Refine
Has Fulltext
- yes (8916) (remove)
Year of publication
Document Type
- Doctoral Thesis (8916) (remove)
Language
- German (6114)
- English (2797)
- French (4)
- Multiple languages (1)
Keywords
- Maus (121)
- Signaltransduktion (104)
- Genexpression (99)
- Taufliege (92)
- Deutschland (83)
- T-Lymphozyt (74)
- Tissue Engineering (72)
- Apoptosis (70)
- Herzinsuffizienz (66)
- Apoptose (60)
Institute
- Graduate School of Life Sciences (1016)
- Theodor-Boveri-Institut für Biowissenschaften (797)
- Physikalisches Institut (411)
- Medizinische Klinik und Poliklinik I (314)
- Institut für Pharmazie und Lebensmittelchemie (293)
- Institut für Anorganische Chemie (261)
- Klinik und Poliklinik für Allgemein-, Viszeral-, Gefäß- und Kinderchirurgie (Chirurgische Klinik I) (256)
- Klinik und Poliklinik für Psychiatrie, Psychosomatik und Psychotherapie (232)
- Institut für Organische Chemie (224)
- Medizinische Klinik und Poliklinik II (216)
Schriftenreihe
Sonstige beteiligte Institutionen
- Fraunhofer-Institut für Silicatforschung ISC (8)
- Helmholtz Institute for RNA-based Infection Research (HIRI) (7)
- Universitätsklinikum Würzburg (5)
- Fraunhofer Institut für Silicatforschung ISC (3)
- Fraunhofer-Institut für Silicatforschung (3)
- Klinikum Fulda (3)
- König-Ludwig-Haus Würzburg (3)
- Technische Hochschule Nürnberg Georg Simon Ohm (3)
- Universitätsklinikum Münster (3)
- CHC Würzburg (Comprehensive Hearing Center) (2)
ResearcherID
- B-1911-2015 (1)
- B-4606-2017 (1)
- C-2593-2016 (1)
- D-1250-2010 (1)
- D-3057-2014 (1)
- I-5818-2014 (1)
- J-8841-2015 (1)
- M-1240-2017 (1)
- N-2030-2015 (1)
- N-3741-2015 (1)
EU-Project number / Contract (GA) number
- 311781 (1)
- 320377 (1)
- EU (FP7/ 2007-2013) (1)
The one electron oxidation potential of ten TAAs with all permutations of Cl , OMe- and Me-substituents in the three p-positions were determined by CV. The half wave potential of the first oxidation wave correlates linearly with the number of Cl- and OMe-substituents. AM1-CISD derived values of the absorption energies are in good agreement with the experiments but differ strongly for the oscillator strengths as well as for neutral compounds and their corresponding mono radical cations. The small solvent dependence of the experimental UV/Vis spectra in CH2Cl2 and MeCN reflects a minor charge transfer character of the electronic transitions. The UV/Vis/NIR spectra of the series of TAAs and their corresponding radical cations and the AM1 computations reveal that even small substituents may lead to strong symmetry breaking and to a modified electronic structure. The spectroscopic properties of a series of four bis-TAA donor-bridge-donor X-B-X dimers, composed of two asymmetric TAA chromophores (monomers) were investigated. UV/vis-, fluorescence and transient absorption spectra were recorded and compared with those of the corresponding X-B monomers. The excited states of the dimers are described as MV states which show, depending on the chemical nature of the bridge, a varying amount of interactions. It was found that superradiant emission only proceeds in the case of weak and medium coupling. Whether the first excited state potential energy surface of the dimers is a single minimum or a double minimum potential depends on the solvent polarity and the electronic coupling. In the latter case, the dimer relaxes in a symmetry broken CT state. The [2.2]paracyclophane bridged dimer is an example for a weakly coupled system, because the spectroscopic behavior is very similar to the corresponding p xylene monomer. In contrast, anthracene as well as p-xylene bridges mediate a stronger coupling and reveal a significant cooperative influence on the optical properties. A series of [2.2]paracylophane bridged bis-TAA MV radical cations X-B-X+ were analyzed by a GMH three-level model which takes two transitions into account: the IV-CT band and the bridge band. From the GMH analysis, one can conclude that the [2.2]paracyclophane moiety is not the limiting factor which governs the intramolecular charge transfer. The electronic interactions are of course smaller than direct conjugation but from the order of magnitude of the couplings of the [2.2]paracyclophane MV species it can be assumed that this bridge is able to mediate significant through-space and through-bond interactions. From the exponential dependence of the electronic coupling V between the two TAA localized states on the distance r between the two redox centers, it was inferred that the HT proceeds via superexchange mechanism. The analysis reveals that even significantly longer conjugated bridges should still mediate significant electronic interactions, because the decay constant of a series of conjugated MV species is small. The absorption properties of a series of bis-TAA-[2.2]paracyclophane dications X+-B-X+ were presented. The localized and the CT transitions of these dications are explained and analyzed by an exciton coupling model which also considers the photophysical properties of the monomeric TAA radical cations. Together with AM1-CISD calculated transition moments, experimental transition moments and transition energies of the bis-TAA dications were used to calculate electronic couplings by a GMH approach. These couplings are a measure for interactions of the excited MV CT states. The modification of the diabatic states reveals similarities of the GMH three-level model and the exciton coupling model. Comparison of the two models shows that the transition moment between the excited mixed-valence states of the dimer equals the dipole moment difference of the ground and the excited bridge state of the corresponding monomer. Thianthrenophane (1) has a cavity which offers enough room to potentially enable endohedral coordination to small ions or molecules. For the complexation of silver(I) perchlorate, the complex stability constants of thianthrenophane logK1=5.45 and of thianthrene logK2=9.16 were determined by UV/Vis titration. Single competition transport experiments with ten metal salts demonstrate a very high selectivity of thianthrenophane as a carrier for silver(I) and a distinctly higher transport rate compared to carriers such as thianthrene and 14-ane-S4. Although the X-ray crystal structure analysis of the polymeric [Ag(1)]ClO4 shows an exohedral coordination to silver(I), the formation of an endohedral [Ag(1)]+ complex is suggested to be the explanation for the unusual carrier selectivity of silver(I) by 1 in bulk liquid membrane.
Nach wie vor ist die Zahl der Malaria-Neuerkrankungen mit ca. 500 Millionen Menschen weltweit sehr besorgniserregend. Durch zunehmende Resistenzen der Erreger gegen zahlreiche Arzneimittel wird die Situation zusätzlich verschärft. Daher ist die Suche und Entwicklung neuartiger Medikamente wichtiger denn je. Die Natur ist immer noch das größte Reservoir an neuen Wirkstoffen, welche als Leitstrukturen für Arzneistoffe fungieren. In den letzten Jahren wurde eine große Zahl neuartiger, biologisch aktiver Naturstoffe identifiziert und hinsichtlich ihres Potenzials für eine pharmazeutische Weiterentwicklung analysiert. Die Naphthylisochinolin-Alkaloide gehören zu solch einer vielversprechenden Wirkstoffklasse, da sie sich v.a. durch ihre hervorragenden pharmakologischen Eigenschaften auszeichnen. Kürzlich wurden die ersten N,C-gekuppelten Naphthyldihydroisochinolin-Alkaloide, Ancistrocladinium A und B, entdeckt. Diese Verbindungen weisen als strukturelle Besonderheit eine außergewöhnliche Iminium-Aryl-Achse auf und besitzen zudem exzellente anti-infektive Aktivitäten, insbesondere gegen den Erreger der Orientbeule, Leishmania major. Ziel der vorliegenden Dissertation war die Synthese neuartiger sterisch gehinderter und strukturell vereinfachter Naphthylisochinoline für weiterführende Struktur-Aktivitäts-Beziehungen (SAR-Studien) und die stereochemische Analyse dieser Verbindungen. Zudem sollte eine Syntheseroute zu den neuartigen dimeren C,C-gekuppelten Naphthylisochinolin-Alkaloiden Shuangancistrotectorin A und B entwickelt werden.
Die vorliegende Arbeit zeigt eine Möglichkeit auf, die bisher meist erfolglose Chemotherapie des malignen Melanoms zu verbessern: Durch Inhibition des Transkriptionsfaktors NF-kB, der für die Regulation vieler tumorrelevanter Gene verantwortlich ist, konnten die Tumorzellen gegenüber der Wirkung von Zytostatika sensibilisiert werden. Zunächst wurden acht verschiedene Melanomzellen in Bezug auf ihre NF-kB-Aktivität und der Expression NF-kB-regulierter Proteine vergleichen. Es konnte gezeigt werden, dass die Mehrzahl der Melanomzellen über konstitutive Aktivität von NF-κB verfügt. Dabei bestand kein eindeutiger Zusammenhang zwischen der Expression NF-kB-regulierter Proteine und der Aktivität dieses Transkriptionsfaktors im Kern, was komplexe Regulationsmechanismen bei der Transkription und Translation vermuten lässt. Anhand einer ausgewählten Melanomzelllinie konnte gezeigt werden, dass zwei verschiedene NF-kB-Inhibitoren, der Proteasom-Inhibitor Bortezomib und der neue IKK-Inhibitor KINK-1 die Aktivität von NF-kB deutlich hemmen. Beim Vergleich beider NF-kB-Inhibitoren ließen sich unerwartet verschiedene molekulare Wirkungsmechanismen nachweisen: Während Bortezomib konzentrationsabhängig eine sehr starke Induktion von NOXA, eine Induktion von p53 sowie eine Abnahme von Cyclin D1 bewirkte, zeigte KINK-1 seine Effekte vor allem in der Reduktion von Chemokinen wie IL-8 und MCP-1. Passend zur Veränderung der Expression zellzyklus-relevanter Proteine hatte Bortezomib einen stärkeren Effekt auf den Zellzyklus als KINK-1. Beide Inhibitoren wurden mit verschiedenen Zytostatika kombiniert und konnten einerseits die Apoptoseinduktion durch Zytostatika verstärken und andererseits die durch Zytostatika reduzierte Invasion weiter reduzieren. Allerdings zeigte sich bei der Untersuchung tumorrelevanter Chemokine, dass KINK-1 im Gegensatz zu Bortezomib synergistische Effekte mit Camptothecin und Doxorubicin aufweist. Trotz molekularer Unterschiede bewirkten beide NF-kB-Inhibitoren vergleichbare funktionelle Effekte auf zellulärer Ebene. Dies galt auch für ein präklinisches in-vivo-Modell, in dem die experimentelle Lungenmetastasierung von B16F10-Melanomzellen in Mäusen ermittelt wurde: Hier wurden die Mäuse mit Camptothecin, KINK-1 und Bortezomib allein im Vergleich zu den jeweiligen Kombinationen aus Zytostatikum und NF-kB-Inhibitor behandelt. Beide Kombinationen zeigten eine signifikante Reduktion des Lungengewichts im Vergleich zu Camptothecin allein. Diese Arbeit konnte also den Nutzen aus NF-kB-Inhibition in Kombination mit Zytostatika für die hier verwendeten Substanzen bekräftigen und dabei einige molekulare Unterschiede aufdecken.
To grow larger, insects must shed their old rigid exoskeleton and replace it with a new one. This process is called molting and the motor behavior that sheds the old cuticle is called ecdysis. Holometabolic insects have pupal stages in between their larval and adult forms, during which they perform metamorphosis. The pupal stage ends with eclosion, i.e., the emergence of the adult from the pupal shell. Insects typically eclose at a specific time during the day, likely when abiotic conditions are at their optimum. A newly eclosed insect is fragile and needs time to harden its exoskeleton. Hence, eclosion is regulated by sophisticated developmental and circadian timing mechanisms.
In Drosophila melanogaster, eclosion is limited to a daily time window in the morning, regarded as the “eclosion gate”. In a population of laboratory flies entrained by light/dark cycles, most of the flies eclose around lights on. This rhythmic eclosion pattern is controlled by the circadian clock and persists even under constant conditions.
Developmental timing is under the control of complex hormonal signaling, including the steroid ecdysone, insulin-like peptides, and prothoracicotropic hormone (PTTH). The interactions of the central circadian clock in the brain and a peripheral clock in the prothoracic gland (PG) that produces ecdysone are important for the circadian timing of eclosion. These two clocks are connected by a bilateral pair of peptidergic PTTH neurons (PTTHn) that project to the PG. Before each molt, the ecdysone level rises and then falls shortly before ecdysis. The falling ecdysone level must fall below a certain threshold value for the eclosion gate to open. The activity of PTTHn is inhibited by short neuropeptide F (sNPF) from the small ventrolateral neurons (sLNvs) and inhibition is thought to lead to a decrease in ecdysone production.
The general aim of this thesis is to further the understanding of how the circadian clock and neuroendocrinal pathways are coordinated to drive eclosion rhythmicity and to identify when these endocrinal signaling pathways are active. In Chapter I, a series of conditional PTTHn silencing-based behavioral assays, combined with neuronal activity imaging techniques such as non-invasive ARG-Luc show that PTTH signaling is active and required shortly before eclosion and may serve to phase-adjust the activity of the PG at the end of pupal development. Trans-synaptic anatomical stainings identified the sLNvs, dorsal neurons 1 (DN1), dorsal neurons 2 (DN2), and lateral posterior neurons (LPNs) clock neurons as directly upstream of the PTTHn.
Eclosion motor behavior is initiated by Ecdysis triggering hormone (ETH) which activates a pair of ventromedial (Vm) neurons to release eclosion hormone (EH) which positively feeds back to the source of ETH, the endocrine Inka cells. In Chapter II trans-synaptic tracing showed that most clock neurons provide input to the Vm and non-canonical EH neurons. Hence, clock can potentially influence the ETH/EH feedback loop. The activity profile of the Inka cells and Vm neurons before eclosion is described. Vm and Inka cells are active around seven hours before eclosion. Interestingly, all EH neurons appear to be exclusively peptidergic.
In Chapter III, using chemoconnectomics, PTTHns were found to express receptors for sNPF, allatostatin A (AstA), allatostatin C (AstC), and myosuppressin (Ms), while EH neurons expressed only Ms and AstA receptors. Eclosion assays of flies with impaired AstA, AstC, or Ms signaling do not show arrhythmicity under constant conditions. However, optogenetic activation of the AstA neurons strongly suppresses eclosion.
Chapter IV focuses on peripheral ventral’ Tracheal dendrite (v’Td) and class IV dendritic arborization (C4da) neurons. The C4da neurons mediate larval light avoidance through endocrine PTTH signaling. The v’Td neurons mainly receive O2/CO2 input from the trachea and are upstream of Vm neurons but are not required for eclosion rhythmicity. Conditional ablation of the C4da neurons or torso (receptor of PTTH) knock-out in the C4da neurons impaired eclosion rhythmicity. Six to seven hours before eclosion, PTTHn, C4da, and Vm neurons are active based on ARG-Luc imaging. Thus, C4da neurons may indirectly connect the PTTHn to the Vm neurons.
In summary, this thesis advances our knowledge of the temporal activity and role of PTTH signaling during pupal development and rhythmic eclosion. It further provides a comprehensive characterization of the synaptic and peptidergic inputs from clock neurons to PTTHn and EH neurons. AstA, AstC, and Ms are identified as potential modulators of eclosion circuits and suggest an indirect effect of PTTH signaling on EH signaling via the peripheral sensory C4da neurons.
Malaria and HIV are among the most important global health problems of our time and together are responsible for approximately 3 million deaths annually. These two diseases overlap in many regions of the world including sub-Saharan Africa, Southeast Asia and South America, leading to a higher risk of co-infection. In this study, we generated and characterized hybrid molecules to target P. falciparum and HIV simultaneously for a potential HIV/malaria combination therapy. Hybrid molecules were synthesized by covalent fusion between azidothymidine (AZT) and dihydroartemisinin (DHA), tetraoxane or chloroquine (CQ); and a small library was generated and tested for antiviral and antimalarial activity. Our data suggest that dihyate is the most potent molecule in vitro, with antiplasmodial activity comparable to that of DHA (IC50 = 26 nM, SI > 3000), a moderate activity against HIV (IC50 = 2.9 µM; SI > 35) and safe to HeLa cells at concentrations used in the assay (CC50 > 100 µM). Pharmacokinetic studies further revealed that dihyate is metabolically unstable and is cleaved following an O-dealkylation once in contact with cytochrome P450 enzymes. The later further explains the uneffectiveness of dihyate against the CQ-sensitive P. berghei N strain in mice when administered by oral route at 20 mg/kg. Here, we report on a first approach to develop antimalarial/anti-HIV hybrid molecules and future optimization efforts will aim at producing second generation hybrid molecules to improve activity against HIV as well as compound bioavailability. With the emergence of resistant parasites against all the counterpart drugs of artemisinin derivatives used in artemisinin based combination therapies (ACTs), the introduction of antibiotics in the treatment of malaria has renewed interest on the identification of antibiotics with potent antimalarial properties. In this study we also investigated the antiplasmodial potential of thiostrepton and derivatives, synthesized using combinations of tail truncation, oxidation, and addition of lipophilic thiols to the terminal dehydroamino acid. We showed that derivatives SS231 and SS234 exhibit a better antiplasmodial activity (IC50 = 1 µM SI > 59 and SI > 77 respectively) than thiostrepton (IC50 = 8.95 µM, SI = 1.7). The antiplasmodial activity of these derivatives was observed at concentrations which are not hemolytic and non-toxic to human cell lines. Thiostrepton and derivatives appeared to exhibit transmission blocking properties when administered at their IC50 or IC90 concentrations and our data also showed that they attenuate proteasome activity of Plasmodium, which resulted in an accumulation of ubiquitinated proteins after incubation with their IC80 concentrations. Our results indicate that the parasite’s proteasome could be an attractive target for therapeutic intervention. In this regard, thiostrepton derivatives are promising candidates by dually acting on two independent targets, the proteasome and the apicoplast, with the capacity to eliminate both intraerythrocytic asexual and transmission stages of the parasite. To further support our findings, we evaluated the activity of a new class of antimalarial and proteasome inhibitors namely peptidyl sulfonyl fluorides on gametocyte maturation and analogues AJ34 and AJ38 were able to completely suppress gametocytogenesis at IC50 concentrations (0.23 µM and 0.17 µM respectively) suggesting a strong transmission blocking potential. The proteasome, a major proteolytic complex, responsible for the degradation and re-cycling of non-functional proteins has been studied only indirectly in P. falciparum. In addition, an apparent proteasome-like protein with similarity to bacterial ClpQ/hslV threonine-peptidases was predicted in the parasite. Antibodies were generated against the proteasome subunits alpha type 5 (α5-SU), beta type 5 (β5-SU) and pfhslV in mice and we showed that the proteasome is expressed in both sexual and asexual blood stages of P. falciparum, where they localize in the nucleus and in the cytoplasm. However, expression of PfhslV was only observed in trophozoites and shizonts. The trafficking of the studied proteasome subunits was further investigated by generating parasites expressing GFP tagged proteins. The expression of α5-SU-GFP in transgenic parasite appeared to localize abundantly in the cytoplasm of all blood stages, and no additional information was obtained from this parasite line. In conclusion, our data highlight two new tools towards combination therapy. Hybrid molecules represent promising tools for the cure of co-infected individuals, while very potent antibiotics with a wide scope of activities could be useful in ACTs by eliminating resistant parasites and limiting transmission of both, resistances and disease.
In the present thesis the MBE growth and sample characterization of HgTe structures is investigated
and discussed. Due to the first experimental discovery of the quantum Spin Hall effect
(QSHE) in HgTe quantum wells, this material system attains a huge interest in the spintronics
society. Because of the long history of growing Hg-based heterostructures here at the Experimentelle
Physik III in Würzburg, there are very good requirements to analyze this material
system more precisely and in new directions. Since in former days only doped HgTe quantum
wells were grown, this thesis deals with the MBE growth in the (001) direction of undoped
HgTe quantum wells, surface located quantum wells and three dimensional bulk layers. All
Hg-based layers were grown on CdTe substrates which generate strain in the layer stack and
provide therefore new physical effects. In the same time, the (001) CdTe growth was investigated
on n-doped (001) GaAs:Si because the Japanese supplier of CdTe substrates had a
supply bottleneck due to the Tohoku earthquake and its aftermath in 2011.
After a short introduction of the material system, the experimental techniques were demonstrated
and explained explicitly. After that, the experimental part of this thesis is displayed.
So, the investigation of the (001) CdTe growth on (001) GaAs:Si is discussed in chapter 4.
Firstly, the surface preparation of GaAs:Si by oxide desorption is explored and analyzed.
Here, rapid thermal desorption of the GaAs oxide with following cool down in Zn atmosphere
provides the best results for the CdTe due to small holes at the surface, while e.g. an atomic
flat GaAs buffer deteriorates the CdTe growth quality. The following ZnTe layer supplies the
(001) growth direction of the CdTe and exhibits best end results of the CdTe for 30 seconds
growth time at a flux ratio of Zn/Te ~ 1/1.2. Without this ZnTe layer, CdTe will grow in the
(111) direction. However, the main investigation is here the optimization of the MBE growth
of CdTe. The substrate temperature, Cd/Te flux ratio and the growth time has to be adjusted
systematically. Therefore, a complex growth process is developed and established. This optimized
CdTe growth process results in a RMS roughness of around 2.5 nm and a FWHM value
of the HRXRD w-scan of 150 arcsec. Compared to the literature, there is no lower FWHM
value traceable for this growth direction. Furthermore, etch pit density measurements show
that the surface crystallinity is matchable with the commercial CdTe substrates (around 1x10^4
cm^(-2)). However, this whole process is not completely perfect and offers still room for improvements.
The growth of undoped HgTe quantum wells was also a new direction in research in contrast
to the previous n-doped grown HgTe quantum wells. Here in chapter 5, the goal of very low
carrier densities was achieved and therefore it is now possible to do transport experiments in
the n - and p - region by tuning the gate voltage. To achieve this high sample quality, very precise
growth of symmetric HgTe QWs and their HRXRD characterization is examined. Here,
the quantum well thickness can now determined accurate to under 0.3 nm. Furthermore, the transport analysis of different quantum well thicknesses shows that the carrier density and
mobility increase with rising HgTe layer thickness. However, it is found out that the band
gap of the HgTe QW closes indirectly at a thickness of 11.6 nm. This is caused by the tensile
strained growth on CdTe substrates. Moreover, surface quantum wells are studied. These
quantum wells exhibit no or a very thin HgCdTe cap. Though, oxidization and contamination
of the surface reduces here the carrier mobility immensely and a HgCdTe layer of around 5 nm
provides the pleasing results for transport experiments with superconductors connected to the
topological insulator [119]. A completely new achievement is the realization of MBE growth
of HgTe quantum wells on CdTe/GaAs:Si substrates. This is attended by the optimization of
the CdTe growth on GaAs:Si. It exposes that HgTe quantum wells grown in-situ on optimized
CdTe/GaAs:Si show very nice transport data with clear Hall plateaus, SdH oscillations, low
carrier densities and carrier mobilities up to 500 000 cm^2/Vs. Furthermore, a new oxide etching
process is developed and analyzed which should serve as an alternative to the standard
HCl process which generates volcano defects at some time. However, during the testing time
the result does not differ in Nomarski, HRXRD, AFM and transport measurements. Here,
long-time tests or etching and mounting in nitrogen atmosphere may provide new elaborate
results.
The main focus of this thesis is on the MBE growth and standard characterization of HgTe bulk
layers and is discussed in chapter 6. Due to the tensile strained growth on lattice mismatched
CdTe, HgTe bulk opens up a band gap of around 22 meV at the G-point and exhibits therefore
its topological surface states. The analysis of surface condition, roughness, crystalline quality,
carrier density and mobility via Nomarski, AFM, XPS, HRXRD and transport measurements
is therefore included in this work. Layer thickness dependence of carrier density and mobility
is identified for bulk layer grown directly on CdTe substrates. So, there is no clear correlation
visible between HgTe layer thickness and carrier density or mobility. So, the carrier density is
almost constant around 1x10^11 cm^(-2) at 0 V gate voltage. The carrier mobility of these bulk
samples however scatters between 5 000 and 60 000 cm^2/Vs almost randomly. Further experiments
should be made for a clearer understanding and therefore the avoidance of unusable
bad samples.But, other topological insulator materials show much higher carrier densities and
lower mobility values. For example, Bi2Se3 exhibits just density values around 1019 cm^(-2)
and mobility values clearly below 5000 cm2/Vs. The carrier density however depends much
on lithography and surface treatment after growth. Furthermore, the relaxation behavior and
critical thickness of HgTe grown on CdTe is determined and is in very good agreement with
theoretical prediction (d_c = 155 nm). The embedding of the HgTe bulk layer between HgCdTe
layers created a further huge improvement. Similar to the quantum well structures the carrier
mobility increases immensely while the carrier density levels at around 1x10^11 cm^(-2) at 0
V gate voltage as well. Additionally, the relaxation behavior and critical thickness of these
barrier layers has to be determined. HgCdTe grown on commercial CdTe shows a behavior as
predicted except the critical thickness which is slightly higher than expected (d_c = 850 nm).
Otherwise, the relaxation of HgCdTe grown on CdTe/GaAs:Si occurs in two parts. The layer
is fully strained up to 250 nm. Between 250 nm and 725 nm the HgCdTe film starts to relax
randomly up to 10 %. The relaxation behavior for thicknesses larger than 725 nm occurs than
linearly to the inverse layer thickness. A explanation is given due to rough interface conditions
and crystalline defects of the CdTe/GaAs:Si compared to the commercial CdTe substrate. HRXRD and AFM data support this statement. Another point is that the HgCdTe barriers protect the active HgTe layer and because of the high carrier mobilities the Hall measurements provide new transport data which have to be interpreted more in detail in the future. In addition, HgTe bulk samples show very interesting transport data by gating the sample from the top and the back. It is now possible to manipulate the carrier densities of the top and bottom surface states almost separately. The back gate consisting of the n-doped GaAs substrate and the thick insulating CdTe buffer can tune the carrier density for Delta(n) ~ 3x10^11 cm^(-2). This is sufficient to tune the Fermi energy from the p-type into the n-type region [138].
In this thesis it is shown that strained HgTe bulk layers exhibit superior transport data by embedding between HgCdTe barrier layers. The n-doped GaAs can here serve as a back gate.
Furthermore, MBE growth of high crystalline, undoped HgTe quantum wells shows also new
and extended transport output. Finally, it is notable that due to the investigated CdTe growth
on GaAs the Hg-based heterostructure MBE growth is partially independent from commercial
suppliers.
Im Zellkern eukaryotischer Zellen werden Gene in mRNAs transkribiert, welche umfangreich prozessiert und aus dem Zellkern exportiert werden. Im Zytoplasma erfolgt die Translation der mRNAs in Proteine, ein Prozess, welcher viel Energie benötigt und daher mittels vielfältiger Mechanismen streng reguliert wird. Ein Beispiel hierfür stellt die Klasse der TOP-mRNAs dar, eine RNA-Spezies, welche hauptsächlich Transkripte von Genen umfasst, die selbst in die Translation involviert sind. Die prominentesten Vertreter dieser Klasse sind die Proteine der kleinen und großen ribosomalen Untereinheiten. TOP-mRNAs zeichnen sich durch ein gemeinsames Sequenz-Motiv am Anfang Ihrer 5’-UTR aus, welches aus einem Pyrimidinstrang besteht und unmittelbar nach dem Cap mit einem Cytosin beginnt. Dieses allen TOP-RNAs gemeinsame Motiv ermöglicht die zeitgleiche Translationskontrolle dieser RNA-Klasse. So kann die Translation der TOP-mRNAs unter Stressbedingungen wie z.B. Nährstoffmangel koordiniert inhibiert werden, wodurch Energie eingespart wird.
Bereits lange wird nach einem Regulator gesucht, der an dieses TOP-Motiv bindet und die koordinierte Regulation ermöglicht. Man kann sich hier einen Inhibitor oder auch einen Aktivator vorstellen. Verschiedene Proteine wurden bereits in Erwägung gezogen. In dieser Arbeit wurde das Protein TIAR mittels Massenspektrometrie als TOP-interagierender Faktor identifiziert und dessen Bindungseigenschaften mit dem TOP-Motiv durch Shift Assays untersucht. Hierbei konnten Minimalkonstrukte verschiedener Organismen sowie RNA-TOP – Sequenzen identifiziert werden, welche sich für Strukturanalysen eignen würden. Als weiterer TOP-interagierender Faktor wurde über verschiedene sequenzielle Reinigungsschritte das Protein 14-3-3ε identifiziert.
Weiterhin wurden die TOP-Motiv-bindenden Proteine LARP1 und LARP7 auf Ihre Bindungseigenschaften mit Ihren Zielsequenzen untersucht. Während gezeigt werden konnte, dass LARP1 einen inhibierenden Einfluss auf TOP-RNAs hat, wurde in weiteren Shift-Assays die Bindungseigenschaften von LARP7 mit 7SK untersucht, wobei ebenfalls ein minimales LARP7–Konstrukt sowie 7SK-Konstrukte für Strukturanalysen identifiziert werden konnten. Weiterhin konnte gezeigt werden, dass verschiedene Substanzen wie tRNA und Arginin einen starken Einfluss auf die LARP7-7SK – Interaktion ausüben, welcher in weiteren Studien berücksichtigt werden sollte.
The interaction between circadian clocks and metabolism is of increasing interest, since clock dysfunction often correlates with metabolic pathologies. Many research articles have been published analysing the impact of factors such as circadian clock, light, feeding time and diet-type on energy homeostasis in various tissues/organs of organisms with most of the findings done in mammals. Little is known about the impact of circadian clock and the above-mentioned factors on circulating lipids, especially the transport form of lipids - diacylglycerol (DG) and membrane lipids such as phosphatidylethanolamine (PE) and phosphatidylcholine (PC) in the Drosophila hemolymph. The fruit fly Drosophila is a prime model organism in circadian, behaviour and metabolism research.
To study the role of circadian clock and behaviour in metabolism, we performed an extensive comparative hemolymph lipid (diacylglycerol: DG, phosphatidylethanolamine: PE, phosphatidylcholine: PC) analysis using ultra performance liquid chromatography coupled to time-of-flight mass spectrometry (UPLC-MS) between wild-type flies (WTCS) and clock disrupted mutants (per01). In addition, clock controlled food intake– feeding behaviour was investigated. Time-dependent variation of transport (DG) and membrane lipids (PE and PC) were not rhythmic in WTCS under constant darkness and in per01 under LD, suggesting an impact of light and clock genes on daily lipid oscillations. Day-time and night-time restriction of food led to comparable lipid profiles, suggesting that lipid oscillations are not exclusively entrained by feeding but rather are endogenously regulated. Ultradian oscillations in lipid levels in WTCS under LD were masked by digested fatty acids since lipid levels peaked more robustly at the beginning and end of light phase when flies were fed a lipid- and protein-free diet. These results suggest that metabolite (DG, PE and PC) oscillation is influenced by complex interactions between nutrient-type, photic conditions, circadian clock and feeding time.
In conclusion, the results of this thesis suggest that circadian clocks determine transport and membrane lipid oscillation in Drosophila hemolymph in complex interactions between nutrient-type, photic conditions and feeding behaviour.
In einem Zeitraum von Oktober 1997 bis Mai 1998 werden an 19 Patienten 22 Untersuchungen der Becken- und Bein-Arterien sowohl in MRA-Technik als auch als i.a. DSA durchgeführt. Hierbei finden im Rahmen der MRA-Untersuchung in allen Fällen die zeitaufgelöste, Kontrastmittel-unterstützte 3d-Flash-Sequenz und die EKG-getriggerte 2d-Flash-Multivenc-Pha-senkontrast-Sequenz Anwendung. Beide Methoden werden in der Diagnostik der pAVK von der Aortenbifurkation bis zum distalen Unterschenkel getestet und in 3 Fällen im Rahmen einer periinterventionellen Kontrolle vor und nach PTA eingesetzt. Das Patientenkollektiv setzt sich ausnahmslos aus Patienten mit pAVK zusammen, die häufig Nebenbefunde wie zum Beispiel einen Diabetes mellitus oder eine Niereninsuffizienz aufweisen. Die Auswertung der Angiographien erfolgt durch die Zuordnung der verschiedenen arte-riellen Abschnitte zu verschiedenen Stenosegraden und dem anschließenden statistischen Ver-gleich der Befunde der MRA und der i.a.DSA. Als Ergebnisse erhalten wir für die Kontrastmittel-unterstützte MRA eine Übereinstim-mungsrate mit der i.a. DSA von 79% sowie eine Sensitivität von 96,7% und eine Spezifität von 97% für die Abbildung hämodynamisch relevanter Stenosen. Die Sensitivität für die Detektion von Verschlüssen beträgt 97,8% und die entsprechende Spezifität 99,2%. Die Phasenkontrast-MRA zeigt im Vergleich mit der i.a.DSA eine schwächere Überein-stimmungsrate von 65,4% sowie eine Sensitivität von 88,3% und eine Spezifität von 85,6% für die Darstellung hämodynamisch relevanter Stenosen. Für die Diagnose eines Gefäßverschlus-ses ist die Sensitivität 89% und die Spezifität 91,8%. Als Schlußfolgerung wird festgestellt, daß die MRA eine nichtinvasive, zur i.a.DSA äqui-valente Untersuchungsmethode darstellt, die bei Kontraindikationen gegen die i.a.DSA einge-setzt werden kann. Im Vergleich zur Phasenkontrast-MRA ist die Kontrastmittel-unterstützte MRA sowohl ein schnelleres als auch ein präziseres Verfahren zur Diagnostik von Gefäßläsio-nen der Becken-Bein-Arterien und bietet den Vorteil der 3-dimensionalen Darstellung. Die Phasenkontrast-MRA ist insbesondere durch die einfache Durchführbarkeit und die fehlende Invasivität ebenfalls als Verfahren zur Diagnostik der peripheren AVK denkbar, jedoch ist zur exakten Stenosegraduierung im Bereich der Läsion eine nachgeschaltete Untersuchung mit weiteren Methoden nötig. Die MRA kann in der postinterventionellen, angiographischen Kontrolle eingesetzt werden. Für die Empfehlung zum routinemäßigen Einsatz in diesem Bereich sind jedoch Studien mit größeren Fallzahlen nötig. In naher Zukunft läßt sich die MRA-Technik durch die Entwicklung von leistungsfähi-geren Gradientenspulensystemen, neuen Prototypen von Oberflächenspulen, intelligenteren Nachverarbeitungs-Algorhytmen und Blutpool-Kontrastmitteln noch weiter optimieren. Die Evolution der MRA-Technik wird ihre Integration in die Routinediagnostik vereinfachen und ihr Indikationsspektrum erweitern.
Infectious diseases caused by pathogenic microorganisms are one of the largest socioeconomic burdens today. Although infectious diseases have been studied for decades, in numerous cases, the precise mechanisms involved in the multifaceted interaction between pathogen and host continue to be elusive. Thus, it still remains a challenge for researchers worldwide to develop novel strategies to investigate the molecular context of infectious diseases in order to devise preventive or at least anti-infective measures. One of the major drawbacks in trying to obtain in-depth knowledge of how bacterial pathogens elicit disease is the lack of suitable infection models to authentically mimic the disease progression in humans. Numerous studies rely on animal models to emulate the complex temporal interactions between host and pathogen occurring in humans. While they have greatly contributed to shed light on these interactions, they require high maintenance costs, are afflicted with ethical drawbacks, and are not always predictive for the infection outcome in human patients. Alternatively, in-vitro two-dimensional (2D) cell culture systems have served for decades as representatives of human host environments to study infectious diseases. These cell line-based models have been essential in uncovering virulence-determining factors of diverse pathogens as well as host defense mechanisms upon infection. However, they lack the morphological and cellular complexity of intact human tissues, limiting the insights than can be gained from studying host-pathogen interactions in these systems.
The focus of this thesis was to establish and innovate intestinal human cell culture models to obtain in-vitro reconstructed three-dimensional (3D) tissue that can faithfully mimic pathogenesis-determining processes of the zoonotic bacterium Campylobacter jejuni (C. jejuni). Generally employed for reconstructive medicine, the field of tissue engineering provides excellent tools to generate organ-specific cell culture models in vitro, realistically recapitulating the distinctive architecture of human tissues. The models employed in this thesis are based on decellularized extracellular matrix (ECM) scaffolds of porcine intestinal origin. Reseeded with intestinal human cells, application of dynamic culture conditions promoted the formation of a highly polarized mucosal epithelium maintained by functional tight and adherens junctions. While most other in-vitro infection systems are limited to a flat monolayer, the tissue models developed in this thesis can display the characteristic 3D villi and crypt structure of human small intestine.
First, experimental conditions were established for infection of a previously developed, statically cultivated intestinal tissue model with C. jejuni. This included successful isolation of bacterial colony forming units (CFUs), measurement of epithelial barrier function, as well as immunohistochemical and histological staining techniques. In this way, it became possible to follow the number of viable bacteria during the infection process as well as their translocation over the polarized epithelium of the tissue model. Upon infection with C. jejuni, disruption of tight and adherens junctions could be observed via confocal microscopy and permeability measurements of the epithelial barrier. Moreover, C. jejuni wildtype-specific colonization and barrier disruption became apparent in addition to niche-dependent bacterial localization within the 3D microarchitecture of the tissue model. Pathogenesis-related phenotypes of C. jejuni mutant strains in the 3D host environment deviated from those obtained with conventional in-vitro 2D monolayers but mimicked observations made in vivo. Furthermore, a genome-wide screen of a C. jejuni mutant library revealed significant differences for bacterial factors required or dispensable for interactions with unpolarized host cells or the highly prismatic epithelium provided by the intestinal tissue model. Elucidating the role of several previously uncharacterized factors specifically important for efficient colonization of a 3D human environment, promises to be an intriguing task for future research.
At the frontline of the defense against invading pathogens is the protective, viscoelastic mucus layer overlying mucosal surfaces along the human gastrointestinal tract (GIT). The development of a mucus-producing 3D tissue model in this thesis was a vital step towards gaining a deeper understanding of the interdependency between bacterial pathogens and host-site specific mucins. The presence of a mucus layer conferred C. jejuni wildtype-specific protection against epithelial barrier disruption by the pathogen and prevented a high bacterial burden during the course of infection. Moreover, results obtained in this thesis provide evidence in vitro that the characteristic corkscrew morphology of C. jejuni indeed grants a distinct advantage in colonizing mucous surfaces.
Overall, the results obtained within this thesis highlight the strength of the tissue models to combine crucial features of native human intestine into accessible in-vitro infection models. Translation of these systems into infection research demonstrated their ability to expose in-vivo like infection outcomes. While displaying complex organotypic architecture and highly prismatic cellular morphology, these tissue models still represent an imperfect reflection of human tissue. Future advancements towards inclusion of human primary and immune cells will strive for even more comprehensive model systems exhibiting intricate multicellular networks of in-vivo tissue. Nevertheless, the work presented in this thesis emphasizes the necessity to investigate host-pathogen interactions in infection models authentically mimicking the natural host environment, as they remain among the most vital parts in understanding and counteracting infectious diseases.