Refine
Has Fulltext
- yes (40)
Is part of the Bibliography
- yes (40) (remove)
Year of publication
- 2011 (40) (remove)
Document Type
- Doctoral Thesis (40) (remove)
Keywords
- Biene (4)
- Genexpression (3)
- Memory (3)
- Taufliege (3)
- Bioinformatik (2)
- Drosophila (2)
- Drosophila melanogaster (2)
- Epidermaler Wachstumsfaktor-Rezeptor (2)
- Gedächtnis (2)
- Learning (2)
Institute
- Theodor-Boveri-Institut für Biowissenschaften (40) (remove)
Trotz beträchtlicher Anstrengung Malaria zu kontrollieren bzw. zu eradizieren, stellt die Krankheit weiterhin eines der gravierendsten Gesundheitsprobleme unseres Jahrtausends dar. Malaria fordert jährlich zwischen 0,7 und 2,7 Millionen Menschenleben, beeinträchtigt schulische und soziale Entwicklung und hemmt erheblich das Wirtschaftswachstum der betroffenen Länder. In Burkina Faso, einem der ärmsten Länder der Welt, ist Malaria eines der größten Gesundheitsprobleme und ca. ein Drittel aller Todesfälle werden hier Malaria angelastet. Die sich weiter ausbreiteten Resistenzen gegen die gängigen Malariamedikamente machen die Bekämpfung der Malaria zunehmend schwierig. Artemisinin basierende Kombinationstherapien sind aktuell, trotz relativ hoher Therapiekosten und erster Resistenzen, die Erstlinien Behandlung. Effektive und billige neue Kombinationstherapien werden dringend benötigt. In dieser Doktorarbeit wurde das Resistenzpotential von Artemisinin modelliert. Die Homologiemodellierungen unterstützen die These von Krishna und Kollegen von SERCA als einzige Zielstruktur von Artemisinin. Des Weiteren wurde Methylenblau als neues altes Malariamittel evaluiert. Methylenblau ist das erste gegen Malaria eingesetzte Medikament, agiert als ein prooxidatives Agens und inhibiert selektiv und nicht-kompetitiv die P. falciparum Glutathion Reduktase. Die additiven und multiplen Zielprotein Effekte von Methylenblau wurden experimentell untersucht und hier in einem bioinformatischem Modell getestet. Unter dem Einfluss von Methylenblau werden einige Schlüsselenzyme des Redoxstoffwechsels in ihrer Aktivität beeinträchtigt und der Parasit wird verstärkt oxidativem Stress ausgesetzt. Des Weiteren konnte in dieser Dr. Arbeit eine starke Kooperationsbereitschaft der urbanen und ländlichen Bevölkerung an zukünftigen Malaria Projekten gezeigt werden.
Das maligne Melanom ist ein Hauttumor mit steigender Inzidenz und hohen Mortalitätsraten. Da die molekularbiologischen Ereignisse, die der Melanomentwicklung zugrundeliegen, nur unzureichend bekannt sind, gibt es kaum spezifische Therapieansätze. Zur Untersuchung der Melanomentwicklung eignet sich das Xiphophorus-Modell. In diesem System ist die Anwesenheit der RTK Xmrk ausreichend, um durch Aktivierung proliferativer und entdifferenzierender Signalwege und Apoptoseinhibition Melanome zu verursachen. Im Rahmen der vorliegenden Arbeit konnte gezeigt werden, dass Xmrk auch die Migration der Melanozytenzellinie Melan a-Hm induzieren kann. Die Migration der durch Xmrk transformierten Zellen ist amöboid und unabhängig von MAPK- und PI3K-Signalwegen. Eine Funktion bei der Migration haben jedoch die Kinasen FAK und Fyn. Sie bilden möglicherweise einen Proteinkomplex, der für FAK und Src aus zahlreichen anderen Systemen bekannt ist und als Signalplattform für die Zellmigration fungiert. Diese Erkenntnisse können dazu beitragen, das Xiphophorus-Modell weiterzuentwickeln und die Grundlagen der Melanomgenese besser zu verstehen.
Spir proteins are the founding members of the novel class of WH2-actin nucleators. A C-terminal modified FYVE zinc finger motif is necessary to target Spir proteins towards intracellular membranes. The function and regulation of the Spir actin organizers at vesicular membranes is almost unknown. Live cell imaging analyses performed in this study show that Spir-2 is localized at tubular vesicles. Cytoplasmic Spir-2-associated vesicles branch and form protrusions, which can make contacts to the microtubule network, where the Spir-2 vesicles stretch and slide along the microtubule filaments. The analysis of living HeLa cells expressing eGFP-tagged Spir-2, Spir-2-ΔKIND and Spir-2-ΔKW (lacking the 4 WH2 domains and the KIND domain) showed Spir-2-associated tubular structures which differ in their length and motility. Throughout the course of that study it could be shown that the tail domain of the actin motor protein myosin Vb, as a force-generating molecule, is colocalizing and co-immunoprecipitating with Spir-2-ΔKW. By using the tail domain of myosin Vb as a dominant negative mutant for myosin Vb-dependent vesicle transport processes it could be shown that Spir-2-ΔKW/MyoVb-cc-tail- associated vesicles exhibit an increased elongation. Moreover, using the microtubule depolymerizing drug nocodazole it could be shown that the elongation and the motility of Spir-2-ΔKW-associated vesicles depends on an intact microtubule cytoskeleton. Motility and morphological dynamics of Spir-2-associated vesicles is therefore dependent on actin, actin motorproteins and microtubule filaments. These results propose a model in which myosin/F-actin forces mediate vesicle branching, allowing the vesicles to move to and in between the microtubule filaments and thereby providing a new degree of freedom in vesicular motility. To determine the exact subcellular localization of Spir-2, colocalization studies were performed. It could be shown that Spir-2 shows a partial colocalization to Rab11a-positive compartments. Furthermore, Spir-2 exhibits an almost identical localization to Arf1 and the Arf1 small G protein but not Rab11a could be immunoprecipitated with Spir-2-ΔKW. This suggests, that Arf1 recruits Spir-2 to Arf1/Rab11a-positive membranes. Another important function of the Spir-2 C-terminus is the membrane targeting by the FYVE domain. By performing a protein-lipid overlay assay, it has been shown that purified GST- and 6xHis-tagged Spir-2-ΔKW bind phosphatidic acid suggesting a mechanism in which Spir-2 is recruited to phosphatidic acid-enriched membranes. To further elucidate the mechanism in which Spir-2 membrane-targeting could be regulated, interaction studies of C-terminal parts of Spir-2 revealed that the Spir-2 proteins interact directly.
There is more and more evidence for the cancer stem cell hypothesis which believes that cancers are driven by a cellular subcomponent that has stem cell properties which is self-renewal, tumorigenicity and multilineage differentiation capacity. Cancer stem cells have been connected to the initiation of tumors and are even found to be responsible for relapses after apparently curative therapies have been undertaken. This hypothesis changes our conceptual approach of oncogenesis and shall have implications in breast cancer prevention, detection and treatment, especially in metastatic breast cancer for which no curative treatment exists. Given the specific stem cell features, novel therapeutic pathways can be targeted. Since the value of vaccinia virus as a vaccination virus against smallpox was discovered by E. Jenner at 18th century, it plays an important role in human medicine and molecular biology. After smallpox was successfully eradicated, vaccinia virus is mainly used as a viral vector in molecular biology and increasingly in cancer therapy. The outstanding capability to specifically target and destroy cancer cells makes it a perfect agent for oncolytic virotherapy. Furthermore, the virus can easily be modified by inserting genes which encode therapeutic or diagnostic proteins to be expressed when a tumor is infected. The emphasis in this study was the establishment of methods for the enrichment of human breast cancer stem-like cells from cancer cell lines and characterization of those cancer stem-like cells in vitro and in vivo. Furthermore, by using the Genelux Corporation vaccinia virus strain GLV-1h68, the isolated cancer stem-like cells can be targeted not only in vitro but also in vivo more efficiently. Side-population (SP) cells within cancers and cell lines are rare cell populations known to be enriched cancer stem-like cells. In this study, we used Hoechst 33342 staining and flow cytometry to identify SP cells from the human breast cancer cell lines MCF-7 and GI-101A as models for cancer stem-like cells. Considering the cytotoxicity of Hoechst dye and the restriction of instrument, we did not carry out further studies by this method. Utilizing in vitro and in vivo experimental systems, we showed that human breast cancer cell line GI-101A with aldehyde dehydrogenase activity (ALDH) have stemlike properties. Higher ALDH activity identifies the tumorigenic cell fraction which is capable of self-renewal and of generating tumors that could recapitulate the heterogeneity of the parental tumor. Furthermore, the cells with higher ALDH activity display significant resistance to chemotherapy and ionizing radiation, which proves their stem-like properties again. The cells which have higher ALDH activity also are more invasive compared to cells which have lower ALDH activity, which connects the cancer stem-like cells with cancer metastases. By analyzing the popular human breast cancer stem cells surface markers CD44, CD49f and CD24, it was discovered that the cells with higher ALDH activity have stronger CD44 and CD49f expression than in those cells with lower ALDH activity, which further confirms their stem-like properties. Finally, the cells with higher ALDH activity and lower ALDH activity were infected in vitro and used in virotherapy in a mouse xenograft model was performed. The results indicated that the vaccinia virus GLV-1h68 can replicate in cells with higher ALDH activity more efficiently than cells with lower ALDH activity. GLV-1h68 also can selectively target and eradicate the xenograft tumors which were derived from cells with higher ALDH activity. The epithelial-mesenchymal transition (EMT) is a key developmental program that is often activated during cancer invasion and metastases. EMT was induced in immortalized human mammary epithelial cells (HMLEs) and in GI-101A cells, which results in the acquisition of mesenchymal traits and in the expression of stem cell markers. Furthermore, the EMT-induced GI-101A cells showed resistance to chemotherapy and invasion capacity. CD44+/CD24- cells were enriched during the EMT induction. Following flow cytometry sorting by using CD44, CD24 and ESA surface marker, the sorted cells were tested in a mouse model regarding tumorigenicity. Unexpectedly, we found that CD44+/CD24+/ESA+ cells could initiate tumors more efficiently rather than CD44+/CD24-/ESA+ and other fractions in EMTinduced GI-101A cells. We also infected the CD44+/CD24+/ESA+ and CD44+/CD24- /ESA+ cells in vitro and performed virotherapy in a mouse xenograft model. The results indicated that the vaccinia virus GLV-1h68 is able to replicate in CD44+/CD24+/ESA+ cells more efficiently than in CD44+/CD24-/ESA+ cells. GLV-1h68 was also capable to selectively target and eradicate the xenograft tumors which derived from CD44+/CD24+/ESA+ cells. Moreover, CD44- cells have much lower tumorigenicity in the mouse model and CD44- cells derived-tumors are not responsive to vaccinia virotherapy. In summary, we have successfully established an in vitro and in vivo system for the identification, characterization and isolation of cancer stem-like cells from the human breast cancer cell line GI-101A by using the ALDEFLUOR assay. The vaccinia virus GLV-1h68 was able to efficiently target and eradicate the higher ALDH activity cells and tumors derived from those cells. Although contrary to the current assumption, CD44+/CD24+/ESA+ cells in the EMT-induced GI-101A cell line showed stem-like properties and GLV-1h68 was able to efficiently target and eradicate the CD44+/CD24+/ESA+ cells and tumors which derived from those cells. Finally, improved understanding of cancer stem cells may have tremendous relevance for how cancer should be treated. It is menacing that cancer stem cells are resistant to almost all anti-tumor approaches which have already been established for the treatment of metastatic diseases such as ionizing radiation, hormonal therapy, chemotherapy, and small molecular inhibitors. Therefore, it is promising that our results suggest that these cancer stem cells may be susceptible to treatment with oncolytic vaccinia virus.
HMGA1 Proteine sind kleine, basische, Nicht-Histon Proteine, die in Lösung keine Struktur aufweisen, durch drei AT-Haken, als DNA-Bindungsmotive, gekennzeichnet sind und präferentiell an die kleine Furche der DNA binden. Als differenziell exprimierte Architekturelemente des Chromatins erfüllen sie wichtige Funktionen bei der Regulation DNA abhängiger Prozesse in Zellen und während Entwicklungsprozessen. Aberrante Expressionen führen zu Entwicklungsdefekten und Krebs. In dieser Arbeit wurde der Einfluss von HMGA1 Proteinen auf die Organisation des Chromatins untersucht. Als Modell diente dabei zunächst die Differenzierung von C2C12 Muskelvorläuferzellen. Wie in einer früheren Arbeit gezeigt wurde, ist die Herunterregulation von HMGA1a essentiell für den Eintritt von C2C12 Zellen in die Myogenese. Eine konstante Überexpression von HMGA1a-eGFP hingegen verhindert die Muskeldifferenzierung durch Beeinflussung der Expression myogenesespezifischer Gene und Etablierung einer stabilen Chromatinstruktur. Wie in der vorliegenden Arbeit herausgefunden wurde, nimmt die differenzielle HMGA1a Expression nicht nur Einfluss auf die Expression muskelspezifischer Gene, sondern auch auf die globale Zusammensetzung des Chromatins durch eine reduzierte Expression von H1 Histonen und einer aberranten Expression von HMGB1, HMGN1 und HP1 Proteinen. HMGA1a wurde zusammen mit ORC Proteinen eine Funktion bei der Definition von Replikationsursprüngen in eukaryotischen Zellen zugesprochen. ORC Proteine wurden auch als Komponenten des Heterochromatins und als Interaktionspartner von HP1α identifiziert. Hier konnte mit Hilfe von Co-Immunpräzipitationen, Pull-down Assays und Verdrängungsexperimenten gezeigt werden, dass HMGA1 ein weiterer, direkter Interaktionspartner von ORC Proteinen im Heterochromatin ist und zusammen mit HP1α kooperiert. Pull-down-, Verdrängungs- und siRNA-Experimente zeigten zudem, dass HMGA1 zwar nicht direkt mit HP1α interagiert, die Kooperation der Proteine über ORC aber dennoch wichtig für die Aufrechterhaltung der Heterochromatinsstruktur ist. Damit erweisen sich HMGA1 Proteine als wichtige Stabilisierungsfaktoren des Heterochromatins. Bislang ging man davon aus, dass HMGA1 Moleküle linear, also eindimensional, an ein DNA Molekül binden. Das Vorhandensein von drei DNA-Bindungsmotiven und die eher struktur- als sequenzabhängige Bindung an die DNA lassen vermuten, dass HMGA1 Proteine auch gleichzeitig an benachbarte DNA-Stränge, also auch dreidimensional, binden könnten. Bekräftigt wurde diese Vermutung durch die Bildung von Chromatinaggregaten in Zellen die HMGA1a-eGFP überexprimierten. Dies wurde mittels konfokaler und hochauflösender Mikroskopie (dSTORM) analysiert. Um das Potential einer DNA-Quervernetzung durch HMGA1 Proteine nachzuweisen, wurde eine neue Methode entwickelt. Mit Hilfe eines neuartigen DNA Cross-linking Assays wurde nachgewiesen, dass HMGA1 Proteine in der Lage sind, zwei individuelle DNA Stränge zu vernetzen. Zudem wurde eine neue Domäne in HMGA1 entdeckt die maßgeblich zum Cross-linking beiträgt. Elektronenmikroskopische Analysen bestätigten, dass HMGA1 Proteine in der Lage sind Kreuzungen und Schleifen in DNA Molekülen zu erzeugen. Diese Ergebnisse unterstützen die Vermutung, dass HMGA1 Proteine im Zellkern ein DNA Gerüst bilden können, das Einfluss auf die zelltypische Chromatinorganisation nimmt und dadurch DNA abhängige Prozesse beeinflusst. In wie weit eine HMGA1 induzierte DNA Quervernetzung in vivo zum Beispiel in Chromozentren von C2C12 Zellen oder in Krebszellen, in denen HMGA1 Proteine stark überexprimiert sind, eine Rolle spielen, müssen künftige Untersuchungen zeigen. In dieser Arbeit konnte also gezeigt werden, dass HMGA1 Proteine die Chromatinstruktur auf drei Ebenen organisieren können: Durch Beeinflussung der Chromatinzusammensetzung durch Veränderung der Expression von Chromatinproteinen, durch Interaktion mit anderen Architekturelementen des Chromatins und durch Organisation eines potentiellen DNA Gerüsts.
Pluripotency describes the ability of stem cells to form every cell type of the body.. Pluripotent stem cells are e.g. embryonic stem cells (ESCs), but also the so called induced pluripotent stem cells (IPS cells), that are generated by reprogramming differentiated somatic cells into a pluripotent state. Furthermore, it has been shown that spermatogonia (SG) derived from adult testes of mouse or human are pluripotent. Because of their ability to differentiate into every somatic cell type, pluripotent stem cells have a unique status in research and regenerative medicine. For the latter, they offer a valuable opportunity to replace destroyed tissues or organs. For basic research, stem cells represent a useful system to study differentiation or developmental processes that are difficult to access in the physiological situation e.g. during embryogenesis. Both applications, however, require methods that allow efficient and directed differentiation of stem cells into defined specialized cell types. This study first aims to investigate the differentiation potential of SG derived from the teleost fish medaka (Oryzias latipes). My results demonstrate that medaka SG are able to form different somatic cell types, namely adipocytes, melanocytes, osteoblasts, and neurons. This indicates that medake SG have retained a broad differentiation potential suggesting that pluripotency is not restricted to mouse and human SG but might be conserved among vertebrates. Next, I wanted to establish a differentiation method that is solely based on ectopic expression of genes known to be essential for the formation of certain somatic cell types – so called master regulators (MRs). My findings show that ectopic expression of the melanocyte-specific transcription factor mitf-m that has previously been shown to induce differentiation of medaka ESCs into pigment cells resulted in the formation of the same cell type in medaka SG. This approach could be used to generate other somatic cell types. Thus, ectopic expression of the MRs cbfa1 and mash1 in MF-SG was sufficient to induce differentiation into osteoblasts and neurons, respectively. Interestingly, these differentiation processes included the activation of genes that are expressed earlier during embryogenesis than the differentiation-inducing MR. Furthermore, my findings show that the approach of MR-induced differentiation can be transferred to mammalian stem cell systems. Ectopic expression of the neural transcription factor ngn2 was sufficient to induce efficient and rapid differentiation of neurons in mouse ESCs. This differentiation process also included the induction of genes that in vivo are activated at earlier stages that ngn2. By generating a transgenic cell line allowing induction of ectopic ngn2 expression, it was possible to obtain a relatively pure culture of functional neurons. Ngn2-induced differentiation did not require any additional signals and occurred even under pluripotency promoting conditions. Moreover, ectopic expression of ngn2 did also induce the formation of cells with neuronal morphology in IPS cells indicating that MR-induced differentiation is operative in different stem cell types. Furthermore, protein transduction of Ngn2 into mouse ESCs also resulted in a neuronal differentiation process up to the appearance of neural precursor cells. Last, my results show that MR-induced differentiation can also be used to generate other cell types than neurons from mouse ESCs. Myoblasts and macrophage-like cells were generated by ectopic expression of the MRs myoD and cebpa, respectively. Using transgenic cell lines enabling induction of MR expression it was possible to obtain mixed cultures with two different differentiation processes occurring in parallel. Altogether this study shows that ectopic expression of single genes is sufficient to induce directed differentiation of stem cells into defined cell types. The feasibility of this approach was demonstrated for different MRs and consequently different somatic cell types. Furthermore, MR induced differentiation was operative in different stem cell types from fish and mouse. Thus, one can conclude that certain genes are able to define cell fates in in vitro stem cell systems and that this cell fate defining potential appears to be a conserved feature in vertebrates. These findings therefore provide new insights in the role of MRs in cell commitment and differentiation processes. Furthermore, this study presents a new method to induce directed differentiation of stem cells that offers several advantages regarding efficiency, rapidness, and reproducibility. MR-induced differentiation therefore represents a promising tool for both stem cell research and regenerative medicine.
Switches in trypanosome differentiation: ALBA proteins acting on post-transcriptional mRNA control
(2011)
Trypanosoma brucei is a digenetic eukaryotic parasite that develops in different tissues of a mammalian host and a tsetse fly. It is responsible for sleeping sickness in sub-saharan Africa. The parasite cycle involves more than nine developmental stages that can be clearly distinguished by their general morphology, their metabolism and the relative positioning of their DNA-containing organelles. During their development, trypanosomes remain exclusively extracellular and encounter changing environments with different physico-chemical properties (nutritional availability, viscosity, temperature, etc.). It has been proposed that trypanosomes use their flagellum as a sensing organelle, in agreement with the established role of structurally-related cilia in metazoa and ciliates. Recognition of environmental triggers is presumed to be at the initiation of differentiation events, leading to the parasite stage that is the best suited to the new environment. These changes are achieved by the modification of gene expression programmes, mostly underlying post-transcriptional control of mRNA transcripts. We first demonstrate that the RNA-binding proteins ALBA3/4 are involved in specific differentiation processes during the parasite development in the fly. They are cytosolic and expressed throughout the parasite cycle with the exception of the stages found in the tsetse fly proventriculus, as shown by both immunofluorescence and live cell analysis upon endogenous tagging with YFP. Knock-down of both proteins in the developmental stage preceding these forms leads to striking modifications: cell elongation, cell cycle arrest and relocalization of the nucleus in a posterior position, all typical of processes acting in parasites found in the proventriculus region. When ALBA3 is over-expressed from an exogenous copy during infection, it interferes with the relocalization of the nucleus in proventricular parasites. This is not observed for ALBA4 over-expression that does not visibly impede differentiation. Both ALBA3/4 proteins react to starvation conditions by accumulating in cytoplasmic stress granules together with DHH1, a recognized RNA-binding protein. ALBA3/4 proteins also partially colocalize with granules formed by polyA+ RNA in these conditions. We propose that ALBA are involved in trypanosome differentiation processes where they control a subset of developmentally regulated transcripts. These processes involving ALBA3/4 are likely to result from the specific activation of sensing pathways. In the second part of the thesis, we identify novel flagellar proteins that could act in sensing mechanisms. Several protein candidates were selected from a proteomic analysis of intact flagella performed in the host laboratory. This work validates their flagellar localization with high success (85% of the proteins examined) and defines multiple different patterns of protein distribution in the flagellum. Two proteins are analyzed during development, one of them showing down-regulation in proventricular stages. The functional analysis of one novel flagellar membrane protein reveals its rapid dynamics within the flagellum but does not yield a visible phenotype in culture. This is coherent with sensory function that might not be needed in stable culture conditions, but could be required in natural conditions during development. In conclusion, this work adds new pieces to the puzzle of identifying molecular switches involved in developmental mRNA control and environmental sensing in trypanosome stages in the tsetse fly.
Desert ants of the genus Cataglyphis have become model systems for the study of insect navigation. An age-related polyethism subdivides their colonies into interior workers and short-lived light-exposed foragers. While foraging in featureless and cluttered terrain over distances up to several hundred meters, the ants are able to precisely return back to their often inconspicuous nest entrance. They accomplish this enormous navigational performance by using a path integration system - including a polarization compass and an odometer - as their main navigational means in addition to landmark-dependent orientation and olfactory cues. C. fortis, being the focus of the present thesis, is endemic to the salt flats of western North Africa, which are completely avoided by other Cataglyphis species. The fact that Cataglyphis ants undergo a behavioral transition associated with drastically changing sensory demands makes these ants particularly interesting for studying synaptic plasticity in visual and olfactory brain centers. This thesis focuses on plastic changes in the mushroom bodies (MBs) - sensory integration centers supposed to be involved in learning and memory presumably including landmark learning - and in synaptic complexes belonging to the lateral accessory lobe (LAL) known to be a relay station in the polarization processing pathway. To investigate structural synaptic plasticity in the MBs of C. fortis, synaptic complexes (microglomeruli, MG) in the visual (collar) and olfactory (lip) input regions of the MB calyx were immunolabeled and their pre- and postsynaptic profiles were quantified. The results show that a volume increase of the MB calyx during behavioral transition is associated with a decrease of MG number - an effect called pruning - in the collar and, less pronounced, in the lip that goes along with dendritic expansion in MB intrinsic Kenyon cells. Light-exposure of dark-reared ants of different age classes revealed similar effects and dark-reared ants age-matched to foragers had MG numbers comparable to those of interior workers. The results indicate that the enormous structural synaptic plasticity of the MB calyx collar is primarily driven by visual experience rather than by an internal program. Ants aged artificially for up to one year expressed a similar plasticity indicating that the system remains flexible over the entire life-span. To investigate whether light-induced synaptic reorganization is reversible, experienced foragers were transferred back to darkness with the result that their MBs exhibit only some reverse-type characteristics, in particular differences in presynaptic synapsin expression. To investigate the structure of large synaptic complexes in the LAL of C. fortis and to detect potential structural changes, pre- and postsynaptic profiles in interior workers and foragers were immunolabeled and quantified by using confocal imaging and 3D-reconstruction. The results show that these complexes consist of postsynaptic processes located in a central region that is surrounded by a cup-like presynaptic profile. Tracer injections identified input and output tracts of the LAL: projection neurons from the anterior optic tubercle build connections with neurons projecting to the central complex. The behavioral transition is associated with an increase by ~13% of synaptic complexes suggesting that the polarization pathway may undergo some sort of calibration process. The structural features of these synaptic contacts indicate that they may serve a fast and reliable signal transmission in the polarization vision pathway. Behavioral analyses of C. fortis in the field revealed that the ants perform exploration runs including pirouette-like turns very close to the nest entrance for a period of up to two days, before they actually start their foraging activity. During these orientation runs the ants gather visual experience and might associate the nest entrance with specific landmarks or get entrained to other visual information like the polarization pattern, and, concomitantly adapt their neuronal circuitries to the upcoming challenges. Moreover, the pirouettes may serve to stimulate and calibrate the neuronal networks involved in the polarization compass pathway. Video recordings and analyses demonstrate that light experience enhanced the ants’ locomotor activity after three days of exposure. The fact that both the light-induced behavioral and neuronal changes in visual brain centers occur in the same time frame suggests that there may be a link between structural synaptic plasticity and the behavioral transition from interior tasks to outdoor foraging. Desert ants of the genus Cataglyphis possess remarkable visual navigation capabilities, but also employ olfactory cues for detecting nest and food sites. Using confocal imaging and 3D-reconstruction, potential adaptations in primary olfactory brain centers were analyzed by comparing the number, size and spatial arrangement of olfactory glomeruli in the antennal lobe of C. fortis, C. albicans, C. bicolor, C. rubra, and C. noda. Workers of all Cataglyphis species have smaller numbers of glomeruli compared to those of more olfactory-guided Formica species - a genus closely related to Cataglyphis - and to those previously found in other olfactory-guided ant species. C. fortis has the lowest number of glomeruli compared to all other species, but possesses a conspicuously enlarged glomerulus that is located close to the antennal nerve entrance. Males of C. fortis have a significantly smaller number of glomeruli compared to female workers and queens and a prominent male-specific macroglomerulus likely to be involved in sex pheromone communication. The behavioral significance of the enlarged glomerulus in female workers remains elusive. The fact that C. fortis inhabits microhabitats that are avoided by all other Cataglyphis species suggests that extreme ecological conditions may not only have resulted in adaptations of visual capabilities, but also in specializations of the olfactory system. The present thesis demonstrates that Cataglyphis is an excellent candidate for studying the neuronal mechanisms underlying navigational features and for studying neuronal plasticity associated with the ant’s lifelong flexibility of individual behavioral repertoires.
Molecular modelling and simulation are powerful methods in providing important in-formation on different biological systems to elucidate their structural and functional proper-ties, which cannot be determined in experiment. These methods are applied to analyse versa-tile biological systems: lipid membrane bilayers stabilized by an intercalated single wall carbon nanotube and retroviral proteins such as HIV protease and integrase. HIV-1 integrase has nuclear localization signals (NLS) which play a crucial role in nuclear import of viral preintegration complex (PIC). However, the detailed mechanisms of PIC formation and its nuclear transport are not known. Previously it was shown that NLSs bind to the cell transport machinery e.g. proteins of nuclear pore complex such as transportins. I investigated the interaction of this viral protein HIV-1 integrase with proteins of the nuclear pore complex such as transportin-SR2 (Shityakov et al., 2010). I showed that the transportin-SR2 in nuclear import is required due to its interaction with the HIV-1 integrase. I analyzed key domain interaction, and hydrogen bond formation in transportin-SR2. These results were discussed in comparison to other retroviral species such as foamy viruses to better understand this specific and efficient retroviral trafficking route. The retroviral nuclear import was next analyzed in experiments regarding the retroviral ability to infect nondividing cells. To accomplish the gene transfer task successfully, ret-roviruses must efficiently transduce different cell cultures at different phases of cell cycle. However, promising and safe foamy viral vectors used for gene transfer are unable to effi-ciently infect quiescent cells. This drawback was due to their inability to create a preintegra-tion complex (PIC) for nuclear import of retroviral DNA. On the contrary, the lentiviral vec-tors are not dependant on cell cycle. In the course of reverse transcription the polypurine tract (PPT) is believed to be crucial for PIC formation. In this thesis, I compared the transduction frequencies of PPT modified FV vectors with lentiviral vectors in nondividing and dividing alveolar basal epithelial cells from human adenocarcinoma (A549) by using molecular cloning, transfection and transduction techniques and several other methods. In contrast to lentiviral vectors, FV vectors were not able to effi-ciently transduce nondividing cell (Shityakov and Rethwilm, unpublished data). Despite the findings, which support the use of FV vectors as a safe and efficient alternative to lentiviral vectors, major limitation in terms of foamy-based retroviral vector gene transfer in quiescent cells still remains. Many attempts have been made recently to search for the potential molecules as pos-sible drug candidates to treat HIV infection for over decades now. These molecules can be retrieved from chemical libraries or can be designed on a computer screen and then synthe-sized in a laboratory. Most notably, one could use the computerized structure as a reference to determine the types of molecules that might block the enzyme. Such structure-based drug design strategies have the potential to save off years and millions of dollars compared to a more traditional trial-and-error drug development process. After the crystal structure of the HIV-encoded protease enzyme had been elucidated, computer-aided drug design played a pivotal role in the development of new compounds that inhibit this enzyme which is responsible for HIV maturation and infectivity. Promising repre-sentatives of these compounds have recently found their way to patients. Protease inhibitors show a powerful sustained suppression of HIV-1 replication, especially when used in combi-nation therapy regimens. However, these drugs are becoming less effective to more resistant HIV strains due to multiple mutations in the retroviral proteases. In computational drug design I used molecular modelling methods such as lead ex-pansion algorithm (Tripos®) to create a virtual library of compounds with different binding affinities to protease binding site. In addition, I heavily applied computer assisted combinato-rial chemistry approaches to design and optimize virtual libraries of protease inhibitors and performed in silico screening and pharmacophore-similarity scoring of these drug candidates. Further computational analyses revealed one unique compound with different protease bind-ing ability from the initial hit and its role for possible new class of protease inhibitors is dis-cussed (Shityakov and Dandekar, 2009). A number of atomistic models were developed to elucidate the nanotube behaviour in lipid bilayers. However, none of them provided useful information for CNT effect upon the lipid membrane bilayer for implementing all-atom models that will allow us to calculate the deviations of lipid molecules from CNT with atomistic precision. Unfortunately, the direct experimental investigation of nanotube behaviour in lipid bilayer remains quite a tricky prob-lem opening the door before the molecular simulation techniques. In this regard, more de-tailed multi-scale simulations are needed to clearly understand the stabilization characteristics of CNTs in hydrophobic environment. The phenomenon of an intercalated single-wall carbon nanotube in the center of lipid membrane was extensively studied and analyzed. The root mean square deviation and root mean square fluctuation functions were calculated in order to measure stability of lipid mem-branes. The results indicated that an intercalated carbon nanotube restrains the conformational freedom of adjacent lipids and hence has an impact on the membrane stabilization dynamics (Shityakov and Dandekar, 2011). On the other hand, different lipid membranes may have dissimilarities due to the differing abilities to create a bridge formation between the adherent lipid molecules. The results derived from this thesis will help to develop stable nanobiocom-posites for construction of novel biomaterials and delivery of various biomolecules for medi-cine and biology.
Das Proto-Onkoprotein Myc ist an der Entstehung und Aufrechterhaltung einer Vielzahl humaner Tumore entscheidend beteiligt. In der vorliegenden Arbeit wurde Serin 227 in Fbw7 als Ziel für eine PI3K-abhängige Phosphorylierung identifiziert. Diese Phosphorylierung führt zur Stabilisierung von Fbw7 und steigert die Fähigkeit von Fbw7, Substratproteine zu ubiquitinieren und abzubauen. Um die Bedeutung von Usp28 in der Myc-induzierten Tumorentstehung und in der normalen Gewebehomöostase zu untersuchen, wurde ein konditionales Knockout-Mausmodell für Usp28 charakterisiert. Mäuse mit einer Keimbahndeletion von Usp28 sind lebensfähig, fertil und phänotypisch unauffällig. Weder in Organen der Usp28-negativen Tiere, noch in entsprechenden murinen embryonalen Fibroblasten kann eine Destabilisierung von Myc festgestellt werden. Allerdings zeigen Fibroblasten mit heterozygotem Usp28-Verlust einen Proliferationsdefekt und in Eμ-Myc-Lymphomen dieses Genotyps werden tendenziell niedrigere Myc-Proteinmengen gefunden. Das tumorfreie Überleben ist bei den Eμ-Myc; Usp28 +/- Tieren verlängert.
Bei einer Vielzahl neuromuskulärer und neurodegenerativer Erkrankungen spielen Fehlfunktionen der Mitochondrien eine wichtige Rolle. Da die Proteine der Atmungsketten-komplexe sowohl durch die mitochondriale DNA als auch durch das Kerngenom codiert werden, können Mutationen in beiden Genomen die Auslöser dieser Erkrankungen darstellen. Veränderungen der mitochondrialen DNA lassen sich - im Gegensatz zum Kerngenom - bisher nicht korrigieren, weshalb bei einem großen Teil der Erkrankungen nur die Symptome und nicht die Auslöser behandelt werden können. Das grundlegende Problem stellt dabei der Transport der DNA in die Mitochondrien dar. Ziel dieser Arbeit war es, mit Hilfe von physikalischen Transfektionsmethoden exogene DNA in die Mitochondrien menschlicher Kulturzellen einzubringen. Dazu wurden unterschiedliche Vektoren hergestellt, die in Mitochondrien das an die Mitochondrien angepasste grün fluoreszierende mtEGFP exprimieren sollen. Die Expressionsfähigkeit und Prozessierung dieser Konstrukte konnte in in-vitro-Assays mit einem Mitochondrienextrakt nachgewiesen werden. Bei Transfektionsversuchen mit der Gene Gun gelang es erstmals, exogene Plasmid-DNA in die Mitochondrien menschlicher Zellen einzubringen. Das durch die transfizierten Vektoren exprimierte mtEGFP konnte am Fluoreszenzmikroskop eindeutig in den Mitochondrien der Zellen lokalisiert werden. Eine Transfektion mit Hilfe magnetischer Partikel erwies sich jedoch nicht als zielführend, da die die Partikel eine Eigenfluoreszenz aufwiesen, die eine Detektion der mtEGFP-Expression verhinderten. Eine wichtige Voraussetzung für die Transfektion von Mitochondrien durch mechanische Methoden wie die Mikroinjektion ist die reversible Induktion von Megamitochondrien, da sie erst in diesem Zustand penetriert werden können. Durch eine Ansäuerung des Kulturmediums mit Natriumacetat bzw. Essigsäure konnten Mitochondrien erzeugt werden, die beinahe die Größe des Zellkerns aufwiesen und somit ideale Bedingungen für die Mikroinjektion darstellen. Bei den anschließenden Mikroinjektionsversuchen mit den hergestellten mitochondrialen Expressionsvektoren wurden wiederum Zellen mit eindeutig grün fluoreszierenden Mitochondrien gefunden. Zusammenfassend wurden im Rahmen dieser Arbeit erstmalig menschliche Mitochondrien mit exogener DNA transfiziert. Dies stellt einen grundlegenden Schritt für die Entwicklung neuer Therapieformen bei mitochondrialen Myopathien dar. Zuvor müssen die Transfektionsmethoden jedoch noch weiter optimiert werden, um eine höhere Transfektionseffizienz zu erreichen.
SYCE3, ein neues Synaptonemalkomplexprotein: Expression, funktionelle Analyse und Bindungspartner
(2011)
Der Synaptonemalkomplex ist eine evolutionär hoch konservierte Struktur. Er wird spezifisch während der Prophase I der Meiose ausgebildet und ist essentiell für die Segregation der homologen Chromosomen während der Meiose und auch für die Entstehung genetischer Vielfalt. Der Synaptonemalkomplex ist eine proteinöse Struktur, deren Aufbau dem einer Leiter ähnelt. Dabei werden die Leiterholme als Lateralelemente bezeichnet. Sie bestehen unter anderem aus den Proteinen SYCP2 und SYCP3 und assoziieren mit dem Chromatin der homologen Chromosomen. Die Stufen der Leiter bestehen hingegen aus Transversalfilamenten, deren Hauptkomponente parallele Homodimere des meiosespezifische Proteins SYCP1 sind. Dabei wird ein SYCP1 Dimer mit seinem C-Terminus in den Lateralelementen verankert und kann über seine N-terminale Domäne eine schwache Interaktion mit der N-terminalen Domäne eines gegenüberliegenden SYCP1 Dimers eingehen. Um diese Bindung zu stabilisieren werden Proteine des Zentralelements des Synaptonemalkomplexes benötigt: Während SYCE1 durch seine Interaktion mit SYCP1 die N-terminale Assoziation zweier gegenüberliegender SYCP1 Dimere stabilisiert, verknüpfen die zwei anderen zentralelementspezifischen Proteine SYCE2 und Tex12 lateral benachbarte SYCP1 Filamente und breiten so das SYCP1 Netzwerk entlang der chromosomalen Achsen aus. Dieser Prozess wird als Synapse bezeichnet und stellt eines der Schlüsselereignisse der Meiose dar. Fehler während dieses Prozesses führen meist zu Aneuploidie der entstehenden Gameten oder zum Abbruch der Meiose und somit zu Infertilität des betroffenen Organismus. In dieser Arbeit wurde mit SYCE3 ein neues Protein des murinen Synaptonemalkomplexes charakterisiert. Es konnte gezeigt werden, dass SYCE3 meiosespezifisch in Männchen und Weibchen exprimiert wird und Bestandteil des Zentralelements des Synaptonemalkomplexes ist. Hierbei zeigt es dasselbe Verteilungsmuster wie SYCP1 und SYCE1 und kann mit beiden Proteinen interagieren. Eine zusätzliche Interaktion konnte zwischen SYCE3 und SYCE2 nachgewiesen werden. Durch Untersuchungen an entsprechenden Knockout Mausmodellen konnte in dieser Arbeit außerdem gezeigt werden, dass SYCE3 in Abwesenheit von SYCP1 nicht an die chromosomalen Achsen rekrutiert werden kann. Die Ausbildung der Lateralelemente und auch die Anwesenheit der anderen zentralelementspezifischen Proteine SYCE1 und SYCE2 sind hingegen für die Anlagerung von SYCE3 an die chromosomalen Achsen nicht essentiell. Somit steht SYCE3 hinsichtlich seiner Bedeutung für die Paarung und die Synapse der homologen Chromosomen hierarchisch offenbar über den bisher beschriebenen Zentralelementproteinen SYCE1, SYCE2 und Tex12. Die funktionelle Bedeutung von SYCE3 für die Synapse der homologen Chromosomen und für den korrekten Ablauf der homologen Rekombination wurde im Rahmen dieser Arbeit durch die Herstellung und die Charakterisierung einer Syce3-/- Maus detailliert untersucht: Dabei führte der Knockout von SYCE3 zur Infertilität in beiden Geschlechtern, die gleichzeitig mit einer signifikanten Reduktion der Größe der entsprechenden Hoden und Ovarien im Vergleich zum Wildtyp einherging. Weitere Untersuchungen ergaben zudem, dass es in Syce3 defizienten Tieren zu einem Abbruch der Meiose kommt. Dabei hatte das Fehlen von SYCE3 keinen Einfluss auf die Ausbildung der Axialelemente. Die Initiation der Synapse hingegen war sowohl in Oocyten als auch in Spermatocyten in Abwesenheit von SYCE3 stark gestört. Darüber hinaus konnte in der vorliegenden Arbeit nachgewiesen werden, dass das Fehlen von SYCE3 Einfluss auf die homologe Rekombination nimmt: Zwar können sich frühe (DNA Doppelstrangbrüche) und intermediäre (Transitionsknoten) Rekombinationsereignisse in der Abwesenheit von SYCE3 ausbilden, die Prozessierung zu späten Rekombinationsstrukturen (Rekombinationsknoten) und die damit einhergehende Ausbildung von Crossing-over Strukturen fand jedoch nicht statt. Zusammengefasst wurde in dieser Arbeit gezeigt, dass das neue Synaptonemalkomplexprotein SYCE3 essentiell für die Fertilität von Mäusen ist. Durch den Knockout von Syce3 kann die Synapse zwischen den Homoligen nicht initiiert werden und es findet kein Crossing-over statt. Im Assembly Prozess des Synaptonemalkomplexes agiert SYCE3 oberhalb der anderen zentralelementspezifischen Proteine und unterhalb von SYCP1.
Characterisation of Metalloprotease-mediated EGFR Signal Transactivation after GPCR Stimulation
(2011)
In the context of metalloprotease-mediated transactivation of the epidermal growth factor receptor, different monoclonal antibodies against ADAM17 / TACE were characterized for their ability to block the sheddase. Activity of some of them was observed at doses between 2µg/mL and 10µg/mL. Kinetic analyses showed their activity starting at around 30 minutes. In cellular assays performed with the antibodies, especially upon treatment of cells with sphingosine-1-phosphate a reduction in proliferation was observed with some candidates. Moreover this study provides potential new roles for ß-Arrestins. Their involvement in the triple membrane-passing signal pathway of EGFR transactivation was shown. Furthermore, in overexpressing cellular model systems, an interaction between ADAM17 and ß-Arrestin1 could be observed. Detailed analysis discovered that phosphorylation of ß-Arrestin1 is crucial for this interaction. Additionally, the novel mechanism of UV-induced EGFR transactivation was extended to squamous cell carcinoma. The mechanism happens in a dose dependent manner and requires a metalloprotease to shed the proligand Amphiregulin. The involvement of both ADAM9 and ADAM17, being the metalloproteases responsible for this cleavage, was shown for SCC9 cells.
This study was conducted to determine the influence of different stress factors on the honeybee Apis mellifera. The investigation was motivated by previous experiments that suggested the existence of an unspecific defense mechanism causing a generalized change of flight behavior after the onset of different diseases. This mechanism is thought to impede the ability of flight bees to return to their respective colonies thereby removing the disease from the colony over time. During the last years, the existence of such a “suicidal behavior” was supported by further studies. Thus, an unnoticed, potentially highly effective defense mechanism of social insects was revealed whose spectrum of activity and physiological basics require further investigation. Suggesting that the reaction by the bees is unspecific to different diseases as well as to other potential stress factors, this study was designed to investigate the influence of pathogens, insecticides, and different brood rearing temperatures on different parameters like lifespan, foraging activity, and foraging trip duration of worker bees.
Tumore der Nebennieren stellen häufige Tumore dar, welche bei mindestens 3 % der Population über 50-Jähriger vorkommen. Im Gegensatz dazu ist das Nebennierenrindenkarzinom mit einer Inzidenz von 1-2 Einwohner pro Million ein sehr seltener Tumor. Da seine Prognose allerdings ungünstig, und diese maßgeblich davon abhängt wie fortgeschritten der Tumor bei Diagnosestellung ist, ist es wichtig, dass die richtige Diagnose frühzeitig gestellt wird. Bis heute ist kein zuverlässiger immunhistochemischer Nebennierenrindenkarzinom-spezifischer Marker etabliert um das Nebennierenrindenkarzinom von anderen retroperitonealen Tumoren zu differenzieren. Sasano et al. schlug bereits 1995 erstmalig den Transkriptionsfaktor Steroidogenic Factor 1 (SF1) als Marker zur Differenzierung von Nebennierenrinden- und Nicht-Nebennierenrindentumoren vor. Allerdings wurde die diagnostische Wertigkeit bisher nur in sehr kleinen Fallserien mit insgesamt nur 17 Nebennierenrindenkarzinomen untersucht. In der vorliegenden Arbeit wurde die SF1 Protein-Expression bei 163 Nebennierenrindenkarzinomen, 52 Nebennierenrinden-Adenomen, 12 normalen steroidogenen Geweben (6 Nebennieren und 6 Ovare), sowie 73 Nicht-Steroidtumoren immunhistochemisch untersucht. Hierbei zeigte sich, das SF1 bei 158 von 161 evaluierbaren Nebennierenrindenkarzinomen und bei allen Proben von normalen und gutartigen Geweben (n=64) nachweisbar war. Im Gegensatz dazu war keine der 73 Nicht-Steroidgeweben SF1 positiv, so dass die diagnostische Genauigkeit extrem gut ist (Sensitivität: 98.6 %, Spezifität: 100 %, positive und negative predictive value jeweils 100 % und 97.3 %). In einem zweiten Schritt wurde untersucht ob die Protein-Expression von SF1 beim Nebennierenrindenkarzinom auch prognostische Bedeutung hat. Hierbei zeigte sich, dass Patienten mit Tumoren mit starker SF1 Färbung (30 %) ein deutlich schlechteres tumorstadium-adjustiertes Rezidiffreies- und Gesamt-Überleben haben als Patienten mit geringer SF1 Expression (hazard ratio: 2.45). Zusätzlich zu den immunhistochemischen Untersuchungen wurden FISH Analysen durchgeführt. Hierbei zeigte sich allerdings keine signifikante Korrelation zwischen SF1 Gendosis und der SF1 Protein-Expression, so dass zu vermuten ist, dass SF1 maßgeblich auf Transkriptions- und Translationsebene reguliert wird. In einem Versuch diese Frage zu beantworten wurden zwei mutmaßliche SF1 Interaktionspartner, FATE1 und DAX1, genauer immunhistochemisch untersucht. Hierbei wurde deutlich, dass FATE1 bei 62 von 141 evaluierbaren Nebenierenrindenkarzinomen und 12 von 62 normalen und gutartigen Geweben nachweisbar war. Im Gegensatz hierzu waren alle 9 Nicht-Steroidgewebe FATE1 negativ. Dies zeigt, das FATE1 nicht zur Diagnostik nutzbar ist (Sensitivität: 61 %, Spezifität: 100 %, positive und negative predictive value 100 % bzw. 14 %). Die DAX1 Analyse zeigte, dass alle 20 normalen und gutartigen Gewebe eine positive DAX1 Färbereaktion zeigten. Von 126 Nebennierenrindenkarzinomen waren 71 DAX1 positiv. Von den 8 untersuchten Nicht-Steroidgeweben waren 6 DAX1 positiv. Diese Ergebnisse belegen, dass auch DAX1 keine diagnostische Genauigkeit besitzt (Sensitivität: 56 %, Spezifität: 25 %, positive und negative predictive value 92 % bzw. 4 %). Die Untersuchung der prognostischen Fähigkeiten von FATE1 und DAX1 zeigte, dass Patienten mit Tumoren mit starker FATE1 Färbung (39 %) ein schlechteres tumorstadium-adjustiertes Gesamt- aber nicht Rezidiffreies-Überleben haben als Patienten mit niedriger FATE1 Protein-Expression (hazard ratio: 2.01). Weiterhin wurde deutlich, dass DAX1 keine deutlichen prognostischen Fähigkeiten besitzt. Zusammenfassend läßt sich aus der vorliegenden Arbeit folgern, das SF1 aktuell der beste diagnostische Marker zur Diagnose von Tumoren der Nebennierenrinde ist und damit Eingang in die histopathologische Routine-Diagnostik von Nebennierentumoren finden wird. Zusätzlich ist die SF1 Expression ein sehr guter prognostischer Marker beim Nebennierenrindenkarzinom, wobei sich die prognostische Aussage durch zusätzliche Färbung von FATE1 und DAX1 nur unwesentlich verbessern läßt.
According to a changing environment it is crucial for animals to make experience and learn about it. Sensing, integrating and learning to associate different kinds of modalities enables animals to expect future events and to adjust behavior in the way, expected as the most profitable. Complex processes as memory formation and storage make it necessary to investigate learning and memory on different levels. In this context Drosophila melanogaster represents a powerful model organism. As the adult brain of the fly is still quite complex, I chose the third instar larva as model - the more simple the system, the easier to isolate single, fundamental principles of learning. In this thesis I addressed several kinds of questions on different mechanism of olfactory associative and synaptic plasiticity in Drosophila larvae. I focused on short-term memory throughout my thesis. First, investigating larval learning on behavioral level, I developed a one-odor paradigm for olfactory associative conditioning. This enables to estimate the learnability of single odors, reduces the complexity of the task and simplify analyses of "learning mutants". It further allows to balance learnability of odors for generalization-type experiments to describe the olfactory "coding space". Furthermore I could show that innate attractiveness and learnability can be dissociated and found finally that paired presentation of a given odor with reward increase performance, whereas unpaired presentations of these two stimuli decrease performance, indicating that larva are able to learn about the presence as well as about the absence of a reward. Second, on behavioral level, together with Thomas Niewalda and colleagues we focussed on salt processing in the context of choice, feeding and learning. Salt is required in several physiological processes, but can neither be synthesized nor stored. Various salt concentrations shift the valence from attraction to repulsion in reflexive behaviour. Interestingly, the reinforcing effect of salt in learning is shifted by more than one order of magnitude toward higher concentrations. Thus, the input pathways for gustatory behavior appear to be more sensitive than the ones supporting gustatory reinforcement, which is may be due to the dissociation of the reflexive and the reinforcing signalling pathways of salt. Third, in cooperation with Michael Schleyer we performed a series of behavioral gustatory, olfactory preference tests and larval learning experiments. Based on the available neuroanatomical and behavioral data we propose a model regarding chemosensory processing, odor-tastant memory trace formation and the 'decision' like process. It incorporates putative sites of interaction between olfactory and gustatory pathways during the establishment as well as behavioral expression of odor-tastant memory. We claim that innate olfactory behavior is responsive in nature and suggest that associative conditioned behavior is not a simple substitution like process, but driven more likely by the expectation of its outcome. Fourth, together with Birgit Michels and colleagues we investigated the cellular site and molecular mode of Synapsin, an evolutionarily conserved, presynaptic vesicular phosphoprotein and its action in larval learning. We confirmed a previously described learning impairment upon loss of Synapsin. We localized this Synapsin dependent memory trace in the mushroom bodies, a third-order "cortical" brain region, and could further show on molecular level, that Synapsin is as a downstream element of the AC-cAMP-PKA signalling cascade. This study provides a comprehensive chain of explanation from the molecular level to an associative behavioral change. Fifth, in the main part of my thesis I focused on molecular level on another synaptic protein, the Synapse associated protein of 47kDa (Sap47) and its role in larval behavior. As a member of a phylogenetically conserved gene family of hitherto unknown function. It is localized throughout the whole neuropil of larval brains and associated with presynaptic vesicles. Upon loss of Sap47 larvae exhibit normal sensory detection of the to-be-associated stimuli as well as normal motor performance and basic synaptic transmission. Interestingly, short-term plasticity is distorted and odorant–tastant associative learning ability is reduced. This defect in associative function could be rescued by restoring Sap47 expression. Therefore, this report is the first to suggest a function for Sap47 and specifically argues that Sap47 is required for synaptic as well as for behavioral plasticity in Drosophila larva. This prompts the question whether its homologs are required for synaptic and behavioral plasticity also in other species. Further in the last part of my thesis I contributed to the study of Ayse Yarali. Her central topic was the role of the White protein in punishment and relief learning in adult flies. Whereas stimuli that precede shock during training are subsequently avoided as predictors for punishment, stimuli that follow shock during training are later on approached, as they predict relief. Concerning the loss of White we report that pain-relief learning as well as punishment learning is changed. My contribution was a comparison between wild type and the white1118 mutant larvae in odor-reward learning. It turned out that a loss of White has no effect on larval odorant-tastant learning. This study, regarding painrelief learning provides the very first hints concerning the genetic determinants of this form of learning.
Stroke, after myocardial infarction and cancer is the third most common cause of death worldwide and 1/6th of all human beings will suffer at least one stroke in their lives. Furthermore, it is the leading cause for adult disability with approximately one third of patients who survive for the next 6 months are dependent on others. Because of its huge socioeconomic burden absorbing 6% of all health care budgets and with the fact that life expectancy increases globally, one can assume that stroke is already, and will continue to be, the most challenging disease. Ischemic stroke accounts for approximately 80% of all strokes and results from a thrombotic or embolic occlusion of a major cerebral artery (most often the middle cerebral artery, MCA) or its branches Following acute ischemic stroke, the most worrisome outcome is the rapidly increasing intra-cranial pressure due to the formation of space-occupying vasogenic oedema which can have lethal consequences. Permeability changes at the Blood-Brain Barrier (BBB) usually accompanies the oedematous development and their time course can provide invaluable insight into the nature of the insult, activation of compensatory mechanisms followed by long term repair. Rodent models of focal cerebral ischemia have been developed and optimized to mimic human stroke conditions and serve as indispensable tools in the field of stroke research. The presented work constituting of three separate but complete works by themselves are sequential, where, the first part was dedicated to the establishment of non-invasive small animal imaging strategies on a 3 tesla clinical magnetic resonance scanner. This facilitated the longitudinal monitoring of pathological outcomes following stroke where identical animals can serve as its own control. Tissue relaxometric estimations were carried out initially to derive the transverse (T2), longitudinal (T1) and the transverse relaxation time due to magnetic susceptibility effects (T2*) at the cortical and striatal regions of the rodent brain. Statistically significant differences in T2*-values could be found between the cortex and striatal regions of the rodent brain. The derived tissue relaxation values were considered to modify the existing imaging protocols to facilitate the study of the rodent model of ischemic stroke. The modified sequence protocols adequately characterized all the clinically relevant sequels following acute ischemic stroke, like, the altered perfusion and diffusion characteristics. Subsequent to this, serial magnetic resonance imaging was performed to investigate the temporal and spatial relationship between the biphasic nature of BBB opening and, in parallel, the oedema formation after I/R injury in rats. T2-relaxometry for oedema assessment was performed at 1 h after ischemia, immediately following reperfusion, and at 4, 24 and 48 hours post reperfusion. Post-contrast T1-weighted imaging was performed at the last three time points to assess BBB integrity. The biphasic course of BBB opening with significant reduction in BBB permeability at 24 hours after reperfusion was associated with a progressive expansion of leaky BBB volume, accompanied by a peak ipsilateral oedema formation. At 48 hours, the reduction in T2-value indicated oedema resorption accompanied by a second phase of BBB opening. In addition, at 4 hours after reperfusion, oedema formation could also be detected at the contralateral striatum which persisted to varying degrees throughout the study, indicative of widespread effects of I/R injury. The observations of this study may indicate a dynamic temporal shift in the mechanisms responsible for biphasic BBB permeability changes, with non-linear relations to oedema formation. Two growth factor peptides namely pigment epithelium derived factor (PEDF) and epidermal growth factor (EGF) with widely different trophic properties were considered for their beneficial effects, if any, in the established rodent model of I/R injury and studied up to one week employing magnetic resonance imaging. Both the selected, trophic factors demonstrated significant neuroprotection as demonstrated by a reduction in infarct volume, even though PEDF was found to be the most potent one. PEDF also demonstrated significant attenuation of oedema formation in comparison to both the control and EGF groups, even though EGF could also demonstrate oedema suppression. In the present work, we noticed that interventions with macromolecule protein/peptides by itself could mediate remote oedema at distant sites even though the significance of such an observation is not clear at present. Susceptibility (T2*) weighted tissue relaxometric estimations were considered at the infarct region to detect any metabolic changes arising out of any neuroprotection and/or cellular proliferation / neurogenesis. PEDF group demonstrated a striking reduction of the T2*-values, which is indicative of an increased metabolic activity. Moreover, all the groups (Control, EGF and PEDF) demonstrated significantly elevated T2*-values at the contralateral striatum, which is indicative of widespread metabolic suppression usually associated with a variety of traumatic brain conditions. Moreover, as expected from the properties of PEDF, it demonstrated an extended BBB permeability suppression throughout the duration of the study. This study underlines the merits of considering non-invasive imaging strategies without which it was not possible to study the required parameters in a longitudinal fashion. All the observations are adequately supported by reasonably well defined mechanisms and needs to be further verified and confirmed by an immunohistochemical study. These results also need to be complemented by a functional study to evaluate the behavioural outcome of animals following these treatments. These studies are progressing at our laboratory and the results will be duly published afterwards.
Die Apoptose der Leberzellen ist abhängig von externen Signalen wie beispielsweise Komponenten der Extrazellulären Matrix sowie anderen Zell-Zell-Kontakten, welche von einer Vielfalt und Vielzahl an Knoten verarbeitet werden. Einige von ihnen wurden im Rahmen dieser Arbeit auf ihre Systemeffekte hin unter- sucht. Trotz verschiedener äußerer Einflüsse und natürlicher Selektion ist das System daraufhin optimiert, eine kleine Anzahl verschiedener und klar voneinander unterscheidbarer Systemzustände anzunehmen. Die verschiedenartigen Einflüsse und Crosstalk-Mechanismen dienen der Optimierung der vorhandenen Systemzustände. Das in dieser Arbeit vorgestellte Modell zeigt zwei apoptotische sowie zwei nicht-apoptotische stabile Systemzustände, wobei der Grad der Aktivierung eines Knotens bis zu dem Moment stark variieren kann, in welchem der absolute Systemzustand selbst verändert wird (Philippi et al., BMC Systems Biology,2009) [1]. Dieses Modell stellt zwar eine Vereinfachung des gesamten zellulären Netzwerkes und seiner verschiedenen Zustände dar, ist aber trotz allem in der Lage, unabhängig von detaillierten kinetischen Daten und Parametern der einzelnen Knoten zu agieren. Gleichwohl erlaubt das Modell mit guter qualitativer Übereinstimmung die Apoptose als Folge einer Stimulation mit FasL zu modellieren. Weiterhin umfasst das Modell sowohl Crosstalk-Möglichkeiten des Collagen-Integrin-Signalwegs, ebenso berücksichtigt es die Auswirkungen der genetischen Deletion von Bid sowie die Konsequenzen einer viralen Infektion. In einem zweiten Teil werden andere Anwendungsmöglichkeiten dargestellt. Hormonale Signale in Pflanzen, Virusinfektionen und intrazelluläre Kommunikation werden semi-quantitativ modelliert. Auch hier zeigte sich eine gute Ubereinstimmung der Modelle mit den experimentellen Daten.
Honeybees (Apis mellifera) forage on a great variety of plant species, navigate over large distances to crucial resources, and return to communicate the locations of food sources and potential new nest sites to nest mates using a symbolic dance language. In order to achieve this, honeybees have evolved a rich repertoire of adaptive behaviours, some of which were earlier believed to be restricted to vertebrates. In this thesis, I explore the mechanisms involved in honeybee learning, memory, numerical competence and navigation. The findings acquired in this thesis show that honeybees are not the simple reflex automats they were once believed to be. The level of sophistication I found in the bees’ memory, their learning ability, their time sense, their numerical competence and their navigational abilities are surprisingly similar to the results obtained in comparable experiments with vertebrates. Thus, we should reconsider the notion that a bigger brain automatically indicates higher intelligence.
An animal depends heavily on its sense of smell and its ability to form olfactory associations as this is crucial for its survival. This thesis studies in two parts about such associative olfactory learning in larval Drosophila. The first part deals with different aspects of odour processing while the second part is concerned with aspects related to memory and learning. Chapter I.1 highlights how odour intensities could be integrated into the olfactory percept of larval Drosophila. I first describe the dose-effect curves of learnability across odour intensities for different odours and then choose odour intensities from these curves such that larvae are trained at intermediate odour intensity, but are tested for retention with either that trained intermediate odour intensity, or with respectively HIGHer or LOWer intensities. I observe a specificity of retention for the trained intensity for all the odours used. Further I compare these findings with the case of adult Drosophila and propose a circuit level model of how such intensity coding comes about. Such intensity specificity of learning adds to appreciate the richness in 'content' of olfactory memory traces, and to define the demands on computational models of olfaction and olfactory learning. Chapter I.2 provides a behaviour-based estimate of odour similarity using four different types of experiments to yield a combined, task-independent estimate of perceived difference between odour-pairs. Further comparison of these perceived differences to published measures of physico- chemical difference reveals a weak correlation. Notable exceptions to this correlation are 3-octanol and benzaldehyde. Chapter I.3 shows for two odours (3-octanol and 1-octene-3-ol) that perceptual differences between these odours can either be ignored after non-discriminative training (generalization), or accentuated by odour-specific reinforcement (discrimination). Anosmic Or83b1 mutants have lost these faculties, indicating that this adaptive adjustment is taking place downstream of Or83b expressing sensory neurons. Chapter II.1 of this thesis deals with food supplementation with dried roots of Rhodiola rosea. This dose-dependently improves odour- reward associative function in larval Drosophila. Supplementing fly food with commercially available tablets or extracts, however, does not have a 'cognitive enhancing' effect, potentially enabling us to differentiate between the effective substances in the root versus these preparations. Thus Drosophila as a genetically tractable study case should now allow accelerated analyses of the molecular mechanism(s) that underlie this 'cognitive enhancement' conveyed by Rhodiola rosea. Chapter II.2 describes the role of Synapsin, an evolutionarily conserved presynaptic phosphoprotein using a combined behavioural and genetic approach and asks where and how, this protein affects functions in associative plasticity of larval Drosophila. This study shows that a Synapsin-dependent memory trace can be pinpointed to the mushroom bodies, a 'cortical' brain region of the insects. On the molecular level, data in this study assign Synapsin as a behaviourally- relevant effector of the AC-cAMP-PKA cascade.