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Die Lamina ist ein dichtes Netzwerk aus Intermediär-Filamenten, den Laminen, an der nucleoplasmatischen Seite der inneren Kernmembran. Hier interagieren Lamine sowohl mit Transmembran-Proteinen der Kernhülle als auch mit dem Chromatin. Diese Wechselwirkungen mit Interaktionspartnern verschiedener zellulärer Kompartimente macht die Lamina, neben einer Gerüststruktur mit wichtigen mechanische Aufgaben, auch zu einer zentralen Schnittstelle von Signalwegen, die eine intrazelluläre Kommunikation zwischen Nucleus und Cytoplasma ermöglichen. Die Lamina ist somit ein entscheidender Regulator der funktionellen Organisation des Chromatins und der differentiellen Genexpression. Das Expressionsmuster der Lamine während der Spermatogenese von Säugern unterscheidet erheblich von der Lamin-Expression somatischer Zellen und weist einige Besonderheiten auf. Dies schließt unter anderem die spezifische Expression der verkürzten A-Typ Lamin-Spleißvariante C2 während der meiotischen Phase der Spermatogenese ein. Diese und andere Beobachtungen deuteten bereits länger darauf hin, dass der speziellen Zusammensetzung der Lamina und vor allem dem meiosespezifischen Lamin C2 während der Gametogenese im männlichen Organismus eine entscheidende Rolle zukommen könnte. Neuere Studien im Mausmodell bekräftigen diese Hypothese und leisten darüber hinaus einen entscheidenden Betrag dazu, die Funktion der Lamina während der Meiose auf molekularer Ebene präzise zu definieren. Im deutlichen Gegensatz zu den weitreichenden Kenntnissen zur Situation in Männchen lagen zu Beginn der vorliegenden Arbeit keine Daten über die Zusammensetzung der Lamina in weiblichen Keimzellen vor. Konsequenterweise existierten auch keine funktionellen Untersuchungen zur Relevanz der Lamina für die Oogenese. In der vorliegenden Arbeit wurden diese reproduktionsbiologisch hoch interessanten Fragestellungen detailliert untersucht. Dabei zeigte sich unter anderem, dass Lamin C2 auch in weiblichen Keimzellen spezifisch während der Meiose exprimiert wird. Durch Studien an einer Lamin C2-defizienten Mauslinie wurde die Funktion von Lamin C2 in der Meiose in Weibchen genau untersucht. Dabei wurde eine erhebliche Beeinträchtigung der strukturellen Paarung der homologen Chromosomen und der homologen Rekombination in Lamin C2-defizienten Weibchen festgestellt. Da die genannten Prozesse Schlüsselereignisse für die korrekte Segregation der Homologen in späteren Stadien der Meiose sind, deuten die erzielten Ergebnisse auf eine erhebliche qualitative Beeinträchtigung der reifen Gameten in Lamin C2-defizienten Weibchen hin. Ein weiterer zentraler Aspekt der Arbeit war die Analyse der molekularen Eigenschaften des meiosespezifischen Lamin C2 in vitro. Diese Experimente definieren wichtige Unterschiede hinsichtlich seiner Polymerisationseigenschaften im Vergleich zu Laminen somatischer Zellen und tragen, zusammen mit anderen Studien, dadurch erheblich dazu bei, die Funktion von Lamin C2 in der Meiose im mechanistischen Sinne besser zu verstehen. Zudem deckt die vorliegende Arbeit erstmals einen funktionellen Zusammenhang zwischen der Lamina-Zusammensetzung und der Qualität der Keimzellen weiblicher Säuger auf und ermöglicht dadurch zukünftige Studien zur Rolle der Lamine in der Oogenese, die möglicherweise auch für die menschliche Fertilität sehr interessant sein könnte. Der zweite Teil der Dissertation beschäftigt sich mit der Beschreibung einer trunkierten A-Typ Lamin-Spleißvariante in einer Mauslinie, die bislang als A-Typ Lamin-defizient angesehen wurde (Lmna-/-). Die durchgeführten Untersuchungen besitzen vor allem dadurch hohe Relevanz, dass die untersuchte Lmna-/- Mauslinie seit Jahren als das wichtigste Modell zur funktionellen Untersuchung der A-Typ Lamine gilt und bereits in einer Vielzahl von Publikationen eingesetzt wurde. In den hierzu durchgeführten Versuchen konnte das in der Lmna-/- Mauslinie persistierende A-Typ Lamin mittels diverser methodischer Ansätze als C-terminale Deletionsmutante definiert werden, der die Exons 8-11 der insgesamt 12 Exons des Lmna-Gens fehlen. Daher wurde diese Lamin A-Mutante als Lamin AΔ8-11 bezeichnet. Die Konsequenzen der C-terminalen Deletion für die physiologischen Eigenschaften des Lamin Adelta8-11 sowie die Auswirkungen seiner Expression in der Lmna-/- Mauslinie auf aktuelle Modellvorstellungen zur Funktion der A-Typ Lamine und zur Entstehung Lamin-assoziierter, humaner Erkrankungen (Laminopathien) werden in der Arbeit ausführlich diskutiert.
Primary contact with human polyomaviruses is followed by lifelong asymptomatic persistence of viral DNA. Under severe immunosuppression JCV activation may lead to unrestricted virus growth in the CNS followed by development of progressive multifocal leukoencephalopathy (PML). Besides the kidney and the brain, target cells of persistent infection were also found in the hematopoietic system. This included the presence of JCV genomes in peripheral blood cells (PBCs). In the attempt to understand the role of PBCs for the JCV infection in humans, we asked for the type of cells affected as well as for virus interaction with PBCs. Analysis of separated subpopulations by highly sensitive and specific polymerase chain reaction and Southern blot hybridization revealed the presence of JCV DNA mostly in circulating granulocytes. These cells have important functions in innate immunity and are professional phagocytes. This suggested that PCR amplified DNA might be the result of an extranuclear association of the virus due to membrane attachment or phagocytosis rather than JCV infection with presence of viral DNA in the nucleus. In the attempt to answer this question JCV DNA was subcellularly localized in the blood of 22 healthy donors by JCV specific fluorescence in situ hybridization (FISH). Granulocytes and peripheral blood mononuclear cells (PBMCs) were separated by Percoll gradient centrifugation. Intracellular JCV DNA was hybridized with Digoxigenin-labeled JCV specific DNA probes covering half of the viral genome. As the sensitivity of the anti-digoxigenin antibody system was lower than the PCR detection level, a chemical amplification step was included consisting of peroxidase labeled secondary antibody precipitating biotinylated tyramide followed by detection with streptavidin-Texas-Red and fluorescence microscopy. Comparison of the number of cells affected in healthy individuals with 15 HIV-1 infected patients with and without PML revealed that the rate of affected PBMCs was comparable in both groups (2.5±0.4 and 14.5±0.9 per 1000). In contrast, the rate of JCV positive granulocytes in the immunosuppressed group was 92.6±1.7% compared to 4±1.4% in healthy donors thus confirming that granulocytes are the major group of circulating cells affected by JCV and that HIV-1 associated immune impairment has an important effect on the virus-cell association. Localization revealed that JCV DNA was predominantly located within the cytoplasm, although hybridizing signals occasionally covered the nuclear compartment. The fluorescent glow of chemical amplification combined with classical fluorescence microscopy did not allow an unequivocal localization of viral DNA. However, confocal microscopy of 24 sections through single cells combined with FISH without chemical amplification confirmed cytoplasmic localization of JCV DNA in a large number of cells. Additionally, it clearly demonstrated that JCV DNA was also located in the nucleus and nuclear localization directly correlated with the number of cells affected. Calculation of the virus load in subcellular compartments revealed that up to 50% of the JCV genomes were located in the nucleus thus pointing to viral infection at least in the granulocytes of HIV-1 infected patients. This may contribute to the distribution of the virus from sites of peripheral infection to the CNS and may promote the development of active PML in the severely immune impaired patients.
The actin cytoskeleton is essential for many cellular functions, such as the regulation of cell morphology, cell migration and vesicle transport processes. The functional diversity of actin structures is reflected in a variety of distinct molecular mechanisms regulating the polymerization of actin filaments. The spontaneous polymerization of actin however is inhibited, by both the instability of small actin oligomers and by actin monomer binding proteins, which prevent the formation of such oligomers. Actin nucleation factors help to overcome this kinetic barrier of filament initiation and are essential for the generation of novel actin filaments at specified subcellular compartments. Spir proteins are the founding members of the novel class of WH2 domain containing actin nucleation factors. They initiate actin polymerization by binding of actin monomers to four WH2 domains in the central part of the protein. Despite their ability to nucleate actin polymerization in vitro by themselves, Spir proteins form a regulatory complex with the distinct actin nucleators of the formin subgroup of formins. Spir functions in the regulation of vesicular originated filamentous actin structures, vesicle transport processes and the assembly of the cleavage furrow during asymmetric meiotic cell divisions. The mammalian genome encodes two spir genes, spir-1 and spir-2. The corresponding proteins have an identical structural array and share a high degree of homology. In order to elucidate the Spir function in developing and adult mouse tissues, the yet unknown expression of the mouse spir-2 gene was addressed. Real-time PCR analysis revealed highest expression of spir-2 in oocytes, the brain, throughout the gastrointestinal tract, testis and kidney of adult mice. In situ hybridizations were performed to substantiate the cellular nature of spir gene expression. During embryogenesis in situ hybridizations show spir-2 to be expressed in the developing nervous system and intestine. In adult mouse tissues highest expression of spir-2 was detected in the epithelial cells of the digestive tract, in neuronal cells of the nervous system and in spermatocytes. In contrast to the more restricted expression of the mouse spir-1 gene, which is mainly found in the nervous system, oocytes and testis, the data presented here show a distinct and broader expression pattern of the spir-2 gene and by this support a more general cell biological function of the novel actin nucleators. In order to address the function of Spir proteins in the developing and adult nervous system, Spir-1 deficient mice were generated by a gene trap method. Spir-1 deficient mice are viable and provide a perfect tool to address the neurobiological function of the Spir-1 protein. Analyses of primary cortical neurons from Spir-1 deficient mice revealed a specific reduction of dendritic branchpoints and are the first description of a neuronal Spir-1 function. Further, a transgenic mouse line (thy1-GFP-M) was employed that expresses the green fluorescent protein (GFP) under the control of neuron specific elements from the thy1 promoter. GFP is thereby expressed in only a subset of neurons and labels the neurons in their entirety. Spir-1 deficient mice carrying the GFP transgene were generated and analyzed. It was found that Spir-1 deficient mice exhibit a reduced number of dendritic spines in the entorhinal cortex compared to wildtype littermates. All together this study gives novel information about the cell biological function of Spir and provides insights how cytoskeletal functions structure the mammalian neuronal network.
The neurodegenerative disorder Alzheimer's disease (AD) is the cause of approximately 60% of the world's 35 million patients suffering from dementia. Current research focuses here are on association with other diseases such as diabetes type 2 (T2DM), possible genetic markers, specific signal transduction pathways within the brain and potential protein modification, because the pathogenesis and etiology of AD are still not fully understood. Specifically association of T2DM with AD came to the focus with the so-called "Rotterdam study" in 1999, indicating that T2DM doubles the risk of developing AD. In the meantime, it is known that the prevalence rate in patients with T2DM is 30%. Drugs commonly used in the treatment of T2DM such as peroxisome proliferator-activated receptors gamma (PPARγ) agonists show improvement of the cognitive abilities in patients with early stage of dementia, with potential therapeutically relevance. Therefore it is important not only to investigate a link between these diseases, but also to investigate the insulin signaling pathway in the brain of AD patients. In order to investigate this complex issue in more details and demonstrate additional links between T2DM and AD, the present study used several basic biological methods to clarify the question: "Is impaired insulin signaling pathway within the brain crucial for the development of AD?" from several points of view. The methods used in this work have been i) an analysis of single nucleotide (SNP) polymorphism of the insulin-degrading enzyme gene (IDE) in relation to risk of AD and / or of T2DM, ii) post-mortem histochemical studies of brain tissue of patients with only AD, with AD combined with T2DM and with only T2DM compared with an age-matched control group, and iii.) investigations of neurochemical pathways and gene/protein expression changes of a human cell culture as a consequences of amyloid β (Aβ) treatment. After analysis of the IDE SNP polymorphism in the selected VITA (Vienna Trans Danube Aging) cohort disease-specific effects were discovered. The upstream polymorphism (IDE2) was found to influence AD risk in a protective manner, while the downstream polymorphism (IDE7) modified the T2DM risk. Based on the SNP results, the presented study delineate the model that IDE promoter and 3‟ untranslated region/downstream variation can have different effects on IDE expression, maybe a relevant endophenotype with disorder-specific effects on AD and T2DM susceptibility. Furthermore, the human post-mortem studies could show that both AD as well as T2DM patients had a significantly lower density of the insulin receptor (IR) in the hippocampus, whereas a significantly increased density of inactive phosphorylated PPARγ has been found and this persisted even in patients with both diseases. Summarizing the histological study, it was possible to reveal common histological features of AD and T2DM, but no direct connection between the two diseases. Although AD is nowadays not only characterized by amyloid-containing plaque deposits and by the hyperphosphorylation of tau protein, the excessive Aβ42 presence in the brains of AD patients is still playing a key role. Up to date it is still not entirely clear which physical form of Aβ42 is responsible for the development of AD. The present work investigated, what impact has the state of aggregation of Aβ42 on genes and proteins of the insulin signaling pathway and the amyloid cascade. It could be shown that the oligomeric variant enhanced specifically the gene and protein expression of glycogen synthase kinase (GSK) 3β and also the enzyme activity was significantly increased, but has in turn strongly inhibited the IR gene and protein expression. Additionally, the effect of Aβ42 on monoamine oxidase B (MAO-B) was examined. An effect of both aggregated forms of Aβ42 had on enzyme activity was discovered. However, the fibrillar variants led to significantly increased activity of MAO-B while the oligomeric variants inhibited the enzyme activity. Several previous studies have demonstrated the involvement of increased MAO-B activity in AD, but the present work provides for the first time a direct link between the states of aggregation of Aβ42 to enzyme activity. Finally the results of the presented thesis can be summarized to following conclusion: Although AD and T2DM sharing some degrees of common features, still there is a lack of direct association, and therefore the diseases must be considered more independent rather than linked. But the impaired cerebral insulin signaling pathway seems to be another manifested hallmark of AD.
Computer Science approaches (software, database, management systems) are powerful tools to boost research. Here they are applied to metabolic modelling in infections as well as health care management. Starting from a comparative analysis this thesis shows own steps and examples towards improvement in metabolic modelling software and health data management. In section 2, new experimental data on metabolites and enzymes induce high interest in metabolic modelling including metabolic flux calculations. Data analysis of metabolites, calculation of metabolic fluxes, pathways and their condition-specific strengths is now possible by an advantageous combination of specific software. How can available software for metabolic modelling be improved from a computational point of view? A number of available and well established software solutions are first discussed individually. This includes information on software origin, capabilities, development and used methodology. Performance information is obtained for the compared software using provided example data sets. A feature based comparison shows limitations and advantages of the compared software for specific tasks in metabolic modeling. Often found limitations include third party software dependence, no comprehensive database management and no standard format for data input and output. Graphical visualization can be improved for complex data visualization and at the web based graphical interface. Other areas for development are platform independency, product line architecture, data standardization, open source movement and new methodologies. The comparison shows clearly space for further software application development including steps towards an optimal user friendly graphical user interface, platform independence, database management system and third party independence especially in the case of desktop applications. The found limitations are not limited to the software compared and are of course also actively tackled in some of the most recent developments. Other improvements should aim at generality and standard data input formats, improved visualization of not only the input data set but also analyzed results. We hope, with the implementation of these suggestions, metabolic software applications will become more professional, cheap, reliable and attractive for the user. Nevertheless, keeping these inherent limitations in mind, we are confident that the tools compared can be recommended for metabolic modeling for instance to model metabolic fluxes in bacteria or metabolic data analysis and studies in infection biology. ...
Ovarian cancer currently causes ~6,000 deaths per year in Germany alone. Since only palliative treatment is available for ovarian carcinomas that have developed resistance against platinum-based chemotherapy and paclitaxel, there is a pressing medical need for the development of new therapeutic approaches. As survival is strongly influenced by immunological parameters, immunotherapeutic strategies appear promising. The research of our group thus aims at overcoming tumour immune escape by counteracting immunosuppressive mechanisms in the tumour microenvironment. In this context, we found that tumour-infiltrating myeloid-derived suppressor cells (MDSC) or tumour associated macrophages (TAM) which are abundant in ovarian cancer express high levels of the enzyme 11β-hydroxysteroid dehydrogenase1 (11-HSD1). This oxido-reductase enzyme is essential for the conversion of biologically inactive cortisone into active cortisol. In line with this observation, high endogenous cortisol levels could be detected in serum, ascitic fluid and tumour exudates from ovarian cancer patients. Considering that cortisol exerts strong anti-inflammatory and immunosuppressive effects on immune cells, it appears likely that high endogenous cortisol levels contribute to immune escape in ovarian cancer. We thus hypothesised that local activation of endogenous glucocorticoids could suppress beneficial immune responses in the tumour microenvironment and thereby prevent a successful immunotherapy. To investigate the in vivo relevance of this postulated immune escape mechanism, irradiated PTENloxP/loxP loxP-Stop-loxP-krasG12D mice were reconstituted with hematopoietic stem cells from either glucocorticoid receptor (GR) expressing mice (GRloxP/loxP) or from mice with a T cell-specific glucocorticoid receptor knock-out (lck-Cre GRloxP/loxP) mice. In the host mice, the combination of a conditional PTEN knock-out with a latent oncogenic kras leads to tumour development when a Cre-encoding adenovirus is injected into the ovarian bursa. Using this model, mice that had been reconstituted with GC-insensitive T cells showed better intratumoural T cell infiltration than control mice that had received functionally unaltered GRloxP/loxP cells via adoptive transfer. However, tumour-infiltrating T cells mostly assumed a Foxp3+ (regulatory) phenotype and survival was even shortened in mice with cortisol-insensitive T cells. Thus, endogenous cortisol seems to inhibit immune cell infiltration in ovarian cancer, but productive anti-tumour immune responses might still be prevented by further factors from the tumour microenvironment. Thus, our data did not provide a sufficiently strong rationale to further pursue the antagonisation of glucocorticoid signalling in ovarian cancer patients, Moreover, glucocorticoids are frequently administered to cancer patients to reduce inflammation and swelling and to prevent chemotherapy-related toxic side effects like nausea or hypersensitivity reactions associated with paclitaxel therapy. Thus, we decided to address the question whether specific signalling pathways in innate immune cells, preferentially in NK cells, could still be activated even in the presence of GC. A careful investigation of the various activating NK cell receptors (i.e. NKp30, NKp44, NKp46), DNAM-1 and NKG2D) was thus performed which revealed that NKp30, NKp44 and NKG2D are all down-regulated by cortisol whereas NKp46 is actually induced by cortisol. Interestingly, NKp46 is the only known receptor that is strictly confined to NK cells. Its activation via crosslinking leads to cytokine release and activation of cytotoxic activity. Stimulation of NK cells via NKp46 may contribute to immune-mediated tumour destruction by triggering the lysis of tumour cells and by altering the cytokine pattern in the tumour microenvironment, thereby generating more favourable conditions for the recruitment of antigen-specific immune cells. Accordingly, our observation that even cortisol-treated NK cells can still be activated via NKp46 and CD2 might become valuable for the design of immunotherapies that can still be applied in the presence of endogenous or therapeutically administered glucocorticoids.
Die Bioinformatik ist eine interdisziplinäre Wissenschaft, welche Probleme aus allen Lebenswissenschaften mit Hilfe computergestützter Methoden bearbeitet. Ihr Ziel ist es, die Verarbeitung und Interpretation großer Datenmengen zu ermöglichen. Zudem unterstützt sie den Designprozess von Experimenten in der Synthetischen Biologie. Die synthetische Biologie beschäftigt sich mit der Generierung neuer Komponenten und deren Eigenschaften, welche durch die Behandlung und Manipulation lebender Organismen oder Teilen daraus entstehen. Ein besonders interessantes Themengebiet hierbei sind Zweikomponenten-Systeme (Two-Component System, TCS). TCS sind wichtige Signalkaskaden in Bakterien, welche in der Lage sind Informationen aus der Umgebung in eine Zelle zu übertragen und darauf zu reagieren. Die vorliegende Dissertation beschäftigt sich mit der Beurteilung, Nutzung und Weiterentwicklung von bioinformatischen Methoden zur Untersuchung von Proteininteraktionen und biologischen Systemen. Der wissenschaftliche Beitrag der vorliegenden Arbeit kann in drei Aspekte unterteilt werden: - Untersuchung und Beurteilung von bioinformatischen Methoden und Weiterführung der Ergebnisse aus der vorhergehenden Diplomarbeit zum Thema Protein-Protein-Interaktionsvorhersagen. - Analyse genereller evolutionärer Modifikationsmöglichkeiten von TCS sowie deren Design und spezifische Unterschiede. - Abstraktion bzw. Transfer der gewonnenen Erkenntnisse auf technische und biologische Zusammenhänge. Mit dem Ziel das Design neuer Experimente in der synthetischen Biologie zu vereinfachen und die Vergleichbarkeit von technischen und biologischen Prozessen sowie zwischen Organismen zu ermöglichen. Das Ergebnis der durchgeführten Studie zeigte, dass Zweikomponenten-Systeme in ihrem Aufbau sehr konserviert sind. Nichtsdestotrotz konnten viele spezifische Eigenschaften und drei generelle Modifikationsmöglichkeiten entdeckt werden. Die Untersuchungen ermöglichten die Identifikation neuer Promotorstellen, erlaubten aber auch die Beschreibung der Beschaffenheit unterschiedlicher Signalbindestellen. Zudem konnten bisher fehlende Komponenten aus TCS entdeckt werden, ebenso wie neue divergierte TCS-Domänen im Organismus Mycoplasma. Eine Kombination aus technischen Ansätzen und synthetischer Biologie vereinfachte die gezielte Manipulation von TCS oder anderen modularen Systemen. Die Etablierung der vorgestellten zweistufigen Modul-Klassifikation ermöglichte eine effizientere Analyse modular aufgebauter Prozesse und erlaubte somit das molekulare Design synthetischer, biologischer Anwendungen. Zur einfachen Nutzung dieses Ansatzes wurde eine frei zugängliche Software GoSynthetic entwickelt. Konkrete Beispiele demonstrierten die praktische Anwendbarkeit dieser Analysesoftware. Die vorgestellte Klassifikation der synthetisch-biologischen und technischen Einheiten soll die Planung zukünftiger Designexperimente vereinfachen und neue Wege für sinnverwandte Bereiche aufzeigen. Es ist nicht die Hauptaufgabe der Bioinformatik, Experimente zu ersetzen, sondern resultierende große Datenmengen sinnvoll und effizient auszuwerten. Daraus sollen neue Ideen für weitere Analysen und alternative Anwendungen gewonnen werden, um fehlerhafte oder falsche Ansätze frühzeitig zu erkennen. Die Bioinformatik bietet moderne, technische Verfahren, um vertraute, aber oft mühsame experimentelle Wege durch neue, vielversprechende Ansätze zur Datenstrukturierung und Auswertung großer Datenmengen zu ergänzen. Neue Sichtweisen werden durch die Erleichterung des Testprozederes gefördert. Die resultierende Zeitersparnis führt zudem zu einer Kostenreduktion.
Das Arbeitsgebiet Tissue Engineering befasst sich mit der Klärung der Mechanismen, die der Funktionen verschiedener Gewebearten zu Grunde liegen sowie mit der Entwicklung alternativer Strategien zur Behandlung von Organversagen bzw. Organverlusten. Einer der kritischsten Punkte im Tissue Engineering ist die ausreichende Versorgung der Zellen mit Nährstoffen und Sauerstoff. Bioartifizielle Gewebe mit einer Dicke von bis zu 200 µm können mittels Diffusion ausreichend versorgt werden. Für dickere Transplantate ist die Versorgung der Zellen alleine durch Diffusion jedoch nicht gegeben. Hierfür müssen Mechanismen und Strategien zur Prävaskularisierung der artifiziellen Gewebekonstrukte entwickelt werden, damit die Nährstoff- und Sauerstoffversorgung aller Zellen, auch im Inneren des Transplantates, von Anfang an gewährleistet ist. Eine wichtige Rolle bei der Prävaskularisierung spielt die Angiogenese. Dabei ist die Wahl einer geeigneten Zellquelle entscheidend, da die Zellen die Basis für die Angiogenese darstellen. Mikrovaskuläre Endothelzellen (mvEZ) sind maßgeblich an der Angiogenese beteiligt. Das Problem bei der Verwendung von humanen primären mvEZ ist ihre geringe Verfügbarkeit, ihre limitierte Proliferationskapazität und der schnelle Verlust ihrer typischen Endothelzellmarker in-vitro. Der Aufbau standardisierter in-vitro Testsysteme ist durch die geringe Zellausbeute auch nicht möglich. Die upcyte® Technologie bietet hierfür einen Lösungsansatz. In der vorliegenden Arbeit konnten upcyte® mvEZ als Alternative zu primären mvEZ generiert werden. Es konnte gezeigt werden, dass die Zellen eine erweiterte Proliferationsfähigkeit aufweisen und im Vergleich zu primären mvEZ durchschnittlich 15 zusätzliche Populationsverdopplungen leisten können. Dadurch ist es möglich 3x104-fach mehr upcyte® mvEZ eines Spenders zu generieren verglichen mit den korrespondierenden Primärzellen. Die gute und ausreichende Verfügbarkeit der Zellen macht sie interessant für die Standardisierung von in-vitro Testsystemen, ebenso können die Zellen zur Prävaskularisierung von Transplantaten eingesetzt werden. Upcyte® mvEZ zeigen zahlreiche Primärzellmerkmale, die in der Literatur beschrieben sind. Im konfluenten Zustand zeigen sie die für primäre mvEZ spezifische pflastersteinartige Morphologie. Darüber hinaus exprimieren upcyte® mvEZ typische Endothelzellmarker wie CD31, vWF, eNOS, CD105, CD146 und VEGFR-2 vergleichbar zu primären mvEZ. Eine weitere endothelzellspezifische Eigenschaft ist die Bindung von Ulex europaeus agglutinin I Lektin an die alpha-L-Fucose enthaltene Kohlenhydratstrukturen von mvEZs. Auch hier wurden upcyte® Zellen mit primären mvEZ verglichen und zeigten die hierfür charkteristischen Strukturen. Zusätzlich zu Morphologie, Proliferationskapazität und endothelzellspezifischen Markern, zeigen upcyte® mvEZ auch mehrere funktionelle Eigenschaften, welche in primären mvEZ beobachtet werden können, wie beispielsweise die Aufnahme von Dil-markiertem acetyliertem Low Density Lipoprotein (Dil-Ac-LDL) oder die Fähigkeit den Prozess der Angiognese zu unterstützen. Zusätzlich bilden Sphäroide aus upcyte® mvEZ dreidimensionale luminäre Zellformationen in einer Kollagenmatrix aus. Diese Charakteristika zeigen den quasi-primären Phänotyp der upcyte® mvEZs. Upcyte® mvEZ stellen darüber hinaus eine neuartige mögliche Zellquelle für die Generierung prävaskularisierter Trägermaterialien im Tissue Engineering dar. In der vorliegenden Arbeit konnte die Wiederbesiedlung der biologisch vaskularisierte Matrix (BioVaSc) mit upcyte® mvEZ vergleichbar zu primären mvEZ gezeigt werden. Der Einsatz von upcyte® mvEZ in der BioVaSc stellt einen neuen, vielversprechenden Ansatz zur Herstellung eines vaskularisierten Modells für Gewebekonstrukte dar, wie beispielsweise einem Leberkonstrukt. Zusammenfassend konnte in der vorliegenden Arbeit gezeigt werden, dass upcyte® mvEZ vergleichbar zu primären mvEZs sind und somit eine geeignete Alternative für die Generierung prävaskulierter Trägermaterialien und Aufbau von in-vitro Testsystemen darstellen. Darüber hinaus wurde ein neues, innovatives System für die Generierung einer perfundierten, mit Endothelzellen wiederbesiedelten Matrix für künstliches Gewebe in-vitro entwickelt.
Das menschliche Genom verschlüsselt 30000 bis 40000 Proteine, von denen ein Großteil kovalent gebundene Karbohydrat-Gruppen an Asparagin-, Serin-, Threonin- oder Hydroxylysin-Resten trägt. Diese sogenannten Glykoproteine sind allgegenwärtige Bestandteile der extrazellulären Matrix von Zelloberflächen. Sie steuern Zell-Zell- und Zell-Matrix-Kommunikationen, können bei der roteinfaltung helfen bzw. die Proteinstabilität erhöhen oder Immunantworten regulieren. Die Auslösung von biologischen Prozesse erfordert aber Übersetzer der zuckerbasierten Informationen. Solche Effektoren sind die Lektine, unter ihnen auch die Galektine. Galektine binden spezifisch β-Galaktosen, weisen strukturelle Übereinstimmungen in der Aminosäuresequenz ihrer Zuckererkennungsdomänen (CRDs) auf und zeigen ein „jelly-roll“-Faltungsmuster, bestehend aus einem β-Sandwich mit zwei antiparallelen Faltblättern. Strukturell werden die CRDs in drei verschiedenen, topologischen Formen präsentiert. Proto-Typen existieren als nicht-kovalent verknüpfte Dimere der CRDs, Chimera-Typen besitzen neben der CRD eine Nicht-Lektin-Domäne und bei den Tandem-Repeat-Typen sind zwei verschiedene CRDs über ein kurzes Linker-Peptid kovalent verbunden. Galektine werden sowohl in normalem wie auch pathogenem Gewebe exprimiert und das zunehmende Wissen über die Beteiligung an verschiedenen Krankheiten und Tumorwachstum liefert die Motivation, strukturelle Aspekte und die Vernetzung von Lektinen detailliert, insbesondere im Hinblick auf ihre intrafamiliären Unterschiede, zu untersuchen. Durch die Kombination verschiedener Spektroskopie-Techniken mit hoher zeitlicher und räumlicher Auflösung, basierend auf der Verwendung von Fluorophoren (intrinsisch und extrinsisch), werden in dieser Arbeit die Eigenschaften von Galektinen näher untersucht. Mit Fluoreszenz-Korrelations-Spektroskopie (FCS) und Anisotropie-Messungen wird gezeigt, dass eine Liganden-Bindung bei Proto-Typ-Galektinen mit einer Verringerung des hydrodynamischen Radius einhergeht. Bei Tandem-Repeat- und Chimera-Typen bleibt der Radius konstant. Dafür skaliert die Diffusionskonstante von Tandem-Repeat-Typen anormal mit der molaren Masse. Die Anisotropie-Messungen werden parallel zu den FCS-Messungen durchgeführt, um einen Einfluss des Fluoreszenzmarkers auszuschließen. Mit Hilfe dieser Technik wird außerdem gezeigt, dass unterschiedliche Dissoziationskonstanten und Kinetiken für den Bindungsprozess innerhalb der Proto-Typ-Gruppe möglichweise auf unterschiedliche Konformationsdynamiken zurückgehen. Der Vergleich von hGal-1 und cG-1B verdeutlicht, dass strukturelle Ähnlichkeiten zwar ein identisches Bindungsverhalten hervorrufen können, der Oxidationsprozess der Proteine aber unterschiedlich ablaufen kann. Beide Methoden können so als sehr sensitive Techniken zur Untersuchung von Strukturmerkmalen bei Galektinen etabliert werden, wobei die Übertragbarkeit auf andere Glykoproteine gewährleistet ist. Weiterhin gilt Quervernetzung als eine der wichtigsten Eigenschaften von Galektinen, da durch die Vernetzung von Glykoproteinen auf der Zelloberfläche Signalwege aktiviert und Immunantworten reguliert werden. Um die räumliche organisation und Quervernetzung von hGal-1 auf den Oberflächen von Neuroblastomzellen nachzuweisen, eignet sich das hochauflösende Mikroskopieverfahren dSTORM sehr gut. Durch Verwendung des photoschaltbaren Fluorophors Alexa647 als spezifischem Marker für hGal-1, einem Standard-Weitfeld-Aufbau und verschiedenen Analyseverfahren, kann eine Clusterformation von hGal-1 auf der Zelloberfläche bestätigt werden. hGal-1 bildet Cluster mit einem mittleren Durchmesser von 81±7 nm aus. Der Durchmesser ist unabhängig von der Konzentration, während die Anzahl der Cluster davon abhängt. Für die Clusterausbildung ist ein Startpunkt, also eine minimale Dichte der Galektin-Moleküle, notwendig. Durch Blockierung der CRDs mit Laktose wird die Clusterbildung unterdrückt und die Spezifität der CRDs gegenüber β-Galaktosen erneut herausgestellt. Anders als dimeres hGal-1 binden Monomere deutlich schlechter an die Membranrezeptoren. Es werden keine Cluster ausgebildet, eine Quervernetzung von Membranrezeptoren ist nicht möglich. Außerdem kann es durch die Monomere zu einer vollständigen Markierung und damit Abkugellung der Zellen kommen. Möglicherweise wird der Zelltod induziert. Hochauflösende Mikroskopieverfahren sind durch den Markierungsprozess limitiert. Die bioorthogonale Click-Chemie eröffnet jedoch neue Möglichkeiten zur Markierung und Visualisierung von Biomolekülen, ohne die Notwenigkeit genetischer Manipulationen. Es werden modifizierte Zuckermoleküle in die Zellmembranen eingebaut, über eine 1,3-polare Cycloaddition mit einem Alkin markiert und ihre Verteilung mit Hilfe von dSTORM untersucht. Es wird nachgewiesen, dass die Zuckermoleküle in Clustern auftreten und Click-Chemie trotz dem Katalysator Kupfer an lebenden Zellen durchführbar ist. Die Bewegung der Gesamtcluster wird mittels Mean Square Displacement aufgeschlüsselt und eine Diffusionskonstante für Cluster im Bereich von 40 - 250 nm bestimmt. Zusammenfassend stellt die Kombination verschiedener Spektroskopie-Techniken ein gutes Werkzeug zur Untersuchung von Karbohydrat-bindendenden Proteinen mit hoher räumlicher und zeitlicher Auflösung dar und ermöglicht einen neuen Einblick in die Biologie der Galektine.
Schwermetallsalze wie beispielsweise Aluminium- oder Eisensalze werden in der Abwasserbehandlung zur Prävention und Bekämpfung von Blähschlamm, Schwimmschlamm und Schaumbildung verwendet. Dadurch kann eine Verbesserung der Schlammabsetzeigenschaften im Nachklärbecken erreicht werden. Übermäßiges Wachstum des grampositiven Bakteriums Microthrix parvicella gilt dabei als Hauptursache von Schlammabsetzproblemen und kann ebenfalls durch die Dosierung von schwermetallhaltigen Flockungs- und Fällungsmitteln vermieden werden. Da diese Verbindungen in Wasser gelöst sind, müssen sie die Außenmembran bestimmter Bakterien passieren. Nur der Einbau von wassergefüllten Kanälen erlaubt den gelösten Salzen das Passieren der durch hydrophobe Fettsäuren aufgebauten zusätzlichen Permeabilitätsbarriere. In dieser Arbeit wurden wassergefüllten Kanäle von Microthrix parvicella isoliert, aufgereinigt und mit Hilfe der Black-Lipid-Bilayer-Technik charakterisiert. Ergänzend wurde der Einfluss und der Durchlass der Flockungs- und Fällungsmittel in Titrationsexperimenten untersucht. Dabei konnte ein wassergefüllter Kanal, der die Bezeichnung MppA erhielt, gefunden werden, welcher eine Leitfähigkeit von 600 pS in 1 M Kaliumchlorid und eine Bindestelle für mehrwertige Kationen wie Eisen oder Aluminium zeigte. Die Bindung dieser mehrwertigen Kationen führte zu einer Änderung der Ionenselektivität. Ohne Bindung mehrwertiger Kationen zeigte der Kanal eine leichte Kationenselektivität. Nach der Bindung wechselte die Ionenselektivität zu einer Anionenselektivität, was auf eine spezifische Ladungsverteilung im Kanal hinweist. Der Kanal MppA zeigte gleichwertige Bindekonstanten für Aluminium und Eisen. Beide Metalle werden als Fällungs- und Flockungsmittel in Kläranlagen zum Verhindern von Schwimm- und Blähschlamm verwendet. Frühere Arbeiten offenbarten bereits, dass hauptsächlich der Aluminiumanteil entscheidend für die Wirkung dieser Mittel ist. Diese Beobachtungen in Verbindung mit den Ergebnissen dieser Arbeit führten zu der Annahme, dass Eisen und Aluminium eine kompetitive Bindung an der Bindestelle im Kanalinneren zeigen könnten. So könnte in manchen Fällen Aluminium anstelle des sonst als Spurenelement benötigten Eisens durch den Kanal transportiert werden und in Enzym-Substrat-Komplexen eingebaut werden. Dadurch könnten toxische Effekte auftreten, die letztlich ein Absterben des Organismus zur Folge hätten. Für die Bindung der Metallsalze konnte zusätzlich eine pH-Abhängigkeit beobachtet werden. Nur eine Zugabe von Metalllösungen mit einem pH-Wert kleiner 6 führte zu einer Bindung im Kanal. Die Zugabe von Metalllösungen mit einem pH-Wert größer 6 zeigte keinen Effekt auf die Leitfähigkeit des Kanals. Diese Ergebnisse bestätigen die auf Kläranlagen und in vorherigen Arbeiten getätigte Beobachtung, dass der pH-Wert für die Wirksamkeit der Verbindungen entscheidend ist. In dieser Arbeit konnte jedoch erstmals gezeigt werden, dass der pH-Wert direkt die Bindung der Metallsalze beeinflusst.
Non–Small-Cell Lung Cancer (NSCLC) is the most frequent human lung cancer and a major cause of death due to its high rate of metastasis1. These facts emphasize the urgent need for the investigation of new targets for anti-metastatic therapy. Up to now a number of genes and gene products have been identified that positively or negatively affect the probability of established human tumor cell lines to metastasize2. Previously, together with the group of Professor Ulf Rapp, we have described the first conditional mouse model for metastasis of NSCLC and identified a gene, c-MYC, that is able to orchestrate all steps of this process. We could identify potential markers for detection of metastasis and highlighted GATA4, which is exclusively expressed during lung development, as a target for future therapeutic intervention2. However, the mechanism underlying this metastatic conversion remained to be identified, and was therefore the focus of the present work. Here, GATA4 is identified as a MYC target in the development of metastasis and epigenetic alterations at the GATA4 promoter level are shown after MYC expression in NSCLC in vivo and in vitro. Such alterations include site-specific demethylation that accompanies the displacement of the MYC-associated zinc finger protein (MAZ) from the GATA4 promoter, which leads to GATA4 expression. Histone modification analysis of the GATA4 promoter revealed a switch from repressive histone marks to active histone marks after MYC binding, which corresponds to active GATA4 expression. This work identifies a novel epigenetic mechanism by which MYC activates GATA4 leading to metastasis in NSCLC, suggesting novel potential targets for the development of anti-metastatic therapy.
Measuring and estimating biodiversity patterns is a fundamental task of the scientist working to support conservation and informmanagement decisions.Most biodiversity studies in temperate regions were often carried out over a very short period of time (e.g., a single season) and it is often—at least tacitly—assumed that these short-termfindings are representative of long-termgeneral patterns.However, should the studied biodiversity pattern in fact contain significant temporal dynamics, perhaps leading to contradictory conclusions. Here, we studied the seasonal diversity dynamics of arboreal spider communities dwelling in 216 European beeches (Fagus sylvatica L.) to assess the spider community composition in the following seasons: two cold seasons (I:November 2005–January 2006; II: February–April) and two warm seasons (III: May–July; IV: August–October). We show that the usually measured diversity of the warmseason community (IV: 58 estimated species) alone did not deliver a reliable image of the overall diversity present in these trees, and therefore, we recommend it should not be used for sampling protocols aimed at providing a full picture of a forest’s biodiversity in the temperate zones. In particular, when the additional samplings of other seasons (I, II, III) were included, the estimated species richness nearly doubled (108). Community I possessed the lowest diversity and evenness due to the harsh winter conditions: this community was comprised of one dominant species together with several species low in abundance. Similarity was lowest (38.6%) between seasonal communities I and III, indicating a significant species turnover due to recolonization, so that community III had the highest diversity. Finally, using nonparametric estimators, we found that further sampling in late winter (February–April) is most needed to complete our inventory. Our study clearly demonstrates that seasonal dynamics of communities should be taken into account when studying biodiversity patterns of spiders, and probably forest arthropods in general.
Background: Combination of oncolytic vaccinia virus therapy with conventional chemotherapy has shown promise for tumor therapy. However, side effects of chemotherapy including thrombocytopenia, still remain problematic. Methods: Here, we describe a novel approach to optimize combination therapy of oncolytic virus and chemotherapy utilizing virus-encoding hyper-IL-6, GLV-1h90, to reduce chemotherapy-associated side effects. Results: We showed that the hyper-IL-6 cytokine was successfully produced by GLV-1h90 and was functional both in cell culture as well as in tumor-bearing animals, in which the cytokine-producing vaccinia virus strain was well tolerated. When combined with the chemotherapeutic mitomycin C, the anti-tumor effect of the oncolytic virotherapy was significantly enhanced. Moreover, hyper-IL-6 expression greatly reduced the time interval during which the mice suffered from chemotherapy-induced thrombocytopenia. Conclusion: Therefore, future clinical application would benefit from careful investigation of additional cytokine treatment to reduce chemotherapy-induced side effects.
Oncolytic viruses refer to those that are able to eliminate malignancies by direct targeting and lysis of cancer cells, leaving non-cancerous tissues unharmed. Several oncolytic viruses including adenovirus strains, canine distemper virus and vaccinia virus strains have been used for canine cancer therapy in preclinical studies. However, in contrast to human studies, clinical trials with oncolytic viruses for canine cancer patients have not been reported. An ‘ideal’ virus has yet to be identified. This review is focused on the prospective use of oncolytic viruses in the treatment of canine tumors - a knowledge that will undoubtedly contribute to the development of oncolytic viral agents for canine cancer therapy in the future.
Background: Tardigrades are multicellular organisms, resistant to extreme environmental changes such as heat, drought, radiation and freezing. They outlast these conditions in an inactive form (tun) to escape damage to cellular structures and cell death. Tardigrades are apparently able to prevent or repair such damage and are therefore a crucial model organism for stress tolerance. Cultures of the tardigrade Milnesium tardigradum were dehydrated by removing the surrounding water to induce tun formation. During this process and the subsequent rehydration, metabolites were measured in a time series by GC-MS. Additionally expressed sequence tags are available, especially libraries generated from the active and inactive state. The aim of this integrated analysis is to trace changes in tardigrade metabolism and identify pathways responsible for their extreme resistance against physical stress. Results: In this study we propose a novel integrative approach for the analysis of metabolic networks to identify modules of joint shifts on the transcriptomic and metabolic levels. We derive a tardigrade-specific metabolic network represented as an undirected graph with 3,658 nodes (metabolites) and 4,378 edges (reactions). Time course metabolite profiles are used to score the network nodes showing a significant change over time. The edges are scored according to information on enzymes from the EST data. Using this combined information, we identify a key subnetwork (functional module) of concerted changes in metabolic pathways, specific for de- and rehydration. The module is enriched in reactions showing significant changes in metabolite levels and enzyme abundance during the transition. It resembles the cessation of a measurablemetabolism (e.g. glycolysis and amino acid anabolism) during the tun formation, the production of storage metabolites and bioprotectants, such as DNA stabilizers, and the generation of amino acids and cellular components from monosaccharides as carbon and energy source during rehydration. Conclusions: The functional module identifies relationships among changed metabolites (e.g. spermidine) and reactions and provides first insights into important altered metabolic pathways. With sparse and diverse data available, the presented integrated metabolite network approach is suitable to integrate all existing data and analyse it in a combined manner.
Myc is a global transcriptional regulator and one of the most frequently overexpressed oncoproteins in human tumors. It is well established that activation of Myc leads to enhanced cell proliferation but can also lead to increased apoptosis. The use of animal models expressing deregulated levels of Myc has helped to both elucidate its function in normal cells and give insight into how Myc initiates and maintains tumorigenesis. Analyses of the medaka (Oryzias latipes) genome uncovered the unexpected presence of two Myc gene copies in this teleost species. Comparison of these Myc versions to other vertebrate species revealed that one gene, myc17, differs by the loss of some conserved regulatory protein motifs present in all other known Myc genes. To investigate how such differences might affect the basic biological functions of Myc, we generated a tamoxifeninducible in vivo model utilizing a natural, fish-specific Myc gene. Using this model we show that, when activated, Myc17 leads to increased proliferation and to apoptosis in a dose-dependent manner, similar to human Myc. We have also shown that long-term Myc17 activation triggers liver hyperplasia in adult fish, allowing this newly established transgenic medaka model to be used to study the transition from hyperplasia to liver cancer and to identify Myc-induced tumorigenesis modifiers.
A metacommunity approach will be a useful framework to assess and predict changes in biodiversity in spatially structured landscapes and changing environments. However, the relationship between two core elements of metacommunity dynamics, dispersal and species interaction are not well understood. Most theoretical studies on dispersal evolution assume that target species are in isolation and do not interact with other species although the species interactions and community structure should have strong interdependence with dispersal. On the one hand, a species interaction can change the cost and benefit structure of dispersing in relation to non-dispersing individuals. On the other hand, with dispersal, an individual can follow respectively avoid species partners. Moreover, it is also important to explore the interdependence between dispersal and species interaction with spatial and temporal heterogeneity of environment because it would allow us to gain more understanding about responses of community to disturbances such as habitat destruction or global climate change, and this aspect is up to now not well-studied. In this thesis, I focus on the interactive and evolutionary feedback effects between dispersal and various types of interspecific interactions in different environmental settings. More specifically, I contrast dispersal evolution in scenarios with different types of interactions (chapter 2), explore the concurrent evolution of dispersal and habitat niche width (specialization) in spatial heterogeneous landscape (chapter 3) and consider (potential) multidimensional evolutionary responses under climate change (chapter 4). Moreover, I investigate consequences of different dispersal probability and group tolerance on group formation respectively group composition and the coexistence of ‘marker types’ (chapter 5). For all studies, I utilize individual-based models of single or multiple species within spatially explicit (grid-based) landscapes. In chapter 5, I also use an analytical model in addition to an individual-based model to predict phenomenon in group recognition and group formation. ...
Cellular responses to outer stimuli are the basis for all biological processes. Signal integration is achieved by protein cascades, recognizing and processing molecules from the environment. Factors released by pathogens or inflammation usually induce an inflammatory response, a signal often transduced by Tumour Necrosis Factor alpha (TNF). TNFα receptors TNF-R1 and TNF-R2 can in turn lead to apoptosis or proliferation via NF-B. These processes are closely regulated by membrane compartimentalization, protein interactions and trafficking. Fluorescence microscopy offers a reliable and non-invasive method to probe these cellular events. However, some processes on a native membrane are not resolvable, as they are well below the diffraction limit of microscopy. The recent development of super-resolution fluorescence microscopy methods enables the observation of these cellular players well below this limit: by localizing, tracking and counting molecules with high spatial and temporal resolution, these new fluorescence microscopy methods offer a previously unknown insight into protein interactions at the near-molecular level. Direct stochastic optical reconstruction microscopy (dSTORM) utilizes the reversible, stochastic blinking events of small commercially available fluorescent dyes, while photoactivated localization microscopy (PALM) utilizes phototransformation of genetically encoded fluorescent proteins. By photoactivating only a small fraction of the present fluorophores in each observation interval, single emitters can be localized with high precision and a super-resolved image can be reconstructed. Quantum Dot Triexciton imaging (QDTI) utilizes the three-photon absorption (triexcitonic) properties of quantum dots (QD) and to achieve a twofold resolution increase using conventional confocal microscopes. In this thesis, experimental approaches were implemented to achieve super-resolution microscopy in fixed and live-cells to study the spatial and temporal dynamics of TNF and other cellular signaling events. We introduce QDTI to study the three-dimensional cellular distribution of biological targets, offering an easy method to achieve resolution enhancement in combination with optical sectioning, allowing the preliminary quantification of labeled proteins. As QDs are electron dense, QDTI can be used for correlative fluorescence and transmission electron microscopy, proving the versatility of QD probes. Utilizing the phototransformation properties of fluorescent proteins, single-receptor tracking on live cells was achieved, applying the concept of single particle tracking PALM (sptPALM) to track the dynamics of a TNF-R1-tdEos chimera on the membrane. Lateral receptor dynamics can be tracked with high precision and the influences of ligand addition or lipid disruption on TNF-R1 mobility was observed. The results reveal complex receptor dynamics, implying internalization processes in response to TNFα stimulation and a role for membrane domains with reduced fluidity, so-called lipid raft domains, in TNF-R1 compartimentalization prior or post ligand induction. Comparisons with previously published FCS data show a good accordance, but stressing the increased data depth available in sptPALM experiments. Additionally, the active transport of NF-κB-tdEos fusions was observed in live neurons under chemical stimulation and/or inhibition. Contrary to phototransformable proteins that need no special buffers to exhibit photoconversion or photoactivation, dSTORM has previously been unsuitable for in vivo applications, as organic dyes relied on introducing the probes via immunostaining in concert with a reductive, oxygen-free medium for proper photoswitching behaviour. ATTO655 had been previously shown to be suitable for live-cell applications, as its switching behavior can be catalyzed by the reductive environment of the cytoplasm. By introducing the cell-permeant organic dye via a chemical tag system, a high specificity and low background was achieved. Here, the labeled histone H2B complex and thus single nucleosome movements in a live cell can be observed over long time periods and with ~20 nm resolution. Implementing these new approaches for imaging biological processes with high temporal and spatial resolution provides new insights into the dynamics and spatial heterogeneities of proteins, further elucidating their function in the organism and revealing properties that are usually only detectable in vitro.
Hey-mutant mouse hearts at embryonic day E14.5 were shown to react to the knock out of Hey2 with several up-regualted genes. This up-regulation is due to the lack of Hey2 and cannot be explained by the structural changes in heart morphology as shown using control animals. Part of the gene regulation was further validated using in situ hybridization. Hey1 was located to the nucleus in immunofluorescence experiments. However, experiments on protein level showed also amount of Hey1 within the cytoplasm. The nuclear localization of Hey1 was unchanged during all cell cycle phases as well as when CaMKII was co-expressed or other cellular pathways were inhibited or stimulated. Hey1 does not seem to interact with the nuclear transport proteins importin-alpha and -beta, therefore it still needs to be elucidated how Hey1 is transported into the nucleus.
Human adult cartilage is an aneural and avascular type of connective tissue, which consequently reflects reduced growth and repair rates. The main cell type of cartilage are chondrocytes, previously derived from human mesenchymal stem cells (hMSCs). They are responsible for the production and maintainance of the cartilaginous extracellular matrix (ECM), which consists mainly of collagen and proteoglycans. Signal transmission to or from chondrocytes, generally occurs via interaction with signalling factors connected to the cartilaginous ECM. In this context, proteins of the CCN family were identified as important matricellular and multifunctional regulators with high significance during skeletal development and fracture repair. In this thesis, main focus lies on WISP1/CCN4, which is known as a general survival factor in a variety of cell types and seems to be crucial during lineage progression of hMSCs into chondrocytes. We intend to counter the lack of knowledge about the general importance of WISP1-signalling within the musculoskeletal system and especially regarding cell death and survival by a variety of molecular and cell biology methods. First, we established a successful down-regulation of endogenous WISP1 transcripts within different cell types of the human musculoskeletal system through gene-silencing. Interestingly, WISP1 seems to be crucial to the survival of all examined cell lines and primary hMSCs, since a loss of WISP1 resulted in cell death. Bioinformatical analyses of subsequent performed microarrays (WISP1 down-regulated vs. control samples) confirmed this observation in primary hMSCs and the chondrocyte cell line Tc28a2. Distinct clusters of regulated genes, closely related to apoptosis induction, could be identified. In this context, TRAIL induced apoptosis as well as p53 mediated cell death seem to play a crucial role during the absence of WISP1 in hMSCs. By contrast, microarray analysis of WISP1 down-regulated chondrocytes indicated rather apoptosis induction via MAPK-signalling. Despite apoptosis relevant gene regulations, microarray analyses also identified clusters of differentially expressed genes of other important cellular activities, e.g. a huge cluster of interferon-inducible genes in hMSCs or gene regulations affecting cartilage homeostasis in chondrocytes. Results of this thesis emphasize the importance of regulatory mechanisms that influence cell survival of primary hMSCs and chondrocytes in the enforced absence of WISP1. Moreover, findings intensified the assumed importance for WISP1-signalling in cartilage homeostasis. Thus, this thesis generated an essential fundament for further examinations to investigate the role of WISP1-signalling in cartilage homeostasis and cell death.