence of frustration on motivational orientation and motivational intensity on the basis of a two-system model of behavior. The definition of frustration as an unexpected obstacle blocking the attainment of an anticipated gratification implies that the obstacle is immediately perceived, whereas the goal is only represented in working memory. According to two-system models, these two types of representations influence different levels of behavior regulation. Whereas spontaneous approach-avoidance tendencies are mainly determined by the valence of the perceptual input, decisions to engage effort to reach the goal are based on knowledge about goals and appraisals of controllability of obstacles. Supporting this theorizing, six experiments demonstrated that frustration immediately activates avoidance tendencies. This was true for frustration of approach goals as well as for frustration of avoidance goals. Furthermore, this effect did not depend on the type of frustration feedback, and was found when approach-avoidance tendencies were measured after completion of goal pursuit as well as while overcoming frustration. In addition, approaching obstacles impaired performance in a subsequent task, suggesting that approaching obstacles consumed cognitive resources. This further supports the assumption that obstacles immediately activate avoidance tendencies. Furthermore, dispositional action-state orientation, which has been previously shown to moderate automatic affective reactions, influenced approach-avoidance tendencies, indicating that affect mediates the impact of frustration on behavioral tendencies. Finally, manipulations of controllability of frustration did not influence spontaneous approach-avoidance tendencies, but measures of motivational intensity such as decisions to engage more effort as well as activation of goal-relevant behavioral schemata. In sum, these findings support the assumptions that immediately elicited motivational orientations are mainly a function of the valence of perceptual input, whereas behavior to reach the goal (i.e. motivational intensity) is regulated by working memory representations such as appraisals of goal expectancy. Motivational orientations may serve to prepare organisms for quick reactions to sudden, unexpected occurrences, whereas behavior regulation based on goal appraisals may provide stability and flexibility in long-term goal pursuit.
1. Host plant finding in walking herbivorous beetles is still poorly understood. Analysis of small-scale movement patterns under semi-natural conditions can be a useful tool to detect behavioural responses towards host plant cues. 2. In this study, the small-scale movement behaviour of the monophagous leaf beetle Cassida canaliculata Laich. (Coleoptera: Chrysomelidae) was studied in a semi-natural arena (r = 1 m). In three different settings, a host (Salvia pratensis L., Lamiales: Lamiaceae), a non-host (Rumex conglomeratus Murr., Caryophyllales: Polygonaceae), or no plant was presented in the centre of the arena. 3. The beetles showed no differences in the absolute movement variables, straightness and mean walking speed, between the three settings. However, the relative movement variables, mean distance to the centre and mean angular deviation from walking straight to the centre, were significantly smaller when a host plant was offered. Likewise, the angular deviation from walking straight to the centre tended to decline with decreasing distance from the centre. Finally, significantly more beetles were found on the host than on the non-host at the end of all the trials. 4. It is concluded that C. canaliculata is able to recognise its host plant from a distance. Whether olfactory or visual cues (or a combination of both) are used to find the host plant remains to be elucidated by further studies.
The steroid hormones corticosterone/cortisol and aldosterone are synthesized and secreted by the adrenal gland in response to stress or an altered salt-water balance. This is controlled by a negative feedback mechanism referred to as the HPA axis and the RAAS. Actions of these steroid hormones are mediated by the glucocorticoid receptor (GR) and the mineralocorticoid receptor (MR), which reside in the cytoplasm in a complex with heat-shock proteins. Both, the GR and the MR belong to the nuclear receptor superfamily and share a common protein structure consisting of three separate domains. However, they have different affinities for various ligands, their actions depend on hormone concentration, they are modulated by pre-receptor mechanisms such as the 11β-HSD2 and they are differently distributed in several tissues. Aldosterone acts via the MR in epithelial and in non-epithelial cells and regulates sodium-water homeostasis, cardiovascular function, neuronal excitability and adipocyte differentiation. So far the analysis of gene inactivation in vivo was limited to mice, but disease models in rats sometimes more closely reflect the situation encountered in humans. Since embryonic stem cells and thus gene targeting in rats is not available, we generated MR knock-down transgenic rats by lentiviral delivery of a shRNA. The F1 progeny of the founder rats showed a wide range of reduced MR mRNA and protein levels in kidney and hippocampus, the two major sites of MR expression. In contrast, expression of the highly homologous GR was unaltered, indicating specificity of gene inactivation. The two MR target genes, Sgk1 and ENaC, were up-regulated while the mRNA levels of other genes such as IK1 and SCD2 was reduced. Similar to the knock-out mice and human patients, the knock-down rats displayed typical signs of pseudohypoaldosteronism type I such as increased serum levels of aldosterone and renin as well as growth retardation. Importantly, we found a linear relationship between MR mRNA expression in kidney, serum aldosterone levels and body weight. Thus, our MR knock-down rats are amongst the first examples of RNAi in vivo and confirm that this technique allows to accomplish graded levels of gene inactivation that mimick human genetic diseases. Secondly, we investigated the role of the GR and the MR for the immunomodulatory activities of glucocorticoids (GCs) in peritoneal macrophages. GCs are involved in the modulation of macrophage function and thereby control the host’s immune responses to pathogens. Therefore, GCs are widely used for the treatment of inflammation and autoimmune diseases. However, concerning these GC activities neither the role of hormone concentration nor the differential contribution of the GR and the MR are known. At first we confirmed that both receptors but not 11β-HSD2 are expressed in peritoneal macrophages. Next, we showed that low levels of corticosterone enhance NO production as well as mRNA expression of pro-inflammatory cytokines, chemokines and enzymes required for mediator synthesis. In contrast, at high corticosterone concentrations macrophage function was strongly repressed. Importantly, inactivation of the GR by lentiviral delivery of siRNAs abrogated both the immunostimulatory and the immunosuppressive GC actions whereas inactivation of the MR had no effect. Furthermore, removal of endogenous GCs by adrenalectomy in vivo induced a pre-activated state in macrophages that could be modulated by corticosterone. We conclude that GCs exert distinct effects on macrophage function dependent on their concentration, and that they act through the GR despite concomitant expression of the MR. In summary, our results confirm that lentiviral delivery of shRNAs is an efficient means to down-regulation gene expression in primary cells and transgenic rats and thereby allows to perform functional studies on gene function that were previously limited to mice.
Interleukin-5 (IL-5) is a member of the hematopoietic class I cytokines and is specifically involved in eosinophil activation. IL-5 plays an important role in disease conditions such as allergic asthma and other hypereosinophilias, which are characterized by highly increased levels of eosinophils in peripheral blood and tissues. The IL-5 receptor is a heterodimer consisting of a binding alpha subunit (IL- 5Rα) and a common beta subunit (IL-5Rβ). This IL-5Rβ is shared with the IL-3 and GM-CSF receptors. The IL-5Rα is required for ligand-specific binding, whereas the association of the IL-5Rβ subunit triggers intracellular signal transduction. Previous studies have described the crystallographic structure of human IL-5 (hIL-5), as well as that of the common IL-5Rβ chain (IL-5Rβc) However, no experimental structural data are yet available for the interaction of the high-affinity IL-5 receptor IL-5Rα with its ligand IL-5. Therefore, this thesis had the principle objective to gain new insights into the basis of this important agonist-receptor interaction. In particular, data on the recombinant expression, purification and preparation of the binary complex of hIL-5 bound to the receptor ectodomain of hIL-5Rα are shown, as well as the subsequent crystal structure analysis of the binary ligand-receptor (hIL-5Rα/hIL-5) complex. Both proteins were expressed in an Escherichia coli expression system, purified to homogeneity, and crystallized. However, since the initial analysis of these crystals did not show any X-ray diffraction, each step of the preparation and crystallization procedure had to be stepwise optimized. Several improvements proved to be crucial for obtaining crystals suitable for structure analysis. A free cysteine residue in the N-terminal domain of the hIL-5Rα ectodomain protein was mutated to alanine to remove protein heterogeneity. In addition, hIL-5 affinity chromatography of the receptor protein proved to be absolutely crucial for crystal quality. Additive screening using the initial crystallization condition finally yielded crystals of the binary complex, which diffracted to 2.5Å resolution and were suitable for structure analysis. The preliminary structure data demonstrate a new receptor architecture for the IL-5Rα ligand-binding domain, which has no similarities to other cytokine class I receptor structures known so far. The complex structure demonstrates that the ligand-binding region of human IL-5Rα is dispersed over all three extracellular domains, and adopts a binding topology in which the cytokine recognition motif (CRM) needs the first Fn-III domain of the human IL-5Rα to bind the ligand. In a second project, a prokaryotic expression system for murine IL-5 (mIL-5) was established to allow the production of mIL-5 and mIL-5 antagonist that should facilitate functional studies in mice. Since the expression of mIL-5 in E. coli had never been successful so far, a fusion protein system was generated expressing high yields of mIL-5. Chemical cleavage with cyanogen bromide (CNBr) was used to release mIL-5 monomers, which were subsequently purified and refolded. This technique yielded an active murine IL-5 dimer as confirmed by TF-1 cell proliferation assays. The protein was crystallized and the structure of mIL-5 could be determined at 2.5Å resolution. The molecular structure revealed a symmetrical left-handed four helices bundle dimer similar to human IL-5. Analysis of the structure-/function relationship allowed us to design specific mIL-5 antagonist molecules, which are still under examination. Taken together, these findings provide further insights in the IL-5 and IL-5R interaction which may help to further understand and depict this and other cytokine-receptor interactions of similar architecture, e.g. the IL-13 ligand-receptor system. Ultimately, this may represent another piece of puzzle in the attempts to rationally design and engineer novel IL-5-related pharmacological therapeutics.
In this study, murine ES cells and DT40 B cells were used in parallel to disrupt the Nfatc1 gene and to study the function of individual 6 Nfatc1 isoforms, especially the function of highly inducible NFATc1/aA.We found that the short isoform NFATc1/aA protects DT40 B cells against apoptosis while the long isoform NFATc1/aC appears to enforce apoptosis. DNA microarray studies have shown that in NFATc1" DT40 B cells expressing ectopically human NFATc1/aA, the pkc-theta gene is several fold stronger expressed as in wild type cells. Our results of EMSA (Electrophoretic Mobility Shift Assays) and ChIP (chromatin immuno-precipitation) experiments demonstrated the binding of NFATc1/aA to the pkc-theta promoter in vitro and in vivo. NF-kappa B was also found to bind to the NFATc1 P1-promoter in vitro and in vivo. These data suggest and further prove that NF-kappa B contributes to the induction of the NFATc1 P1 promoter upon activation of T cells. So, NFATc1/aA and NF-kappa B were found to cross-talk in the transcriptional upregulation of their target genes, such as the IL-2 gene and the Nfatc1 gene itself, at multiple steps upon induction of apoptosis. While the pro-apoptotic mechanism of NFATc1s long isoform(s) remains unclear, its corresponding “death partners” are worth further studies. The elucidation of functional roles of NFATc1s short or long isoforms in the control of apoptosis of lymphocytes helps to understand apoptosis regulation, and thereby, the fate of lymphocytes.
Neural crest cells and sensory neurons are two prominent cell populations which are induced at the border between neural and non-neural ectoderm during early vertebrate development. The neural crest cells are multipotent and highly migratory precursors that give rise to face cartilage, peripheral neurons, glia cells, pigment cells and many other cell types unique to vertebrates. Sensory neurons are located dorsally in the neural tube and are essential for sensing and converting environmental stimuli into electrical motor reflexes. In my PhD thesis, I obtained novel insights into the complex processes of cell induction at the neural plate border by investigating the regulation and function of mdkb in zebrafish. First, it was possible to demonstrate that mdkb expression is spatiotemporally correlated with the induction of neural crest cells and primary sensory neurons at the neural plate border. Second, it became evident that the expression of mdkb is activated by known neural crest cell inducing signals, like Wnts, FGFs and RA, but that it is independent of Delta-Notch signals essential for lateral inhibition. Knockdown experiments showed that mdkb function is necessary for induction of neural crest cells and sensory neurons at the neural plate border, probably through determination of a common pool of progenitor cells during gastrulation. The present study also used the advantages of the zebrafish model system to investigate the in vivo function of all midkine gene family members during early brain development. In contrast to the situation in mouse, all three zebrafish genes show distinct expression patterns throughout CNS development. mdka, mdkb and ptn expression is detected in mostly non-overlapping patterns during embryonic brain development in the telencephalon, the mid-hindbrain boundary and the rhombencephalon. The possibility of simultaneously knocking down two or even three mRNAs by injection of morpholino mixtures allowed the investigation of functional redundancy of midkine factors during brain formation. Knockdown of Midkine proteins revealed characteristic defects in brain patterning indicating their association with the establishment of prominent signaling centers such as the mid-hindbrain boundary and rhombomere 4. Interestingly, combined knockdown of mdka, mdkb and ptn or single knockdown of ptn alone prevented correct formation of somites, either by interfering with the shifting of the somite maturation front or interferance with cell adhesion in the PSM. Thus, Ptn was identified as a novel secreted regulator of segmentation in zebrafish.
Spinal muscular atrophy with respiratory distress type 1 (SMARD1) is an autosomal recessive neuronal disorder in infants. The disease is marked by early onset of respiratory distress and predominantly distal muscle weakness, as consequences of diaphragmatic paralysis and progressive degeneration of  motor neurons in the spinal cord, respectively. Genetically, SMARD1 is caused by mutations in the single gene encoding Immunoglobulin µ-Binding Protein 2 (IGHMBP2). Despite the tissue specific degeneration observed in SMARD1 patients, the disease gene product IGHMBP2 is ubiquitously expressed in human and mouse tissues. Therefore, SMARD1 appears to be a motor neuron disease caused by the malfunction of a “housekeeping” protein, rather than a neuron specific factor. IGHMBP2 harbors an N-terminal DEXDc-type helicase/ATPase domain and has been classified as a member of the Superfamily 1 (SF1) of helicases. This protein has been assigned to various cellular activities such as DNA replication, pre-mRNA splicing and transcription. However its precise function in either process has remained elusive. The study presented here aimed at the enzymatic characterization of IGHMBP2, the identification of a specific cellular process to which IGHMBP2 is connected and the role of this factor in the pathophysiology of SMARD1. As a first step toward this end, a two-step purification strategy was established, which enabled the large-scale purification of properly folded and enzymatically active IGHMBP2. In vitro enzymatic studies using this recombinant protein defined IGHMBP2 as an ATP-dependent helicase that catalyzes unwinding of duplices composed of either DNA or RNA in a 5’→3’ direction. In contrast to previous reports, indirect immunofluorescence studies revealed a predominantly cytoplasmic localization of IGHMBP2. Size-fractionation studies and affinity-purification experiments further showed that IGHMBP2 is part of an RNase-sensitive macromolecular complex, which was identified as the ribosome. Interestingly, IGHMBP2 was abundantly detected in both subunits as well as to 80S ribosomes but only in small amounts in actively translating polysomes. These data strongly point to a role of IGHMBP2 in ribosomes-associated gene regulation control, such as in mRNA stabilization or mRNA translation. However, its precise function in those pathways remains to be identified. The biochemical and enzymatic characterization of IGHMBP2 allowed for the first time insights into the pathomechanism of SMARD1. SMARD1-causing pathogenic IGHMBP2 variants were investigated for their enzymatic activities and interaction with ribosomal subunits. Interestingly, among all missense mutations that have been tested thus far, none obstructs association with ribosomal subunits. However, these mutants exhibit specific defects in either the ATPase or RNA helicase activity or both. The data suggest that defects in the enzymatic activity of IGHMBP2 directly correlate with the pathogenesis of SMARD1. Furthermore, these data also raise the possibility that the disease SMARD1 is caused by alterations in the cellular translation machinery.
Henri J.M. Nouwen (1932-1996), a renowned pastoral theologian, has written more than 40 books among which several are about pastoral care and the spirituality of pastoral care. It was interesting for me to notice the parallel between his life and the contents of his books. He has undergone a tremendous personal development and spiritual maturity. His books invite all the christians and pastors to grow in the spiritual life. The spirituality is the underlying principle of creative ministry. Nouwen moves away from the traditional approach and concepts and develops his own concept of spiritual growth and pastoral care. Rooted in tradition and trained as a pastoral psychologist Nouwen is very appealing to the modern generation. This dissertation takes the reader through the life and writings of Nouwen to come to his original and new understanding of the spirituality of the pastoral care.
Albeit of high technological import, epitaxial self-assembly of CdSe/ZnSe QDs is non-trivial and still not clearly understood. The origin and attributes of these QDs are significantly different from those of their III-V and group-IV counterparts. For III-V and group-IV heterosystems, QD-formation is assigned to the Stranski Krastanow (SK) transition, wherein elastic relaxation of misfit strain leads to the formation of coherent three-dimensional (3D) islands, from a supercritically strained two-dimensional (2D) epilayer. Unfortunately, this phenomenon is inconspicuous for the CdSe/ZnSe heterosystem. Well-defined 3D islands are not readily formed in conventional molecular beam epitaxial (MBE) growth of CdSe on ZnSe. Consequently, several alternative approaches have been adopted to induce/enhance formation of QDs. This thesis systematically investigates three such alternative approaches, along with conventional MBE, with emphasis on the formation-mechanism of QDs, and optimization of their morphological and optical attributes. It is shown here that no distinct 3D islands are formed in MBE growth of CdSe on ZnSe. The surface of the CdSe layer represents a rough 2D layer, characterized by a dense array of shallow (<1nm) abutting mounds. In capped samples, the CdSe deposit forms an inhomogeneous CdZnSe quantum well (QW)-like structure. This ternary QW consists of local Cd-rich inclusions, which confine excitons three-dimensionally, and act as QDs. The density of such QDs is very high (~ 1012 cm-2). The QDs defined by the composition inhomogeneities of the CdZnSe QW presumably originate from the shallow mounds of the uncapped CdSe surface. By a technique wherein a CdSe layer is grown at a low temperature (TG = 230 °C) and subsequently annealed at a significantly higher temperature (TA =310 °C), tiny but distinct 3D islands are formed. In this work, the mechanism underlying the formation of these islands is reported. While the CdSe deposit forms a quasi-two-dimensional (quasi-2D) layer at TG = 230 °C, subsequent annealing at TA = 310 °C results in a thermally activated “up-climb” of adatoms onto two-dimensional clusters (or precursors) and concomitant nucleation of 3D islands. The areal density of QDs, achieved by this technique, is at least a decade lower than that typical for conventional MBE growth. It is demonstrated that further reduction is possible by delaying the temperature ramp-up to TA. In the second technique, formation of distinct islands is demonstrated by deposition of amorphous selenium (a-Se) onto a 2D CdSe epilayer at room temperature and its subsequent desorption at a higher temperature (TD = 230 °C). Albeit the self-assembled islands are large, they are severely truncated during subsequent capping with ZnSe, presumably due to segregation of Cd and Zn-alloying of the islands. The segregation phenomenon is analyzed in this work and correlated to the optical properties of the QDs. Additionally, very distinct vertical correlation of QDs in QD-superlattices, wherein the first QD-layer is grown by this technique and the subsequent ones by migration enhanced epitaxy (MEE), is reported. The process steps of the third variant technique, developed in course of this work, are very similar to those of the previous one-the only alteration being the substitution of selenium with tellurium as the cap-forming-material. This leads not only to large alteration of the morphological and optical attributes of the QDs, but also to formation of unique self-assembled island-patterns. Oriented dashes, straight and buckled chains of islands, and aligned island-pairs are formed, depending on the thickness of the Te-cap layer. The islands are partially alloyed with Te and emit luminescence at very low energies (down to 1.7 eV at room temperature). The Te cap layer undergoes (poly)crystallization during temperature ramp-up (from room temperature to TD) for desorption. Here, it is shown that the self-assembled patterns of the island-ensembles are determined by the pattern of the grain boundaries of the polycrystalline Te layer. Based on an understanding of the mechanism of pattern formation, a simple and “clean” method for controlled positioning of individual QDs and QD-based extended nanostructures, is proposed in this work. The studies carried out in the framework of this thesis provide not only a deeper insight into the microscopic processes governing the heteroepitaxial self-assembly of CdSe/ZnSe(001) QDs, but also concrete approaches to achieve, optimize, and control several technologically-important features of QD-ensembles. Reduction and control of QD-areal-density, pronounced vertical correlation of distinctly-defined QDs in QD-superlattices, and self-assembly of QD-based extended structures, as demonstrated in this work, might turn out to be beneficial for envisioned applications in information-, and communication-technologies.
Abiotic environmental stress, as evoked by short-term exposure of greenhousegrown plants to ambient ultraviolet radiation (UV), induces chemical and morphological adaptations of plants. Responses depend on the strength of stress and differ between species and tissues of variable age. In two Brassicaceae, Sinapis alba and Nasturtium officinale, stress responses towards short-term exposure to ambient radiation including or excluding UV reveal a high phenotypic plasticity, with strong differences their chemical composition compared to plants that remained in the greenhouse. The most pronounced defensive response against UV, the accumulation of flavonoid pigments, was strongest in young UV-exposed leaves, with an increase of the more effectice flavonol quercetin on the expense of less effectice kaempferol. Glucosinolates and myrosinase enzymes showed highly species-specific responses to UV-stress. Feeding behaviour and larval performance of the oligophagous Brassicaceae specialist, Phaedon cochleariae (Chrysomelidae; Coleoptera) were poorly affected by these differently UV-exposed host plants. Effects of plant stress on larval development were restricted to a minor variation in body mass due to variable food conversion of certain larval instars, which were compensated until pupation. Moreover, larval developmental times were unaffected by UV-exposure, but varied between species and leaves of different age. For P. cochleariae, this lack of variation in larval and pupal development towards UV-altered phytochemistry may suggest a strong genetic fixation of life history traits. In combination, the high plasticity towards variable food quality may correspond to the beetles’s specialisation on a narrow range of chemically highly variable host plants. Apart from being involved in plant defence against generalist herbivores, glucosinolates may also act as recognition cues and feeding stimulants for specialist insects. In earlier studies, glucosinolates were assumed to stimulate feeding by P. cochleariae, and they were suggested to be present on outermost leaf surfaces. However, since these findings were based on crude extraction methods, the presence of feeding stimulants in epicuticular waxes of Brassicaceae was re-investigated. In our study, glucosinolates were not detectable in mechanically removed waxes in Brassica napus and N. officinale, whereas substrate concentrations in solvent leaf extracts corresponded to densities and closure of leaf surface stomata. Therefore, glucosinolates that originate from the mesophyll may have been washed out through open stomata. Neither leaf waxes, nor leaf waxes combined with sinigrin or pure sinigrin evoked feeding. Moreover, in choice tests, these leaf beetles clearly preferred to feed on de-waxed surfaces. Finally, the presence of feeding stimulants in epicuticular waxes is highly unlikely considering the physico-chemical properties of the plant cuticle. The lack of stimulants on the outermost surface corresponds to the plant’s perspective, which should avoid easily accessible feeding stimulants. Nevertheless, the role of glucosinolates for feeding stimulation of P. cochleariae remained unclear. Therefore, S. alba leaf extracts of different polarities were tested in bioassays in order to identify which chemical leaf compounds act as stimulants. In bioassay-guided fractionations of methanol extracts by semi-preparative HPLC, two distinct fractions with stimulating activity were detected, whereas other fractions were not effective. Flavonoids were identified as main component in one stimulating fractions, the second fraction mainly contained glucosinolates, including sinalbin. The combination of both fractions was significantly more stimulating than each individual fraction, indicating additive effects of at least one compound of each fraction. However, since the combined fractions were less effective compared to the original extracts, other compounds may additionally be involved in the complex composition of leaf compounds acting as feeding stimulants for P. cochleariae. Finally, fractionated extracts of UV altered plants were used to test whether the strength of feeding responses depend on different ratios of glucosinolates and flavonoids. However, since the feeding behavior of this leaf beetle was not affected, such quantitative variations were concluded to be less important. The initiation of feeding behaviour may solely depend on the presence of stimulating compounds.
The aim of the present study was to design different dosage forms as carrier systems to deliver sorafenib to the lung of BXB-23 transgenic mice using different routes of administration. Three dosage forms were used one of them was an oil-in-water emulsion and the oral route was chosen for this experiment. The other delivery system was a liposome preparation for intratracheal instillation. In this case the oral route was considered as a control experiment. The last dosage form was PLGA microspheres. Before sorafenib administration it was important to develop a HPLC method to assess sorafenib absorption after its administration and to determine its concentrations in mouse serum. The HPLC method allowed sorafenib quantification in small volumes (30 µl) of mouse serum and tissues. The developed HPLC method was validated resulting in satisfactory selectivity, good linearity, good accuracy and precision over the concentration range examined. Sorafenib was successfully incorporated in a fat emulsion (o/w) using a traditional method resulting in a white homogenous emulsion and no particle aggregation was observed. Sorafenib exhibited antitumor activity on the lung adenoma in BXB-23 transgenic mice when administered orally (2 mg sorafenib per mouse) in the emulsion preparation. The determined effect was an approximately 29 % reduction in the tumor area of the adenoma foci and a proliferation reduction. In order to improve the pharmacological effects of sorafenib on the lung adenoma in BXB-23 mice, the targeting of sorafenib directly to the site of action (the lung) was an attractive concept. For this purpose the intratracheal route was used. Since sorafenib administration by instillation required incorporation of sorafenib in a dosage form suitable for its lipophilic nature, a liposome suspension was the second dosage form used. A lyophilization method was employed for sorafenib liposome preparation utilizing dilauroylphosphatidylcholine (DLPC) which is safe and tolerable for the lung. Incorporation of sorafenib in the liposomes did not influence the particle size and its distribution. The sorafenib liposomes showed high encapsulation efficiency, good stability at 4 °C for one month and satisfactory in vitro release properties and inhibited Raf-1 mediated activation of ERK in cell culture assay. In a pharmacokinetic experiment sorafenib loaded liposomes were instilled directly into the lung. The results revealed that a significant level of sorafenib was achieved in the lung tissues after 2 hours and then reduced after 48 h and remained nearly constant for one week. On the other hand, only traces of sorafenib were found in the mice serum up to 48 h. Subsequently, the pharmacological activity of sorafenib (1 mg per mouse) was studied when delivered in a liposomal suspension intratracheally to treat the lung adenoma of BXB-23 mice. The data of this experiment demonstrated that sorafenib intratracheal instillation resulted in a reduction of tumor area of adenoma foci (67 %) and an elevation of the percent of apoptotic cells. In contrast, prolongation of the treatment period did not further enhance sorafenib activity on the lung adenoma. This previous finding suggested a development of multidrug resistance (MDR) by the adenoma foci cells against sorafenib instillation, which was examined by immunohistochemistry staining. The percent of MDR positive cells was higher after two and three weeks sorafenib liposome instillation treatment than that after one week treatment. The last dosage form used for sorafenib was microspheres, which were prepared by emulsion-diffusion-evaporation method using biodegradable PLGA 50:50 resulting in a white lyophilized powder. The system was characterized physicochemically and revealed a good microspheres yield, high encapsulation efficiency, a homogenous particle size distribution and slow in vitro release of sorafenib. The other strategy studied in the present research project was gene delivery to target the lung bearing tumor of BXB-23 mice using a non-viral vector (polyethylenimine). Polyethylenimine (PEI) was used to investigate its efficiency in transfecting lung bearing tumor of BXB-23 mice model and its ability to transfect the adenoma foci cells. LacZ, which encodes Beta-galactosidase was used in the present study as a reporter gene and was complexed with PEI before delivered intravenously. A high LacZ expression in the alveolar region with some expression in the adenoma foci was observed. On contrary, a low LacZ expression in the alveoli and in the adenoma foci was achieved after instillation of the same polyplex intratracheally.
Cardiovascular disease is the major cause of mortality morbidity in both men and women in industrialized countries. The incidence of cardiovascular diseases in pre-menopausal women is lower compared to age-matched men but the risk of heart diseases increases dramatically after the onset of menopause.Therefore, it has been postulated that female sex hormones play an important role in cardiovascular health in pre-menopausal women. In contrast to clinical data, which failed to show positive estrogen effects on cardiovascular system of post- menopausal women, extensive experimental studies indicated cardioprotective effects of estrogens in laboratory animals. The majority of experimental estrogen substitution studies were performed with young individuals, thus the effects of ageing remain neglected and are poorly understood. The present project is the first attempt to study the cardiac effects of each estrogen receptor isoform (estrogen receptor alpha (ERa) and estrogen receptor beta (ERb)) in adult (“menopausal”) and senescent (“post- menopausal”) hypertensive rats. The female senescent spontaneously hypertensive rats (SHR) served as a model system for age- associated hypertension in females whereas young individuals were used for control experiments. Young and senescent SHR rats were treated with 17b- estradiol as well as new estrogen receptor isoform selective ligands 16a-LE2 (ERa agonist) and 8b-VE2 (ERb agonist). The results showed different functions of both estrogen receptor isoforms in cardiovascular system: ERa attenuated cardiac hypertrophy but not hypertension whereas ERb could significantly reduce both, blood pressure and cardiac hypertrophy. Surprisingly, both agonists and 17b- estradiol were effective in young animals but not in senescent SHR rats. These findings match with the clinical data and could be related to altered estrogen metabolism in senescent rats, since estrogen plasma levels did not increase to measurable extent in senescent animals receiving estrogen. Estrogen is metabolized by several 17b- hydroxysteroid dehydrogenase isoforms. In the current study, 17b- hydroxysteroid dehydrogenase type 10 (17b- HSD10) was identified as a novel protein- protein interaction partner of estrogen receptor alpha ligand binding domain (ERaLBD) in human heart. Cellular localization experiments of ERa in the cardiac myocytes showed nuclear and cytosolic localization pattern which overlapped partially with that of cardiac mitochondria. 17b-HSD10 is localized only in mitochondria. Direct interaction of both proteins was confirmed by pull- down experiments where 17b-HSD10 could be co-precipitated with ERa. Interestingly, protein interaction could be detected only under estrogen- free conditions whereas the presence of estrogen in the system blocked this interaction. Enzymatic assay which was developed in our laboratory, helped to define functional relevance of this interaction. The data obtained from enzymatic assays and protein- protein interaction studies strongly suggest that estrogen receptor could play an important role in the control of intracellular (or mitochondrial) estogen metabolism. The second potential ERa interaction partner in the heart- bladder cancer associated protein 10 (BLCAP10) - was initially identified in non- invasive bladder cancer cell lines. BLCAP10 protein expression in the heart as well as its localization pattern in cardiac myocytes is shown in the last part of the theses. Due to perinuclear localization similarity with ERb, we conclude that BLCAP10 could interact with ERb rather than with ERa. Poor BLCAP10 protein overexpression and toxicity in both, bacteria and eukaryotic cells, suggested that BLCAP10 could be involved in cell- cycle and/ or protein expression control. In summary, the results showed that isoform selective activation of estrogen receptors exert divergent effects in the cardiovascular system both by upregulation of aMHC expression or by lowering blood pressure. Hormones were effective in young animals but had only minor effects in senescent rats. The new ERa protein- protein interaction partners identified during the project provide new information about estrogen receptor function in the heart and its possible role in the regulation of estrogen homeostasis.
Directed cortical actin assembly is the driving force for intercellular adhesion. Vasodilator-stimulated phosphoprotein (VASP) participates in actin-fiber formation and VASP activity is regulated by phosphorylations. We screened for endothelial cell proteins, which bind to VASP dependent on its phosphorylation status. Differential proteomics identified αII-spectrin as novel VASP-interacting protein. αII-spectrin binds to the triple GP5-motif in VASP via its SH3 domain. cAMP-dependent protein kinase-mediated VASP phosphorylation at Ser157 inhibits αII-spectrin/VASP complex formation. VASP becomes dephosphorylated upon formation of cell-cell contacts and in confluent but not in sparse endothelial cells αII-spectrin colocalizes with non-phosphorylated VASP at cell-cell junctions. Ectopic expression of the αII-spectrin SH3 domain fused to claudin-5 translocates VASP to cell-cell contacts and is sufficient to initiate the formation of cortical actin cytoskeletons. αII-spectrin SH3 domain overexpression stabilizes cell-cell contacts and decreases endothelial permeability. Conversely, permeability of VASP-deficient endothelial cells is elevated. In a skin edema model, microvascular leakage is increased in VASP-deficient over wild-type mice. We propose that αII-spectrin/VASP complexes regulate cortical actin cytoskeleton assembly with implications for formation of endothelial cell-cell contacts and regulation of vascular permeability.
This work studies the convergence of trajectories of gradient-like systems. In the first part of this work continuous-time gradient-like systems are examined. Results on the convergence of integral curves of gradient systems to single points of Lojasiewicz and Kurdyka are extended to a class of gradient-like vector fields and gradient-like differential inclusions. In the second part of this work discrete-time gradient-like optimization methods on manifolds are studied. Methods for smooth and for nonsmooth optimization problems are considered. For these methods some convergence results are proven. Additionally the optimization methods for nonsmooth cost functions are applied to sphere packing problems on adjoint orbits.
Calculations of multi-particle processes at the one-loop level: precise predictions for the LHC
(2007)
The Standard Model (SM) of elementary particle physics provides a uniform framework for the description of three fundamental forces, the electromagnetic and weak forces, describing interactions between quarks and leptons, and the strong force, describing a much stronger interaction between the coloured quarks. Numerous experimental tests have been performed in the last thirty years, showing a spectacular agreement with the theoretical predictions of the Standard Model, even at the per mille level, therefore validating the model at the quantum level. An important cornerstone of the Standard Model is the Higgs mechanism, which provides a possible explanation of electroweak symmetry breaking, responsible for the masses of elementary fermions and the W and Z bosons, the carriers of the weak force. This mechanism predicts a scalar boson, the Higgs boson, which has escaped its discovery so far. If the Higgs mechanism is indeed realised in nature, the upcoming Large Hadron Collider (LHC) at CERN will be able to find the associated Higgs boson. The discovery of a Higgs boson by itself is not sufficient to establish the Higgs mechanism, the basic ingredient being the Higgs potential which predicts trilinear and quartic couplings. These have to be confirmed experimentally by the study of multi-Higgs production. We therefore present a calculation of the loop-induced processes gg to HH and gg to HHH, and investigate the observability of multi-Higgs boson production at the LHC in the Standard Model and beyond. While the SM cross sections are too small to allow observation at the LHC, we demonstrate that physics beyond the SM can lead to amplified, observable cross sections. Furthermore, the applicability of the heavy top quark approximation in two- and three-Higgs boson production is investigated. We conclude that multi-Higgs boson production at the SuperLHC is an interesting probe of Higgs sectors beyond the SM and warrants further study. Despite the great success of the SM, it is widely believed that this model cannot be valid for arbitrarily high energies. The LHC will probe the TeV scale and theoretical arguments indicate the appearance of physics beyond the SM at this scale. The search for new physics requires a precise understanding of the SM. Precise theoretical predictions are needed which match the accuracy of the experiments. For the LHC, most analyses require next-to-leading order (NLO) precision. Only then will we be able to reliably verify or falsify different models. At the LHC, many interesting signatures involve more than two particles in the final state. Precise theoretical predictions for such multi-leg processes are a highly nontrivial task and new efficient methods have to be applied. The calculation of the process PP to VV+jet at NLO is an important background process to Higgs production in association with a jet at the LHC. We compute the virtual corrections to this process which form the "bottleneck" for obtaining a complete NLO prediction. The resulting analytic expressions are generated with highly automated computer routines and translated into a flexible Fortran code, which can be employed in the computation of differential cross sections of phenomenological interest. The obtained results for the virtual corrections indicate that the QCD corrections are sizable and should be taken into account in experimental studies for the LHC.
Artificial light-harvesting (LH) systems have been obtained by self-assembly of naphthalene diimide-functionalized zinc chlorin dyads and triad in nonpolar, aprotic solvents. UV-vis, CD, and steady-state emission spectroscopy as well as atomic force microscopy showed that rod-like structures are formed by excitonic interactions of zinc chlorin units, while the appended naphthalene diimide dyes do not aggregate at the periphery of the cylinders. In all cases, photoexcitation of the enveloping naphthalene diimides at 540 and 620 nm, respectively, was followed by highly efficient energy-transfer processes to the inner zinc chlorin backbone, as revealed by time-resolved fluorescence spectroscopy on the picosecond time-scale. As a consequence, the LH efficiencies of zinc chlorin rod aggregates were increased by up to 63%. The effective utilization of solar energy recommends these biomimetic systems for an application in electronic materials on the nanoscale.
Background: The frequency of the most observed cancer, Non Hodgkin Lymphoma (NHL), is further rising. Diffuse large B-cell lymphoma (DLBCL) is the most common of the NHLs. There are two subgroups of DLBCL with different gene expression patterns: ABC (“Activated B-like DLBCL”) and GCB (“Germinal Center B-like DLBCL”). Without therapy the patients often die within a few months, the ABC type exhibits the more aggressive behaviour. A further B-cell lymphoma is the Mantle cell lymphoma (MCL). It is rare and shows very poor prognosis. There is no cure yet. Methods: In this project these B-cell lymphomas were examined with methods from bioinformatics, to find new characteristics or undiscovered events on the molecular level. This would improve understanding and therapy of lymphomas. For this purpose we used survival, gene expression and comparative genomic hybridization (CGH) data. In some clinical studies, you get large data sets, from which one can reveal yet unknown trends. Results (MCL): The published proliferation signature correlates directly with survival. Exploratory analyses of gene expression and CGH data of MCL samples (n=71) revealed a valid grouping according to the median of the proliferation signature values. The second axis of correspondence analysis distinguishes between good and bad prognosis. Statistical testing (moderate t-test, Wilcoxon rank-sum test) showed differences in the cell cycle and delivered a network of kinases, which are responsible for the difference between good and bad prognosis. A set of seven genes (CENPE, CDC20, HPRT1, CDC2, BIRC5, ASPM, IGF2BP3) predicted, similarly well, survival patterns as proliferation signature with 20 genes. Furthermore, some bands could be associated with prognosis in the explorative analysis (chromosome 9: 9p24, 9p23, 9p22, 9p21, 9q33 and 9q34). Results (DLBCL): New normalization of gene expression data of DLBCL patients revealed better separation of risk groups by the 2002 published signature based predictor. We could achieve, similarly well, a separation with six genes. Exploratory analysis of gene expression data could confirm the subgroups ABC and GCB. We recognized a clear difference in early and late cell cycle stages of cell cycle genes, which can separate ABC and GCB. Classical lymphoma and best separating genes form a network, which can classify and explain the ABC and GCB groups. Together with gene sets which identify ABC and GCB we get a network, which can classify and explain the ABC and GCB groups (ASB13, BCL2, BCL6, BCL7A, CCND2, COL3A1, CTGF, FN1, FOXP1, IGHM, IRF4, LMO2, LRMP, MAPK10, MME, MYBL1, NEIL1 and SH3BP5; Altogether these findings are useful for diagnosis, prognosis and therapy (cytostatic drugs).
Ferromagnetic semiconductors (FS) promise the integration of magnetic memory functionalities and semiconductor information processing into the same material system. The prototypical FS (Ga,Mn)As has become the focus of semiconductor spintronics research over the past years. The spin-orbit mediated coupling of magnetic and semiconductor properties in this material gives rise to many novel transport-related phenomena which can be harnessed for device applications. In this thesis we address challenges faced in the development of an all-semiconductor memory architecture. A starting point for information storage in FS is the knowledge of their detailed magnetic anisotropy. The first part of this thesis concentrates on the investigation of the magnetization behaviour in compressively strained (Ga,Mn)As by electrical means. The angle between current and magnetization is monitored in magnetoresistance(MR) measurements along many in-plane directions using the Anisotropic MR(AMR) or Planar Hall effect(PHE). It is shown, that a full angular set of such measurements displayed in a color coded resistance polar plot can be used to identify and quantitatively determine the symmetry components of the magnetic anisotropy of (Ga,Mn)As at 4 K. We compile such "anisotropy fingerprints" for many (Ga,Mn)As layers from Wuerzburg and other laboratories and find the presence of three symmetry terms in all layers. The biaxial anisotropy term with easy axes along the [100] and [010] crystal direction dominates the magnetic behaviour. An additional uniaxial term with an anisotropy constant of ~10% of the biaxial one has its easy axis along either of the two <110> directions. A second contribution of uniaxial symmetry with easy axis along one of the biaxial easy axes has a strength of only ~1% of the biaxial anisotropy and is therefore barely visible in standard SQUID measurements. An all-electrical writing scheme would be desirable for commercialization. We report on a current assisted magnetization manipulation experiment in a lateral (Ga,Mn)As nanodevice at 4 K (far below Tc). Reading out the large resistance signal from DW that are confined in nanoconstrictions, we demonstrate the current assisted magnetization switching of a small central island through a hole mediated spin transfer from the adjacent leads. One possible non-perturbative read-out scheme for FS memory devices could be the recently discovered Tunneling Anisotropic MagnetoResistance (TAMR) effect. Here we clarify the origin of the large amplification of the TAMR amplitude in a device with an epitaxial GaAs tunnel barrier at low temperatures. We prove with the help of density of states spectroscopy that a thin (Ga,Mn)As injector layer undergoes a metal insulator transition upon a change of the magnetization direction in the layer plane. The two states can be distinguished by their typical power law behaviour in the measured conductance vs voltage tunneling spectra. While all hereto demonstrated (Ga,Mn)As devices inherited their anisotropic magnetic properties from their parent FS layer, more sophisticated FS architectures will require locally defined FS elements of different magnetic anisotropy on the same wafer. We show that shape anisotropy is not applicable in FS because of their low volume magnetization. We present a method to lithographically engineer the magnetic anisotropy of (Ga,Mn)As by submicron patterning. Anisotropic strain relaxation in submicron bar structures (nanobars) and the related deformation of the crystal lattice introduce a new uniaxial anisotropy term in the energy equation. We demonstrate by both SQUID and transport investigations that this lithographically induced uniaxial anisotropy overwrites the intrinsic biaxial anisotropy at all temperatures up to Tc. The final section of the thesis combines all the above into a novel device scheme. We use anisotropy engineering to fabricate two orthogonal, magnetically uniaxial, nanobars which are electrically connected through a constriction. We find that the constriction resistance depends on the relative orientation of the nanobar magnetizations, which can be written by an in-plane magnetic field. This effect can be explained with the AMR effect in connection with the field line patterns in the respective states. The device offers a novel non-volatile information storage scheme and a corresponding non-perturbative read-out method. The read out signal is shown to increase drastically in samples with partly depleted constriction region. This could be shown to originate in a magnetization direction driven metal insulator transition of the material in the constriction region.
The live sciences currently undergo a paradigm shift to computer aided discoveries. Discoveries in the live sciences were historically made by either direct observation or as a result of chemical assays. Today we see a growing shift toward computer aided analysis and visualization. This gradual process happens in microscopy. Multidimensional laser scanning microscopy can acquire very complex multichannel data from fixed or live specimen. New probes such as visible fluorescent proteins let us observe the expression of genes and track protein localization. Ion sensitive dyes change intensity with the concentration of ions in the cell. The laser scanning confocal allows us to record these processes in three dimensions over time. This work demonstrates the application of software analysis to multidimensional microscopy data. We introduce methods for volume investigation, ion flux analysis and molecular modeling. The visualization methods are based on a multidimensional data model to accommodate complex datasets. The software uses vector processing and multiple processors to accelerate volume rendering and achieve interactive rendering. The algorithms are based on human visual perception and allow the observer a wide range of mixed render modes. The software was used to reconstruct the pituitary development in zebrafish and observe the degeneration of neurons after injury in a mouse model. Calicum indicator dyes have long been used to study calcium fluxes. We optimized the imaging method to minimize impact on the cell. Live cells were imaged continuously for 45 minutes and subjected to increasing does of a drug. We correlated the amplitude of calcium oscillations to increasing doses of a drug and obtain single cell dose response curves. Because this method is very sensitive and measures single cell responses it has potential in drug discovery and characterization. Microtubules form a dynamic cytoskeleton, which is responsible for cell shape, intracellular transport and has an integral role in mitosis. A hallmark of microtubule organization is lateral interactions. Microtubules are bundles by proteins into dense structures. To estimate the contribution of this bundling process, we created a fractal model of microtubule organization. This model demonstrates that morphology of complex microtubule arrays can be explained by bundling alone. In summary we showed that advances in software for visualization, data analysis and modeling lead to new discoveries.
Caterpillars of the butterfly Maculinea rebeli develop as parasites inside ant colonies. In intensively studied French populations, about 25% of caterpillars mature within 1 year (fast-developing larvae [FDL]) and the others after 2 years (slow-developing larvae [SDL]); all available evidence indicates that this ratio is under the control of egg-laying females. We present an analytical model to predict the evolutionarily stable fraction of FDL (pESS). The model accounts for added winter mortality of SDL, general and kin competition among caterpillars, a competitive advantage of SDL over newly entering FDL (priority effect), and the avoidance of renewed infection of ant nests by butterflies in the coming season (segregation). We come to the following conclusions: (1) all factors listed above can promote the evolution of delayed development; (2) kin competition and segregation stabilize pESS near 0.5; and (3) a priority effect is the only mechanism potentially selecting for. However, given the empirical data, pESS is predicted to fall closer to 0.5 than to the 0.25 that has been observed. In this particular system, bet hedging cannot explain why more than 50% of larvae postpone growth. Presumably, other fitness benefits for SDL, for example, higher fertility or longevity, also contribute to the evolution of delayed development. The model presented here may be of general applicability for systems where maturing individuals compete in small subgroups.
A torsion free abelian group of finite rank is called almost completely decomposable if it has a completely decomposable subgroup of finite index. A p-local, p-reduced almost completely decomposable group of type (1,2) is briefly called a (1,2)-group. Almost completely decomposable groups can be represented by matrices over the ring Z/hZ, where h is the exponent of the regulator quotient. This particular choice of representation allows for a better investigation of the decomposability of the group. Arnold and Dugas showed in several of their works that (1,2)-groups with regulator quotient of exponent at least p^7 allow infinitely many isomorphism types of indecomposable groups. It is not known if the exponent 7 is minimal. In this dissertation, this problem is addressed.
Adaptive Polarization Pulse Shaping and Modeling of Light-Matter Interactions with Neural Networks
(2007)
The technique of ultrafast polarization shaping is applied to a model quantum system, the potassium dimer. The polarization dependence of the multiphoton ionization dynamics in this molecule is first investigated in pump–probe experiments, and it is then more generally addressed and exploited in an adaptive quantum control experiment utilizing near–IR polarization–shaped laser pulses. The extension of these polarization shaping techniques to the UV spectral range is presented, and methods for the generation and characterization of polarization–shaped laser pulses in the UV are introduced. Systematic scans of double–pulse sequences are introduced for the investigation and interpretation of control mechanisms. This concept is first introduced and illustrated for an optical demonstration experiment, and it is then applied for the analysis of the intrapulse dumping mechanism that is observed in the excitation of a large dye molecule in solution with ultrashort laser pulses. Shaped laser pulses are employed as a means for obtaining copious amounts of data on light–matter interactions. Neural networks are introduced as a novel tool for generating computer–based models for these interactions from the accumulated data. The viability of this approach is first tested for second harmonic generation (SHG) and molecular fluorescence processes. Neural networks are then utilized for modeling the far more complex coherent strong–field dynamics of potassium atoms.
Background: According to the classical model of Macevicz and Oster, annual eusocial insects should show a clear dichotomous "bang-bang" strategy of resource allocation; colony fitness is maximised when a period of pure colony growth (exclusive production of workers) is followed by a single reproductive period characterised by the exclusive production of sexuals. However, in several species graded investment strategies with a simultaneous production of workers and sexuals have been observed. Such deviations from the "bang-bang" strategy are usually interpreted as an adaptive (bet-hedging) response to environmental fluctuations such as variation in season length or food availability. To generate predictions about the optimal investment pattern of insect colonies in fluctuating environments, we slightly modified Macevicz and Oster's classical model of annual colony dynamics and used a dynamic programming approach nested into a recurrence procedure for the solution of the stochastic optimal control problem. Results: 1) The optimal switching time between pure colony growth and the exclusive production of sexuals decreases with increasing environmental variance. 2) Yet, for reasonable levels of environmental fluctuations no deviation from the typical bang-bang strategy is predicted. 3) Model calculations for the halictid bee Lasioglossum malachurum reveal that bet-hedging is not likely to be the reason for the graded allocation into sexuals versus workers observed in this species. 4) When environmental variance reaches a critical level our model predicts an abrupt change from dichotomous behaviour to graded allocation strategies, but the transition between colony growth and production of sexuals is not necessarily monotonic. Both, the critical level of environmental variance as well as the characteristic pattern of resource allocation strongly depend on the type of function used to describe environmental fluctuations. Conclusion: Up to now bet-hedging as an evolutionary response to variation in season length has been the main argument to explain field observations of graded resource allocation in annual eusocial insect species. However, our model shows that the effect of moderate fluctuations of environmental conditions does not select for deviation from the classical bang-bang strategy and that the evolution of graded allocation strategies can be triggered only by extreme fluctuations. Detailed quantitative observations on resource allocation in eusocial insects are needed to analyse the relevance of alternative explanations, e.g. logistic colony growth or reproductive conflict between queen and workers, for the evolution of graded allocation strategies.
- 77/83 allerdings inaktiv in Kulturen und Embryonen von Medaka. Dieser Unterschied wird durch Daten aus humanen ES-Zellkulturen unterstützt. Letztere sind ebenfalls komplett STAT3 unabhängig. Die BMP-Smad Kaskade wiederum ist in Medaka-Stammzellen aktiv, Antidifferenzierungsgene wie id2, die durch BMP direkt kontrolliert werden, sind dementsprechend exprimiert. Diese Daten stimmen wiederum mit dem Maussystem überein, während humane ES-Zellen diesbezüglich bislang nicht untersucht wurden. Die Interaktion zwischen verschiedenen Signalwegen ist ein bisher noch nicht gut verstandenes Gebiet. Die Integration verschiedener Signale ist aber speziell für Stammzellen, die ihr Differenzierungsschicksal von winzigen Abweichungen in der Signalmixtur abhängig machen, von entscheidender Bedeutung. Im zweiten Teil der hier vorgelegten Arbeit konnte eine Interaktion zwischen dem BMP-Rezeptor 1a und STAT3 nachgewiesen werden. Diese Interaktion ist offenbar Teil eines variablen Komplexes. Zum ersten Mal war es auch möglich, funktionale Konsequenzen für STAT3 nach Stimulierung des BMP-Rezeptors 1a zu dokumentieren. Nach Belegung des BMP-Rezeptors 1a mit dem mutierten BMP2-A34D wird STAT3 trotz Aktivierung durch Phosphorylierung an Tyrosin 705 im Zytoplasma von Maus Stammzellen festgehalten. Zusammengenommen konnte hier gezeigt werden, dass eine Interaktion zwischen den bislang als isoliert betrachteten Signalwegen BMP-Smad und STAT3 besteht. Des Weiteren wurde das Medaka-Stammzellkultursystem benutzt, um zu zeigen, dass STAT3 für die Pluripotenz von Stammzellen nur im Maussystem eine Rolle spielt, wohingegen BMPZielgene wie id2 in bislang allen getesteten ES-Zellkultursystemen aktiv sind.
Oxylipins are important biological active compounds that play essential roles in defense, growth, development, and reproduction of plants and animals. Oxylipins are formed either by enzymatic pathways or radical catalyzed reaction from polyunsaturated fatty acids. Products of oxidation of arachidonic acid (C20:4) in animals by enzymatic and non-enzymatic pathways are prostaglandins and isoprostanes, respectively. In plants, radical catalyzed reaction of -linolenic acid (C18:3) forms phytoprostanes and enzymatic oxidation of this fatty acid produces OPDA and jasmonic acid. Like plants, cyanobacterial membranes contain a high ratio of polyunsaturated fatty acid, about 25% of total fatty acids. Oxylipin biosynthesis and function was studied in two model cyanobacteria, Anabaena PCC 7120 and Synechocystis PCC 6803, for the first time: 1. The filamentous cyanobaterium Anabaena PCC 7120 can naturally produce phytoprostanes type I and II as well as hydroxy fatty acids like in plants but lacks the enzymatic capacity to form jasmonates (12-oxo-phytodienoic acid and jasmonic acid) and prostaglandins. Data obtained provide the first evidence for the occurence of phytoprostanes in cyanobacteria as well as in the baterial kingdom. 2. By GC-MS analysis, the E1- and F1-phytoprostanes in Anabaena PCC 7120 were detected both in free and esterified form. Their levels are comparable with those in plants, in the range of ng/g DW. In one week old cultures, there was no evidence of PPF1 in the medium but its level accumulated up to 142 ng/l in six weeks old cultures. In contrast, PPE1 was stable over time, about 20 ng/g DW. Free cellular PPE1 was found about 4 times higher than that of PPF1, 80.5  23.6 and 24.1  10.9 ng/g DW, respectively. However, there was no significant difference in the total cellular levels of PPF1 and PPE1, ranging from 150 to about 200 ng/g DW. 3. Phytoprostanes are inducible in Anabaena. In the combination of oxidative stress (200 µM H2O2 or 10 µM CuSO4) with high light intensity (330 µE.m-2.s-1) for 8 h, levels of total cellular PPE1 and PPF1 were increased about 2 to 4 times. Interestingly, unlike in higher plants, application of oxidative stress or high light intensity alone showed no phytoprostaneous induction in this cyanobacterium. 4. When Anabaena cells were treated with phytoprostanes, Anabaena cells became remarkably resistant against subsequently applied – otherwise lethal – oxidative stress. All phytoprostanes displayed a high protective effect except for PPE1. The highest protection level was contributed by a mixture of PPA1 type I and II. After preincubation of Anabena cells with 100 µM PPA1–type I/II for 16 h followed by application of 1 mM H2O2 or 50 µM CuSO4 for 5 h, A1-phytoprostane pre-treatment protected 84.2% and 77.5% of the cells from cell death, respectively. Without oxylipins pre-treatment, about 98% of the cells were dead. Surprisingly, preincubation of Anabaena with other oxylipins derived from enzymatic pathway in plants and animals showed also an effect, however, the protection effect was low and ranged from 10 to 30%. In contrast, phytoprostanes did not protect Pseudomonas syringae and Escherichia coli from the toxicity of hydrogen peroxide. However, these bacteria do not synthesize polyunsaturated fatty acids and are therefore devoid of and not exposed to endogenously formed oxidized lipids. 5. Exogenous application of 100 µM PPF1 or 1.5 mM H2O2 for 90 min did not activate the expression of isiA in Anabaena. Oxylipins also displayed no effect on shinorine and tocopherol levels in Anabaena. However, application of 100 µM PPF1 for 6 h altered the protein expression in Anabaena. Most PPF1-modulated proteins are down-regulated and related to photosynthesis. Since oxidative stress only in combination with high light intensity increased lipid peroxidation, down-regulation of photosynthesis after recognition of oxidised lipids (phytoprostanes) may be a survival strategy of Anabaena to avoid damage by peroxidized lipids. 6. Dead plants may be the main source of (exogenous) phytoprostanes in the natural environment of Anabaena. Dry hay releases PPE1 and PPF1 (11 µg/g DW) into an aqueous environment. Anabaena is the typical cyanobacterium in paddy rice fields. After harvesting, most of uneconomical parts of rice plants are abundant on the field, which may release phytoprostanes that in turn might have an impact on cyanobacteria in the rice ecosystems. However, field research is needed to clarify this suspection. 7. A new class of oxylipins, phytoprostanes type III and IV, was identified and quantified in vitro. The two main phytoprostanes, PPE1 and PPF1 (type III and IV), can be obtained by autoxidation of -linolenic acid or Borage oil (containing 25% esterified -linolenic acid). After 12 days of autoxidation and subsequent hydrolysis, 1 g of Borage oil yielded 112.71 ± 1.93 µg of PPF1 and 3.80 ± 0.14 mg of PPE1. PPB1 and PPA1 (type III and IV) were prepared by isomerization and dehydration of PPE1 (type III and IV). The overall yield of PPB1 was 1.71 ± 0.04 mg/g oil (type III) and 2.09 ± 0.12 mg/g oil (type IV). Those of PPA1 were 8.38 ± 0.35 µg/g and 10.18 ± 0.30 µg/oil, respectively. 8. A rapid HPLC-MS/MS method for phytoprostane and phytohormone analysis has been developed. This method was applied to quantify free and esterified E1- and F1-phytoprostanes type III and IV in Synechocystis PCC 6803. The in vivo phytoprostanes type III and IV are present both in free and esterified form. The total cellular level of PPE1 type III and IV in Synechocystis is at least 2 times higher than that of PPF1. Unlike Anabaena, PPE1 and PPF1 were detectable in the medium of one week old Synechocystis cultures. Free levels of PPF1 in the medium (231.8 ± 36.2 ng/l) and in the cells (164.9 ± 15.2 ng/g DW) are lower than those of PPE1 (1003.3 ± 365.2 ng/l and 2331.0 ± 87.7 ng/g DW).
In the present study numerical methods are employed within the framework of multiscale modeling. Quantum mechanics and finite element method simulations have been used in order to calculate thermoelastic properties of ceramics. At the atomic scale, elastic constants of ten different ceramics (Al2O3, alpha- and beta-SiC, TiO2-rutile and anatase, AlN, BN, CaF2, TiB2, ZrO2) were calculated from the first principles (ab-initio) using the density functional theory with the general gradient approximation. The simulated elastic moduli were compared with measured values. These results have shown that the ab-initio computations can be used independently from experiment to predict elastic behavior and can provide a basis for the modeling of structural and elastic properties of more complex composite ceramics. In order to simulate macroscopic material properties of composite ceramics from the material properties of the constituting phases, 3D finite element models were used. The influence of microstructural features such as pores and grain boundaries on the effective thermoelastic properties is studied through a diversity of geometries like truncated spheres in cubic and random arrangement, modified Voronoi polyhedra, etc. A 3D model is used for modeling the microstructure of the ceramic samples. The measured parameters, like volume fractions of the two phases, grain size ratios and grain boundary areas are calculated for each structure. The theoretical model is then varied to fit the geometrical data derived from experimental samples. The model considerations are illustrated on two types of bi-continuous materials, a porous ceramic, alumina (Al2O3) and a dense ceramic, zirconia-alumina composite (ZA). For the present study, alumina samples partially sintered at temperatures between 800 and 1320 C, with fractional densities between 58.4% and 97% have been used. For ZA ceramic the zirconia powder was partially stabilized and the ratio between alumina and zirconia was varied. For these two examples of ceramics, Young’s modulus and thermal conductivity were calculated and compared to experimental data of samples of the respective microstructure. Comparing the experimental and simulated values of Young’s modulus for Al2O3 ceramic a good agreement was obtained. For the thermal conductivity the consideration of thermal boundary resistance (TBR) was necessary. It was shown that for different values of TBR the experimental data lie within the simulated thermal conductivities. In the case of ZA ceramic also a good agreement between simulated and experimental values was observed. For smaller ZrO2 fractions, a larger Young’s modulus and thermal conductivity was observed in the experimental samples. The discrepancies have been discussed by taking into account the effect of pressure. Considering the dependence of the thermoelastic properties on the pressure, it has been shown that the thermal stresses resulting from the cooling process were insufficient to explain the discrepancies between experimental and simulated thermoelastic properties.