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Sonstige beteiligte Institutionen
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Depressive Erkrankungen verursachen sowohl das persönliche Leid der erkrankten Individuen als auch volkswirtschaftlichen Schaden durch krankheitsbedingten Arbeitsausfall und Belastung der Gesundheitsversorgungssysteme. Therapeutische Konzepte wie die Anwendung pharmakotherapeutischer Intervention sind in unterschiedlichem Maß von Erfolg gekrönt.
Zahlreiche somatische Faktoren wurden mit der Ätiologie depressiver Störungen in Verbindung gebracht. Die primär verfolgten pharmakologischen Ansätze basieren nach wie vor auf Erkenntnissen aus der Mitte des vergangenen Jahrhunderts. In erster Linie setzt die Pharmakotherapie Substanzen ein, die die Wiederaufnahme monoaminerger Neurotransmitter (Serotonin, Noradrenalin, zum Teil auch Dopamin) aus dem synaptischen Spalt inhibieren und nach einer allerdings meist mehrwöchigen, regelmäßigen Einnahme des Präparates zu einem Rückgang der depressiven Symptomatik führen. Andererseits kann jedoch bei zahlreichen Erkrankten auch nach fortgesetzter Therapie mit verschiedenen Behandlungsansätzen keine Remission verzeichnet werden und es stellt sich die Frage nach der Ursache dieser Diskrepanz.
Im Fokus der vorliegenden Arbeit stand der als Antidepressivum eingesetzte selektive Serotonin- / Noradrenalin-Wiederaufnahme-Inhibitor Venlafaxin. Durch Blockade des präsynaptischen Serotonin- und Noradrenalin-Transporters führt Venlafaxin initial zu einer intensivierten Neurotransmission. Die Zielstrukturen von Venlafaxin sind der präsynaptische Serotonin- und der Noradrenalin-Transporter, wobei aufgrund unterschiedlicher Affinität eine geringe Dosis beziehungsweise Konzentration als rein serotonerg betrachtet wird und bei einer hohen Dosis beziehungsweise Konzentration sowohl die Wiederaufnahme von Serotonin als auch Noradrenalin inhibiert wird.
Es wurden in dieser Arbeit zwei Ziele verfolgt. Im ersten Teil wurde mittels Gen-expressionsuntersuchungen nach potentiellen Effektoren von Venlafaxin gesucht, um prinzipielle Mechanismen der antidepressiven Wirkung zu identifizieren und auf ihrer Basis die Entwicklung spezifischerer Intervention zu ermöglichen.
Der zweite Teil beinhaltet eine pharmakogenetische Untersuchung am Menschen. Ziel war zu evaluieren, inwieweit die Expressionsaktivität von SLC6A2 und SLC6A4 und damit die präsynaptische Transportkapazität in Kombination mit der Serumkonzentration aktiver Substanz als Prädiktor des therapeutischen Effektes dienen kann. Die Kenntnis dieser Zusammenhänge würde bei Vorliegen eines bestimmten Genotyps eine gezieltere Titration der individuell benötigten Konzentration ermöglichen und könnte die Effektivität der Therapie steigern.
Für die Genexpressionsuntersuchungen erhielten DBA/2-Mäuse über einen Zeitraum von 30 Tagen Venlafaxin in verschiedenen Dosierungen über das Trinkwasser. Anschließend wurden die Hippokampi der Tiere mittels genomweiter Microarray-Analyse hypothesenfrei auf zwischen den Dosisgruppen differentiell exprimierte Gene hin untersucht. Der Hippokampus wird als zentrales Element der Steuerung, Ausbildung und Veränderung von Verhaltensmustern gesehen. Signifikant differentiell exprimierte Gene, die in vorherigen Studien mit depressiver Erkrankung beziehungsweise einem Effekt psychiatrischer Medikation assoziiert worden waren, wurden mittels qRT-PCR-Analyse validiert. Im Anschluss an die Analyse im Tier wurden als differentiell exprimiert bestätigte Gene per qRT-PCR analog in humanen Leukozyten untersucht. Die Blutproben waren in einem klinisch-naturalistischen Design während der ersten und der fünften Woche einer Venlafaxin-Pharmakotherapie von Patienten der Klinik für Psychiatrie, Psychosomatik und Psychotherapie des Universitätsklinikums Würzburg gewonnen worden, das heißt vor und nach potentiellem Eintreten der antidepressiven Wirkung. Trotz der unterschiedlichen Herkunft der analysierten Gewebe könnten auf diesem Weg Hinweise auf Vorgänge im menschlichen Gehirn gefunden werden, wie in vergleichenden post mortem Untersuchungen zwischen peripherem und zentralem humanem Material erkannt worden war.
Die in der Tierstudie identifizierten Gene kodieren für Transkriptionsfaktoren sowie Proteine die als Teil von second messenger-Kaskaden bekannt sind. Von statistischer Signifikanz erwies sich in der Analyse der humanen Leukozyten die Expressionsreduktion der mRNA der Transkriptionsfaktor-Untereinheit Fos.
Befunde zu einer Funktion von Fos, die eine Interpretation im Bezug auf den antidepressiven Effekt von Venlafaxin ermöglichen, liegen lediglich aus Tierstudien vor. Fos-ko im Hippo-kampus von Mäusen wurde mit reduziertem Angstverhalten und höherer Exzitabilität von hippokampalen Neuronen assoziiert. Auch wurde eine Assoziation mit Vorgängen bei synaptischer Plastizität und damit potentiell bei Lernvorgängen gefunden. Auf der anderen Seite wurde depressions-ähnliches Verhalten bei Ratten mit niedriger hippokampaler Fos-Expression und dessen erfolgreiche pharmakologische "Therapie" mit einer Induktion der Fos-Expression assoziiert. Es scheinen also bereits zwischen nicht-menschlichen Spezies ausgeprägte Unterschiede der Rolle von Fos beziehungsweise Fos zu bestehen.
Aufgrund der unterschiedlichen Spezies und Gewebe in den hier durchgeführten Untersuchungen sowie den uneinheitlichen Befunden bezüglich der Rolle von Fos beziehungsweise Fos in vorangegangenen Studien kann abschließend lediglich konstatiert werden, dass Fos vermutlich an der Entstehung depressionsbegünstigender Physiologie beteiligt ist und auch, dass eine antidepressive Pharmakotherapie mit Venlafaxin ihre Wirkung vermutlich unter Beteiligung von Fos entfaltet.
Die Entwicklung innovativer Antidepressiva die unter Umgehung der monoaminergen Transmissionssysteme durch gezielte Reduktion der Fos-Abundanz das therapeutische Ziel erreichen lassen, könnte auf Basis der vorliegenden Studie angedacht werden, scheint allerdings aufgrund der ubiquitären Mediatorentätigkeit des Proteins und insbesondere aufgrund seiner nicht endgültig definierten Rolle bei der Entstehung von Krebs nicht praktikabel. Zukünftige Untersuchungen sollten daher auf andere im Microarray differentiell exprimiert gefundene Gene fokussieren.
In die Untersuchung der Expressionsaktivität der für die primären Zielstrukturen von Venlafaxin (Serotonin- beziehungsweise Noradrenalin-Transporter) kodierenden Gene (SLC6A4 beziehungsweise SLC6A2) und der Serumkonzentration an aktiver Substanz nach Venlafaxin-Applikation im Hinblick auf deren Prädiktivität des therapeutischen Effektes, wurden in einem klinisch-naturalistischen Design Patienten der Klinik für Psychiatrie, Psychosomatik und Psychotherapie des Universitätsklinikums Würzburg eingeschlossen. Genotypisiert wurden für SLC6A2 der SNP rs28386840 und für SLC6A4 der Polymorphismus 5-HTTLPR. Die Genotypen wurden jeweils in niedrig- und hoch-exprimierend unterteilt und damit auf die phänotypische Transportkapazität der präsynaptischen Membran Bezug genommen. Der therapeutische Erfolg wurde anhand der CGI-I-Skala evaluiert und für die Analysen in "gutes Ansprechen" und "schlechtes Ansprechen" dichotomisiert.
Der SLC6A2-Polymorphismus zeigte sich als nicht mit dem therapeutischen Effekt assoziiert. Der hochexprimierende SLC6A4-Genotyp wurde signifikant mit einem schlechteren Ansprechen assoziiert. Dies war in den nach Serumkonzentration aktiver Substanz stratifizierten Unterkollektiven insbesondere in dem Bereich zwischen 200 und 400 ng / ml zu erkennen, wohingegen unter- und oberhalb dieses Bereiches keine Assoziation zu finden war.
Aus diesen Resultaten kann gefolgert werden, dass sich aus der Genotypisierung von rs28386840 keine therapeutischen Instruktionen ableiten lassen. Bei Kenntnis des 5-HTTLPR-Genotyps könnte für den klinischen Alltag die Empfehlung ergehen, falls Venlafaxin als sSNRI bei Patienten mit hochexprimierendem Genotyp eingesetzt werden soll, eine Serumsummenkonzentration jenseits des durch die AGNP empfohlenen Bereiches (100 - 400 ng / ml) anzustreben.
Da hier jedoch lediglich eine Stichprobe von 56 Patienten untersucht und insbesondere, da zahlreiche potentielle Kofaktoren des therapeutischen Effektes nicht in die Analyse einbezogen werden konnten, ist die Assoziation vor Anwendung in der Therapiesteuerung anhand umfassenderer prospektiver kontrollierter Studien zu validieren.
This thesis reviews the fundamentals of three-dimensional super-resolution localization imaging. In order to infer the axial coordinate of the emission of single fluorophores, the point spread function is engineered following a technique usually referred to as astigmatic imaging by the introduction of a cylindrical lens to the detection path of a microscope.
After giving a short introduction to optics and localization microscopy, I outline sources of aberrations as frequently encountered in 3D-localization microscopy and will discuss their respective impact on the precision and accuracy of the localization process. With the knowledge from these considerations, experiments were designed and conducted to verify the validity of the conclusions and to demonstrate the abilities of the proposed microscope to resolve biological structures in the three spatial dimensions. Additionally, it is demonstrated that measurements of huge volumes with virtually no aberrations is in principle feasible.
During the course of this thesis, a new method was introduced for inferring axial coordinates. This interpolation method based on cubic B-splines shows superior performance in the calibration of a microscope and the evaluation of subsequent measurement and will therefore be used and explained in this work.
Finally, this work is also meant to give future students some guidance for entering the field of 3D localization microscopy and therefore, detailed protocols are provided covering the specific aspects of two color 3D localization imaging.
Murine embryonale Stammzellen (ES-Zellen) stellen mit ihrem Selbsterneuerungs- und Differenzierungspotenzial einen einzigartigen Zelltyp für die Grundlagenforschung und angewandte Wissenschaften dar. Auf Grund ihrer Fähigkeit, in vitro die embryonale Entwicklung eines Organismus nachzuahmen, sind sie für die Untersuchung der Zell-Differenzierung, wie z.B. der embryonalen Hämatopoese geeignet. Während der ES-Zell-Selbsterneuerung und -Differenzierung spielen epigenetischen Modifikationen, unter anderem Histon-Methylierungen, eine wichtige Rolle. Transkriptionell aktivierende (H3K4me2/3, di- bzw. trimethyliertes Lysin 4 an Histon 3) und reprimierende (H3K27me2/3; di- bzw. trimethyliertes Lysin 27 an Histon 3) Histon-Methylierungs-Muster und die epigenetische Gen-Regulierung werden unter anderem durch die entgegenwirkenden PcG- und MLL-Protein-Komplexe koordiniert. Die H3K27me2/3-spezifische Demethylase UTX/KDM6A ist eine Komponente des MLL-Komplexes und somit an aktivierenden Gen-Regulationsmechanismen beteiligt. Im Rahmen dieser Arbeit war es mein Ziel zu untersuchen, inwieweit UTX für die Aufrechterhaltung der ES-Zell-Pluripotenz und für die ES-Zell-Differenzierung, insbesondere die hämatopoetische Differenzierung, von Bedeutung ist. Meine Daten zeigten, dass UTX in undifferenzierten ES-Zellen, während der ES-Zell-Differenzierung und in adulten Geweben ubiquitär exprimiert ist. Um Aufschluss über die UTX-Funktion zu bekommen, wurde UTX in ES-Zellen mittels RNA-Interferenz und Gene-Targeting gezielt ablatiert. Genexpressions-Analysen zeigten, dass die Expression von Pluripotenzgenen, genauso wie die Zellproliferation und die Verteilung der Zellzyklus-Phasen in ES-Zellen durch den Verlust von UTX unbeeinflusst blieben, während globale H3K4me3- sowie H3K27me3-Level reduziert waren. Während der ES-Zell-Differenzierung konnte ich eine verminderte Induktion der mesodermalen und hämatopoetischen Marker Flk1, Brachyury, Runx1 und Gata1 beobachten. Zudem war die Expression von UTY, dem auf dem Y-Chromosom kodierten UTX-Homolog, in ES-Zellen und während der Differenzierung runterreguliert, was auf eine Regulierung durch UTX schließen lässt. Des Weiteren zeigten UTX-Knockdown und –Knockout-Zellen in funktionellen hämatopoetischen in vitro Assays eine verminderte Fähigkeit, Blast-Kolonien und hämatopoetische Vorläuferzellen zu generieren. Interessanterweise zeigten ChIP-Analysen in differenzierenden wt und UTX-Knockout-EBs unveränderte H3K27me3-Level an Promotoren der hämatopoetischen Gene, was auf eine Demethylase-unabhängige Funktion von UTX während der frühen Hämatopoese hindeutet. Um die Funktion von UTX während der Entwicklung in vivo, insbesondere während der embryonalen Hämatopoese, untersuchen zu können, habe ich eine konditionelle UTX-Knockout-Maus hergestellt, die für eine gezielte UTX-Deletion im hämatopoetischen System verwendet wird. Zusammenfassend zeigen meine Daten, dass UTX für die ES-Zell-Proliferation und –Pluripotenz unbedeutend ist und die Reduzierung der H3K27-Trimethylierung auch bei fehlendem UTX weiterhin herbeigeführt werden kann. Im Gegensatz dazu übernimmt UTX eine entscheidende Rolle während der mesodermalen und hämatopoetischen ES-Zell-Differenzierung, vermutlich über eine Histon-Demethylase-unabhängige Funktion.
Cord blood hematopoietic stem cells (CB-HSCs) are an outstanding source for the treatment of a variety of malignant and non-malignant disorders. However, the low amount of cells collected per donor is often insufficient for treatment of adult patients. In order to make sufficient numbers of CB-HSCs available for adults, expansion is required. Different approaches were described for HSC expansion, however these approaches are impeded by the loss of engrafting potential during ex vivo culture. Little is known about the underlying molecular mechanisms. Epigenetic mechanisms play essential roles in controlling stem cell potential and fate decisions and epigenetic strategies are considered for HSC expansion. Therefore, this study aimed to characterize global and local epigenotypes during the expansion of human CB-CD34+, a well established CB progenitor cell type, to better understand the molecular mechanisms leading to the culture-associated loss of engrafting potential. Human CB-CD34+ cells were cultured using 2 different cytokine cocktails: the STF cocktail containing SCF, TPO, FGF-1 and the STFIA cocktail, which combines STF with Angiopoietin-like 5 (Angptl5) and Insulin-like growth factor-binding protein 2 (IGFBP2). The latter expands CB-HSCs ex vivo. Subsequently, the NOD-scid gamma (NSG) mouse model was used to study the engraftment potential of expanded cells. Engraftment potential achieved by fresh CB-CD34+ cells was maintained when CB-CD34+ cells were expanded under STFIA but not under STF conditions. To explore global chromatin changes in freshly isolated and expanded CB-CD34+ cells, levels of the activating H3K4me3 and the repressive H3K27me3 histone marks were determined by chromatin flow cytometry and Western blot analyses. For analysis of genome-wide chromatin changes following ex vivo expansion, transcriptome profiling by microarray and chromatin immunoprecipitation combined with deep sequencing (ChIP-seq) were performed. Additionally, local chromatin transitions were monitored by ChIP analyses on promoter regions of developmental and self-renewal factors. On a global level, freshly isolated CD34+ and CD34- cells differed in H3K4me3 and H3K27me3 levels. After 7 days of expansion, CD34+ and CD34- cells adopted similar levels of active and repressive marks. Expanding the cells without IGFBP2 and Angptl5 led to a higher global H3K27me3 level. ChIP-seq analyses revealed a cytokine cocktail-dependent redistribution of H3K27me3 profiles. Chemical inhibition of the H3K27 methyltransferase EZH2 counteracted the culture-associated loss of NSG engraftment potential. Collectively, the data presented in this study revealed that by adding epigeneticly active compounds in the culture media we observed changes on a chromatin level which counteracted the loss of engraftment potential. H3K27me3 rather than H3K4me3 may be critical to establish a specific engraftment supporting transcriptional program. Furthermore, I identified a critical function for the Polycomb repressive complex 2-component EZH2 in the loss of engraftment potential during the in vitro expansion of HPSCs. Taken together this thesis provides a better molecular understanding of chromatin changes upon expansion of CB-HSPCs and opens up new perspectives for epigenetic ex vivo expansion strategies.
Localization microscopy is a class of super-resolution fluorescence microscopy techniques. Localization microscopy methods are characterized by stochastic temporal isolation of fluorophore emission, i.e., making the fluorophores blink so rapidly that no two are
likely to be photoactive at the same time close to each other. Well-known localization microscopy methods include dSTORM}, STORM, PALM, FPALM, or GSDIM. The biological community has taken great interest in localization microscopy, since it can enhance the resolution of common fluorescence microscopy by an order of magnitude at little experimental cost.
However, localization microscopy has considerable computational cost since millions of individual stochastic emissions must be located with nanometer precision. The computational cost of this evaluation, and the organizational cost of implementing the complex algorithms, has impeded adoption of super-resolution microscopy for a long time.
In this work, I describe my algorithmic framework for evaluating localization microscopy data.
I demonstrate how my novel open-source software achieves real-time data evaluation, i.e., can evaluate data faster than the common experimental setups can capture them.
I show how this speed is attained on standard consumer-grade CPUs, removing the need for computing on expensive clusters or deploying graphics processing units.
The evaluation is performed with the widely accepted Gaussian PSF model and a Poissonian maximum-likelihood noise model.
I extend the computational model to show how robust, optimal two-color evaluation is realized, allowing correlative microscopy between multiple proteins or structures. By employing cubic B-splines, I show how the evaluation of three-dimensional samples can be made simple and robust, taking an important step towards precise imaging of micrometer-thick samples.
I uncover the behavior and limits of localization algorithms in the face of increasing emission densities.
Finally, I show up algorithms to extend localization microscopy to common biological problems.
I investigate cellular movement and motility by considering the in vitro movement of myosin-actin filaments. I show how SNAP-tag fusion proteins enable imaging with bright and stable organic fluorophores in live cells. By analyzing the internal structure of protein clusters, I show how localization microscopy can provide new quantitative approaches beyond pure imaging.
This thesis explores the influence of social and environmental cues on the nest building behavior of leaf-cutting ants. Especially, the investigations are aimed at evaluating the mechanisms of nest building and how the nest environment can spatially guide building responses that lead to an adaptive nest architecture. The emergence of nest chambers in the nest of the leaf-cutting ant Acromyrmex lundi were evaluated. Rather than excavating nest chambers in advance, at places where workers encounter suitable environmental conditions for brood and fungus rearing, these items have to be present at a site. When presented in the laboratory with a choice between two otherwise identical digging sites, offering suitable environmental conditions, but one containing brood, the workers displayed a higher excavation activity at the site where they encountered the putative content of a chamber. The shape of the excavated cavity was also more round and chamber-like. It is concluded that leaf-cutting ants respond to social cues during nest building. Excavation is a costly process and colonies have to spend a part of their energy stores on nest building, so that regulatory responses for the control of nest excavation are expected to occur. Worker density at the beginning of the digging process influenced digging activity while the presence of in-nest stores did not. Stored brood and fungus did however influence the architecture of the excavated nest, leading to the excavation of larger chambers and smaller tunnels. While self-organized mechanisms appear to be involved in the nest building process, the social cues of the ants’ environment during building clearly influence the nest architecture and lead to an adjustment of the nest size to the current space needs of the colony. Workers secondarily regulated nest size by the opportunistic refilling of unused space with excavated soil pellets. As the ants should provide suitable conditions for brood and fungus rearing, they should show a behavioral response to CO2 concentrations, as the gas is known to hinder fungus respiration. Workers of A. lundi did indeed avoid high CO2-levels for fungus rearing but actually preferred CO2-values in the range encountered close to the soil surface, where this species excavates their nests. However, different CO2-levels did not affect their excavation behavior. While fungus chambers make up part of a leaf-cutting ant nest, most leaf-cutting ants of the genus Atta also spent part of the colony’s energy on excavating large, voluminous chambers for waste disposal, rather than scattering the material aboveground. It is expected that leaf-cutting ants also show environmental preferences for waste management. In experiments Atta laevigata workers preferred deposition in a warm and dry environment and showed no preference for specific CO2-levels. The continued accumulation of waste particles in a waste chamber seems to be based on the use of volatiles. These originate from the waste itself, and seem to be used as an orientation cue by workers relocating the material. The ensuing large accumulation of waste at one site should result in the emergence of more voluminous chambers for waste disposal.
The intracellular pathogen Chlamydia is the causative agent of millions of new infections per year transmitting diseases like trachoma, pelvic inflammatory disease or lymphogranuloma venereum. Undetected or recurrent infections caused by chlamydial persistence are especially likely to provoke severe pathologies. To ensure host cell survival and to facilitate long term infections Chlamydia induces anti-apoptotic pathways, mainly at the level of mitochondria, and restrains activity of pro-apoptotic proteins. Additionally, the pathogen seizes host energy, carbohydrates, amino acids, lipids and nucleotides to facilitate propagation of bacterial progeny and growth of the chlamydial inclusion.
At the beginning of this study, Chlamydia-mediated apoptosis resistance to DNA damage induced by the topoisomerase inhibitor etoposide was investigated. In the course of this, a central cellular protein crucial for etoposide-mediated apoptosis, the tumour suppressor p53, was found to be downregulated during Chlamydia infections. Subsequently, different chlamydial strains and serovars were examined and p53 downregulation was ascertained to be a general feature during Chlamydia infections of human cells. Reduction of p53 protein level was established to be mediated by the PI3K-Akt signalling pathway, activation of the E3-ubiquitin ligase HDM2 and final degradation by the proteasome. Additionally, an intriguing discrepancy between infections of human and mouse cells was detected. Both activation of the PI3K-Akt pathway as well as degradation of p53 could not be observed in Chlamydia-infected mouse cells. Recently, production of reactive oxygen species (ROS) and damage to host cell DNA was reported to occur during Chlamydia infection. Thus, degradation of p53 strongly contributes to the anti-apoptotic environment crucial for chlamydial infection.
To verify the importance of p53 degradation for chlamydial growth and development, p53 was stabilised and activated by the HDM2-inhibiting drug nutlin-3 and the DNA damage-inducing compound etoposide. Unexpectedly, chlamydial development was severely impaired and inclusion formation was defective. Completion of the chlamydial developmental cycle was prevented resulting in loss of infectivity. Intriguingly, removal of the p53 activating stimulus allowed formation of the bacterial inclusion and recovery of infectivity. A similar observation of growth recovery was made in infected cell lines deficient for p53.
As bacterial growth and inclusion formation was strongly delayed in the presence of activated p53, p53-mediated inhibitory regulation of cellular metabolism was suspected to contribute to chlamydial growth defects. To verify this, glycolytic and pentose phosphate pathways were analysed revealing the importance of a functioning PPP for chlamydial growth. In addition, increased expression of glucose-6-phosphate dehydrogenase rescued chlamydial growth inhibition induced by activated p53. The rescuing effect was even more pronounced in p53-deficient cells treated with etoposide or nutlin-3 revealing additional p53-independent aspects of Chlamydia inhibition. Removal of ROS by anti-oxidant compounds was not sufficient to rescue chlamydial infectivity. Apparently, not only the anti-oxidant capacities of the PPP but also provision of precursors for nucleotide synthesis as well as contribution to DNA repair are important for successful chlamydial growth.
Modulation of host cell signalling was previously reported for a number of pathogens. As formation of ROS and DNA damage are likely to occur during infections of intracellular bacteria, several strategies to manipulate the host and to inhibit induction of apoptosis were invented. Downregulation of the tumour suppressor p53 is a crucial point during development of Chlamydia, ensuring both host cell survival and metabolic support conducive to chlamydial growth.
Cell growth and cell division are two interconnected yet distinct processes. Initiation of proliferation of central brain progenitor cells (neuroblasts) after the late embryonic quiescence stage requires cell growth, and maintenance of proper cell size is an important prerequisite for continuous larval neuroblast proliferation. Beside extrinsic nutrition signals, cell growth requires constant supply with functional ribosomes to maintain protein synthesis.
Mutations in the mushroom body miniature (mbm) gene were previously identified in a screen for structural brain mutants. This study focused on the function of the Mbm protein as a new nucleolar protein, which is the site of ribosome biogenesis. The comparison of the relative expression levels of Mbm and other nucleolar proteins in different cell types showed a pronounced expression of Mbm in neuroblasts, particularly in the fibrillar component of the nucleolus, suggesting that in addition to nucleolar components generally required for ribosome biogenesis, more neuroblast specific nucleolar factors exist. Mutations in mbm cause neuroblast proliferation defects but do not interfere with cell polarity, spindle orientation or asymmetry of cell division of neuroblasts. Instead a reduction in cell size was observed, which correlates with an impairment of ribosome biogenesis. In particular, loss of Mbm leads to the retention of the small ribosomal subunit in the nucleolus resulting in decreased protein synthesis. Interestingly, the defect in ribosome biogenesis was only observed in neuroblasts. Moreover, Mbm is apparently not required for cell size and proliferation control in wing imaginal disc and S2 cells supporting the idea of a neuroblast-specific function of Mbm.
Furthermore, the transcriptional regulation of the mbm gene and the functional relevance of posttranslational modifications were analyzed. Mbm is a transcriptional target of dMyc. A common feature of dMyc target genes is the presence of a conserved E-box sequence in their promoter regions. Two E-box motifs are found in the vicinity of the transcriptional start site of mbm. Gene reporter assays verified that only one of them mediates dMyc-dependent transcription. Complementary studies in flies showed that removal of dMyc function in neuroblasts resulted in reduced Mbm expression levels.
At the posttranslational level, Mbm becomes phosphorylated by protein kinase CK2. Six serine and threonine residues located in two acidic amino acid rich clusters in the C-terminal half of the Mbm protein were identified as CK2 phosphorylation sites.
Mutational analysis of these sites verified their importance for Mbm function in vivo and indicated that Mbm localization is controlled by CK2-mediated phosphorylation.
Although the molecular function of Mbm in ribosome biogenesis remains to be determined, the results of this study emphasize the specific role of Mbm in neuroblast ribosome biogenesis to control cell growth and proliferation.
Malaria is a challenging infection with increasing and wide-spread treatment failure risk due to resistance. With a estimated death toll of 1-3 Million per year, most cases of Malaria affect children under the age of five years in Sub-Saharan Africa. In this thesis, I analyse the current status of malaria control (focussing on diagnosis and therapy) in Burkina Faso to show how this disease burdens public health in endemic countries and to identify possible approaches to improvement. MB is discussed as a therapeutic option under these circumstances.
Burkina Faso is used as a representative example for a country in Sub-Saharan Africa with high endemicity for malaria and is here portrayed, its health system characterised and discussed under socioeconomic aspects.
More than half of this country’s population live in absolute poverty. The burden that malaria, especially treatment cost, poses on these people cannot be under-estimated.
A retrospective study of case files from the university pediatric hospital in Burkina Faso’s capital, Ouagadougou, shows that the case load is huge, and especially the specific diagnosis of severe malaria is difficult to apply in the hospital’s daily routine. Treatment policy as proposed by WHO is not satisfactorily implemented neither in home treatment nor in health services, as data for pretreatment clearly show.
In the face of growing resistance in malaria parasites, pharmacological combination therapies are important. Artemisinins currently are the last resort of malaria therapy. As I show with homology models, even this golden bullet is not beyond resistance development. Inconsidered mass use has rendered other drugs virtually useless before. Artemisinins should thus be protected similar to reserve antibiotics against multi-resistant bacteria.
There is accumulating evidence that MB is an effective drug against malaria. Here the biological effects of both MB alone and in combination therapy is explored via modeling and experimental data. Several different lines of MB attack on Plasmodium redox defense were identified by analysis of the network effects. Next, CQ resistance based on Pfmdr1 and PfCRT transporters as well as SP resistance were modeled in silico. Further modeling shows that MB has a favorable synergism on antimalarial network effects with these commonly used antimalarial drugs, given their correct application.
Also from the economic point of view MB shows great potential: in terms of production price, it can be compared to CQ, which could help to diminuish the costs of malaria treatment to affordable ranges for those most affected and struk by poverty.
Malaria control is feasible, but suboptimal diagnosis and treatment are often hindering the achievment of this goal. In order to achieve malaria control, more effort has to be made to implement better adjusted and available primary treatment strategies for uncomplicated malaria that are highly standardised. Unfortunately, campaigns against malaria are chronically underfinanced. In order to maximize the effect of available funds, a cheap treatment option is most important, especially as pharmaceuticals represent the biggest single matter of expense in the fight against malaria.
Dynamic interactions and their changes are at the forefront of current research in bioinformatics and systems biology. This thesis focusses on two particular dynamic aspects of cellular adaptation: miRNA and metabolites.
miRNAs have an established role in hematopoiesis and megakaryocytopoiesis, and platelet miRNAs have potential as tools for understanding basic mechanisms of platelet function. The thesis highlights the possible role of miRNAs in regulating protein translation in platelet lifespan with relevance to platelet apoptosis and identifying involved pathways and potential key regulatory molecules. Furthermore, corresponding miRNA/target mRNAs in murine platelets are identified. Moreover, key miRNAs involved in aortic aneurysm are predicted by similar techniques. The clinical relevance of miRNAs as biomarkers, targets, resulting later translational therapeutics, and tissue specific restrictors of genes expression in cardiovascular diseases is also discussed.
In a second part of thesis we highlight the importance of scientific software solution development in metabolic modelling and how it can be helpful in bioinformatics tool development along with software feature analysis such as performed on metabolic flux analysis applications. We proposed the “Butterfly” approach to implement efficiently scientific software programming. Using this approach, software applications were developed for quantitative Metabolic Flux Analysis and efficient Mass Isotopomer Distribution Analysis (MIDA) in metabolic modelling as well as for data management. “LS-MIDA” allows easy and efficient MIDA analysis and, with a more powerful algorithm and database, the software “Isotopo” allows efficient analysis of metabolic flows, for instance in pathogenic bacteria (Salmonella, Listeria). All three approaches have been published (see Appendices).
In contrast to c-Myc, a deregulated expression of the MYCN gene is restricted to human neuroendocrine tumours. In most cases, the excessive activity of N-Myc results from a MYCN amplification. In neuroblastoma, amplification of MYCN is a predictor of poor prognosis and resistance to therapy. The inability to target the N-Myc protein directly necessitates the search for alternative targets. This project aimed at identifying genes specifically required for growth and survival of cells that express high levels of N-Myc using high-throughput shRNA screening combined with next generation sequencing. The identification and analysis of these genes will shed light on functional interaction partners of N-Myc.
We screened a shRNA library containing 18,327 shRNAs and identified 148 shRNAs, which were selectively depleted in the presence of active N-Myc. In addition, shRNAs targeting genes that are involved in p53 and ARF turnover and apoptosis were depleted in the cell population during the screen. These processes are known to affect N-Myc-mediated apoptosis. Consequently, these results biologically validated the screen. The 148 shRNAs that showed a significant synthetic lethal interaction with high levels of N-Myc expression were further analysed using the bioinformatics program DAVID. We found an enrichment of shRNAs that target genes involved in specific biological processes. For example, we validated synthetic lethal interactions for genes such as, THOC1, NUP153 and LARP7, which play an important role in the process of RNA polymerase II-mediated transcription elongation. We also validated genes that are involved in the neddylation pathway.
In the screen we identified Cullin 3, which is a component of the BTB-CUL3-Rbx1 ubiquitin ligase that is involved in the turnover of Cyclin E. Depletion of cullin 3 and activation of N-Myc was found to synergistically increase Cyclin E expression to supraphysiological levels, inducing S-phase arrest and a strong DNA damage response.
Together with results from a proteomics analysis of N-Myc associated proteins, our results lead us to the following hypothesis: In a neuroblastoma cell, the high levels of N-Myc result in a conflict between RNA polymerase II and the replication machinery during S-phase. The newly identified interaction partners of N- Myc are required to solve this conflict. Consequently, loss of the interaction leads to a massive DNA damage and the induction of apoptosis. In addition, inhibition or depletion of the essential components of the neddylation pathway also results in an unresolvable problem during S-phase.
Die Einführung der Fluoreszenzmikroskopie ermöglicht es, Strukturen in Zellen spezifisch und mit hohem Kontrast zu markieren und zu untersuchen. Da die Lichtmikroskopie jedoch in ihrer Auflösung begrenzt ist, bleiben Strukturinformationen auf molekularer Ebene verborgen. Diese als Beugungsgrenze bekannte Limitierung, kann mit modernen Verfahren umgangen werden. Die Lokalisationsmikroskopie nutzt hierfür photoschaltbare Fluorophore, deren Fluoreszenz räumlich und zeitlich separiert wird, um so einzelne Fluorophore mit
Nanometer-Genauigkeit lokalisieren zu können. Aus tausenden Einzelmolekül-Lokalisationen wird ein künstliches, hochaufgelöstes Bild rekonstruiert. Die
hochauflösende Mikroskopie ist grade für die Lebendzell-Beobachtung ein wertvolles Werkzeug, um subzelluläre Strukturen und Proteindynamiken jenseits der Beugungsgrenze unter physiologischen Bedingungen untersuchen zu können.
Als Marker können sowohl photoaktivierbare fluoreszierende Proteine als auch photoschaltbare organische Fluorophore eingesetzt werden. Während die
Markierung mit fluoreszierenden Proteinen einfach zu verwirklichen ist, haben organische Farbstoffe hingegen den Vorteil, dass sie auf Grund der höheren Photonenausbeute eine präzisere Lokalisation erlauben. In lebenden Zellen wird die Markierung von Strukturen mit synthetischen Fluorophoren über sogenannte
chemische Tags ermöglicht. Diese sind olypeptidsequenzen, die genetisch an das Zielprotein fusioniert werden und anschließend mit Farbstoff-gekoppelten Substraten gefärbt werden. An der Modellstruktur des Histonproteins H2B
werden in dieser Arbeit Farbstoffe in Kombination mit chemischen Tags identifiziert, die erfolgreich für die Hochauflösung mit direct stochastic optical
reconstruction microscopy (dSTORM) in lebenden Zellen eingesetzt werden können. Für besonders geeignet erweisen sich die Farbstoffe Tetramethylrhodamin,
505 und Atto 655, womit der gesamte spektrale Bereich vertreten ist. Allerdings können unspezifische Bindung und Farbstoffaggregation ein Problem bei der effizienten Markierung in lebenden Zellen darstellen. Es wird
gezeigt, dass die Beschichtung der Glasoberfläche mit Glycin die unspezifische Adsorption der Fluorophore erfolgreich minimieren kann. Weiterhin wird der
Einfluss des Anregungslichtes auf die lebende Zelle diskutiert. Es werden Wege beschrieben, um die Photoschädigung möglichst gering zu halten, beispielsweise
durch die Wahl eines Farbstoffs im rotem Anregungsbereich.
Die Möglichkeit lebende Zellen mit photoschaltbaren organischen Fluorophoren spezifisch markieren zu können, stellt einen großen Gewinn für die Lokalisationsmikroskopie dar, bei der ursprünglich farbstoffgekoppelte Antikörper zum Einsatz kamen. Diese Markierungsmethode wird in dieser Arbeit eingesetzt, um
das Aggregationsverhalten von Alzheimer verursachenden -Amyloid Peptiden im Rahmen einer Kooperation zu untersuchen. Es werden anhand von HeLa Zellen verschiedene beugungsbegrenzte Morphologien der Aggregate aufgeklärt. Dabei wird gezeigt, dass intrazellulär vorhandene Peptide größere Aggregate formen als die im extrazellulären Bereich. In einer zweiten Kollaboration wird mit Hilfe des photoaktivierbaren Proteins
mEos2 und photoactivated localization microscopy (PALM) die strukturelle Organisation zweier Flotillinproteine in der Membran von Bakterien untersucht.
Diese Proteine bilden zwei Cluster mit unterschiedlichen Durchmessern, die mit Nanometer-Genauigkeit bestimmt werden konnten. Es wurde außerdem festgestellt, dass beide Proteine in unterschiedlichen Anzahlen im Bakterium
vorliegen.
The auditory system is an exquisitely complex sensory organ dependent upon the synchronization of numerous processes for proper function. The molecular characterization of hereditary hearing loss is complicated by extreme genetic heterogeneity, wherein hundreds of genes dispersed genome-wide play a central and irreplaceable role in normal hearing function. The present study explores this area on a genome-wide and single gene basis for the detection of genetic mutations playing critical roles in human hearing.
This work initiated with a high resolution SNP array study involving 109 individuals. A 6.9 Mb heterozygous deletion on chromosome 4q35.1q35.2 was identified in a syndromic patient that was in agreement with a chromosome 4q deletion syndrome diagnosis. A 99.9 kb heterozygous deletion of exons 58-64 in USH2A was identified in one patient. Two homozygous deletions and five heterozygous deletions in STRC (DFNB16) were also detected. The homozygous deletions alone were enough to resolve the hearing impairment in the two patients. A Sanger sequencing assay was developed to exclude a pseudogene with a high percentage sequence identity to STRC from the analysis, which further solved three of the six heterozygous deletion patients with the hemizygous, in silico predicted pathogenic mutations c.2726A>T (p.H909L), c.4918C>T (p.L1640F), and c.4402C>T (p.R1468X). A single patient who was copy neutral for STRC and without pathogenic copy number variations had compound heterozygous mutations [c. 2303_2313+1del12 (p.G768Vfs*77) and c.5125A>G (p.T1709A)] in STRC. It has been shown that STRC has been previously underestimated as a hearing loss gene. One additional patient is described who does not have pathogenic copy number variation but is the only affected member of his family having hearing loss with a paternally segregating translocation t(10;15)(q26.13;q21.1).
Twenty-four patients without chromosomal aberrations and the above described patient with an USH2A heterozygous deletion were subjected to a targeted hearing loss gene next generation sequencing panel consisting of either 80 or 129 hearing-relevant genes. The patient having the USH2A heterozygous deletion also disclosed a second mutation in this gene [c.2276G>T (p.C759F)]. This compound heterozygous mutation is the most likely cause of hearing loss in this patient. Nine mutations in genes conferring autosomal dominant hearing loss [ACTG1 (DFNA20/26); CCDC50 (DFNA44); EYA4 (DFNA10); GRHL2 (DFNA28); MYH14 (DFNA4A); MYO6 (DFNA22); TCF21 and twice in MYO1A (DFNA48)] and four genes causing autosomal recessive hearing loss were detected [GJB2 (DFNB1A); MYO7A (DFNB2); MYO15A (DFNB3), and USH2A]. Nine normal hearing controls were also included. Statistical significance was achieved comparing controls and patients that revealed an excess of mutations in the hearing loss patients compared to the control group. The family with the GRHL2 c.1258-1G>A mutation is only the second family published worldwide with a mutation described in this gene to date, supporting the initial claim of this gene causing DFNA28 hearing loss. Audiogram analysis of five affected family members uncovered the progressive nature of DFNA28 hearing impairment. Regression analysis predicted the annual threshold deterioration in each of the five family members with multiple audiograms available over a number of years.
The synaptonemal complex (SC) is a highly conserved structure in sexually reproducing organism. It has a tripartite, ladder-like organization and mediates the stable pairing, called synapsis, of the homologous chromosomes during prophase of meiosis I. Failure in homolog synapsis result in aneuploidy and/or apoptosis of the developing germ cells.
Since 1956, the SC is subject of intense research and its presence was described in various species from yeast to human. Its structure was maintained during millions of years of evolution consist-ing of two parallel lateral elements (LEs), joined by numerous transverse filaments (TFs) which run perpendicular to the LEs and an electron dense central element (CE) in the middle of the SC. Individual protein components, however, were characterized only in few available model organ-isms, as for example Saccharomyces cerevisiae, Arabidopsis thaliana, Drosophila melanogaster, Ceanorhabditis elegans and Mus musculus. Rather unexpectedly, these characterizations failed to detect an evolutionary homology between the protein components of the different SCs. This fact challenged the general idea of a single origin of the SC in the evolution of meiosis and sexual reproduction.
This thesis now addressed itself to the task to unravel the discrepancy between the high conser-vation of the SC structure and its diverse and apparently non-homologous protein composition, focusing on the animal kingdom. It is the first study dealing with the evolution of the SC in Meta-zoa and demonstrates the monophyly of the mammalian SC components in metazoan species. The thesis demonstrates that at least four out of seven murine SC proteins emerged in Eumeta-zoa at the latest and have been likewise part of an ancient SC as it can be found in the present-day cnidarian species Hydra. This SC displays the common organization and already possesses the minimal protein kit corresponding to the three different structural domains: LEs, TFs and the CE. Additionally, the individual phylogenies of the murine SC proteins revealed the dynamic evolu-tionary history of the ancient SC. Further components were added during the diversification of Bilateria and vertebrates while ancestral proteins likely duplicated in the vertebrate lineage and diversified or got lost in the branch leading to ecdysozoan species. It is hypothesized that the apparently non-homologous SC proteins in D. melanogaster and C. elegans actually do derive from the ancient SC proteins but diversified beyond recognition during the fast evolution of Ar-thropoda and Nematoda.
The study proposes Hydra as an alternative invertebrate model system for meiosis and SC re-search to the standard organisms D. melanogaster and C. elegans. Recent results about the cni-darian SC as well as the possible application of standard methods is discussed and summarized in the concluding section.
1. Pollination of sexually reproducing plants requires pollen transfer agents, which can be biotic, abiotic or a combination of biotic and abiotic agents. The dominance of one of pollination system in wild plant communities depends on climatic factors and/or degrees of anthropogenic influences, which have effects on pollinator diversity and pollination function. Anthropogenic activities and climate change are also considered as main causes of ongoing invasion of invasive species into wild and managed habitats which can bring up competition for pollinators with possible negative consequences for the reproduction of co-occurring native plant species.
2. The study aimed to determine pollination systems and pollination limitation of invasive and native plant communities in natural savannah between 870 – 1130 m and semi-natural (managed) grassland between 1300 – 1750 m above sea level; effects of flower density and pollinator abundance on seed production of cross-pollinated and self-pollinated plants; and relationships of bee abundance and the proportion of cross- pollinated plants at the southern slope of Mount Kilimanjaro, Tanzania.
3. Pollinator-exclusion, open pollination and supplemental hand-pollination treatments were applied to 27 plant species in savannah and grassland habitats. Flowers were counted in each clusters based upon their species. Pollinators were sampled by using pan traps. Information-theory-based multi-model averaging and generalized linear mixed effects models were used to identify and analyze the effects of flower density, pollinator abundance, pollination treatments and habitat types on seed production. Regression models were used to determine relationships of altitude with bee abundance, and with proportion of cross-pollinated plants.
4. My results show that mean seed numbers of native plants were significantly lower in pollinator-exclusion treatments than in open-pollination treatments, indicating their reliance on pollinators for reproductive success. In contrast, seed numbers of invasive plants were similar in pollinator-exclusion and open-pollination treatments, demonstrating an ability of reproduction without pollinators. Despite of higher levels of self-pollination in invasive plants, supplemental hand-pollination treatments revealed pollen limitation in grassland and marginally in savannah habitats. There were no significant difference in seed numbers between supplemental hand pollination and open pollination treatments of native plant communities in savannah and grassland, which indicates no pollination limitation in the studied ecological system for native communities. Besides, grassland plants produced comparatively more seeds than savannah plants, however seeds in grasslands were lighter than those of the savannah which may be due to nutrient limitation in grassland.
5. I found 12 cross-pollinated and 15 self-pollinated plants along altitudinal gradient after comparing seeds from pollinator-excluded and open-pollinated experiments. I also found that proportions of cross-pollinated plants and bee abundance simultaneously decreased with increasing altitude. All cross-pollinated plants were native and grew in savannah habitats, with an exception of one species.
6. Neither effects of focal flower density nor a significant interaction between focal flower densities and bee abundance for self-pollinated plants were observed. However, there were effects of focal flower densities and interactions of flower density with bee abundance for cross-pollinated plants. Non-focal flower density has no significant effects on seed production of cross-pollinated and self-pollinated plants.
7. The results show that native plants depend more on cross-pollination than invasive plants, despite of most native plants in managed habitat (grassland) rely on self-pollination for reproduction. The tendency of having more cross-pollinated plants in natural savannah which are in low altitude coincides with other finding that the cross-pollinated plants and bee abundance simultaneously decrease with increasing altitude. Therefore, our findings support the hypotheses that self-fertilization of flowering plants increases with increasing altitude, and pollinator limitation is most pronounced in managed or disturbed habitats. Despite of reduction of pollinators in grassland, only invasive plants experience pollen limitation, which may be due to poor integration with available pollinator networks.
8. I also found bee abundance and flower density are not the main pollination factors required by self-pollinated plants during reproduction. However, focal flower density, which influences pollinator diversity, is more applicable to cross-pollinated plants. Climate change and anthropogenic activities in natural habitats are factors that influence pollinator abundance and functioning, which lead to a shift of mating systems in plant communities so as to assure their reproduction.
Toll-like receptors (TLR) are pattern recognition receptors (PRR) by which macrophages (MØ) sense pathogen-associated molecular patterns (PAMPs). The recognition of lipopolysaccharide (LPS), the PAMP of gram negative bacteria, by TLR4 triggers signaling cascades and leads to the pro-inflammatory activation of the cells. A recent quantitative and kinetic analysis of the phosphoproteome of LPS-activated primary macrophages highlighted the cytoskeleton as a cell compartment with an enriched protein phosphorylation. In total 44 cytoskeleton-associated proteins were regulated by this post-translational modification and thus might be involved in the control and regulation of key macrophage functions like spreading, motility and phagocytosis.
To investigate the control of cytoskeleton-associated cell functions by TLR4 activation, we first developed a method to quantitatively measure the spreading response of bone marrow MØ after stimulation with LPS. Fluorescence microscopy was used for cell imaging and visualisation of the MØ contact area. In collaboration with the Fraunhofer Institute Erlangen, we developed and validated a software tool for the semi-automated segmentation and quantitation of MØ fluorescence microscopy data, which allowed fast, robust and objective image analysis. Using this method, we observed that LPS caused time-dependent spreading, which was detectable after 1-2 h and maximal after 24 h. Next, the impact of genetic or pharmacological inhibition of known TLR signaling components was investigated. Deficiency in the adapter protein MYD88 strongly reduced spreading activity at the late time points, but had no impact early after LPS-stimulation. A similar effect was observed upon pharmacological inhibition of ERK1/2 signaling, indicating that ERK1/2 mediates MYD88-dependent MØ spreading. In contrast, MØ lacking the MAPK p38 were impaired in the initial spreading response but responded normally 8-24 h after stimulation. The genetic deletion of the MAPK phosphatases DUSP1 and DUSP16 resulted in impaired late spreading, corroborating the essential role for functional MAPK signaling in TLR4-driven MØ spreading.
To identify the contribution of other cytoskeletal phosphoproteins to MØ spreading, siRNA knockdown of selected candidate genes in primary murine MØ was employed and combined with automated quantitative image analysis. These experiments revealed a functional role for the Myosins MYO1e and MYO1f in MØ spreading. These motor proteins are strongly phosphorylated in LPS-activated MØ. Because of their ability to simultaneously bind to actin filaments and cell membrane or other proteins, we investigated their role in phagocytosis, cytokine production and antigen presentation. Phagocytosis and killing of bacteria were not affected in Myo1e-/- macrophages. However, MYO1e plays a role in chemokine secretion and antigen presentation processes. MCP1 (CCL2) release was selectively increased in Myo1e-deficient MØ and dendritic cells (DC), while cytokine secretion was unaffected. Furthermore, macrophages and DCs lacking MYO1e showed lower levels of MHC-II on the cell surface. However, mRNA levels of CCL2 and of MHC-II were unaltered. These data suggest a role for MYO1e in the transport of selected chemokines and of MHC-II molecules to the cell surface. MHC-II-restricted antigen presentation assays revealed an impaired capacity of macrophages and DC lacking MYO1e to stimulate antigen-specific T cells, suggesting that the reduced MHC-II expression is functionally relevant.
Taken together, in this study first a quantitative image analysis method was developed which allows the unbiased, robust and efficient investigation of the macrophage spreading response. Combination of this method with siRNA knockdown of selected cytoskeleton-associated phosphoproteins led to the identification of MYO1e and MYO1f as regulators of macrophage spreading. Furthermore, we identified MYO1e in MØ and DC to be essential for the intracellular transport of CCL2 and MHC-II to the cell surface and for optimal stimulation of antigen-specific CD4 T cells.
Assistierte Reproduktionstechniken (ARTs) zur Behandlung von Infertilität werden mit einer erhöhten Häufigkeit von epigenetischen Aberrationen während der Gametogenese und der frühen Embryonalentwicklung in Verbindung gebracht, speziell durch eine Beeinträchtigung von geprägten Genen. Die in vitro-Maturation (IVM) von Eizellen ist eine ART, die bereits routinemäßig zur Reproduktion von ökonomisch wertvollen Zuchttieren wie dem Hausrind (Bos taurus) eingesetzt wird. IVM-Oozyten weisen jedoch eine verringerte Entwicklungs-kompetenz zum Blastozystenstadium dar, welche möglicherweise auf eine beeinträchtigte epigenetische Regulation zurückzuführen ist.
Von allen bekannten epigenetischen Mechanismen ist die DNA-Methylierung die meist untersuchte DNA-Modifikation. In dieser Arbeit wurden zur Klärung der Frage nach den Auswirkungen der IVM auf die DNA-Methylierung geprägter als auch nicht geprägter Gene Oozyten des Hausrinds analysiert. Diese Tierart weist eine ähnliche Präimplantations-entwicklung und Tragezeit wie der Mensch auf und wird daher zunehmend als Modell zum Studium der humanen Keimzell- und Embryonalentwicklung herangezogen. Im Gegensatz zu Mensch und Maus gibt es bislang nur wenig Information über bovine geprägte Gene. Das erste Ziel der hier dargestellten Forschungsarbeiten war daher die Identifizierung und Charakterisierung der bovinen differenziell methylierten Regionen (DMRs) der drei geprägten Genorte von IGF2/H19, SNRPN und PEG3, welche mit Imprintingdefekten des Menschen und/oder im Mausmodell assoziiert werden. Die hier erstmalig erfolgte Beschreibung von mehreren intergenischen DMRs mittels Bisulfitsequenzierung und Pyrosequenzierung belegt die Existenz und evolutionäre Konservierung der IGF2/H19-Imprintingkontrollregion (ICR) beim Rind. Der geprägte Zustand der IGF2/H19-ICR sowie der bovinen Gene SNRPN und PEG3 wurde durch den Nachweis differenzieller Methylierung in plazentalen und somatischen Geweben sowie in Spermien und parthenogenetischen Embryonen bestätigt. Die beobachteten Methylierungsprofile waren typisch für genomische Prägung.
Die direkte Bisulfitsequenzierung nach vorangegangener Limiting Dilution (LD) erlaubt die Analyse von Methylierungsmustern einzelner Allele (DNA-Moleküle) von einigen wenigen oder auch nur einer einzigen Zelle (El Hajj et al., 2011). In einem ersten LD-Versuch an bovinen Oozyten wurden die drei vorab charakterisierten und geprägten Gene hinsichtlich möglicher epigenetischer Veränderungen untersucht, welche durch verschiedene IVM-Bedingungen und -Medien (TCM und mSOF) hervorgerufen werden könnten. Die Gesamtrate von Methylierungsfehlern einzelner CpG-Stellen sowie die von ganzen Allelen (Imprintingfehlern) unterschied sich nicht wesentlich zwischen den beiden IVM-Gruppen und der in vivo-Gruppe. Dieses Ergebnis weist darauf hin, dass die gängigen IVM-Protokolle keinen oder nur einen geringfügigen Einfluss auf diese entscheidenden epigenetischen Markierungen haben.
IVM-Oozyten präpuberaler Kälber weisen eine herabgesetzte Entwicklungskompetenz im Vergleich zu IVM-Oozyten aus adulten Tieren auf. Aus diesem Grund wurde in einem zweiten LD-Versuchsansatz die Promotormethylierung von drei entwicklungsrelevanten, nicht geprägten Genen (SLC2A1, PRDX1, ZAR1) nach ovarieller Stimulation mit FSH und/oder IGF1 untersucht. Sowohl ungereifte als auch in vitro-gereifte Oozyten präpuberaler und adulter Kühe zeigten eine deutliche, unbeeinträchtige Hypomethylierung der drei Genpromotoren ohne jegliche Unterschiede zwischen den verschiedenen Alterstypen der Spendertiere oder deren Behandlung. Weder das Alter, die hormonelle Stimulation noch die IVM scheinen somit einen Einfluss auf den Methylierungsstatus dieser drei Gene zu haben.
Zusammenfassend spiegelte sich die reduzierte Entwicklungsfähigkeit von IVM-Eizellen aus adulten und präpuberalen Kühen nicht in abnormalen Methylierungsmustern der untersuchten geprägten und ungeprägten Gene wider. Dies lässt auf eine generelle Stabilität der etablierten DNA-Methylierungsprofile in Oozyten schließen. Aus diesem Grund müssen andere epigenetische Mechanismen als die DNA-Methylierung wie beispielsweise ncRNAs oder Histonmodifikationen zur Reduktion der Entwicklungskompetenz von präpuberalen und IVM-Oozyten beitragen. Diese Veränderungen behindern mutmaßlich die zytoplasmatische Reifung der Eizelle, welche wiederum zu einer späteren Beeinträchtigung der Entwicklung der Zygote und des Embryos führt.
The Notch signaling pathway is crucial for mammalian heart development. It controls cell-fate decisions, coordinates patterning processes and regulates proliferation and differentiation. Critical Notch effectors are Hey bHLH transcription factors (TF) that are expressed in atrial (Hey1) and ventricular (Hey2) cardiomyocytes (CM) and in the developing endocardium (Hey1/2/L). The importance of Hey proteins for cardiac development is demonstrated by knockout (KO) mice, which suffer from lethal cardiac defects, such as ventricular septum defects (VSD), valve defects and cardiomyopathy. Despite this clear functional relevance, little is known about Hey downstream targets in the heart and the molecular mechanism by which they are regulated.
Here, I use a cell culture system with inducible Hey1, Hey2 or HeyL expression to study Hey target gene regulation in HEK293 cells, in murine embryonic stem cells (ESC) and in ESC derived CM. In HEK293 cells, I could show that genome wide binding sites largely overlap between all three Hey proteins, but HeyL has many additional binding sites that are not bound by Hey1 or Hey2. Shared binding sites are located close to transcription start sites (TSS) where Hey proteins preferentially bind to canonical E boxes, although more loosely defined modes of binding exist. Additional sites only bound by HeyL are more scattered across the genome. The ability of HeyL to bind these sites depends on the C-terminal part of the protein. Although there are genes which are differently regulated by HeyL, it is unclear whether this regulation results from binding of additional sites by HeyL.
Additionally, Hey target gene regulation was studied in ESC and differentiated CM, which are more relevant for the observed cardiac phenotypes. ESC derived CM contract in culture and are positive for typical cardiac markers by qRT PCR and staining. According to these markers differentiation is unaffected by prolonged Hey1 or Hey2 overexpression. Regulated genes are largely redundant between Hey1 and Hey2. These are mainly other TF involved in e.g. developmental processes, apoptosis, cell migration and cell cycle. Many target genes are cell type specifically regulated causing a shift in Hey repression of genes involved in cell migration in ESC to repression of genes involved in cell cycle in CM.
The number of Hey binding sites is reduced in CM and HEK293 cells compared to ESC, most likely due to more regions of dense chromatin in differentiated cells. Binding sites are enriched at the proximal promoters of down-regulated genes, compared to up-or non-regulated genes. This indicates that up-regulation primarily results from indirect effects, while down-regulation is the direct results of Hey binding to target promoters. The extent of repression generally correlates with the amount of Hey binding and subsequent recruitment of histone deacetylases (Hdac) to target promoters resulting in histone H3 deacetylation.
However, in CM the repressive effect of Hey binding on a subset of genes can be annulled, likely due to binding of cardiac specific activators like Srf, Nkx2-5 and Gata4. These factors seem not to interfere with Hey binding in CM, but they recruit histone acetylases such as p300 that may counteract Hey mediated histone H3 deacetylation. Such a scenario explains differential regulation of Hey target genes between ESC and CM resulting in gene and cell-type specific regulation.
Das atriale natriuretische Peptid (ANP) wird infolge einer Zunahme des atrialen Drucks aus den Myozyten des Atriums sezerniert. Es spielt lokal eine bedeutende, protektive Rolle und wirkt der Entstehung von Herzhypertrophie und Fibrose entgegen. Darüber hinaus kommt ANP vor allem eine wichtige Rolle als endokrines Hormon zu, das den arteriellen Blutdruck und das Blutvolumen regelt. Diese physiologischen Effekte vermittelt das Herzhormon durch seinen Rezeptor, das Transmembranprotein Guanylatzyklase A (GC-A). Durch Bindung von ANP an die extrazelluläre Domäne der GC-A wird intrazellulär, durch die katalytische Domäne des Rezeptors, der sekundäre Botenstoff cGMP gebildet. Patienten mit einer, durch Bluthochdruck verursachten Herzhypertrophie und Herzinsuffizienz weisen erhöhte ANP-Konzentrationen im Plasma auf. Die durch ANP vermittelten, protektiven Effekte sind allerdings vermindert. Zahlreiche Studien haben in vitro gezeigt, dass die chronische Inkubation der GC-A mit ihrem Liganden, sowie die Behandlung von GC-A exprimierenden Zellen mit Hormonen wie Angiotensin II, zur Desensitisierung des Rezeptors führen. Der Verlust der Funktionsfähigkeit geht einher mit der Dephosphorylierung des Rezeptors an spezifischen, intrazellulär lokalisierten Aminosäuren. Durch die Erforschung dieses Mechanismus und Identifizierung möglicher Interaktionspartner in vivo könnte der Grundstein für neue oder verbesserte Therapieformen gelegt werden.
Im ersten Teil der vorliegenden Arbeit wurde eine kürzlich identifizierte Isoform des GC-A-Rezeptors identifiziert, die durch alternatives Spleißen des Exons 4 entsteht und in einer Vielzahl untersuchter Gewebe der Maus vorkommt. Die Deletion umfasst 51 Basenpaare und resultiert in einem um 17 Aminosäuren verkürzten GC-A-Rezeptor (GC-AΔLys314-Gln330). Molekulare Modellierungen der extrazellulären Domänen des wildtypischen GC-A-Rezeptors und der Isoform zeigten, dass sich die Deletion im membrannahen Bereich der extrazellulären Domäne und damit deutlich entfernt von der ANP-Bindungsdomäne befindet. Oberflächenbiotinylierungs- und Zellfraktionierungsversuche zeigten, dass die Isoform des GC-A-Rezeptors an der Oberfläche von Zellmembranen transient transfizierter HEK 293-Zellen präsentiert wird. Jedoch zeigten die ANP-Stimulationsexperimente unter Anwendung von cGMP-Radioimmunassay (cGMP-RIA) und Förster-Resonanzenergietransfer (FRET)-Messungen, dass die Isoform nicht zur ANP-vermittelten intrazellulären cGMP-Bildung stimuliert werden kann. Im Rahmen von ANP-Bindungsstudien mit 125I-ANP wurde gezeigt, dass GC-AΔLys314-Gln330 die Fähigkeit zur Bindung des Liganden ANP verloren hat. Jedoch zeigten die Koimmunpräzipitationsversuche, dass die Isoform des GC-A-Rezeptors Heterodimere mit dem wildtypischen GC-A-Rezeptor bilden und dadurch die ligandeninduzierte Bildung von cGMP reduzieren kann. In vivo konnte gezeigt werden, dass unter Angiotensin II-induzierter Hypertonie die mRNA-Expression für GC-AΔLys314-Gln330 in der Lunge gesteigert, und gleichzeitig die ANP-vermittelte cGMP-Bildung deutlich reduziert ist. Daher kann davon ausgegangen werden, dass das alternative Spleißen ein regulierender Mechanismus ist, der auf den ANP/GC-A-Signalweg Einfluss nimmt. Angiotensin II-induziertes alternatives Spleißen des GC-A-Gens kann daher einen neuen Mechanismus für die Verringerung der Sensitivität des GC-A-Rezeptors gegenüber ANP darstellen.
Im zweiten Teil der vorliegenden Arbeit wurden transgene Tiere mit kardiomyozytenspezifischer Überexpression eines Epitop-getaggten GC-A-Rezeptors generiert. Durch dieses Modell sollte es ermöglicht werden, den Rezeptor aus murinem Gewebe anreichern und aufreinigen zu können um danach Analysen zu posttranslationalen Veränderungen und möglichen Interaktionspartnern durchzuführen. Zunächst wurde in eine FLAG-Epitop-getaggte GC-A zusätzlich ein HA-tag, sowie eine Erkennungssequenz für die Protease des tobacco etch virus (TEV) eingefügt. Die Expression und Funktionsfähigkeit des modifizierten Rezeptors wurde durch ANP-Stimulationsexperimente unter Anwendung von cGMP-RIA und FRET-Messungen verifiziert. Die Funktionsfähigkeit der TEV-Erkennungssequenz wurde durch die Elution mittels TEV-Protease nach Immunpräzipitation (IP) nachgewiesen. In vivo wurde an Mäusen die Expression und Lokalisation der GC-A auf Proteinebene, unter Anwendung von Zellfraktionierungsexperimenten und Immunpräzipitationen, überprüft. Die entstandenen transgenen Tiere zeigten eine deutliche, in den Zellmembranen von Kardiomyozyten lokalisierte, Überexpression des Rezeptors. Dieser konnte über das HA-tag angereichert und aufgereinigt werden. Um die Funktionsfähigkeit des modifizierten Rezeptors in vivo nachzuweisen, wurde in zwei Versuchsreihen kardiale Hypertrophie durch chronische Applikation von Angiotensin II induziert. Es wurde postuliert, dass die Überexpression funktionsfähiger GC-A im Herzen die Tiere vor Herzhypertrophie schützt. Die Ergebnisse der Studien zeigen allerdings, dass die generierten transgene Tiere trotz kardiomyozytenspezifischer Überexpression des Rezeptors nicht den erwarteten Schutz vor Herzhypertrophie aufwiesen, sondern ähnlich wie ihre wildtypischen Geschwistertiere reagieren. Jedoch gelang es mit Hilfe des Überexpressionsmodells zusammen mit anderen Mitarbeitern der AG Kuhn eine zuvor in vitro beschriebene Interaktion des GC-A-Rezeptors mit den Kationenkanälen TRPC3 und TRPC6 in vivo nachzuweisen. Somit besteht die Möglichkeit die Epitope und das murine Überexpressionsmodell auch zukünftig zu nutzen, um Interaktionspartner der GC-A zu identifizieren.
Post-translational histone modifications (PTMs) such as methylation of lysine residues influence chromatin structure and function. PTMs are involved in different cellular processes such as DNA replication, transcription and cell differentiation. Deregulations of PTM patterns are responsible for a variety of human diseases including acute leukemia. DOT1 enzymes are highly conserved histone methyltransferases that are responsible for methylation of lysine 79 on histone H3 (H3K79). Most eukaryotes contain one single DOT1 enzyme, whereas African trypanosomes have two homologues, DOT1A and DOT1B, which methylate H3K76 (H3K76 is homologous to H3K79 in other organisms). DOT1A is essential and mediates mono- and di-methylations, whereas DOT1B additionally catalyzes tri-methylation of H3K76. However, a mechanistic understanding how these different enzymatic activities are achieved is lacking. This thesis exploits the fact that trypanosomes possess two DOT1 enzymes with different catalytic properties to understand the molecular basis for the differential product-specificity of DOT1 enzymes. A trypanosomal nucleosome reconstitution system was established to analyze methyltransferase activity under defined in vitro conditions. Homology modeling allowed the identification of critical residues within and outside the catalytic center that modulate product-specificity. Exchange of these residues transferred the product-specificity from one enzyme to the other and revealed regulatory domains adjacent to the catalytic center. This work provides the first evidence that few specific residues in DOT1 enzymes are crucial to catalyze methyl-state-specific reactions. These results have also consequences for the functional understanding of homologous enzymes in other eukaryotes.
Die Lokalisationsmikroskopie ist eine neue, vielversprechende Methode der hochauflösenden Fluoreszenzmikroskopie. Sie ermöglicht detaillierte Einblicke in die Organisation und den strukturellen Aufbau von Zellen. Da die Vorbereitung der Proben und das Aufnehmen der Bilder im Vergleich zu herkömmlichen Methoden höhere Anforderungen stellt, mussten ihr Potential und ihre Zuverlässigkeit erst noch überzeugend gezeigt werden. Bis vor kurzem wurde das Auflösungsvermögen vor allem an Mikrotubuli gezeigt, deren filamentöse Struktur allerdings schon in konfokalen Bildern zu erkennen ist. Deswegen wurde in dieser Dissertation der Kernporenkomplex (NPC), dessen Struktur in der konventionellen Fluoreszenzmikroskopie nicht auflösbar ist, als Modellstruktur für die hochauflösende Fluoreszenzmikroskopie eingeführt.
Dazu wurden Kernporenkomplexe aus Kernhüllen von Xenopus laevis Oocyten mit dSTORM (direct stochastic optical reconstruction microscopy), einer Methode der Lokalisationsmikroskopie, hochaufgelöst. Damit konnte nun erstmals die Achtfachsymmetrie dieses Proteinkomplexes lichtmikroskopisch dargestellt werden. Desweiteren konnte der Zentralkanal mit einem Durchmesser von ca. 40 nm aufgelöst werden. Die Daten eigneten sich außerdem für eine automatisierte Bildanalyse nach dem sogenannten "particle averaging" - einer aus der Elektronenmikroskopie bekannten Methode, um eine Durchschnittsstruktur zu ermitteln.
Darüber hinaus wurden Zweifach-Färbungen von NPCs benutzt, um verschiedene Ansätze für Zweifarben-Aufnahmen mit dSTORM zu testen. Neben dem mittlerweile standardmäßig benutzten, sequentiellen Ansatz mit zwei spektral getrennten Farbstoffen, wurde auch ein simultaner Ansatz mit zwei spektral überlappenden Farbstoffen erfolgreich angewandt. Auch für 3D-Messungen mit den Ansätzen Biplane und Astigmatismus eignete sich die Markierung der Kernhülle. Hier wurden jedoch A6-Zellen benutzt und die Krümmung des Zellkerns über die gefärbten Kernporen dargestellt.
dSTORM-Messungen können nicht nur an fixierten, sondern auch in lebenden Zellen durchgeführt werden. Hierzu eignen sich vor allem sehr immobile Proteine, wie H2B oder Lamin C. Anhand von SNAP-Tag- und Halo-Tag-Konstrukten konnte gezeigt werden, dass sich kommerziell erhältliche, organische Farbstoffe auch in endogener zellulärer Umgebung schalten lassen, wodurch Lebendzell-Aufnahmen mit dSTORM möglich sind.
Ein weiterer Teil dieser Arbeit befasst sich mit korrelativen Aufnahmen aus dSTORM und Rasterelektronenmikroskopie (SEM). Hierzu wurden Xenopus laevis Kernhüllen zuerst mit dSTORM hochaufgelöst und danach für die EM präpariert. Anschließend wurden zugehörige Bereiche am Rasterelektronenmikroskop aufgenommen. Mit den erhaltenen korrelativen Bildern konnte gezeigt werden, dass sich dSTORM und SEM bei geeigneten Proben durchaus kombinieren lassen. Proteine können somit spezifisch markiert und im Rahmen ihrer strukturellen Umgebung mit nahezu molekularer Auflösung dargestellt werden.
Da hochwertige Aufnahmen eine ausgereifte Probenpräparation voraussetzen, darf deren Etablierung nicht zu kurz kommen. Unter dieser Prämisse wurde ein optimiertes Markierungsprotokoll mit dem Namen ClickOx entwickelt. Mit ClickOx bleibt bei der kupferkatalysierten Azid-Alkin-Cycloaddition die Feinstruktur von Aktinfilamenten, sowie die Fluoreszenz fluoreszierender Proteine, deutlich sichtbar erhalten. Während bei den klassischen Click-Protokollen auf Grund der Entstehung von reaktiven Sauerstoff-Spezies (ROS) feine zelluläre Strukturen, wie Aktinfilamente, angegriffen oder zerstört werden, schützt das neue Protokoll mit enzymatischem Sauerstoffentzug Proteine und somit Strukturen vor Reaktionen mit ROS. Das unterstreicht, wie wichtig es ist auch sogenannte "etablierte" Protokolle weiterzuentwickeln, denn bestimmte Nebeneffekte in Präparationen werden unter Umständen erstmals in der Hochauflösung sichtbar.
Ein weiterer Aspekt war die Untersuchung des Einflusses von D1 auf die Chromatinorganisation. Mit verschiedenen mikroskopischen Methoden konnten Hinweise auf eine mögliche DNA-Cross-Linking-Fähigkeit dieses Proteins gesammelt werden. Hier wurde die Einzelmolekülinformation der dSTORM-Filme genutzt, um unterschiedliche Grade von DNA- bzw. Chromatin-Akkumulation zu vergleichen. Die Ergebnisse deuten darauf hin, dass wildtypisches D1 DNA vernetzen kann. Dies erfolgt über die sogenannten AT-Haken-Motive. Sobald diese alle durch Mutation funktionsunfähig gemacht werden - wie bei der verwendeten R10xG-Mutante - lässt sich keine Akkumulation der DNA mehr beobachten. Neben der Chromatinaggregation durch D1-Expression konnte in FRAP-Experimenten gezeigt werden, dass nur die "echten" AT-Haken eine hohe Affinität zum Chromatin aufweisen, die sogenannten "potentiellen" hingegen nicht.
Neisseria gonorrhoeae is a human-specific pathogen that causes gonorrhea. It is defined as a super bacterium by the WHO due to the emergence of gonococci that are resistant to a variety of antibiotics and a rapidly increasing infection incidence. Genome-wide investigation of neisserial gene essentiality and novel virulence factors is urgently required in order to identify new targets for anti-neisserial therapeutics. To identify essential genes and new virulence factors, a high-density mutant library in N. gonorrhoeae MS11 was generated by in vitro transposon mutagenesis. The transposon library harbors more than 100,000 individual mutants, a density that is unprecedented in gonococcal research. Essential genes in N. gonorrhoeae were determined by enumerating frequencies of transposon insertion sites (TIS) with Illumina deep sequencing (Tn-seq). Tn-seq indicated an average distance between adjacent TIS of 25 bp. Statistical analysis unequivocally demonstrated 781 genes that were significantly depleted in TIS and thus are essential for Neisseria survival. A subset of the genes was experimentally verified to comprise essential genes and thus support the outcome of the study. The hereby identified candidate essential genes thus may constitute excellent targets for the development of new antibiotics or vaccines.
In a second study, the transposon mutant library was applied in a genome-scale “negative-selection strategy” to identify genes that are involved in low phosphate-dependent invasion (LPDI). LPDI is dependent on the Neisseria porin subtype PorBIA which acts as an epithelial cell invasin in absence of phosphate and is associated with severe pathogenicity in disseminated gonococcal infections (DGI). Tn-seq demonstrated 98 genes, which were involved in adherence to host cells and 43 genes involved in host cell invasion. E.g. the hypothetical protein NGFG_00506, an ABC transporter ATP-binding protein NGFG_01643, as well as NGFG_04218 encoding a homolog of mafI in N. gonorrhoeae FA1090 were experimentally verified as new invasive factors in LPDI. NGFG_01605, a predicted protease, was identified to be a common factor involved in PorBIA, Opa50 and Opa57-mediated neisserial engulfment by the epithelial cells. Thus, this first systematic Tn-seq application in N. gonorrhoeae identified a set of previously unknown N. gonorrhoeae invasive factors which demonstrate molecular mechanisms of DGI.
Since more than two centuries naturalists are fascinated by the profound changes in biodiversity observed along climatic gradients. Although the theories explaining changes in the diversity and the shape of organisms along climatic gradients belong to the foundations of modern ecology, our picture on the spatial patterns and drivers of biodiversity is far from being complete. Ambiguities in theory and data are common and past work has been strongly concentrated on plants and vertebrates. In the last two decades, interest in the fundamental processes structuring diversity along climatic gradients gained new impetus as they are expected to improve our understanding about how ecosystems will respond to global environmental changes. Global temperatures are rising faster than ever before; natural habitats are transformed into agricultural land and existing land use systems get more and more intensified to meet the demands of growing human populations. The fundamental shifts in the abiotic and biotic environment are proclaimed to affect ecosystems all over the world; however, precise predictions about how ecosystems respond to global changes are still lacking. We investigated diversity, traits and ecosystem services of wild bees along climate and land use gradients on Mount Kilimanjaro (Tanzania, East Africa). Wild bees play a major role in ecosystems, as they contribute to the reproduction and performance of wild and crop plants. Their responsiveness to environmental changes is therefore of high ecological and economic importance.
Temperature and energy resources have often been suggested to be the main determinants of global and local species richness, but the mechanisms behind remain poorly understood. In the study described in chapter II we analyzed species richness patterns of wild bees along climate and land use gradients on Mount Kilimanjaro and disentangled the factors explaining most of the changes in bee richness. We found that floral resources had a weak but significant effect on pollinator abundance, which in turn was positively related to species richness. However, temperature was the strongest predictor of species richness, affecting species richness both directly and indirectly by positively influencing bee abundances. We observed higher levels of bee-flower-interactions at higher temperatures, independently of flower and bee abundances. This suggests that temperature restricts species richness by constraining the exploitation of resources by ectotherms. Current land use did not negatively affect species richness. We conclude that the richness of bees is explained by both temperature and resource availability, whereas temperature plays the dominant role as it limits the access of ectotherms to floral resources and may accelerate ecological and evolutionary processes that drive the maintenance and origination of diversity.
Not only species numbers, but also morphological traits like body size are expected to be shaped by both physiological and energetic constraints along elevational gradients. Paradoxically, Bergmann´s rule predicts increases of body sizes in cooler climates resulting from physiological constraints, while species-energy theory suggests declines in the mean body size of species caused by increased extinction probabilities for large-bodied species in low-energy habitats. In chapter III we confronted this ambiguity with field data by studying community-wide body size variation of wild bees on Mt. Kilimanjaro. We found that along a 3680 m elevational gradient bee individuals became on average larger within species, while large species were increasingly absent from high-elevational communities. This demonstrates, on the one hand, how well-established, but apparently contrasting ecological theories can be merged through the parallel consideration of different levels of biological organization. On the other hand it signals that the extinction risk in the course of environmental change is not equally distributed among species within a community.
Land use intensification is known to threaten biodiversity, but the consequences for ecosystem services are still a matter of debate. In chapter IV, we experimentally tested the single and combined contributions of pest predators and pollinators to coffee production along a land use intensification gradient on Mount Kilimanjaro. We found that pest predation increased fruit set by on average 9%, while pollination increased fruit weight of coffee by on average 7.4%. Land use had no significant effect on both ecosystem services. However, we found that in coffee plantations with most intensified land use, pollination services were virtually exclusively provided by the honey bee (Apis mellifera). The reliance on a single pollinator species is risky, as possible declines of that species may directly lower pollination services, resulting in yield losses. In contrast, pollination services in structurally complex homegardens were found to be provided by a diverse pollinator community, increasing the stability of pollination services in a long term.
We showed that on Mount Kilimanjaro pollinator communities changed along elevational gradients in terms of species richness (chapter II) and trait composition (chapter III). Temperature and the temperature-mediated accessibility of resources were identified as important predictors of these patterns, which contributes to our fundamental understanding about the factors that shape ectothermic insect communities along climatic gradients. The strong temperature-dependence of pollinators suggests that temperature shifts in the course of global change are likely to affect pollinator communities. Pollinators might either profit from rising temperatures, or shift to higher elevations, which could result in related biotic attrition in the lowland with consequences for the provision of ecosystem services in cropping systems. Up to now, land use intensification had no significant impact on the diversity of pollinator communities and their ecosystem services. Pollinators might profit from the strong landscape heterogeneity in the region and from the amount of flower resources in the understory of cropping systems. However,progressing homogenization of the landscape and the pronounced application of pesticides could result in reduced diversity and dominance of single species, as we already found in sun coffee plantations. Such shifts in community compositions could threaten the stability of ecosystem services within cropping and natural systems in a long term.
Organisms have evolved endogenous clocks which allow them to organize their behavior, metabolism and physiology according to the periodically changing environmental conditions on earth. Biological rhythms that are synchronized to daily changes in environment are governed by the so-called circadian clock. Since decades, chronobiologists have been investigating circadian clocks in various model organisms including the fruitfly Drosophila melanogaster, which was used in the present thesis.
Anatomically, the circadian clock of the fruitfly consists of about 150 neurons in the lateral and dorsal protocerebrum, which are characterized by their position, morphology and neurochemistry. Some of these neurons had been previously shown to contain either one or several neuropeptides, which are thought to be the main signaling molecules used by the clock. The best investigated of these neuropeptides is the Pigment Dispersing Factor (PDF), which had been shown to constitute a synchronizing signal between clock neurons as well as an output factor of the clock.
In collaboration with various coworkers, I investigated the roles of three other clock expressed neuropeptides for the generation of behavioral rhythms and the partly published, partly unpublished data are presented in this thesis. Thereby, I focused on the Neuropeptide F (NPF), short Neuropeptide F (sNPF) and the Ion Transport Peptide (ITP). We show that part of the neuropeptide composition within the clock network seems to be conserved among different Drosophila species. However, the PDF expression pattern in certain neurons varied in species deriving from lower latitudes compared to higher latitudes. Together with findings on the behavioral level provided by other people, these data suggest that different species may have altered certain properties of their clocks - like the neuropeptide expression in certain neurons - in order to adapt their behavior to different habitats.
We then investigated locomotor rhythms in Drosophila melanogaster flies, in which neuropeptide circuits were genetically manipulated either by cell ablation or RNA interference (RNAi). We found that none of the investigated neuropeptides seems to be of equal importance for circadian locomotor rhythms as PDF. PDF had been previously shown to be necessary for rhythm maintenance in constant darkness (DD) as well as for the generation of morning (M) activity and for the right phasing of the evening (E) activity in entrained conditions. We now demonstrate that NPF and ITP seem to promote E activity in entrained conditions, but are clearly not the only factors doing so. In addition, ITP seems to reduce nighttime activity. Further, ITP and possibly also sNPF constitute weak period shortening components in DD, thereby opposing the effect of PDF. However, neither NPF or ITP, nor sNPF seem to be necessary in the clock neurons for maintaining rhythmicity in DD.
It had been previously suggested that PDF is released rhythmically from the dorsal projection terminals. Now we discovered a rhythm in ITP immunostaining in the dorsal projection terminals of the ITP+ clock neurons in LD, suggesting a rhythm in peptide release also in the case of ITP. Rhythmic release of both ITP and PDF seems to be important to maintain rhythmic behavior in DD, since constantly high levels of PDF and ITP in the dorsal protocerebrum lead to behavioral arrhythmicity.
Applying live-imaging techniques we further demonstrate that sNPF acts in an inhibitory way on few clock neurons, including some that are also activated by PDF, suggesting that it acts as signaling molecule within the clock network and has opposing effects to PDF. NPF did only evoke very little inhibitory responses in very few clock neurons, suggesting that it might rather be used as a clock output factor. We were not able to apply the same live-imaging approach for the investigation of the clock neuron responsiveness to ITP, but overexpression of ITP with various driver lines showed that the peptide most likely acts mainly in clock output pathways rather than inter-clock neuron communication.
Taking together, I conclude that all investigated peptides contribute to the control of locomotor rhythms in the fruitfly Drosophila melanogaster. However, this control is in most aspects dominated by the actions of PDF and rather only fine-tuned or complemented by the other peptides. I assume that there is a high complexity in spatial and temporal action of the different neuropeptides in order to ensure correct signal processing within the clock network as well as clock output.