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The expression of the MYC proto-oncogene is elevated in a large proportion of patients with pancreatic ductal adenocarcinoma (PDAC). Previous findings in PDAC have shown that this increased MYC expression mediates immune evasion and promotes S-phase progression. How these functions are mediated and whether a downstream factor of MYC mediates these functions has remained elusive. Recent studies identifying the MYC interactome revealed a complex network of interaction partners, highlighting the need to identify the oncogenic pathway of MYC in an unbiased manner.
In this work, we have shown that MYC ensures genomic stability during S-phase and prevents transcription-replication conflicts. Depletion of MYC and inhibition of ATR kinase showed a synergistic effect to induce DNA damage. A targeted siRNA screen targeting downstream factors of MYC revealed that PAF1c is required for DNA repair and S-phase progression. Recruitment of PAF1c to RNAPII was shown to be MYC dependent. PAF1c was shown to be largely dispensable for cell proliferation and regulation of MYC target genes.
Depletion of CTR9, a subunit of PAF1c, caused strong tumor regression in a pancreatic ductal adenocarcinoma model, with long-term survival in a subset of mice. This effect was not due to induction of DNA damage, but to restoration of tumor immune surveillance.
Depletion of PAF1c resulted in the release of RNAPII with transcription elongation factors, including SPT6, from the bodies of long genes, promoting full-length transcription of short genes. This resulted in the downregulation of long DNA repair genes and the concomitant upregulation of short genes, including MHC class I genes. These data demonstrate that a balance between long and short gene transcription is essential for tumor progression and that interference with PAF1c levels shifts this balance toward a tumor-suppressive transcriptional program. It also directly links MYC-mediated S-phase progression to immune evasion. Unlike MYC, PAF1c has a stable, known folded structure; therefore, the development of a small molecule targeting PAF1c may disrupt the immune evasive function of MYC while sparing its physiological functions in cellular growth.
Das Multiple Myelom (MM) ist eine durch monoklonale Vermehrung terminal differenzierter Antikörper-produzierender B-Lymphozyten (Plasmazellen) im Knochenmark charakterisierte maligne Krankheit, die sich v.a. in osteolytischen Knochendestruktionen, hämatopoetischer und Niereninsuffizienz äußert. Verbesserte Therapieansätze wie die Hochdosis-Chemotherapie mit Melphalan und anschließender autologer Stammzelltransplantation sowie die Einführung neuer pharmakologischer Substanzklassen (Proteasom-Inhibitoren, Cereblon-bindende Thalidomidderivate) führten zu einer Verlängerung der durchschnittlichen Überlebenszeit, für die meisten der Patienten ist die Erkrankung jedoch derzeit unheilbar. Die Erforschung neuer potenzieller therapeutischer Angriffspunkte auf Grund pathobiologischer Erkenntnisse bleibt daher unabdingbar. Ein Ansatz zur Verbesserung des Verständnisses der Pathogenese ist die funktionelle, molekulare und genetische Analyse des Signalnetzwerkes im MM. Im Zusammenhang mit diesem Konzept wurde entdeckt, dass wachstums-regulierende Signalwege in MM Zellen aktiviert oder dereguliert sind und zum Überleben und der Proliferation des Tumors beitragen. So konnte beispielsweise von unserer Arbeitsgruppe bereits gezeigt werden, dass onkogenes Ras essentiell zum Überleben der MM Zellen beiträgt. Da Ras derzeit mangels spezifischer Inhibitoren pharmakologisch nicht angreifbar ist, stellen weitere funktionelle Bestandteile des Signalweges eine potenzielle therapeutische Zielstruktur dar. Während die Blockade von MEK1/2 in MM Zellen keinen Einfluss auf das Überleben hatte, konnte durch die Blockade von Raf in ersten Tests unserer Arbeitsgruppe Apoptose hervorgerufen werden. Aus diesem Grund habe ich in der vorliegenden Arbeit zur Evaluation eines neuen Therapieansatzes die Rolle der Raf-abhängigen Signaltransduktion eingehend untersucht. Als Grundlage diente dabei die Hypothese, dass die Raf-Kinasen entscheidende Effektoren der durch onkogenes Ras vermittelten apoptotischen Effekte darstellen. In einem ersten Schritt konnte ich nachweisen, dass alle drei Raf-Isoformen (A-, B- und C-Raf) in humanen MM Zelllinien und in primären MM Zellen aktiviert sind. Mittels shRNA-vermittelter, Isoform-spezifischer Raf-Knockdown-Experimente konnte ich zeigen, dass nur ein simultaner Knockdown aller Isoformen, d.h. ein Pan-Raf-Knockdown, zu einer De-Phosphorylierung von MEK1/2 und ERK1/2 führte. Dieser Versuch ließ sich mittels pharmakologischer Raf-Inhibition, bei der ebenfalls nur eine Pan-Raf-Blockade zu einer Herunterregulation von MEK1/2 und ERK1/2 in MM Zellen führte, bestätigen. Das MEK/ERK-Modul stellte somit einen hervorragenden Surrogat- und Biomarker für die Pan-Raf-Aktivität dar. Im Gegensatz zur Blockade des MEK/ERK-Moduls führte eine Hemmung der Pan-Raf-Aktivität mittels shRNA oder pharmakologischer Inhibitoren in allen untersuchten Zelllinien und in der Mehrheit der primären MM Zellen zu einer starken Induktion von Apoptose. Da das Ansprechen auf eine Pan-Raf-Blockade nicht mit dem Ras-Mutationsstatus korrelierte, könnten die Raf-Kinasen eine von onkogenem Ras unabhängie Qualität als therapeutische Zielstruktur aufweisen. Zur Untersuchung möglicher MEK/ERK-unabhängiger Effektormechanismen der Pan-Raf-Inhibition habe ich die mRNA-basierten Genexpressionsprofile von INA-6 Zellen nach pharmakologischer Pan-Raf- oder MEK-Inhibition verglichen. Dabei führte die Pan-Raf-Inhibition zu einer Regulation von wesentlich mehr Genen, wobei sich auch die Art der regulierten Gene unterschied, darunter Gene mit tumorrelevanten Funktionen wie Regulation von Proliferation, Zellzyklus und Apoptose. Für eine dieser Gengruppen, die Gruppe der PI3K-abhängigen, mTOR-assoziierten Gene, konnte ich eine Regulation auch auf der Proteinebene nachweisen: die Phosphorylierungen von mTOR, p70S6K, Rb und AKT und die Expression von CyclinD1 und PDK1 waren nach Pan-Raf-Inhibition, nicht jedoch nach MEK-Blockade herunterreguliert. Dieses Ergebnis deutet auf eine Ko-Regulation der PI3K-abhängigen Signaltransduktion durch die Raf-kinasen hin. Mittels spezifischer PI3K-Inhibitoren ließ sich sowohl bei der Regulation der untersuchten Proteine als auch bei der Induktion von Apoptose eine deutliche Verstärkung der Pan-Raf-Inhibition in HMZL und in primären Zellen erzielen. Zusammengefasst zeigt diese Arbeit, dass die Pan-Raf-Blockade eine neue Therapiemöglichkeit darstellt, die durch Kombination mit einer PI3K/AKT-Inhibition noch verstärkt werden kann.
The biosphere harbors a large quantity and diversity of microbial organisms that can thrive in all environments. Estimates of the total number of microbial species reach up to 1012, of which less than 15,000 have been characterized to date. It has been challenging to delineate phenotypically, evolutionary and ecologically meaningful lineages such as for example, species, subspecies and strains. Even within recognized species, gene content can vary considerably between sublineages (for example strains), a problem that can be addressed by analyzing pangenomes, defined as the non-redundant set of genes within a phylogenetic clade, as evolutionary units.
Species considered to be ecologically and evolutionary coherent units, however to date it is still not fully understood what are primary habitats and ecological niches of many prokaryotic species and how environmental preferences drive their genomic diversity. Majority of comparative genomics studies focused on a single prokaryotic species in context of clinical relevance and ecology. With accumulation of sequencing data due to genomics and metagenomics, it is now possible to investigate trends across many species, which will facilitate understanding of pangenome evolution, species and subspecies delineation.
The major aims of this thesis were 1) to annotate habitat preferences of prokaryotic species and strains; 2) investigate to what extent these environmental preferences drive genomic diversity of prokaryotes and to what extent phylogenetic constraints limit this diversification; 3) explore natural nucleotide identity thresholds to delineate species in bacteria in metagenomics gene catalogs; 4) explore species delineation for applications in subspecies and strain delineation in metagenomics.
The first part of the thesis describes methods to infer environmental preferences of microbial species. This data is a prerequisite for the analyses performed in the second part of the thesis which explores how the structure of bacterial pangenomes is predetermined by past evolutionary history and how is it linked to environmental preferences of the species. The main finding in this subchapter that habitat preferences explained up to 49% of the variance for pangenome structure, compared to 18% by phylogenetic inertia. In general, this trend indicates that phylogenetic inertia does not limit evolution of pangenome size and diversity, but that convergent evolution may overcome phylogenetic constraints. In this project we show that core genome size is associated with higher environmental ubiquity of species. It is likely this is due to the fact that species need to have more versatile genomes and most necessary genes need to be present in majority of genomes of that species to be highly prevalent. Taken together these findings may be useful for future predictive analyses of ecological niches in newly discovered species.
The third part of the thesis explores data-driven, operational species boundaries. I show that homologous genes from the same species from different genomes tend to share at least 95% of nucleotide identity, while different species within the same genus have lower nucleotide identity. This is in line with other studies showing that genome-wide natural species boundary might be in range of 90-95% of nucleotide identity. Finally, the fourth part of the thesis discusses how challenges in species delineation are relevant for the identification of meaningful within-species groups, followed by a discussion on how advancements in species delineation can be applied for classification of within-species genomic diversity in the age of metagenomics.
The neuronal ceroid lipofuscinoses (NCLs) are fatal neurodegenerative disorders in which the visual system is affected in early stages of disease. A typical accompanying feature is neuroinflammation, the pathogenic impact of which is presently unknown. In this study, the role of inflammatory cells in the pathogenesis was investigated in Palmitoyl-protein thioesterase 1-deficient (Ppt1-/-) and Ceroidlipofuscinosis, neuronal 3-deficient (Cln3-/-) mice, models of the infantile and juvenile forms of NCL, respectively. Focusing predominantly on the visual system, an infiltration of CD8+ cytotoxic Tlymphocytes and an activation of microglia/macrophage-like cells was observed early in disease. To analyze the pathogenic impact of lymphocytes, Ppt1-/- mice were crossbred with mice lacking lymphocytes (Rag1-/-) and axonal transport, perturbation and neuronal survival were scored. Lack of lymphocytes led to a significant amelioration of neuronal disease and reconstitution experiments revealed a crucial role of CD8+ cytotoxic T-lymphocytes. Lack of lymphocytes also caused an improved clinical phenotype and extended longevity. To investigate the impact of microglia/macrophage-like cells, Ppt1-/- and Cln3-/- mice were crossbred with mice lacking sialoadhesin (Sn-/-), a monocyte lineage-restricted cell adhesion molecule important for interactions between macrophage-like cells and lymphocytes. Similar to the lack of lymphocytes, absence of sialoadhesin significantly ameliorated the disease in Ppt1-/- and Cln3-/- mice. Taken together, both T-lymphocytes and microglia/macrophage-like cells were identified as pathogenic mediators in two distinct forms of fatal inherited neurodegenerative storage disorders. These studies expand the concept of secondary inflammation as a common pathomechanistic feature in some neurological diseases and provide novel insights that may be crucial for developing treatment strategies for different forms of NCL.
This thesis elucidates patterns and drivers of invertebrate herbivory, herbivore diversity, and community-level biomass along elevational and land use gradients at Mt. Kilimanjaro, Tanzania.
Chapter I provides background information on the response and predictor variables, study system, and the study design. First, I give an overview of the elevational patterns of species diversity/richness and herbivory published in the literature. The overview illuminates existing debates on elevational patterns of species diversity/richness and herbivory. In connection to these patterns, I also introduce several hypotheses and mechanisms put forward to explain macroecological patterns of species richness. Furthermore, I explain the main variables used to test hypotheses. Finally, I describe the study system and the study design used.
Chapter II explores the patterns of invertebrate herbivory and their underlying drivers along extensive elevational and land use gradients on the southern slopes of Mt. Kilimanjaro. I recorded standing leaf herbivory from leaf chewers, leaf miners and gall-inducing insects on 55 study sites located in natural and anthropogenic habitats distributed from 866 to 3060 meters above sea level (m asl) on Mt. Kilimanjaro. Standing leaf herbivory was related to climatic variables [mean annual temperature - (MAT) and mean annual precipitation - (MAP)], net primary productivity (NPP) and plant functional traits (leaf traits) [specific leaf area (SLA), carbon to nitrogen ratio (CN), and nitrogen to phosphorous ratio (NP)]. Results revealed an unimodal pattern of total leaf herbivory along the elevation gradient in natural habitats. Findings also revealed differences in the levels and patterns of herbivory among feeding guilds and between anthropogenic and natural habitats. Changes in NP and CN ratios which were closely linked to NPP were the strongest predictors of leaf herbivory. Our study uncovers the role of leaf nutrient stoichiometry and its linkages to climate in explaining the variation in leaf herbivory along climatic gradients.
Chapter III presents patterns and unravels direct and indirect effects of resource (food) abundance (NPP), resource (food) diversity [Functional Dispersion (FDis)], resource quality (SLA, NP, and CN rations), and climate variables (MAT and MAP) on species diversity of phytophagous beetles. Data were collected from 65 study sites located in natural and anthropogenic habitats distributed from 866 to 4550 m asl on the southern slopes of Mt. Kilimanjaro. Sweep net and beating methods were used to collect a total of 3,186 phytophagous beetles representing 21 families and 304 morphospecies. Two groups, weevils (Curculionidae) and leaf beetles (Chrysomelidae) were the largest and most diverse families represented with 898 and 1566 individuals, respectively. Results revealed complex (bimodal) and dissimilar patterns of Chao1-estimated species richness (hereafter referred to as species diversity) along elevation and land use gradients. Results from path analysis showed that temperature and climate-mediated changes in NPP had a significant positive direct and indirect effect on species diversity of phytophagous beetles, respectively. The results also revealed that the effect of NPP (via beetles abundance and diversity of food resources) on species diversity is stronger than that of temperature. Since we found that factors affecting species diversity were intimately linked to climate, I concluded that predicted climatic changes over the coming decades will likely alter the species diversity patterns which we observe today.
Chapter IV presents patterns and unravels the direct and indirect effects of climate, NPP and anthropogenic disturbances on species richness and community-level biomass of wild large mammals which represent endothermic organisms and the most important group of vertebrate herbivores. Data were collected from 66 study sites located in natural and anthropogenic habitats distributed from 870 to 4550 m asl on the southern slopes of Mt. Kilimanjaro. Mammals were collected using camera traps and used path analysis to disentangle the direct and indirect effects of climatic variables, NPP, land use, land area, levels of habitat protection and occurrence of domesticated mammals on the patterns of richness and community-level biomass of wild mammals, respectively. Results showed unimodal patterns for species richness and community-level biomass of wild mammals along elevation gradients and that the patterns differed depending on the type of feeding guild. Findings from path analysis showed that net primary productivity and levels of habitat protection had a strong direct effect on species richness and community-level biomass of wild mammals whereas temperature had an insignificant direct effect. Findings show the importance of climate-mediated food resources in determining patterns of species richness of large mammals. While temperature is among key predictors of species richness in several ectotherms, its direct influence in determining species richness of wild mammals was insignificant. Findings show the sensitivity of wild mammals to anthropogenic influences and underscore the importance of protected areas in conserving biodiversity.
In conclusion, despite a multitude of data sets on species diversity and ecosystem functions along broad climatic gradients, there is little mechanistic understanding of the underlying causes. Findings obtained in the three studies illustrate their contribution to the scientific debates on the mechanisms underlying patterns of herbivory and diversity along elevation gradients. Results present strong evidence that plant functional traits play a key role in determining invertebrate herbivory and species diversity along elevation gradients and that, their strong interdependence with climate and anthropogenic activities will shape these patterns in future. Additionally, findings from path analysis demonstrated that herbivore diversity, community-level biomass, and herbivory are strongly influenced by climate (either directly or indirectly). Therefore, the predicted climatic changes are expected to dictate ecological patterns, biotic interactions, and energy and nutrient fluxes in terrestrial ecosystems in the coming decades with stronger impacts probably occurring in natural ecosystems. Furthermore, findings demonstrated the significance of land use effects in shaping ecological patterns. As anthropogenic pressure is advancing towards more pristine higher elevations, I advocate conservation measures which are responsive to and incorporate human dimensions to curb the situation. Although our findings emanate from observational studies which have to take several confounding factors into account, we have managed to demonstrate global change responses in real ecosystems and fully established organisms with a wide range of interactions which are unlikely to be captured in artificial experiments. Nonetheless, I recommend additional experimental studies addressing the effect of top-down control by natural enemies on herbivore diversity and invertebrate herbivory in order to deepen our understanding of the mechanisms driving macroecological patterns along elevation gradients.
This study investigated patterns of arthropod community organisation and the processes structuring these communities on a range of different tree species in a natural West African savannah (Comoé National Park, Côte d'Ivoire). It described and analysed patterns of arthropod distribution on the level of whole communities, on the level of multiple-species interactions, and on the level of individual insect species. Community samples were obtained by applying (i) canopy fogging for mature individuals of three tree species (Anogeissus leiocarpa, Burkea africana, Crossopteryx febrifuga) and (ii) a modified beating technique allowing to sample the complete arthropod communities of the respective study plants for medium-sized (up to 3 m) individuals of two other species (Combretum fragrans, Pseudocedrela kotschyi). General information on ant-plant interactions was retrieved from ant community comparisons of the mature savannah trees. In addition, ant-ant, ant-plant and ant-herbivore interactions were studied in more detail considering the ant assemblages on the myrmecophilic tree Pseudocedrela kotschyi. Herbivore-plant interactions were investigated on a multiple-species level (interrelationships between herbivores and Pseudocedrela trees) and on a species level (detailed studies of interrelationships between herbivorous beetles and caterpillars and the host tree Combretum fragrans). The studies on individual herbivore species were complemented by a study on an abundant ant species, clarifying not only the relationship between host plant and associated animal but allowing also to look at interactive (competitive) aspects of community organisation. The study demonstrated for the first time that (i) the structure of beetle communities on tropical trees can be strongly dependent on the host tree species, (ii) individual trees can host specific arthropod communities whose characteristic structure is stable over years and is strongly determined by the individual tree's attributes, (iii) ants can express a pronounced fidelity to single leaves as foraging area and can thereby determine distribution patterns of other ants, (iv) intraspecifically variable palatability of plants for insect herbivores can be stable over years and can influence the distribution of herbivores that can distinguish between individual hosts according to palatability and (v) intraspecific host plant change can positively affect fitness of herbivores if host plant quality is variable. In general, the present study contributes to our knowledge of anthropogenically unaltered processes affecting community assembly in a natural environment. The fundamental understanding of these processes is crucial for the identification of anthropogenic alterations and the establishment of sustainable management measures. The study points out the important role local factors can play for the distribution of organisms and thereby for community organisation. It emphasises the relevance of small scale heterogeneity of the abiotic and biotic environment to biodiversity and the need to consider these factors for development of effective conservation and restoration strategies.
The development of ethanol tolerance is due to changes in synaptic plasticity. Since the mechanisms mediating synaptic plasticity are probably defective in the mutant hangAE10, it was a goal of the present study to find out how HANG contributes to synaptic plasticity. In particular, it was important to clarify in which neuronal process HANG plays a role. Antibody stainings against HANG revealed that the protein is localized in all neuronal nuclei of larval and adult brains; the staining is absent in hangAE10, thus confirming that this P-element insertion stock is a protein null for HANG. Detailed analysis of the subnuclear distribution of HANG showed that HANG immunoreactivity is enriched at distinct spots in the nucleus in a speckled pattern; these speckles are found at the inside of the nuclear membrane and do not colocalize with chromatin nor with the nucleolus; thus, HANG is probably involved in the stabilization, processing or export of RNAs. As synaptic plasticity can be studied in single neurons at the larval neuromuscular junction, the morphology of the synaptic terminals of hangAE10 mutants was analyzed at muscle 6/7, segment A4. These studies revealed that hangAE10 mutants display a 40 % increase in bouton number and axonal branch length; in addition, some boutons have an abnormal hourglass-like shape, suggesting that they are arrested in a semi-separated state following the initiation of bouton division. The increase in bouton number of hang mutants is mainly due to an increase in numbers of type Ib boutons. The analysis of the distribution of several synaptic markers in hang mutants did not show abnormalities. The presynaptic expression of HANG in hang mutants rescues the increase in bouton number and axonal branch length, thus proving that the phenotypes seen in the P-element insertion hangAE10 are attributable to the lack of HANG rather than to effects of the P-element marker rosy or to a secondary hit on the same chromsome during mutagensis. This finding is further supported by the fact that postsynaptic expression of HANG does not rescue the abnormal NMJ morphology of hangAE10. Alterations in cAMP levels regulate the number of boutons; since hang mutants display an increase in bouton number, the questions was whether this morphological abnormality was due to defects in cAMP signalling. To test this hypothesis, hangAE10 NMJs were compared to those of the hypomorphic allele dnc1 that has a defective cAMP cascade. Some aspects of the NMJ phenotype (e.g. the increase in bouton number and the unaltered ratio of active zones per bouton area) are similar in hangAE10 and dnc1, other differ. Expression of a UAS-dnc transgene in hangAE10 mutants does not modify the phenotype. In summary, the results of this study indicate that nuclear protein HANG might be involved in isoform-specific splicing of genes required for synaptic plasticity at the NMJ.
The goal of the project VascuBone is to develop a tool box for bone regeneration, which on one hand fulfills basic requirements (e.g. biocompatibility, properties of the surface, strength of the biomaterials) and on the other hand is freely combinable with what is needed in the respective patient's situation. The tool box will include a variation of biocompatible biomaterials and cell types, FDA-approved growth factors, material modification technologies, simulation and analytical tools like molecular imaging-based in vivo diagnostics, which can be combined for the specific medical need. This tool box will be used to develop translational approaches for regenerative therapies of different types of bone defects. This project receives funding from the European Union's Seventh Framework Program (VascuBone 2010).
The present study is embedded into this EU project. The intention of this study is to assess the changes of the global gene expression patterns of endothelial progenitor cells (EPCs) and mesenchymal stem cells (MSCs) after direct cell-cell contact as well as the influence of conditioned medium gained from MSCs on EPCs and vice versa. EPCs play an important role in postnatal vasculogenesis. An intact blood vessel system is crucial for all tissues, including bone. Latest findings in the field of bone fracture healing and repair by the use of tissue engineering constructs seeded with MSCs raised the idea of combining MSCs and EPCs to enhance vascularization and therefore support survival of the newly built bone tissue. RNA samples from both experimental set ups were hybridized on Affymetrix GeneChips® HG-U133 Plus 2.0 and analyzed by microarray technology. Bioinformatic analysis was applied to the microarray data and verified by RT-PCR.
This study gives detailed information on how EPCs and MSCs communicate with each other and therefore gives insights into the signaling pathways of the musculoskeletal system. These insights will be the base for further functional studies on protein level for the purpose of tissue regeneration. A better understanding of the cell communication of MSCs and EPCs and subsequently the targeting of relevant factors opens a variety of new opportunities, especially in the field of tissue engineering.
The second part of the present work was to develop an ELISA (enzyme-linked immunosorbent assay) for a target protein from the lists of differentially expressed genes revealed by the microarray analysis. This project was in cooperation with Immundiagnostik AG, Bensheim, Germany. The development of the ELISA aimed to have an in vitro diagnostic tool to monitor e.g. the quality of cell seeded tissue engineering constructs. The target protein chosen from the lists was klotho. Klotho seemed to be a very promising candidate since it is described in the literature as anti-aging protein. Furthermore, studies with klotho knock-out mice showed that these animals suffered from several age-related diseases e.g. osteoporosis and atherosclerosis. As a co-receptor for FGF23, klotho plays an important role in bone metabolism. The present study will be the first one to show that klotho is up-regulated in EPCs after direct cell-cell contact with MSCs. The development of an assay with a high sensitivity on one hand and the capacity to differentiate between secreted and shedded klotho on the other hand will allow further functional studies of this protein and offers a new opportunity in medical diagnostics especially in the field of metabolic bone disease.
Chapter I – Introduction
Global trade of beans of the cacao tree (Theobroma cacao), of which chocolate is produced, contributes to the livelihoods of millions of smallholder farmers. The understorey tree is native to South America but is nowadays cultivated in many tropical regions. In Peru, a South American country with a particularly high cacao diversity, it is common to find the tree cultivated alongside non-crop trees that provide shade, in so-called agroforestry systems. Because of the small scale and low management intensity of such systems, agroforestry is one of the most wildlife-friendly land-use types, harbouring the potential for species conservation. Studying wildlife-friendly land-use is of special importance for species conservation in biodiversity-rich tropical regions such as Peru, where agricultural expansion and intensification are threatening biodiversity. Moreover, there is a growing body of evidence that shows co-occurrence of high biodiversity levels and high yield in wildlife-friendly cacao farming. Yet studies are restricted to non-native cacao countries, and since patterns might be different among continents, it is important to improve knowledge on wildlife-friendly agroforestry in native countries.
Because studies of wildlife-friendly cultivation processes are still largely lacking for South America, we set out to study multiple aspects of cacao productivity in agroforests in Peru, part of cacao´s region of origin. The natural pollination process of cacao, which is critically understudied, was investigated by trapping flower visitors and studying pollen deposition from macrophotographs (Chapter II). Next, we excluded birds, bats, ants and flying insects and squirrels from cacao trees in a full-factorial field experiment and quantified these animals´ contribution to cacao fruit set, fruit loss and yield (Chapter III). Lastly, we aimed to assess whether fruit quantity and quality of native cacao increases through manually supplementing pollen (Chapter II and IV), and whether microclimatic conditions and the genetic background of the studied varieties limit fruit set (Chapter IV).
Chapter II – Cacao flower visitation: Low pollen deposition, low fruit set and dominance of herbivores
Given the importance of cacao pollination for the global chocolate production, it is remarkable that fruit set limitations are still understudied. Knowledge on flower visitation and the effect of landscape context and local management are lacking, especially in the crop’s region of origin. Moreover, the role of pollen deposition in limiting fruit set as well as the benefits of hand pollination in native cacao are unknown. In this chapter, we aimed to close the current knowledge gaps on cacao pollination biology and sampled flower visitors in 20 Peruvian agroforests with native cacao, along gradients of shade cover and forest distance. We also assessed pollen quantities and compared fruit set between manually and naturally pollinated flowers. We found that herbivores were the most abundant flower visitors in both northern and southern Peru, but we could not conclude which insects are effective cacao pollinators. Fruit set was remarkably low (2%) but improved to 7% due to pollen supplementation. Other factors such as a lack of effective pollinators, genetic pollen incompatibility or resource unavailability could be causing fruit set limitations. We conclude that revealing those causes and the effective pollinators of cacao will be key to improve pollination services in cacao.
Chapter III – Quantifying services and disservices provided by insects and vertebrates in cacao agroforestry landscapes
Pollination and pest control, two ecosystem services that support cacao yield, are provided by insects and vertebrates. However, animals also generate disservices, and their combined contribution is still unclear. Therefore, we excluded flying insects, ants, birds and bats, and as a side effect also squirrels from cacao trees and we assessed fruit set, fruit loss and final yield. Local management and landscape context can influence animal occurrence in cacao agroforestry landscapes; therefore, shade cover and forest distance were included in the analyses. Flying insects benefitted cacao fruit set, with largest gains in agroforests with intermediate shade cover. Birds and bats were also associated with improved fruit set rates and with a 114% increase in yield, potentially due to pest control services provided by these animals. The role of ants was complicated: these insects had a positive effect on yield, but only close to forest. We also evidenced disservices generated by ants and squirrels, causing 7% and 10% of harvest loss, respectively. Even though the benefits provided by animals outweighed the disservices, trade-offs between services and disservices still should be integrated in cacao agroforestry management.
Chapter IV – Cross-pollination improves fruit set and yield quality of Peruvian native cacao
Because yields of the cacao tree are restricted by pollination, hand pollination has been proposed to improve yield quantity and potentially, also quality. However, low self- and cross-compatibility of native cacao, and abiotic conditions could cancel out hand pollination benefits. Yet, the impact of genetic constraints and abiotic conditions on fruit set have not been assessed in native cacao so far. To increase our understanding of the factors that limit fruit set in native cacao, we compared manual self- and cross-pollination with five native genotypes selected for their sensorial quality and simultaneously tested for effects of soil water content, temperature, and relative air humidity. We also compared quality traits between manually and naturally pollinated fruits. Success rates of self-pollination were low (0.5%), but increased three- to eightfold due to cross-pollination, depending on the genotype of the pollen donor. Fruit set was also affected by the interaction between relative air humidity and temperature, and we found heavier and more premium seeds in fruits resulting from manual than natural pollination. Together, these findings show that reproductive traits of native cacao are constrained by genetic compatibility and abiotic conditions. We argue that because of the high costs of hand pollination, natural cross-pollination with native pollen donors should be promoted so that quality improvements can result in optimal economic gains for smallholder farmers.
Chapter V – Discussion
In this thesis, we demonstrated that the presence of flying insects, ants and vertebrates, local and landscape management practices, and pollen supplementation interactively affected cacao yield, at different stages of the development from flower to fruit. First, we showed that fruit set improved by intermediate shade levels and flower visitation by flying insects. Because the effective cacao pollinators remain unknown, we recommend shade cover management to safeguard fruit set rates. The importance of integrating trade-offs in wildlife-friendly management was highlighted by lower harvest losses due to ants and squirrels than the yield benefits provided by birds and bats. The maintenance of forest in the landscape might further promote occurrence of beneficial animals, because in proximity to forest, ants were positively associated with cacao yields. Therefore, an integrated wildlife-friendly farming approach in which shade cover is managed and forest is maintained or restored to optimize ecosystem service provision, while minimizing fruit loss, might benefit yields of native cacao. Finally, manual cross-pollination with native genotypes could be recommended, due to improved yield quantity and quality. However, large costs associated with hand pollination might cancel out these benefits. Instead, we argue that in an integrated management, natural cross-pollination should be promoted by employing compatible genotypes in order to improve yield quantity and quality of native cacao.
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.
Avocado (Persea americana Mill.) is a major horticultural crop that relies on insect mediated pollination. In avocado production, a knowledge gap exists as to the importance of insect pollination, especially in East African smallholder farms. Although it is evident that pollination improves the yield of avocado fruits, it is still unclear if pollination has benefits on fruit quality and the nutritional profile, particularly oils. Prior studies have shown that honey bees increase avocado’s fruit set and yield. However, an avocado flower is being visited by various insect species. Therefore, determining pollination efficiency will allow a comparison of the relative importance of the different insect species to optimize crop pollination for increased fruit set and crop yield and pollinator conservation. This study was conducted in a leading smallholder avocado production region in Kenya, first I assessed the dependence of avocado fruit set on insect pollination and whether current smallholder production systems suffer from a deficit in pollination services. Furthermore, I assessed if supplementation with colonies of the Western honey bee (Apis mellifera L.) to farms mitigated potential pollination deficits. The results revealed a very high reliance of avocado on insect pollinators, with a significantly lower fruit set observed for self- and wind-pollinated (17.4%) or self-pollinated flowers (6.4%) in comparison with insect-pollinated flowers (89.5%). I found a significant pollination deficit across farms, with hand-pollinated flowers on average producing 20.7% more fruits than non-treated open flowers prior to fruit abortion. This pollination deficit could be compensated by the supplementation of farms with A. mellifera colonies. These findings suggest that pollination is limiting fruit set in avocado and that A. mellifera supplementation on farms is a potential option to increase fruit yield. Secondly, I investigated the contribution of insect pollination to fruit and seed weight, oil, protein, carbohydrate, and phytochemicals contents (flavonoids and phenolics), and whether supplementation with pollinators (honey bee) could improve these fruit parameters was assessed. This was through pollinator-manipulative pollination treatments: hand, open, pollinator exclusion experiments. The results showed that avocado fruit weight was significantly higher in open and hand-pollinated than pollinator exclusion treatments, indicating that flower visitors/pollinators contribute to avocado yields and enhance marketability. Furthermore, insect pollination resulted in heavier seeds and higher oil contents, indicating that insect pollination is beneficial for the fruit’s high seed yield and quantity of oil. Honey bee supplementation also enhanced the avocado fruit weight by 18% more than in control farms and slightly increased the avocado oil content (3.6%). Contrarily, insect pollination did not influence other assayed fruit quality parameters (protein, carbohydrates, and phytochemicals). These results indicate that insect pollinators are essential for optimizing avocado yields, nutritional quality (oils), and thus marketability, underscoring the value of beehive supplementation to achieve high-quality avocado fruits and improved food security. Thirdly, pollinator efficiency based on pollen deposition after single visits by different pollinator species in avocado flowers was tested, and their frequency was recorded. The estimated pollination efficiency was highest in honey bees (Apis mellifera), followed by the hoverfly species (Phytomia incisa). These two species had the highest pollen deposition and more pollen grains on their bodies. In addition, honey bees were the most frequent avocado flower visitors, followed by flies. The findings from this study highlight the higher pollination efficiency of honey bees and Phytomia incisa. Hence, management practices supporting these species will promote increased avocado fruit yield. Additionally, these results imply that managed honey bees can be maintained to improve avocado pollination, particularly in areas lacking sufficient wild pollinators.
Die Dissertation beschreibt die Positionsklonierung von VMD2, einem Krankheitsgen des Menschen, dass der dominant vererbten vitelliformen Makuladystrophie Typ 2 (VMD2) zugrundeliegt. Zu diesem Zweck wurde zunächst ein etwa 1.4 Mbp großer Klon-'Contig' aus artifiziellen Phagenchromosomen ('phage artificial chromosomes', PAC) erstellt, der die VMD2-Kandidatengenregion auf Chromosom 11q12-q13.1 physikalisch repräsentiert. Durch die Identifizierung polymorpher (CA)n-Dinukleotidmarker aus dem kritschen Intervall und anschließender Kopplungsanalyse gelang es, die Kandidatengenregion auf ca. 500 kbp zu reduzieren. In der öffentlichen Datenbank (GenBank) bereitgestellte Nukleinsäuresequenzen zweier genomischer Klone aus dem Kern des relevanten chromosomalen Bereichs von zusammen etwa 290 kbp wurden dazu genutzt, über eine Kombination aus computergestützter Vorhersagen kodierender Sequenzen, Kartierung von EST-Klonen ('expressed sequence tags'), RT-PCR-Analysen und, wenn erforderlich, 5'-RACE-Experimenten, acht neue Gene des Menschen zu isolieren. Von den charakterisierten Genen erwiesen sich mehrere als potentielle Kandidaten für VMD2. Ein Gen, provisorisch als Transkriptionseinheit TU15B bezeichnet, konnte durch eine Mutationsanalyse schließlich eindeutig mit der Erkrankung assoziiert werden und wurde 1998 als VMD2 publiziert. Drei Gene aus der untersuchten Region kodieren Mitglieder einer Familie von Fettsäuredesaturasen (FADS1, FADS2 und FADS3), während ein anderes Gen ('Rabin3 interacting protein-like 1'; RAB3IL1) signifikante Sequenzidentität zu einem Transkript der Ratte besitzt, welches das GTPase-interagierende Protein Rabin3 kodiert. Den putativen Translationsprodukten drei weiterer Gene (C11orf9, C11orf10 und C11orf11) konnte bislang keine präzise Funktion zugeschrieben werden. Mit FTH1 ('ferritin heavy chain 1') und FEN1 ('flap endonuclease 1') liegen zudem zwei bekannte Gene im analysierten Intervall, deren cDNA-Sequenzen bereits 1984 bzw. 1995 von anderen Forschungsgruppen isoliert und publiziert wurden. Zweifellos kann die Region als sehr genreicher Abschnitt des menschlichen Genoms bezeichnet werden. Neben der Erstellung des PAC-'Contigs', der Einengung der VMD2-Kandidatenregion und der Klonierung von VMD2 war die vollständige genetische Charakterisierung der genannten Fettsäuredesaturase-Gene ein weiterer Schwerpunkt der Arbeit. Unabhängig von der Klonierung und Charakterisierung des VMD2-Gens sowie der chromosomal eng benachbarten Gene, richtete sich mein Interesse schließlich noch auf drei Gene des Menschen, provisorisch als TU51, TU52 und TU53 bezeichnet, die gemeinsam mit VMD2 eine Genfamilie bilden und auf den Chromosomen 19p13.2-p13.12 (TU51), 12q14.2-q15 (TU52) und 1p32.3-p33 (TU53) lokalisiert werden konnten. Durch die Aufklärung der kodierenden Nukleinsäuresequenzen der Gene wurden konservierte Sequenzabschnitte innerhalb der Genfamilie erkennbar, die auf wichtige funktionelle Abschnitte der Translationsprodukte schließen lassen.
Die Lamine gehören zu einer Familie von Proteinen, die als strukturelle Hauptelemente die Kernlamina ausbilden, einen wesentlichen Bestandteil der Kernhülle eukaryontischer Zellen. In Säugern exprimieren differenzierte somatische Zellen die Lamine A, C, B1 und B2. Die Kernhülle in Keimzellen unterscheidet sich in Bezug auf Struktur und Proteinzusammensetzung deutlich von der einer somatischen Zelle. So exprimieren Keimzellen Lamin B1 als einziges der somatischen Lamine und zwei kurze keimbahnspezifische Spleißvarianten, die Lamine C2 und B3. Die vorliegende Arbeit enthält eine detaillierte Analyse des Expressionsmusters und der zellulären Verteilung von Lamin B3 im Verlauf der Spermatogenese der Maus. Die Daten aus RT-PCR, Western Blot und Immunfluoreszenz belegen eindeutig, dass Lamin B3 ausschließlich in postmeiotischen Stadien während der Spermiogenese exprimiert wird. In runden Spermatiden konnte das Protein an der Kernhülle und überraschenderweise auch im Nukleoplasma nachgewiesen werden. Im weiteren Verlauf der Spermiogenese kommt es zu einer Umverteilung des Proteins, es konzentriert sich zunehmend am posterioren Pol des Spermatidenkerns. Damit ist die Lamina während der Säuger-Spermiogenese nur aus B-Typ-Laminen aufgebaut und Lamin B3 ist in Säugern das erste Beispiel für ein Lamin, das selektiv nur in postmeiotischen Stadien der Spermatogenese exprimiert wird. Die ektopische Expression von Lamin B3 in Kulturzellen führt zu einer Deformation der Zellkerne, die eine hakenförmige Gestalt annehmen. Mit Hilfe von Transfektionsexperimenten in COS-7-Zellen konnte eindeutig gezeigt werden, dass die auftretenden morphologischen Veränderungen der Kerne transfizierter Zellen auf die trunkierte zentrale Stäbchendomäne in Lamin B3 zurückzuführen ist. Darüber hinaus zeigte das Protein eine stark erhöhte Löslichkeit im Vergleich zu Lamin B2 und die Analyse transfizierter Kulturzellen mit „fluorescence recovery after photobleaching“ (FRAP) und „fluorescence loss in photobleaching“ (FLIP) ergab, dass ein erheblicher Anteil der Lamin-B3-Moleküle eine hohe Mobilität aufweist, die ebenfalls ausschließlich durch die kurze Stäbchendomäne begründet ist. Die Ergebnisse führen zu dem Schluss, dass Lamin B3 die Kernhülle in Keimzellen flexibler macht, was eine Voraussetzung für einige Vorgänge in der Spermiogenese sein könnte. Mit einem Fusionsprotein aus GST und dem 84 Aminosäuren umfassenden N-Terminus von Lamin B3 wurde über einen „Pull-Down-Assay“ nach möglichen Interaktionspartnern in Keimzellen gesucht. Mit MSY2, MSY2a und MSY4 wurden drei hoch interessante Kandidaten identifiziert. Sie gehören zu den Y-Box-Proteinen, DNA- und RNA-bindende Proteine, die bei der Speicherung und späteren Translation von mRNAs beteiligt sind, u.a. die mRNA von Protamin 1 (diese Form der Regulation von Genexpression hat in der Spermatogenese große Bedeutung). Die Interaktion von Lamin B3 mit diesen Proteinen muss noch überprüft werden, würde aber einen weiteren Bezug zwischen Kernhülle und Chromatinreorganisation in der Spermiogenese herstellen, wie es für die Kernhüllenproteine GCL und LBR bereits gezeigt werden konnte. Außerdem wäre es ein erster Hinweis auf eine funktionelle Bedeutung der N-terminalen Domäne von Lamin B3.
Listeria monocytogenes ist ein weit verbreitetes, Gram-positives humanpatho-genes Bakterium, welches in immunsupprimierten Personen das Krankheitsbild der Listeriose auslösen kann. Der Infektionszyklus der Listerien im Wirt ist im Hinblick auf die Pathogenese dieses Erregers intensiv untersucht worden. Die Regulation der verschiedenen beteiligten Virulenzfaktoren unterliegt in L. monocytogenes einer starken Kontrolle, die einerseits durch regulatorische Proteine aber auch durch Umweltfaktoren beeinflusst wird. Die Mechanismen, die auf transkriptionaler wie auch auf translationaler Ebene die Expression verschiedener listerieller Virulenzgene regulieren, wurden kürzlich näher charakterisiert. Es wurden für verschiedene listerielle Virulenzgene Riboswitch-mechanismen zur Expressionskontrolle in Listerien neu beschrieben. Durch Vorarbeiten wurde auch für das inlAB-Operon ein posttranskriptionaler Regu-lationsmechanismus postuliert. Dabei wurde der anaerobe Stoffwechsel der Listerien als möglicher Auslöser für die beobachtete Translationssteigerung des inlA- und inlB-Gens diskutiert. Innerhalb der vorliegenden Arbeit sollte nun weitergehend untersucht werden, in welchem Bereich der Sequenz des inlAB-Operons sich regulatorische Strukturen zur posttranskriptionalen Regulation unter anaeroben Wachstumsbedingungen befinden. Dazu wurden verschiedene Mutanten mit unterschiedlichen Deletionen im inlAB-Operon konstruiert und die Transkription und Translation sowohl des inlA-, als auch des inlB-Gens betrachtet. Eine Deletion im aroA-Gen bewirkt das Wachstum der Bakterien bei anaerobem Stoffwechsel. Diese Deletion wurde in die konstruierten Stämme eingefügt, um die Expression der Gene unter den verschiedenen Wachstumsbedingungen vergleichen zu können. Außerdem wurden verschiedene gus-Reportergen-Fusionsmutanten und Promotor-austauschmutanten konstruiert, um quantitativ aussagekräftigere Daten zu erheben. Die Charakterisierung der Mutanten ließ erkennen, dass keiner der deletierten Bereiche des inlAB-Operons von L. monocytogenes für die beobachtete Translationssteigerung im inlA-Gen bei anaerobem Stoffwechsel verantwortlich zu sein scheint. Das inlB-Gen war innerhalb der hier gezeigten Experimente nicht posttranskriptional reguliert, wie im Vorfeld postuliert. Nach plasmidkodierter Expression verschiedener Bereiche des inlAB-Operons konnte, verglichen mit genomischer Expression, keine Veränderung in der inlA-Expression beobachtet werden. Die mögliche Beteiligung eines potentiellen Regulatorproteins konnte innerhalb dieser Arbeit daher nicht näher eingegrenzt werden. Auch ein Einfluss der regulatorischen Faktoren Hfq und CcpA auf die Expression des InlA Proteins in der L. monocytogenes ΔaroA-Mutante konnte nicht gefunden werden. Es zeigte sich interessanterweise außerdem, dass weitere Virulenzgene wie actA und hly unter den anaeroben Bedingungen ebenfalls eine Translations-steigerung zeigten. Somit stellt sich abschließend die Frage, ob es sich bei der beobachteten Translationssteigerung des inlA-Gens wirklich um einen durch bestimmte Strukturen in der inlAB-mRNA ausgelösten Mechanismus handelt. L. monocytogenes ist als intrazellulär replizierendes, Gram-positives Bakterium interessant für den Einsatz in immun- und tumortherapeutischen Anwendungen. Attenuierte L. monocytogenes-Stämme wurden dazu bereits erfolgreich im Mausmodell als Trägerbakterien für Impfstoffstrategien eingesetzt. Die gezielte Infektion von Geweben ist jedoch aufgrund des wenig ausgeprägten Zelltropismus der Listerien im Wirt bisher ein Problem für einen Einsatz in bakterienbasierten Anwendungen, wie z.B. der Tumor- oder Gentherapie. Innerhalb dieser Arbeit wurden L. monocytogenes-Stämme konstruiert, bei denen chromosomal das für die Integrase codierende Gen gegen das Gen für das Staphylokokken Protein A (SPA) unter der Kontrolle listerieller Promotoren ausgetauscht wurde. Die erfolgreiche Oberflächenlokalisation von Protein A in der Zellwand von Listerien konnte im Western Blot oder in funktionellen Immunfluoreszenzfärbungen in Mikroskop- und FACS-Analysen nachgewiesen werden. Diese Stämme sollen im Cell Targeting zur gezielten Infektion von Geweben eingesetzt werden. Dazu konnten die Bakterien über Herceptin®-HER2/neu-vermittelte Adhäsion an SK-BR-3-Zellen erfolgreich in diese aufgenommen werden und innerhalb dieser replizieren. Die neu konstruierten Listeria-Stämme zeigten im Mausmodell keine Veränderung in ihrer Virulenz verglichen mit nicht-SPA-exprimierenden Stämmen. Die in dieser Arbeit vorgestellte Antikörper-Rezeptor-vermittlelte Aufnahme der Listerien in Zellen stellt einen neuen, bisher nicht beschriebenen Mechanismus dar, der in vielen therapeutischen Anwendungen zur Infektion spezifischer Gewebe durch Listerien genutzt werden kann.
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.
Chronic Obstructive Pulmonary Disease (COPD) exacerbations are a considerable reason for increased morbidity and mortality in patients. Infections with influenza virus (H1N1), respiratory syncytial virus (RSV) or nontypeable Haemophilus influenzae (NTHi) are important triggers of exacerbations. To date, no treatments are available which can stop the progression of COPD. Novel approaches are urgently needed. Pre-clinical models of the disease are crucial for the development of novel therapeutic options.
In order to establish pre-clinical models which mimic aspects of human COPD exacerbations, mice were exposed to cigarette smoke (CS) and additionally infected with H1N1, RSV and/or NTHi. Clinically relevant treatments such as the corticosteroids Fluticasone propionate and Dexamethasone, the phosphodiesterase-4 (PDE-4) inhibitor Roflumilast and the long-acting muscarinic receptor antagonist Tiotropium were tested in the established models. Furthermore, a novel treatment approach using antibodies (Abs) directed against IL-1α, IL-1β or IL-1R1 was examined in the established CS/H1N1 model. Levels of IFN-γ, IL-1β, IL-2, IL-6, KC, TNF-α, RANTES, IL-17, MCP-1, MIP 1α and MIP-1β were measured in lung homogenate. Numbers of total cells, neutrophils and macrophages were assessed in bronchoalveolar lavage (BAL) fluid. Hematoxylin- and eosin- (H&E-) stained lung slices were analyzed to detect pathological changes. Quantitative polymerase-chain-reaction (qPCR) was used to investigate gene expression of ICAM-1 and MUC5 A/C. The viral/bacterial load was investigated in lung homogenate or BAL fluid. In addition to the in vivo studies, the effects of the above mentioned treatments were investigated in vitro in H1N1, RSV or NTHi-infected (primary) human bronchial epithelial cells using submerged or air-liquid-interface (ALI) cell culture systems.
Four pre-clinical models (CS/H1N1, CS/RSV, CS/NTHi, CS/H1N1/NTHi) were established depicting clinically relevant aspects of COPD exacerbations such as increased inflammatory cells and cytokines in the airways and impaired lung function.
In the CS/H1N1 model, Tiotropium improved lung function and was superior in reducing inflammation in comparison to Fluticasone or Roflumilast. Moreover, Fluticasone increased the loss of body-weight, levels of IL-6, KC and TNF-α and worsened lung function. In CS/RSV-exposed mice Tiotropium but not Fluticasone or Roflumilast treatment reduced neutrophil numbers and IL-6 and TNF α levels in the lung. The viral load of H1N1 and RSV was significantly elevated in CS/virus-exposed mice and NCI-H292 cells after Fluticasone and Dexamethasone treatment. The results from these studies demonstrate that Tiotropium has anti-inflammatory effects on CS/virus-induced inflammation and might help to explain the observed reduction of exacerbation rates in Tiotropium-treated COPD patients. Furthermore, the findings from this work indicate that treatment with Fluticasone or Dexamethasone might not be beneficial to reduce inflammation in the airways of COPD patients and supports clinical studies that link treatment with corticosteroids to an increased risk for pneumonia.
Testing of anti-IL-1α, anti-IL-1β or anti-IL-1R1 Abs in the CS/H1N1 model suggests that, in line with clinical data, antagonization of IL-1β is not sufficient to reduce pulmonary inflammation and indicates a predominant role of IL-1α in CS/virus-induced airway inflammation. In line with the in vivo findings, anti-IL-1α but not anti-IL-1β Abs reduced levels of TNF-α and IL-6 in H1N1-infected primary human bronchial epithelial ALI cell culture. Blocking the IL-1R1 provided significant inhibitory effects on inflammatory cells in vivo but was inferior compared to inhibiting both its soluble ligands IL-1α and IL-1β. Concomitant usage of Abs against IL-1α/IL-1β revealed strong effects and reduced total cells, neutrophils and macrophages. Additionally, levels of KC, IL-6, TNF-α, MCP-1, MIP-1α and MIP-1β were significantly reduced and ICAM-1 mRNA expression was attenuated. These results suggest that combined inhibition of IL-1α/IL-1β might be beneficial to reduce inflammation and exacerbations in COPD patients. Moreover, combined targeting of both IL-1α/IL-1β might be more efficient compared to inhibition of the IL-1R1.
As in the CS/virus models, corticosteroid treatment failed to reduce inflammatory cells in the CS/NTHi and CS/H1N1/NTHi models, increased the loss of body-weight and the bacterial load. Furthermore, Roflumilast administration had no significant effects on cell counts or cytokines. However, it improved compliance in the CS/NTHi model. Treatment with Azithromycin reduced the bacterial load in the CS/NTHi model and reduced numbers of total cells, neutrophils, macrophages and levels of KC and TNF-α in the CS/H1N1/NTHi model.
In conclusion, the established CS/H1N1, CS/RSV, CS/NTHi, CS/H1N1/NTHi models depict clinically relevant aspects of human COPD exacerbations in mice and provide the opportunity to investigate underlying disease mechanisms and to test novel therapies.
African trypanosomes are the causative agents of fatal diseases in humans and livestock. Trypanosomes show a complex lifecycle and shuttle between the transmitting vector, the tsetse (Glossina spec.), and the mammalian host. As a result of this the parasite undergoes tremendous changes in morphology and metabolism to adapt to the different living environments.
The two best-studied lifecycle stages are the procyclic forms (PCF) that live in the tsetse fly and the proliferative bloodstream form (BSF) that resides in the mammalian blood. The most conspicuous weapon that trypanosomes use to evade the host immune attack is a dense layer of a single protein type, the variant surface glycoprotein (VSG), which shields the entire cell surface. Immune evasion required high rates of surface membrane turnover and surface coat recycling.
Trypanosomes show highly polarised cell architecture with all major eukaryotic organelles (endoplasmic reticulum, Golgi apparatus, endosomal apparatus, lysosome, mitochondrion and peroxisome-like glycosomes) generally present in single copy. Furthermore, trypanosomes possess a single flagellum, which is important not only for cellular motility but also for cell division.
How the duplication of all these cellular components is coordinated in order to progresss through the cell division cycle is poorly understood.
We used trypanosomes as a model organism due to the relative simplicity and the polarised nature of their cell architecture and determined the duplication of all their compartments. This was only possible due to a new synchronisation approach developed during this project.
In the first part of the thesis a precise temporal map of the cell division cycle of the BSF T. brucei cell division cycle was generated. By the use of well-described morphological markers (K/N status, new flagellum outgrowth and DNA synthesis) the position of individual cells was determined with high temporal resolution; this allowed us for the first time to synchronise a cell population in silico without affecting the naturally asynchronous growth.
In the second part of the thesis we used this tool to follow duplication events of the Major organelles during progression through the cell division cycle. We precisely determined the time points of organelle duplication and found that it is ordered in trypanosomes. Furthermore we found that BSF T. brucei cells do not grow continuously, cell size start to increase rapidly, during a short period of time, late in the cell division cycle. We speculate that the initiation of cell volume increase is temporally separated from the formation of all secretory organelles in order to ensure maintenance of the protective coat, which must remain intact at all times in order for BSF trypanosomes to be able to evade the host immune response.
The honeybee is a well studied and important organism in neuroethology. The possibility to train them with a classical conditioning paradigm and their miniature brain provide a perfect requisite to investigate the neuronal principles of learning and memory. Honeybees use visual and olfactory cues to detect flowers during their foraging trips. Hence, the reward association of a nectar source is a multi-modal construct, which has at least two major components - olfactory and visual cues. It is still an open question, how both sensory components are converged in the mushroom body, which represent the multi-modal integration centre of the honeybee brain. The main goal of this study, is to investigate the processing of multiple modalities and how a reward association is formed. This includes, how and wether both sensory modalities interfere during learning. Thus, in this study stimulation with UV, blue and green light was used to evoke distinct photoreceptor activities in the compound eye. Furthermore, three different odours (Geraniol, Citronellol and Farnesol) were used. These stimuli were tested in three different experimental series. The first experiment involved classical differential conditioning of the single modalities - odour and colour. Honeybees showed high learning performances in differentiating olfactory stimuli and also reliable responses for visual conditioning. Furthermore, a temporal discrepancy in the stimulus length for best learning in the olfatcoty and visual cues was found. In the second series, it was tested how multi-modal compounds are perceived. This includes, unique cues (configural processing) or the sum of the single components of a compound (elemen- tal processing). This was tested by combining single odour components with monochromatic light in a positive (PP) and negative patterning (NP) experiment. During PP, the olfactory- visual compound was rewarded, whereas the single components were unrewarded. In contrast, during NP the single components were reinforced, but the compound was not. In addition, the ability to distinguish between two different light stimuli presented as a part of an olfactory-visual compound with the same odour component during acquisition was tested. In a memory test, the light stimuli were presented again as a compound and in addition as the single components. The results revealed that bees used elemental processing with compounds containing green and blue light. In contrast, when UV light was presented the bees used configural processing. Finally, a third experiment was conducted at the neuronal level. Multi-unit recordings were established to provide a suitable method to analyse extrinsic neurons at the mushroom body output region, the so called ventral lobe of the pedunculus. Here, three different odours (Geran- iol, Farnesol and Citronellol), two colours (green and blue) and two combined stimuli (colour + odour) were chosen as stimuli, to search for possible variations in processing stimuli with different modalities. Two units could be detected that responded mainly to visual stimuli.
The behavior of honeybees and bumblebees relies on a constant sensory integration of abiotic or biotic stimuli. As eusocial insects, a sophisticated intraspecific communication as well as the processing of multisensory cues during foraging is of utter importance. To tackle the arising challenges, both honeybees and bumblebees have evolved a sophisticated olfactory and visual processing system.
In both organisms, olfactory reception starts at the antennae, where olfactory sensilla cover the antennal surface in a sex-specific manner. These sensilla house olfactory receptor neurons (ORN) that express olfactory receptors. ORNs send their axons via four tracts to the antennal lobe (AL), the prime olfactory processing center in the bee brain. Here, ORNs specifically innervate spheroidal structures, so-called glomeruli, in which they form synapses with local interneurons and projection neurons (PN). PNs subsequently project the olfactory information via two distinct tracts, the medial and the lateral antennal-lobe tract, to the mushroom body (MB), the main center of sensory integration and memory formation. In the honeybee calyx, the sensory input region of the MB, PNs synapse on Kenyon cells (KC), the principal neuron type of the MB. Olfactory PNs mainly innervate the lip and basal ring layer of the calyx. In addition, the basal ring receives input from visual PNs, making it the first site of integration of visual and olfactory information. Visual PNs, carrying sensory information from the optic lobes, send their terminals not only to the to the basal ring compartment but also to the collar of the calyx. Receiving olfactory or visual input, KCs send their axons along the MB peduncle and terminate in the main output regions of the MB, the medial and the vertical lobe (VL) in a layer-specific manner. In the MB lobes, KCs synapse onto mushroom body output neurons (MBON). In so far barely understood processes, multimodal information is integrated by the MBONs and then relayed further into the protocerebral lobes, the contralateral brain hemisphere, or the central brain among others.
This dissertation comprises a dichotomous structure that (i) aims to gain more insight into the olfactory processing in bumblebees and (ii) sets out to broaden our understanding of visual processing in honeybee MBONs.
The first manuscript examines the olfactory processing of Bombus terrestris and specifically investigates sex-specific differences. We used behavioral (absolute conditioning) and electrophysiological approaches to elaborate the processing of ecologically relevant odors (components of plant odors and pheromones) at three distinct levels, in the periphery, in the AL and during olfactory conditioning. We found both sexes to form robust memories after absolute conditioning and to generalize towards the carbon chain length of the presented odors. On the contrary, electroantennographic (EAG) activity showed distinct stimulus and sex-specific activity, e.g. reduced activity towards citronellol in drones. Interestingly, extracellular multi-unit recordings in the AL confirmed stimulus and sex-specific differences in olfactory processing, but did not reflect the differences previously found in the EAG. Here, farnesol and 2,3-dihydrofarnesol, components of sex-specific pheromones, show a distinct representation, especially in workers, corroborating the results of a previous study. This explicitly different representation suggests that the peripheral stimulus representation is an imperfect indication for neuronal representation in high-order neuropils and ecological importance of a specific odor.
The second manuscript investigates MBONs in honeybees to gain more insights into visual processing in the VL. Honeybee MBONs can be categorized into visually responsive, olfactory responsive and multimodal. To clarify which visual features are represented at this high-order integration center, we used extracellular multi-unit recordings in combination with visual and olfactory stimulation. We show for the first time that information about brightness and wavelength is preserved in the VL. Furthermore, we defined three specific classes of visual MBONs that distinctly encode the intensity, identity or simply the onset of a stimulus. The identity-subgroup exhibits a specific tuning towards UV light. These results support the view of the MB as the center of multimodal integration that categorizes sensory input and subsequently channels this information into specific MBON populations.
Finally, I discuss differences between the peripheral representations of stimuli and their distinct processing in high-order neuropils. The unique activity of farnesol in manuscript 1 or the representation of UV light in manuscript 2 suggest that the peripheral representation of a stimulus is insufficient as a sole indicator for its neural activity in subsequent neuropils or its putative behavioral importance. In addition, I discuss the influence of hard-wired concepts or plasticity induced changes in the sensory pathways on the processing of such key stimuli in the peripheral reception as well as in high-order centers like the AL or the MB. The MB as the center of multisensory integration has been broadly examined for its olfactory processing capabilities and receives increasing interest about its visual coding properties. To further unravel its role of sensory integration and to include neglected modalities, future studies need to combine additional approaches and gain more insights on the multimodal aspects in both the input and output region.
In the course of this study, several endogenous compounds and model substances were used to mimic the conditions in patients suffering from hypertension. As endogenous compounds, angiotensin II and aldosterone were chosen. As model substances, 4-nitroquinoline-1-oxide (NQO), hydrogen peroxide and phorbol 12-myristate 13-acetate (PMA) were selected. Benfotiamine as well as α-tocopherol proved in the course of the experiments to be able to prevent angiotensin II-induced formation of oxidative DNA strand breaks and micronuclei. This could be due to a prior inhibition of the release of reactive oxygen species and is in contrast to results which were achieved using thiamine. Furthermore, experiments in which cells were pre-incubated with benfotiamine followed by incubation with NQO showed that benfotiamine was not able to prevent the induction of oxidative stress. The hypothesis that benfotiamine has, like α-tocopherol, direct antioxidative capacity was fortified by measurements in cell free systems. In brief, a new working mechanism for benfotiamine in addition to the ones already known could be provided. In the second part of the study, angiotensin II was shown to be dose-dependently genotoxic. This effect is mediated via the angiotensin II type 1 receptor (AT1R) which. Further experiments were extended from in vitro settings to the isolated perfused kidney. Here it could be shown that angiotensin II caused vasoconstriction and DNA strand breaks. Co-perfusion of kidneys with angiotensin II and candesartan prevented vasoconstriction and formation of strand breaks. DNA strand break formation due to mechanical stress or hypoxia could be ruled out after additional experiments with the thromboxane mimetic U 46619. Detailed investigation of the DNA damage in vitro revealed that angiotensin II induces single strand breaks, double strand breaks and 8-hydroxydeoxyguanosine (8-oxodG)-adducts as well as abasic sites. Investigations of the effects of aldosterone-treatment in kidney cells showed an increase of oxidative stress, DNA strand breaks and micronuclei which could be prevented by the steroidal mineralocorticoid receptor antagonist eplerenone. Additional experiments with the non-steroidal mineralocorticoid receptor antagonist (S)-BR-4628 revealed that this substance was also able to prevent oxidative stress and genomic damage and proved to be more potent than eplerenone. In vivo, hyperaldosteronism was imitated in rats by aid of the deoxycorticosteroneacetate (DOCA) salt model. After this treatment, levels of DNA strand breaks and chromosomal aberrations in the kidney could be observed. Furthermore, an increase in the release of ROS could be measured. Treatment of these animals with spironolactone , BR-4628 and enalaprile revealed that all antagonists were effective BR-4628 was the most potent drug. Finally, rosuvastatin was investigated. In HL-60 cells phorbol 12-myristate 13-acetate caused oxidative stress. Rosuvastatin was able to prevent the release of ROS and subsequent oxidative DNA damage when co-incubated with PMA. Furthermore, not only an inhibition of PMA-induced oxidative stress but also inhibition of the unspecific release of ROS induced by hydrogen peroxide was observable. Addition of farnesyl pyrophosphate (FPP), geranylgeranyl pyrophosphate (GGPP), and mevalonate, intermediates of the cholesterol pathway, caused only a marginal increase of oxidative stress in cells treated simultaneously with PMA and rosuvastatin, thus indicating the effect of rosuvastatin to be HMG-CoA-reductase-independent. Investigation of the gene expression of subunits of NAD(P)H oxidase revealed a down-regulation of p67phox following rosuvastatin-treatment. Furthermore, it could be shown that rosuvastatin treatment alone or in combination with PMA increased total glutathione levels probably due to an induction of the gene expression and enzyme activity of γ-glutamylcysteine synthetase (γ-GCS).
Protection of healthy tissues from infection with systemically administered vaccinia virus strains
(2012)
Oncolytic virotherapy using recombinant vaccinia virus strains is a promising approach for the treatment of cancer. To further improve the safety of oncolytic vaccinia viruses, the cellular microRNA machinery can be applied as the host’s own security mechanism to avoid unwanted viral replication in healthy tissues. MicroRNAs are a class of small single-stranded RNAs which due to their ability to mediate post-transcriptional gene-silencing, play a crucial role in almost every regulatory process in cellular metabolism. Different cancers display unique microRNA expression patterns, showing significant up- or downregulation of endogenously expressed microRNAs. Furthermore, the behavior of cancer cells can be altered by either adding microRNAs known to inhibit cancer cell spread and proliferation or suppressing cancer promoting microRNAs (oncomirs) making microRNAs promising targets for cancer gene therapy. The cell’s own RNAi machinery can also be utilized to control viral replication due to the virus dependence on the host cell replication machinery, a process controlled by microRNAs. GLV-1h68 is a replication-competent recombinant oncolytic vaccinia virus constructed and generated by Genelux Corp., San Diego, CA, USA which carries insertions of three reporter gene cassettes for detection and attenuation purposes and is currently being evaluated for cancer treatment in clinical trials. Though there are hardly any side effects found in GLV-1h68 mediated oncolytic therapy an increased tropism for replication exclusively in cancer cells is desirable. Therefore it was investigated whether or not further cancer cell specificity of a recombinant vaccinia virus strain could be obtained without compromising its oncolytic activity using microRNA interference. Let-7a is a well characterized microRNA known to be expressed in high levels in healthy tissues and strongly downregulated in most cancers. To control vaccinia virus replication rates, four copies of the mature human microRNA let-7a target sequence were cloned behind the stop codon in the 3’end of the vaccinia virus D4R gene, using a GLV-1h68 derivative, GLV-1h190, as parental strain yielding the new recombinant virus strain GLV-1h250. The D4R gene belongs to the group of early transcribed vaccinia genes and encodes an essential enzyme, uracil DNA glycosylase, which catalyzes the removal of uracil residues from double-stranded DNA. A defect in D4R prevents vaccinia virus from entering into the intermediate and late phase of replication, leading to an aborted virus replication. After expression of the microRNA target sequence from the vaccinia virus genome, the endogenously expressed microRNA-let-7a should recognize its target structure within the viral mRNA transcript, thereby binding and degrading the viral mRNA which should lead to a strong inhibition of the virus replication in healthy cells. GLV-1h250 replication rates in cancerous A549 lung adenocarcinoma cells, which show a strong down-regulation of microRNA let-7a, was comparable to the replication rates of its parental strain GLV-1h190 and the control strain GLV-1h68. In contrast, GLV-1h250 displayed a 10-fold decrease in viral replication in non-cancerous ERC cells when compared to GLV-1h190 and GLV-1h68. In A549 tumor bearing nude mice GLV-1h250 replicated exclusively in the tumorous tissue and resulted in efficient tumor regression without adverse effects leading to the conclusion that GLV-1h250 replicates preferentially in cancerous cells and tissues, which display low endogenous let-7a expression levels.
BAKTERIELLE ENDOSYMBIONTEN DER BIENENWÖLFE Symbiontische Interaktionen zwischen verschiedenen Arten stellen allgegenwärtige und essentielle Bestandteile natürlicher Systeme dar und haben wahrscheinlich die Evolution jedes rezenten Lebewesens beeinflusst. Insekten als die diverseste Metazoen-Klasse der Erde profitieren von dem außerordentlichen metabolischen Potenzial vieler Mikroorganismen in einer großen Anzahl mutualistischer Assoziationen. Die große Mehrheit der bisher untersuchten Symbiosen zwischen Insekten und Mikroorganismen stellen Interaktionen dar, in denen die Wirte durch die Symbionten mit essentiellen Nährstoffen versorgt werden. Es sind jedoch auch einige Fälle bekannt, in denen symbiontische Bakterien eine wichtige Rolle für die intraspezifische olfaktorische Kommunikation spielen oder zur Verteidigung gegen Pathogene oder Parasitoide dienen. Die vorliegende Arbeit untersucht eine hoch spezialisierte Assoziation zwischen einer Grabwespen-Art, dem Europäischen Bienenwolf (Philanthus triangulum, Hymenoptera, Crabronidae), und Bakterien aus der Familie der Actinomyceten. Die bakteriellen Symbionten sind an einem einzigartigen Ort zu finden: Sie werden in den Reservoiren spezialisierter Antennendrüsen weiblicher Bienenwölfe kultiviert. Das Weibchen sezerniert vor der Eiablage große Mengen dieser Bakterien in die unterirdischen Brutkammern. Wenn die Bienewolf-Larve einige Tage später ihre Nahrungsaufnahme an den von der Mutter als Nahrungsvorrat bereitgestellten Honigbienen beendet hat, nimmt sie die Bakterien auf und spinnt sie in ihren Kokon mit ein. Dort erfüllen die Symbionten eine wichtige Funktion, indem sie den Schimmelbefall herabsetzen und dadurch die Überlebenschancen der Larve im Kokon während der langen und gefährlichen Winterruhe signifikant erhöhen. Experimente, in denen Bienenwolf-Weibchen ohne die Bakterien aufgezogen wurden, und Beobachtungen an Bienenwolf-Larven deuten darauf hin, dass die Symbionten vertikal von der Mutter an die Töchter weitergegeben werden. Vermutlich werden die Bakterien während des Schlupfes oder kurz davor vom Kokon in die Antennendrüsen-Reservoire aufgenommen. Phylogenetische Untersuchungen von Wirten und Symbionten sowie Transfer-Experimente mit den Bakterien wären notwendig, um herauszufinden, ob ein horizontaler Austausch der Symbionten zwischen verschiedenen Bienenwolf-Arten möglich ist. Genetische Analysen zeigen, dass die Symbionten einer unbeschriebenen Art der Gattung Streptomyces innerhalb der Actinomyceten angehören. 16s rDNA Primer und eine fluoreszenzmarkierte Oligonukleotid-Sonde wurden entwickelt, um die Bienenwolf-Symbionten mittels PCR und Fluoreszenz-in-situ-Hybridisierung (FISH) spezifisch nachweisen zu können. Mit Hilfe von PCR und Sequenzierungen der 16s rDNA konnten nah verwandte Endosymbionten in den Antennen von 28 Arten und Unterarten der Gattung Philanthus festgestellt werden, nicht aber in anderen Gattungen der Unterfamilie Philanthinae (Aphilanthops, Clypeadon, Cerceris), so dass die Symbiose auf die Gattung Philanthus beschränkt zu sein scheint. Phylogenetische Untersuchungen auf der Grundlage nahezu kompletter 16s rDNA-Sequenzen belegen, dass die Symbionten aller analysierten Bienenwolf- Arten eine monophyletische Gruppe innerhalb der Gattung Streptomyces bilden, was darauf hindeutet, dass die Symbiose hoch spezifisch ist und wahrscheinlich das Ergebnis einer langen Koevolution und Kospeziation darstellt. Anhand von Sequenzunterschieden zwischen den Symbionten lässt sich das Alter der Assoziation zwischen Philanthus und Streptomyces auf etwa 26-67 Millionen Jahre schätzen, was der Entstehung der Gattung Philanthus entsprechen könnte. Auf der Basis von 16s rDNA Sequenzen und Ultrastruktur-Daten wurden die Antennensymbionten der Bienenwölfe als neues Taxon ‚Candidatus Streptomyces philanthi’ beschrieben, wobei die Symbionten verschiedener Wirtsarten als Ökotypen behandelt und nach der Wirtsart benannt wurden (z.B. ‚Candidatus Streptomyces philanthi triangulum’). Wie die Bakterien von der Assoziation mit Bienenwölfen profitieren, ist noch unklar. Auf jeden Fall wird ihnen vom Wirt eine unbesetzte und wahrscheinlich konkurrenzfreie ökologische Nische in den Antennen sowie eine zuverlässige Weitergabe an die nächste Generation garantiert. Außerdem sprechen einige Hinweise für eine Versorgung der Bakterien mit Nährstoffen durch den Bienenwolf: (1) Weibchen legen manchmal mehrere Brutkammern pro Tag an und sezernieren jedes Mal große Mengen an Bakterien; die Bakterien müssen sich also in den Drüsen-Reservoiren schnell vermehren, um den Vorrat an Symbionten wieder aufzufüllen. (2) Die Reservoire sind von Typ 3-Drüsenzellen umgeben, die die Bakterien mit Nährstoffen versorgen könnten. (3) Eine der Reservoir-Wände weist eine netzartige Struktur auf, die möglicherweise den Eintritt von Hämolymphe und damit von Nährstoffen in das Reservoir zulässt. Dies wird durch chemische Analysen der Kohlenwasserstoffe in der Hämolymphe und in dem Antennendrüsen-Sekret untermauert, die sehr ähnliche Zusammensetzungen aufweisen. Die Assoziation zwischen Bienenwölfen und Streptomyceten stellt den ersten bekannten Fall einer Symbiose dar, bei der Bakterien in den Antennen von Insekten kultiviert werden, und sie repräsentiert eines von wenigen Beispielen für Actinomyceten als Symbionten von Insekten. Weitere Untersuchungen evolutionärer und ökologischer Aspekte dieser Symbiose werden wertvolle Erkenntnisse über die Bedeutung von Actinomyceten für die Pathogen-Abwehr bei Insekten liefern und könnten sogar zur Entdeckung neuer Sekundärmetabolite mit antibiotischen Eigenschaften für die Verwendung in der Humanmedizin führen. CHEMISCHE KOMMUNIKATION UND PARTNERWAHL BEIM EUROPÄISCHEN BIENENWOLF Chemische Signale stellen sowohl die älteste als auch die am weitesten verbreitete Form von Kommunikation zwischen Organismen dar. Bei Insekten spielen Pheromone eine essentielle Rolle für die intraspezifische Kommunikation, und eine Vielzahl aktueller Untersuchungen belegt die Bedeutung olfaktorischer Signale für die Balz und Paarung. Die meisten dieser Studien konzentrieren sich jedoch auf Weibchen-Pheromone, während von Männchen produzierte Pheromone trotz ihrer ökologischen und evolutionären Bedeutung für die Partneranlockung und Partnerwahl bisher wenig Beachtung gefunden haben. Männchen des Europäischen Bienenwolfes etablieren und verteidigen Territorien, die sie mit einem Kopfdrüsen-Sekret markieren. Dieses Sekret wirkt höchstwahrscheinlich als ein Sex- Pheromon und lockt paarungsbereite Weibchen an. Da Männchen-Territorien meist aggregiert in der Nähe von Weibchennestern auftreten, haben die Weibchen die Möglichkeit, zwischen verschiedenen potenziellen Paarungspartnern zu wählen. Die chemischen Analysen der vorliegenden Arbeit zeigen, dass die Zusammensetzung und Menge des männlichen Markierpheromons vom Verwandtschaftsgrad, der Herkunft, dem Alter und der Größe der Männchen abhängen. Das Pheromon beinhaltet demnach Informationen über eine Vielzahl von Eigenschaften der Männchen, die für die Weibchenwahl von Bedeutung sein könnten. Sowohl die genetische Distanz („optimal outbreeding“) als auch die allgemeine genetische Qualität („good genes“) eines Männchens könnte die Partnerwahl der Bienenwolf-Weibchen beeinflussen. In dieser Arbeit für den Europäischen Bienenwolf entwickelte polymorphe Mikrosatelliten legen den Grundstein für Vaterschaftsanalysen und ermöglichen so die Durchführung und Auswertung von Experimenten zur Weibchenwahl bei dieser Art.
VACV GLV-1h68 was reported as a diagnostic/therapeutic vector which enters, replicates in, and reveals the locations of tumors in mice. Furthermore, the effect on tumor colonization, on tumor growth, regression and eradication by VACV GLV-1h68 without the need of any known genes with anti-tumoral activities was determined. To investigate differential protein expression between infected tumor cells and corresponding tumors, as well as between infected tumor cells, between infected tumors, proteomics is particularly used, possibly contributing to the understanding oncolytic ability on the protein level of VACV GLV-1h68. The given effects of VACV GLV-1h68 infection on cellular protein expression support tumor cell killing. In this study, differential protein expression was analyzed at different time points with two-dimensional gel electrophoresis (2DE) followed by MALDI-TOF/TOF identification. Comparative analysis of multiple 2-DE gels revealed that the majority of protein expression changes appeared at 48 hours post infection in cell cultivation and at 42 days post infection in tumors. Mass spectrometry identified 68, 75, 159 altered cellular proteins in the GI-101A, HT-29, PC-3 infected cells, respectively, including 30, 23, 49 up-regulated proteins and 38, 52, 110 down-regulated proteins 12 to 48 hours after infection. For xenografts, mass spectrometry identified 270, 101, 91 altered cellular proteins in the infected GI-101A, HT-29, PC-3 tumors, respectively, including 89, 70, 40 up-regulated proteins and 181, 31, 51 down-regulated proteins 7 to 42 days after infection. In general, in the cell lines, the proteins found to be differentially regulated are most often associated with metabolic processes, in particular with primary energy metabolism (glucose catabolism, TCA and lactate production). VAVC GLV 1h68 infection results in hijacking of the host translation apparatus, alteration of cytoskeleton networks, induce ubiqitin proteasome pathway (UPP) disorders. Particularly in tumors, the responses cover a much broader panel of cellular processes, including signalling (e.g., cell death), transport (in particular of iron ions) and migration. A common pathway to be up-regulated in both tumors and cell lines is the "unfolded protein response". Notably, VACV GLV-1h68 affected the anti-apoptosis pathways in GI-101A and PC-3 cancer cells but not in HT-29 xenografts. For example, GI-101A xenografts in mice appear 12 proteins associated with anti-apoptosis function. They were found down-regulated, including tumor protein-translationally-controlled (H-TPT1), rho-GDP-dissociation inhibitor alpha (H-GDIa), ywhaq protein (M-1433T), H-PRDX4, serine/threonine-protein phosphatase-2A-catalytic subunit beta isoform PP2A (M-Ppp2cb), eukaryotic translation initiation factor 2-subunit 1 alpha-35kDa (H-eIF2), H-actinin-α1 (ACTN1 ), Annexin A1 (H-A1), annexin A5 (H-A5), Mouse albumin 1 (M-Alb1), dimethylarginine dimethylaminohydrolase 2 (H-DDAH2). In PC-3 xenografts, anti-apoptosis expression is lesser than those in GI-101A cells, however 3 anti-apoptosis associated proteins were down-regulated such as ARP3 actin-related protein-3-homolog (H-ARP3), Human FLNA protein, Rho GDP dissociation inhibitor (GDI) alpha (H-GDIa). In contrast, in HT-29 xenografts, there are several anti-apoptosis-associated proteins that show even to be up-regulated; they mostly belong to peroxiredoxin proteins. Lesson from HT-29 had been given what various means the HT-29 cells use to escape their apoptosis fate. This suggests that VAVC GLV1h68 infection may induce unbalance of unfolded protein response (UPR) but tending to anti-apoptosis-mediated proteins and promote the destructive elements of UPR, including caspase-12 cleavage and apoptosis. Taken together in this thesis research I have tried to compare protein profiles obtained from responder cell line and from regressing solid tumors colonized by VAVC GLV-1h68 with that of non-responding tumors. I also compared these data with PC-3 prostate cell line and tumor data on intermediate responder which alter mouse protein profiling in tumors similarly to the highly efficacious GI-101A breast tumor cell line. From these comparisons I have deduced exciting protein pattern signature characteristic for a responder or distinctly different from non-responder system. Combining these few crucial genes involved with the transcriptional test data obtained by fellow graduate student at NIH a novel national designed VACV GLV-1h68 strains with enhanced efficacy in many today non-responder cancer cell lines will be available to be tested into ongoing clinical trials.
Während der Spermatogenese finden erstaunliche Differenzierungsprozessen statt. Reguliert wird die Spermatogenese sowohl hormonell als auch durch Wechselwirkungen zwischen verschiedenen Zelltypen und der extrazellulärer Matrix. Unterteilt wird die Spermatogenese in drei funktionelle Einheiten. Die Proliferationsphase, die Meiose und die Spermiogenese. Im Laufe der Proliferationsphase gehen aus den Spermatogonien, Spermatocyten hervor, die die Meiose durchlaufen. Während der Prophase I der Meiose kommt es zur Reduktion und Rekombination des genetischen Materials, was mit charakteristischen und höchst dynamischen Bewegungsvorgängen der Telomere einhergeht. Auf die Meiose folgt die Spermiogenese, in der das genetische Material in seine „Transportform“ überführt wird und aus einer stationären, zellverbundenen Einheit ein mobiles autark funktionierendes Vehikel des genetischen Materials wird; das Spermium. Um das Verständnis dieser Vorgänge zu erweitern wurden in dieser Arbeit die Verteilungsmuster einiger Proteine in der Kernhülle von Zellen der Spermatogenese, in Hinblick auf ihre dynamische Umverteilung untersucht. Bei diesen Proteinen handelte es sich um die SUN-Domänen Proteine und das meiosespezifische Lamin C2. Die SUN-Domänen Proteine sind Teil des membrandurchspannenden LINC-Komplexes, der Komponenten des Nukleoplasma mit denen des Cytoplasma verbindet. In dieser Arbeit konnte gezeigt werden, dass die SUN-Domänen Proteine, Sun1 und Sun2 während der Meiose exprimiert werden, und an den Anheftungsplatten meiotischer Chromosomen lokalisieren und deren dynamisches Verteilungsmuster dem Verteilungsmuster der Telomere während der Prophase I der Meiose entsprechen. Dies deutet darauf hin, dass Sun1 und Sun2 eine tragende Rolle, während der koordinierten Bewegungsprozessen der Prophase I der Meiose spielen. In der Spermiogenese sind die SUN-Domänen Proteine, Sun1 und Sun3 vertreten. Dabei weist deren unterschiedliche Lokalisation an entgegengesetzten Zellpolen darauf hin, dass Sun1 und Sun3 möglicherweise unterschiedliche Funktionen bei der Umgestaltung des Spermienkopfes während der Spermiogenese erfüllen. Ein weiterer Schwerpunkt dieser Arbeit war die Etablierung einer Mauslinie um die Rolle von Lamin C2 in der Meiose untersuchen zu können. Hierzu wurde eine Lamin C2 Knock-out Studie begonnen. In ersten Untersuchungen der knock-out Tiere konnte eine Größenreduktion der Hoden beobachtet werden. Ebenso konnte ein Abbruch der Meiose vermerkt werden. Die Ergebnisse dieser Arbeit verdeutlichen, dass sowohl die SUN-Domänen Proteine, als auch Lamin C2, wichtige Rollen in dem komplexen Arrangement der Spermatogenese übernehmen.
Ziel dieser Arbeit war die Untersuchung der psychischen Befindlichkeit und anderer gesundheitsbezogenen Konditionen der Frauen und Männer mit familiären Mamma- und Ovarialkarzinomrisiko sowie die Klärung hinsichtlich der Bewältigung und Auswirkung genetischer Risikoinformation. Es wurden Risikowahrnehmung, Informationsstand, Inanspruchnahme der Beratungsangebote sowie der Früherkennungsmaßnahmen, Einstellung gegenüber genetischer Brustkrebsdiagnostik und familiärer/sozialer Kommunikation untersucht. Die vollständig ausgefüllten Fragebögen von Ratsuchenden und Betroffenen, die an der Beratung und Befragung im Zentrum für „Familiären Brust-/Eierstockkrebs“ teilgenommen haben, wurden von uns ausgewertet. Für die beratenden Institutionen ist das Wissen der vielfältigen psychischen und sozialen Folgen bei den Testsuchenden und deren Familien sehr wichtig. Nur so kann das Betreuungskonzept und das Beratungsangebot verbessert werden.
The plasma membrane is one of the most thoroughly studied and at the same time most complex, diverse, and least understood cellular structures. Its function is determined by the molecular composition as well as the spatial arrangement of its components. Even after decades of extensive membrane research and the proposal of dozens of models and theories, the structural organization of plasma membranes remains largely unknown. Modern imaging tools such as super-resolution fluorescence microscopy are one of the most efficient techniques in life sciences and are widely used to study the spatial arrangement and quantitative behavior of biomolecules in fixed and living cells. In this work, direct stochastic optical reconstruction microscopy (dSTORM) was used to investigate the structural distribution of mem-brane components with virtually molecular resolution. Key issues are different preparation and staining strategies for membrane imaging as well as localization-based quantitative analyses of membrane molecules.
An essential precondition for the spatial and quantitative analysis of membrane components is the prevention of photoswitching artifacts in reconstructed localization microscopy images. Therefore, the impact of irradiation intensity, label density and photoswitching behavior on the distribution of plasma membrane and mitochondrial membrane proteins in dSTORM images was investigated. It is demonstrated that the combination of densely labeled plasma membranes and inappropriate photoswitching rates induces artificial membrane clusters. Moreover, inhomogeneous localization distributions induced by projections of three-dimensional membrane structures such as microvilli and vesicles are prone to generate artifacts in images of biological membranes. Alternative imaging techniques and ways to prevent artifacts in single-molecule localization microscopy are presented and extensively discussed.
Another central topic addresses the spatial organization of glycosylated components covering the cell membrane. It is shown that a bioorthogonal chemical reporter system consisting of modified monosaccharide precursors and organic fluorophores can be used for specific labeling of membrane-associated glycoproteins and –lipids. The distribution of glycans was visualized by dSTORM showing a homogeneous molecule distribution on different mammalian cell lines without the presence of clusters. An absolute number of around five million glycans per cell was estimated and the results show that the combination of metabolic labeling, click chemistry, and single-molecule localization microscopy can be efficiently used to study cell surface glycoconjugates.
In a third project, dSTORM was performed to investigate low-expressing receptors on cancer cells which can act as targets in personalized immunotherapy. Primary multiple myeloma cells derived from the bone marrow of several patients were analyzed for CD19 expression as potential target for chimeric antigen receptor (CAR)-modified T cells. Depending on the patient, 60–1,600 CD19 molecules per cell were quantified and functional in vitro tests demonstrate that the threshold for CD19 CAR T recognition is below 100 CD19 molecules per target cell. Results are compared with flow cytometry data, and the important roles of efficient labeling and appropriate control experiments are discussed.
In our analysis I was interested in the gene duplications, with focus on in-paralogs. In-paralogs are gene duplicates which arose after species split. Here I analysed the in-paralogs quantitatively, as well as qualitatively. For quantitative analysis genomes of 21 species were taken. Most of them have vastly different lifestyles with maximum evolutionary distance between them 1100 million years. Species included mammals, fish, insects and worm, plus some other chordates. All the species were pairwised analysed by the Inparanoid software, and in-paralogs matrix were built representing number of in-paralogs in all vs. all manner. Based on the in-paralogs matrix I tried to reconstruct the evolutionary tree using in-paralog numbers as evolutionary distance. If all 21 species were used the resulting tree was very far from real one: a lot of species were misplaced. However if the number was reduced to 12, all of the species were placed correctly with only difference being wrong insect and fish clusters switched. Then to in-paralogs matrix the neighbour-net algorithm was applied. The resulting "net" tree showed the species with fast or slow duplications rates compared to the others. We could identify species with very high or very low duplications frequencies and it correlates with known occurrences of the whole genome duplications. As the next step I built the graphs for every single species showing the correlation between their in-paralogs number and evolutionary distance. As we have 21 species, graph for every species is built using 20 points. Coordinates of the points are set using the evolutionary distance to that particular species and in-paralogs number. In mammals with increasing the distance from speciation the in-paralogs number also increased, however not in linear fashion. In fish and insects the graph close to zero is just the same in mammals' case. However, after reaching the evolutionary distances more than 800 million years the number of inparalogs is beginning to decrease. We also made a simulation of gene duplications for all 21 species and all the splits according to the fossil and molecular clock data from literature. In our simulation duplication frequency was minimal closer to the past and maximum in the near-present time. Resulting curves had the same shape the experimental data ones. In case of fish and insect for simulation the duplication rate coefficient even had to be set negative in order to repeat experimental curve shape. To the duplication rate coefficient in our simulation contribute 2 criteria: gene duplications and gene losses. As gene duplication is stochastical process it should always be a constant. So the changing in the coefficient should be solely explained by the increasing gene loss of old genes. The processes are explained by the evolution model with high gene duplication and loss ratio. The drop in number of in-paralogs is probably due to the BLAST algorithm. It is observed in comparing highly divergent species and BLAST cannot find the orthologs so precisely anymore. In the second part of my work I concentrated more on the specific function of inparalogs. Because such analysis is time-consuming it could be done on the limited number species. Here I used three insects: Drosophila melanogaster (fruit y), Anopheles gambiae (mosquito) and Apis mellifera (honeybee). After Inparnoid analyses and I listed the cluster of orthologs. Functional analyses of all listed genes were done using GO annotations and also KEGG PATHWAY database. We found, that the gene duplication pattern is unique for each species and that this uniqueness is rejected through the differences in functional classes of duplicated genes. The preferences for some classes reject the evolutionary trends of the last 350 million years and allow assumptions on the role of those genes duplications in the lifestyle of species. Furthermore, the observed gene duplications allowed me to find connections between genomic changes and their phenotypic manifestations. For example I found duplications within carbohydrate metabolism rejecting feed pattern adaptation, within photo- and olfactory-receptors indicating sensing adaptation and within troponin indicating adaptations in the development. Despite these species specific differences, found high correlations between the independently duplicated genes between the species. This might hint for a "pool" of genes preferentially duplicated. Taken together, the observed duplication patterns reject the adaptational process and provide us another link to the field of genomic zoology.
Many polymorphisms are linked to alternative reproductive strategies. In animals, this is particularly common in males. Ant queens are an important exception. The case of ant queen size dimorphisms has not been studied in sufficient detail, and thus this thesis aimed at elucidating causes and consequences of the different size of small (microgynous) and large (macrogynous)ant queens using the North American ant species Leptothorax rugatulus as a model system. Employing neutral genetic markers, no evidence for a taxonomically relevant separation of the gene pools of macrogynes and microgynes was found. Queens in polygynous colonies were highly related to each other, supporting the hypothesis that colonies with more than one queen commonly arise by secondary polygyny, i.e. by the adoption of daughter queens into their natal colonies. These results and conclusions are also true for the newly discovered queen size polymorphism in Leptothorax cf. andrei. Several lines of evidence favor the view that macrogynes predominantly found their colonies independently, while microgynes are specialized for dependent colony founding by readoption. Under natural conditions, mother and daughter size are highly correlated and this is also true for laboratory colonies. However, the size of developing queens is influenced by queens present in the colony. Comparing populations across the distribution range, it turns out that queen morphology (head width and ovariole number) is more differentiated among populations than worker morphology (coloration, multivariate size and shape), colony characteristics (queen and worker number per colony) or neutral genetic variation. Northern and southern populations differed consistently which indicates the possibility of two different species. The queen size dimorphism in L. rugatulus did neither influence the sex ratio produced by a colony, nor its ratio of workers to gynes. However, the sex ratio covaried strongly across populations with the average number of queens per colony in accordance with sex ratio theory. At the colony level, sex ratio could not be explained by current theory and a hypothesis at the colony-level was suggested. Furthermore, queen body size has no significant influence on the amount of reproductive skew among queens. Generally, the skew in L. rugatulus is low, and supports incomplete control models, rather than the classic skew models. In eight of fourteen mixed or microgynous colonies, the relative contributions of individual queens to workers, gynes and males were significantly different. This was mainly due to the fact that relative body size was negatively correlated with the ratio of gynes to workers produced. This supports the kin conflict over caste determination hypothesis which views microgyny as a selfish reproductive tactic.
Eine wichtige Standardtherapie in der modernen Behandlung von Krebserkrankungen ist die Strahlentherapie, in welcher Tumorzellen mittels ionisierender Strahlung geschädigt und abgetötet werden. Dabei soll die Schädigung des umgebenden Normalgewebes möglichst gering gehalten und trotzdem eine maximale Schädigung des Tumorgewebes erreicht werden. Deshalb sind neue Strategien zur Steigerung der Radiosensitivität des Tumorgewebes sehr wichtig, die es erlauben, bei gleicher Dosis eine verstärkte Strahlenantwort im Tumorgewebe zu erreichen. Hier kommen zunehmend sog. Radiosensibilisatoren zum Einsatz, die unter anderem onkogene Signalwege in den Tumorzellen inhibieren. Der PI3K/Akt/mTOR Signalweg stellt hierbei einen wichtigen Ansatzpunkt dar, da er in vielen Tumorentitäten dereguliert vorliegt und diese Signalkaskade bekanntermaßen einen Einfluss auf die zelluläre Strahlensensitivität hat. Obwohl es für diesen Signalweg schon eine Reihe von Inhibitoren gibt, für die bereits neben einer anti-proliferativen Wirkung auch ein radiosensibilisierender Effekt nachgewiesen wurde (z.B. Wortmannin und Rapamycin), machten eine geringe Spezifität, starke Nebenwirkungen und negative Rückkopplungsmechanismen im Signalweg, die die Wirkung des Inhibitors kompensieren, die Entwicklung neuer Inhibitoren notwendig. Das Imidazoquinolinderivat NVP-BEZ235 inhibiert den PI3K/Akt/mTOR Signalweg an mehreren Stellen gleichzeitig, indem es kompetitiv zu ATP das katalytische Zentrum von PI3K und mTOR blockiert. Für diesen kleinmolekularen, dualen Inhibitor gibt es bereits erste vielversprechende Forschungsergebnisse hinsichtlich einer radiosensibilisierenden Wirkung, allerdings sind die zugrunde liegenden molekularbiologischen Mechanismen noch nicht vollständig geklärt. Deshalb war das Ziel der vorliegenden Dissertation, in drei Teilprojekten mehrere Aspekte der NVP-BEZ235-induzierten Radiosensibilisierung aufzuklären: a) Einfluss des Behandlungsschemas für NVP-BEZ235 in vier Glioblastomzelllinien mit unterschiedlichem PTEN und TP53 Mutationsstatus, b) Einfluss der Sauerstoffversorgung (Hypoxie, Normoxie, reoxygeniert nach Bestrahlung) auf die strahlensensibilisierende Wirkung von NVP-BEZ235 in zwei Mammakarzinomzelllinien, c) gleichzeitige Inhibierung des MAPK Signalwegs durch AZD6244 und der PI3K/Akt/mTOR Signalkaskade durch NVP-BEZ235 in zwei Zelllinien mit unter-schiedlichem Mutationsstatus aus verschiedenen Tumorentitäten, um synergistische Effekte zu untersuchen. Um diese Fragestellungen zu beantworten, wurde im Rahmen - 142 -
der Dissertation eine Auswahl an humanen Tumorzelllinien mit unterschiedlich deregulierten Signalwegen bearbeitet. Dabei wurde die Expression von Schlüsselproteinen der MAPK/Erk und der PI3K/Akt/mTOR Signalwege analysiert und mit zellbiologischen Daten verschiedener phänotypischer Endpunkte nach Inhibitor Behandlung und Bestrahlung integriert (Proliferationsrate, klonogenes Überleben, Zellzyklusaberrationen, DNS-Schäden und -Reparatur, Zelltod und Autophagie).
Im Teilprojekt zum Behandlungsschema der NVP-BEZ235 Inhibierung und Bestrahlung konnte in vier Glioblastomzelllinien mit Behandlungsschema I (NVP-BEZ235 Behandlung 24 Stunden vor Bestrahlung) kein radiosensibilisierender Effekt hinsichtlich klonogenem Überleben nachgewiesen werden, wohingegen Behandlungsschema II (NVP-BEZ235 Behandlung 1 h vor und im Anschluss an die Bestrahlung) unabhängig vom Mutationsstatus in allen vier Zelllinien eine starke Radiosensibilisierung bewirkte. Auf molekularer Ebene war zwischen beiden Behandlungsschemata für das antiapoptotische Protein Akt ein großer Unterschied zu beobachten, welches bei Behandlung nach Schema I zum Zeitpunkt der Bestrahlung überaktiviert, nach Behandlung mit Schema II hingegen inhibiert war. Weiterhin resultierte Behandlungsschema I in einem erhöhten Anteil der Zellen in der radioresistenteren G1-Phase des Zellzyklus zum Zeit-punkt der Bestrahlung. Behandlungsschema II führte hingegen nach Bestrahlung zu einer verminderten Expression des Reparaturproteins Rad51 und damit zu verminderter DNS-Schadensreparatur und schließlich zu einem stabilen Arrest in der G2/M-Phase des Zellzyklus sowie zu verstärkter Apoptose (erhöhte Spaltung von PARP, erhöhter Anteil hypodiploider Zellen). Somit zeigen diese Ergebnisse, dass unabhängig vom PTEN und TP53 Mutationsstatus eine Radiosensibilisierung nur durch das Behandlungsschema II erreicht werden konnte. Ferner deuten die Ergebnisse der Proteinexpression darauf hin, dass durch NVP-BEZ235 ein negativer Rückkopplungsmechanismus ausgelöst wird, wodurch die PI3K/Akt/mTOR Signalkaskade 24h nach Zugabe des Inhibitors aktiviert und synergistische Effekte mit ionisierender Bestrahlung aufgehoben wurden.
Im Teilprojekt zur Abhängigkeit der NVP-BEZ235 Inhibition vom Sauerstoffgehalt wurden in den beiden Brustkrebszelllinien MCF-7 (ER-positiv) und TN MDA-MB-231 (TP53 mutiert) normoxische, hypoxische und nach Bestrahlung reoxygenierte Kulturbedingungen im Hinblick auf die Koloniebildungsfähigkeit nach NVP-BEZ235 Behandlung und Bestrahlung untersucht. Die beobachtete Radiosensibilisierung war unter allen getesteten Bedingungen auf gleichem Niveau. In beiden Zelllinien bewirkte NVP-BEZ235 eine Inhibition des antiapoptotischen HIF-1α Proteins, eine stabile Inaktivierung des PI3K/Akt/mTOR Signalweges und eine Aktivierung der Autophagie. Nach Bestrahlung waren zudem erhöhte residuale DNS-Schäden und ein stabiler Arrest in der G2/M-Phase des Zellzyklus unter allen Oxygenierungsbedingungen in beiden Zelllinien zu beobachten. Eine Apoptose Induktion (Spaltung von PARP, hypodiploide Zellen) trat nur in der TP53 wildtypischen MCF-7 Zelllinie nach NVP-BEZ235 Behandlung auf. Somit konnte in beiden Zelllinien in allen pathophysiologisch relevanten Oxygenierungszuständen eine sauerstoffunabhängige Radiosensibilisierung durch NVP-BEZ235 gezeigt werden.
Der bisher nicht erforschte Aspekt zur synergistischen Wirkung des MEK Inhibitors AZD6244 und des dualen PI3K/Akt/mTOR Inhibitors NVP-BEZ235 nach Bestrahlung wurde an der Glioblastomzelllinie SNB19 und der Lungenkarzinomzelllinie A549 anhand der Koloniebildungsfähigkeit der behandelten Zellen untersucht. Eine Behandlung mit dem MEK Inhibitor bewirkte lediglich eine moderate Radiosensibilisierung, wohin-gegen der duale PI3K/Akt/mTOR Inhibitor beide Zelllinien in stärkerem Maße sensibilisierte. Eine Kombination beider Inhibitoren resultierte bei keiner Zelllinie in einer Verstärkung der durch NVP-BEZ235 induzierten Radiosensibilisierung. Eine mögliche Erklärung für die fehlende Synergie im Bezug auf die Radiosensibilisierung können die gegensätzlichen Effekte der beiden Inhibitoren auf den Zellzyklus sein. Auf Proteinebene führte eine simultane Behandlung mit beiden Substanzen zur Inhibition beider Signalwege. Darüber hinaus war in SNB19 Zellen eine verstärkte Dephosphorylierung von Rb und ein erhöhter Anteil an G1-Phase Zellen bei kombinierter Gabe der Inhibitoren zu beobachten.
Im Rahmen dieser Arbeit konnte somit die radiosensibilisierende Wirkung von NVP-BEZ235 in Abhängigkeit vom Behandlungsschema gezeigt werden. Ferner wurde nachgewiesen, dass die Radiosensibilisierung unabhängig von der Sauerstoffversorgung sowie von den PTEN und TP53 Mutationsstatus der Tumorzellen ist. Die kombinierte Inhibition der MAPK und PI3K/Akt/mTOR Signalwege resultierte zwar in einem verstärkten zytostatischen, aber nicht in einem verstärkten radiosensibilisierenden Effekt. Da allerdings eine große Anzahl verschiedener Inhibitoren der MAPK/Erk und der PI3K/Akt/mTOR Signalkaskade verfügbar sind, sollte die kombinatorische Inhibition dieser Signalwege systematisch weiter verfolgt werden. Die vorliegende Arbeit liefert auch weitere grundlegende Erkenntnisse zu den molekularen Mechanismen der Radiosensibilisierung durch NVP-BEZ235, die auch auf Verknüpfungen und Wechselwirkungen mit anderen als den bisher bekannten Proteinen hindeuten, die für jeden Inhibitor aufgeklärt werden müssen, um eine effektive radiosensibilisierende Wirkung vorher-sagen zu können.
The Ras/RAF/MEK/ERK cascade is a central cellular signal transduction pathway involved in cell proliferation, differentiation, and survival where RAF kinases are pivotal kinases implicated in cancer. The development of specific irreversible kinase inhibitors is a rewarding but difficult aim. CI-1033 was developed to irreversibly inhibit erbB receptor tyrosine kinases by reacting to the Cys113 residue (p38alpha MAP kinase numbering) of the kinase domain. In this study we tried a similar approach to target the RAF oncoproteins which posses a similar cysteine at position 108 in the hinge region between the small n-lobe and the large c-lobe of the kinase domain. A novel synthetic approach including a lyophilization step allowed us the synthesis of a diphenyl urea compound with an epoxide moiety (compound 1). Compound 1 possessed inhibitory activity in vitro. However our time kinetics experiments and mass spectroscopic studies clearly indicate that compound 1 does not react covalently with the cysteine residue in the hinge region. Moreover, in cell culture experiments, a strong activation of the RAF signaling pathway was observed, an effect which is known from several other RAF kinase inhibitors and is here reported for the first time for a diphenyl urea compound, to which the clinically used unspecific kinase inhibitor BAY 43-9006 (Sorafinib, Nexavar) belongs. Although activation was apparently independent on B- and C-RAF hetero-oligomerization in vitro, in vivo experiments support such a mechanism as the activation did not occur in starved knockout cells lacking either B-RAF or C-RAF. Furthermore, we developed a mathematical model of the Ras/RAF/MEK/ERK cascade demonstrating how stimuli induce different signal patterns and thereby different cellular responses, depending on cell type and the ratio between B-RAF and C-RAF. Based on biochemical data for activation and dephosphorylation, we set up differential equations for a dynamical model of the Ras/RAF/MEK/ERK cascade. We find a different signaling pattern and response result for B-RAF (strong activation, sustained signal) and C-RAF (steep activation, transient signal). We further support the significance of such differential modulatory signaling by showing different RAF isoform expression in various cell lines and experimental testing of the predicted kinase activities in B-RAF, C-RAF as well as mutated versions. Additionally the effect of the tumor suppressor DiRas3 (also known as Noey2 or ARHI) on RAF signaling was studied. I could show that DiRas3 down-regulates the mitogenic pathway by inhibition of MEK, a basis for a refined model of the Ras/RAF/MEK/ERK cascade.
Understanding the emergence of species' ranges is one of the most fundamental challenges in ecology. Early on, geographical barriers were identified as obvious natural constraints to the spread of species. However, many range borders occur along gradually changing landscapes, where no sharp barriers are obvious. Mechanistic explanations for this seeming contradiction incorporate environmental gradients that either affect the spatio-temporal variability of conditions or the increasing fragmentation of habitat. Additionally, biological mechanisms like Allee effects (i.e. decreased growth rates at low population sizes or densities), condition-dependent dispersal, and biological interactions with other species have been shown to severely affect the location of range margins. The role of dispersal has been in the focus of many studies dealing with range border formation. Dispersal is known to be highly plastic and evolvable, even over short ecological time-scales. However, only few studies concentrated on the impact of evolving dispersal on range dynamics. This thesis aims at filling this gap. I study the influence of evolving dispersal rates on the persistence of spatially structured populations in environmental gradients and its consequences for the establishment of range borders. More specially I investigate scenarios of range formation in equilibrium, periods of range expansion, and range shifts under global climate change ...
The sequencing of several ant genomes within the last six years open new research avenues for understanding not only the genetic basis of social species but also the complex systems such as immune responses in general. Similar to other social insects, ants live in cooperative colonies, often in high densities and with genetically identical or closely related individuals. The contact behaviours and crowd living conditions allow the disease to spread rapidly through colonies. Nevertheless, ants can efficiently combat infections by using diverse and effective immune mechanisms. However, the components of the immune system of carpenter ant Camponotus floridanus and also the factors in bacteria that facilitate infection are not well understood.
To form a better view of the immune repository and study the C. floridanus immune responses against the bacteria, experimental data from Illumina sequencing and mass-spectrometry (MS) data of haemolymph in normal and infectious conditions were analysed and integrated with the several bioinformatics approaches. Briefly, the tasks were accomplished in three levels. First, the C. floridanus genome was re-annotated for the improvement of the existing annotation using the computational methods and transcriptomics data. Using the homology based methods, the extensive survey of literature, and mRNA expression profiles, the immune repository of C. floridanus were established. Second, large-scale protein-protein interactions (PPIs) and signalling network of C. floridanus were reconstructed and analysed and further the infection induced functional modules in the networks were detected by mapping of the expression data over the networks. In addition, the interactions of the immune components with the bacteria were identified by reconstructing inter-species PPIs networks and the interactions were validated by literature. Third, the stage-specific MS data of larvae and worker ants were analysed and the differences in the immune response were reported.
Concisely, all the three omics levels resulted to multiple findings, for instance, re-annotation and transcriptome profiling resulted in the overall improvement of structural and functional annotation and detection of alternative splicing events, network analysis revealed the differentially expressed topologically important proteins and the active functional modules, MS data analysis revealed the stage specific differences in C. floridanus immune responses against bacterial pathogens.
Taken together, starting from re-annotation of C. floridanus genome, this thesis provides a transcriptome and proteome level characterization of ant C. floridanus, particularly focusing on the immune system responses to pathogenic bacteria from a biological and a bioinformatics point of view. This work can serve as a model for the integration of omics data focusing on the immuno-transcriptome of insects.
Peritonitis is a common disease in man, frequently caused by fungi, such as Candida albicans; however, in seldom cases opportunistic infections with Saccharomyces cerevisiae are described. Resident peritoneal macrophages (prMΦ) are the major group of phagocytic cells in the peritoneum. They express a broad range of surface pattern recognition receptors (PRR) to recognize invaders. Yeast infections are primarily detected by the Dectin-1 receptor, which triggers activation of NFAT and NF-κB pathways.
The transcription of the Nfatc1 gene is directed by the two alternative promoters, inducible P1 and relatively constitutive P2 promoter. While the role of P1-directed NFATc1α-isoforms to promote survival and proliferation of activated lymphocytes is well-established, the relevance of constitutively generated NFATc1β-isoforms, mainly expressed in resting lymphocytes, myeloid and non-lymphoid cells, remains unclear. Moreover, former work at our department indicated different roles for NFATc1α- and NFATc1β-proteins in lymphocytes.
Our data revealed the functional role of NFATc1 in peritoneal resident macrophages. We demonstrated that the expression of NFATc1β is required for a proper immune response of prMΦ during fungal infection-induced acute peritonitis. We identified Ccl2, a major chemokine produced in response to fungal infections by prMΦ, as a novel NFATc1 target gene which is cooperatively regulated through the NFAT- and canonical NF-κB pathways. Consequently, we showed that NFATc1β deficiency in prMΦ results in a decreased infiltration of inflammatory monocytes, leading to a delayed clearance of peritoneal fungal infection.
We could further show that the expression of NFATc1β-isoforms is irrelevant for homeostasis of myeloid and adaptive immune system cells and that NFATc1α- (but not β-) isoforms are required for a normal development of peritoneal B1a cells. In contrast to the situation in myeloid cells, NFATc1β deficiency is compensated by increased expression of NFATc1α-isoforms in lymphoid cells. As a consequence, NFATc1ß is dispensable for activation of the adaptive immune system.
Taken together our results illustrate the redundancy and indispensability of NFATc1-isoforms in the adaptive and innate immune system, indicating a complex regulatory system for Nfatc1 gene expression in different compartments of the immune system and likely beyond that.
Das pleiotrope Zytokin TNF (tumor necrosis factor) kann an den TNF-Rezeptor 1 (TNFR1) und den TNF-Rezeptor 2 (TNFR2) binden und mit deren Hilfe seine biologischen Funktionen über verschiedene Signalwege, wie z.B. NFB- und MAPK-Aktivierung bzw. Apop¬toseinduktion, vermitteln. In früheren Arbeiten konnte gezeigt werden, dass die Aktivierung des TNFR2 zur proteasomalen Degradation des Adaterproteins TRAF2 führt und dadurch die TNFR1-induzierte Apoptose verstärkt wird. TWEAK (tumor necrosis like weak inducer of apoptosis), das ebenfalls der TNF-Ligandenfamilie angehört und die Interaktion mit dessen Rezeptor Fn14 (fibroblast growth factor-inducible 14), der wie der TNFR2 zur Untergruppe der TRAF-bindenden Rezeptoren der TNF-Rezeptorfamilie gehört, zeigten in verschiedenen Arbeiten auch eine TRAF2-degradierende Wirkung. In der vorliegenden Arbeit konnte nun gezeigt werden, dass dies auch im Falle des TWEAK/Fn14-Systems mit einem verstärkenden Effekt auf die TNFR1-vermittelte Apoptose einhergeht. Darüber hinaus konnte gezeigt werden, dass TWEAK zusätzlich auch die TNFR1-induzierte Nekrose verstärkt, die den Zelltod durch andere Mechanismen als bei der Apoptose induziert. Von anderen Arbeiten unserer Gruppe war bekannt, dass lösliches TWEAK (sTWEAK) und membranständiges TWEAK (mTWEAK) bezüglich der TRAF2-Depletion wirkungs¬gleich sind. Da der apoptotische Fn14-TNFR1-„crosstalk“ auf der Depletion von TRAF2-Komplexen beruht wurden auch keine signifikanten Unterschiede zwischen sTWEAK und mTWEAK in Bezug auf die Verstärkung der TNFR1-induzierten Apoptose beobachtet. Interessanter¬weise zeigte sich in der vorliegenden Arbeit jedoch, dass sTWEAK den klassischen NFB-Signalweg gar nicht bzw. nur schwach aktiviert, wohingegen mTWEAK diesen stark induziert. Bei der Aktivierung des alternativen NFB-Signalweges hingegen ließen sich keine Unterschiede zwischen sTWEAK und mTWEAK erkennen. Die Aktivierung eines Signalweges wird also durch die Oligomerisierung des Liganden nicht moduliert, demgegenüber aber erwies sich die Aktivierung eines anderen Signalweges als stark abhängig von der Liganden-Oligomerisierung. Vor dem Hintergrund, dass das Adapterprotein TRAF1 (TNF-receptor-associated factor 1) Heterotrimere mit TRAF2 bildet, wurde weiterhin untersucht, ob dieses Molekül einen Einfluss auf die Aktivität der TWEAK-induzierten Signalwege hat. Tatsächlich zeigte sich in TRAF1-exprimie¬renden Zellen eine Verstärkung der TWEAK-induzierten Aktivierung des klassischen NFB-Signalweges Zukünftige Studien müssen nun aufklären, inwieweit die hier gefundenen Mecha-nismen das Zusammenspiel von TNF und TWEAK in vivo bestimmen.
The mechanisms that enable cells to regulate their gene expression and thus their metabolism, proliferation or cellular behaviour are not only important to understand the basic biology of a living cell, but are also of crucial interest in cancerogenesis. Highly interwoven and tightly regulated pathways are the basis of a robust but also flexible regulatory network. Interference with these pathways can be either causative for tumorigenesis or can modify its outcome. The receptor tyrosine kinase (RTK) and RAS dependent pathways leading to AKT or ERK1/2 activation are of particular interest in melanoma. These signaling modules are commonly activated by different mutations that can be found in various pathway components like NRAS, BRAF or PTEN. The first part of this work deals with the diverse and versatile functions of the ERK1/2 pathway feedbackregulator MKP2 in different cellular, melanoma relevant settings. In addition, a functional role of the AP1-complex member FOSL1, an ERK1/2 transcriptional target being implicated in the regulation of proliferation, is demonstrated. Secondly, aspects of direct pharmacological inhibition of the ERK1/2 pathway with regard to the induction of apoptosis have been analysed. Due to the high frequency of melanoma related mutations occurring in the RAS/RAF/MEK/ERK pathway (e.g. NRASQ61K, BRAFV600E), inhibition of this signaling cascade is deemed to be a promising therapeutic strategy for the treatment of malignant melanoma. However, although in clinical trials mono-therapeutic treatment with MEK- or RAF inhibitors was successful in the short run, it failed to show satisfactory long-lasting effects. Hence, combination therapies using a MAPK pathway inhibitor and an additional therapy are currently under investigation. I was able to demonstrate that inhibition of MEK using the highly specific inhibitor PD184352 can have a protective effect on melanoma cells with regard to their susceptibility towards the apoptosis inducing agent cisplatin. Single application of cisplatin led to strong DNA damage and the induction of caspase-dependent apoptosis. Additional administration of the MEK inhibitor, however, strongly reduced the apoptosis inducing effect of cisplatin in several melanoma cell lines, These cells displayed an increased activation of the serine/threonine kinase AKT after MEK inhibition. This AKT activation concomitantly led to the phosphorylation of FOXO transcription factors, attenuating the cisplatin induced expression of the BH3-only protein PUMA. PUMA in turn was important to mediate the apoptosis machinery after cisplatin treatment. My results also indicate a participation of RTKs, in particular EGFR, in mediating MEK inhibitor induced activation of AKT. These results demonstrate that inhibition of the RAS/RAF/MEK/ERK signaling pathway in melanoma cell lines does not necessilary have favourable effects in a cytotoxic co-treatment situation. Instead, it can even enhance melanoma survival under pro-apoptotic conditions.
Regulation of mitotic progression : Focus on Plk1 function and the novel Ska complex at kinetochores
(2006)
During mitosis the duplicated chromosomes have to be faithfully segregated into the nascent daughter cells in order to maintain genomic stability. This critical process is dependent on the rearrangement of the interphase microtubule (MT) network, resulting in the formation of a bipolar mitotic spindle. For proper chromosome segregation all chromosomes have to become connected to MTs emanating from opposite spindle poles. The MT attachment sites on the chromosomes are the kinetochores (KTs), which are also required to monitor the integrity of KT-MT interactions via the spindle assembly checkpoint (SAC). The first part of this work concerns the action of Polo-like kinase 1 (Plk1). Plk1 is one of the most prominent mitotic kinases and is involved in the regulation of multiple essential steps during mitosis consistent with its dynamic localisation to spindle poles, KTs and the central spindle. Despite a nice model of Plk1 targeting to different mitotic structures via its phosphopeptide binding Polo-box domain (PBD), the exact molecular details of Plk1 functioning, in particular at the KTs, remain obscure. By two different approaches we obtained cells with an unlocalised Plk1 kinase activity: first by generating stable HeLa S3 cell lines, which upon induction expressed the PBD and thus displaced endogenous Plk1 from its sites of action. Secondly, by rescuing cells RNAi-depleted of Plk1 with the catalytic Plk1 domain only. Centrosome maturation, bipolar spindle assembly and loss of cohesion between the chromatid arms proceeded normally in either cells, in contrast to Plk1-depleted cells, arguing that PBD-mediated targeting of Plk1 is less critical for the tested functions. Remarkably, however, both the PBD expressing as well as the Plk1-depleted cells rescued with the catalytic domain of Plk1 arrested in early mitosis in a SAC-dependent manner with uncongressed chromosomes. These data disclose a so far unrecognised role of Plk1 in proper chromosome congression and point at a particular requirement for PBD-mediated localised Plk1 activity at the KTs. In the second part of the thesis, we characterised a novel spindle and KT associated protein, termed Ska1, which was originally identified in a spindle inventory. Ska1 associated with KTs following MT attachment during prometaphase and formed a complex with at least another novel protein of identical localisation, called Ska2. Ska1 was required for Ska2 stability in vivo and depletion of either Ska1 or Ska2 resulted in the loss of both proteins from the KTs. The absence of Ska proteins did not disrupt overall KT structure but most strikingly induced cells to undergo a prolonged SAC-dependent delay in a metaphase-like state. The delay was characterised by weakened kinetochore-fibre stability, recruitment of Mad2 protein to a few KTs and the occasional loss of individual chromosomes from the metaphase plate. These data indicate that the Ska1/2 complex plays a critical role in the maintenance of a KT-MT attachments and/or SAC silencing.
The oncogenic MYC protein is a transcriptional regulator of multiple cellular processes and is aberrantly activated in a wide range of human cancers. MYC is an unstable protein rapidly degraded by the ubiquitin-proteasome system. Ubiquitination can both positively and negatively affect MYC function, but its direct contribution to MYC-mediated transactivation remained unresolved.
To investigate how ubiquitination regulates MYC activity, a non-ubiquitinatable MYC mutant was characterized, in which all lysines are replaced by arginines (K-less MYC). The absence of ubiquitin-acceptor sites in K-less MYC resulted in a more stable protein, but did not affect cellular localization, chromatin-association or the ability to interact with known MYC interaction partners.
Unlike the wild type protein, K-less MYC was unable to promote proliferation in immortalized mammary epithelial cells. RNA- and ChIP-Sequencing analyses revealed that, although K-less MYC was present at MYC-regulated promoters, it was a weaker transcriptional regulator. The use of K-less MYC, a proteasomal inhibitor and reconstitution of individual lysine residues showed that proteasomal turnover of MYC is required for MYC target gene induction. ChIP-Sequencing of RNA polymerase II (RNAPII) revealed that MYC ubiquitination is dispensable for RNAPII recruitment and transcriptional initiation but is specifically required to promote transcriptional elongation. Turnover of MYC is required to stimulate histone acetylation at MYC-regulated promoters, which depends on a highly conserved region in MYC (MYC box II), thereby enabling the recruitment of BRD4 and P-TEFb and the release of elongating RNAPII from target promoters. Inhibition of MYC turnover enabled the identification of an intermediate in MYC-mediated transactivation, the association of MYC with the PAF complex, a positive elongation factor, suggesting that MYC acts as an assembly factor transferring elongation factors onto RNAPII. The interaction between MYC and the PAF complex occurs via a second highly conserved region in MYC’s amino terminus, MYC box I.
Collectively, the data of this work show that turnover of MYC coordinates histone acetylation with recruitment and transfer of elongation factors on RNAPII involving the cooperation of MYC box I and MYC box II.
A hitherto unresolved problem is how workers are prevented from reproducing in large insect societies. The queen informs about her fertility and health which ensures sufficient indirect fitness benefits for workers. In the ant Camponotus floridanus, I found such a signal located on eggs of highly fertile queens. Groups of workers were regularly provided with different sets of brood. Only in groups with queen eggs workers refrain from reproducing. Thus, the eggs seem to inform the workers about queen presence. The signal on queen eggs is presumably the same that enables workers to distinguish between queen and worker-laid eggs, latter are destroyed by workers. Queen and worker-laid eggs differ in their surface hydrocarbons in a similar way as fertile queens differ from workers in the composition of their cuticular hydrocarbons. When I transferred hydrocarbons from the queen cuticle to worker eggs the eggs were no longer destroyed, indicating that they now carry the signal. These hydrocarbons thus represent a queen signal that regulates worker reproduction in this species. But the signal is not present in all fertile queens. Founding queens with low egg-laying rates differ in the composition of cuticular hydrocarbons from queens with high productivity. Similar differences in the composition of surface hydrocarbons were present on their eggs. The queen signal develops along with an increasing fertility and age of the queen, and this is perceived by the workers. Eggs from founding queens were destroyed like worker eggs. This result shows that founding queens lack the appropriate signal. In these little colony foundations chemical communication of queen status may not be necessary to prevent workers from reproducing, since workers may benefit more from investing in colony growth and increased productivity of large colonies rather than from producing male eggs in incipient colonies. If the queen is missing or the productivity of the queen decreases, workers start laying eggs. There is some evidence from correlative studies that, under queenless conditions, worker police each other because of differences in individual odors as a sign of social status. It can be expressed as either aggressive inhibition of ovarian activity, workers with developed ovaries are attacked by nest-mates, or destruction by worker-laid eggs. I found that in C. floridanus workers, in contrast to known studies, police only by egg eating since they are able to discriminate queen- and worker-laid eggs. Workers with developed ovaries will never attacked by nest-mates. This is further supported by qualitative and quantitative differences in the cuticular hydrocarbon profile of queens and workers, whereas profiles of workers with and without developed ovaries show a high similarity. I conclude that workers discriminate worker eggs on the basis of their hydrocarbon profile, but they are not able to recognize egg-laying nest-mates. Improving our knowledge of the proximate mechanisms of the reproductive division of labor in evolutionary derived species like C. floridanus will help to understand the evolution of extreme reproductive altruism involving sterility as a characteristic feature of advanced eusocial systems.
The reprogramming of metabolic pathways is a hallmark of cancer: Tumour cells are dependent on the supply with metabolites and building blocks to fulfil their increased need as highly proliferating cells. Especially de novo synthesis pathways are upregulated when the cells of the growing tumours are not able to satisfy the required metabolic levels by uptake from the environment.
De novo synthesis pathways are often under the control of master transcription factors which regulate the gene expression of enzymes involved in the synthesis process. The master regulators for de novo fatty acid synthesis and cholesterogenesis are sterol regulatory element-binding proteins (SREBPs). While SREBP1 preferably controls the expression of enzymes involved in fatty acid synthesis, SREBP2 regulates the transcription of the enzymes of the mevalonate pathway and downstream processes namely cholesterol, isoprenoids and building blocks for ubiquinone synthesis.
SREBP activity is tightly regulated at different levels: The post-translational modification by ubiquitination decreases the stability of active SREBPs. The attachment of K48-linked ubiquitin chains marks the transcription factors for the proteasomal degradation. In tumour cells, high levels of active SREBPs are essential for the upregulation of the respective metabolic pathways. The increased stability and activity of SREBPs were investigated in this thesis.
SREBPs are ubiquitinated by the E3 ligase Fbw7 which leads to the subsequential proteolysis of the transcription factors. The work conducted in this thesis identified the counteracting deubiquitination enzyme USP28 which removes the ubiquitin chains from SREBPs and prevents their proteasomal degradation.
It further revealed that the stabilization of SREBP2 by USP28 plays an important role in the context of squamous cancers. Increased USP28 levels are associated with a poor survival in patients with squamous tumour subtypes. It was shown that reduced USP28 levels in cell lines and in vivo result in a decrease of SREBP2 activity and downregulation of the mevalonate pathway. This manipulation led to reduced proliferation and tumour growth.
A direct comparison of adenocarcinomas and squamous cell carcinomas in lung cancer patients revealed an upregulation of USP28 as well as SREBP2 and its target genes. Targeting the USP28-SREBP2 regulatory axis in squamous cell lines by inhibitors also reduced cell viability and proliferation.
In conclusion, this study reports evidence for the importance of the mevalonate pathway regulated by the USP28-SREBP2 axis in tumour initiation and progression of squamous cancer. The combinatorial inhibitor treatment of USP28 and HMGCR, the rate limiting enzyme of the mevalonate pathway, by statins opens the possibility for a targeted therapeutic treatment of squamous cancer patients.
Soluble guanylyl cyclase (sGC) is the best established receptor for nitric oxide (NO) and regulates a great number of important physiological functions. Surprisingly, despite the wellappreciated roles of this enzyme in regulation of vascular tone, smooth muscle cell proliferation, platelet aggregation, renal sodium secretion, synaptic plasticity, and other functions, extremely little is known about the regulation of sGC activity and protein levels. To date, the only well-proven physiologically relevant sGC regulator is NO. In the present study, some additional possibilities for sGC regulation were shown. Firstly, we evaluated the ability of different NO donors to stimulate sGC. Significant differences in the sGC stimulation by SNP and DEA/NO were found. DEA/NO stimulated sGC much stronger than did SNP. Interestingly, no correlation between the sGC protein and maximal activity distribution was found in rat brain regions tested, suggesting the existence of some additional regulatory mechanisms for sGC. The failure of SNP to stimulate sGC maximally might be one of the reasons why the lack of correlation between the distribution of sGC activity and proteins in brain was not detected earlier. Prolonged exposure of endothelial cells to NO donors produced desensitization of the cGMP response. This desensitization cannot be explained by increased PDE activity, since PDE inhibitors were not able to prevent the NO donor-induced decrease of the maximal cGMP response in endothelial cells. The failure of SH-reducing agents to improve the cGMP response after its desensitization by NO suggests that a SH-independent mechanism mediates NO effects. Demonstration that the potency of the recently described activator of oxidized (heme-free) sGC, BAY58-2667, to stimulate sGC increases after prolonged exposure of the cells to an NO donor, DETA/NO, suggests that oxidation of heme may be a reason for NOinduced desensitization of sGC and decrease in sGC protein level. Indeed, the well-known heme-oxidizing agent ODQ produces a dramatic decrease in sGC protein levels in endothelial cells and BAY58-2667 prevents this effect. Although the mechanism of sGC activation and stabilization by BAY58-2667 is unknown, this substance is an interesting candidate to modulate sGC under conditions where sGC heme iron is oxidized. Very little is known about regulation of sGC by intracellular localization or translocation between different intracellular compartments. In the present study, an increase in sGC sensitivity to NO under membrane association was demonstrated. Treatment of isolated lung with VEGF markedly increased sGC in membrane fractions of endothelial cells. Failure of VEGF to stimulate sGC membrane association in cultured endothelial cells allows us to propose a complex mechanism of regulation of sGC membrane association and/or a transient character of sGC membrane attachment. A very likely mechanism for the attachment of sGC to membranes is via sGCinteracting proteins. These proteins may participate also in other aspects of sGC regulation. The role of the recently described sGC interaction partner, Hsp90, was investigated. Shortterm treatment of endothelial cells with an Hsp90 inhibitor does not affect NO donor or calcium ionophore-stimulated cGMP accumulation in the cells. However, inhibition of Hsp90 results in a rapid and dramatic decrease in sGC protein levels in endothelial cells. These effects were unrelated to changes in sGC transcription, since inhibition of transcription had much slower effect on sGC protein levels. In contrast, inhibitors of proteasomes abolished the reduction in sGC protein levels produced by an Hsp90 inhibitor, suggesting involvement of proteolytic degradation of sGC proteins during inhibition of Hsp90. All these data together suggest that Hsp90 is required to maintain mature sGC proteins. In conclusion, in the present study it was demonstrated that multiple mechanisms are involved in the regulation of sGC activity and its sensitivity to NO. Oxidation of sGC heme by NO seems to be one of the mechanisms for negative regulation of sGC in the presence of high or prolonged stimulation with NO. Another possible means of regulating sGC sensitivity to NO is via the intracellular translocation of the enzyme. It has been also demonstrated here that attachment of sGC to the membrane fraction results in an apparent increase in the enzyme sensitivity to NO. Additionally, Hsp90 was required to maintain sGC protein in endothelial and other cell types. However, we could not find any acute affect of Hsp90 on sGC activity, as reported recently. All these findings demonstrate that the regulation of sGC activity and protein level is a much more complex process than had been assumed earlier.
Honeybees are among the few animals that rely on eusociality to survive. While the
task of queen and drones is only reproduction, all other tasks are accomplished by sterile
female worker bees. Different tasks are mostly divided by worker bees of different ages
(temporal polyethism). Young honeybees perform tasks inside the hive like cleaning and
nursing. Older honeybees work at the periphery of the nest and fulfill tasks like guarding
the hive entrance. The oldest honeybees eventually leave the hive to forage for resources
until they die. However, uncontrollable circumstances might force the colony to adapt or
perish. For example, the introduced Varroa destructor mite or the deformed wing virus
might erase a lot of in-hive bees. On the other hand, environmental events might kill a
lot of foragers, leaving the colony with no new food intake. Therefore, adaptability of
task allocation must be a priority for a honeybee colony.
In my dissertation, I employed a wide range of behavioral, molecular biological and analytical techniques to unravel the underlying molecular and physiological mechanisms of
the honeybee division of labor, especially in conjunction with honeybee malnourishment.
The genes AmOARα1, AmTAR1, Amfor and vitellogenin have long been implied to
be important for the transition from in-hive tasks to foraging. I have studied in detail
expression of all of these genes during the transition from nursing to foraging to understand how their expression patterns change during this important phase of life. My focus
lay on gene expression in the honeybee brain and fat body. I found an increase in the
AmOARα1 and the Amforα mRNA expression with the transition from in-hive tasks to
foraging and a decrease in expression of the other genes in both tissues. Interestingly,
I found the opposite pattern of the AmOARα1 and AmTAR1 mRNA expression in the
honeybee fat body during orientation flights. Furthermore, I closely observed juvenile
hormone titers and triglyceride levels during this crucial time. Juvenile hormone titers
increased with the transition from in-hive tasks to foraging and triglyceride levels decreased.
Furthermore, in-hive bees and foragers also differ on a behavioral and physiological level.
For example, foragers are more responsive towards light and sucrose. I proposed that
modulation via biogenic amines, especially via octopamine and tyramine, can increase
or decrease the responsiveness of honeybees. For that purpose, in-hive bees and foragers were injected with both biogenic amines and the receptor response was quantified
1
using electroretinography. In addition, I studied the behavioral response of the bees to
light using a phototaxis assay. Injecting octopamine increased the receptor response and
tyramine decreased it. Also, both groups of honeybees showed an increased phototactic
response when injected with octopamine and a decreased response when injected with
tyramine, independent of locomotion.
Additionally, nutrition has long been implied to be a driver for division of labor. Undernourished honeybees are known to speed up their transition to foragers, possibly to
cope with the missing resources. Furthermore, larval undernourishment has also been
implied to speed up the transition from in-hive bees to foragers, due to increasing levels
of juvenile hormone titers in adult honeybees after larval starvation. Therefore, I reared
honeybees in-vitro to compare the hatched adult bees of starved and overfed larvae to
bees reared under the standard in-vitro rearing diet. However, first I had to investigate
whether the in-vitro rearing method affects adult honeybees.
I showed effects of in-vitro rearing on behavior, with in-vitro reared honeybees foraging
earlier and for a shorter time than hive reared honeybees. Yet, nursing behavior was
unaffected.
Afterwards, I investigated the effects of different larval diets on adult honeybee workers.
I found no effects of malnourishment on behavioral or physiological factors besides a
difference in weight. Honeybee weight increased with increasing amounts of larval food,
but the effect seemed to vanish after a week.
These results show the complexity and adaptability of the honeybee division of labor.
They show the importance of the biogenic amines octopamine and tyramine and of the
corresponding receptors AmOARα1 and AmTAR1 in modulating the transition from inhive bees to foragers. Furthermore, they show that in-vitro rearing has no effects on
nursing behavior, but that it speeds up the transition from nursing to foraging, showing
strong similarities to effects of larval pollen undernourishment. However, larval malnourishment showed almost no effects on honeybee task allocation or physiology. It seems
that larval malnourishment can be easily compensated during the early lifetime of adult
honeybees.
The variant surface glycoprotein (VSG) of African trypanosomes plays an essential role in protecting the parasites from host immune factors. These trypanosomes undergo antigenic variation resulting in the expression of a single VSG isoform out of a repertoire of around 2000 genes. The molecular mechanism central to the expression and regulation of the VSG is however not fully understood.
Gene expression in trypanosomes is unusual due to the absence of typical RNA polymerase II promoters and the polycistronic transcription of genes. The regulation of gene expression is therefore mainly post-transcriptional. Regulatory sequences, mostly present in the 3´ UTRs, often serve as key elements in the modulation of the levels of individual mRNAs. In T. brucei VSG genes, a 100 % conserved 16mer motif within the 3´ UTR has been shown to modulate the stability of VSG transcripts and hence their expression. As a stability-associated sequence element, the absence of nucleotide substitutions in the motif is however unusual. It was therefore hypothesised that the motif is involved in other essential roles/processes besides stability of the VSG transcripts.
In this study, it was demonstrated that the 100 % conservation of the 16mer motif is not essential for cell viability or for the maintenance of functional VSG protein levels. It was further shown that the intact motif in the active VSG 3´ UTR is neither required to promote VSG silencing during switching nor is it needed during differentiation from bloodstream forms to procyclic forms. Crosstalk between the VSG and procyclin genes during differentiation to the insect vector stage is also unaffected in cells with a mutated 16mer motif. Ectopic overexpression of a second VSG however requires the intact motif to trigger silencing and exchange of the active VSG, suggesting a role for the motif in transcriptional VSG switching. The 16mer motif therefore plays a dual role in VSG in situ switching and stability of VSG transcripts. The additional role of the 16mer in the essential process of antigenic variation appears to be the driving force for the 100 % conservation of this RNA motif.
A screen aimed at identifying candidate RNA-binding proteins interacting with the 16mer motif, led to the identification of a DExD/H box protein, Hel66. Although the protein did not appear to have a direct link to the 16mer regulation of VSG expression, the DExD/H family of proteins are important players in the process of ribosome biogenesis. This process is relatively understudied in trypanosomes and so this candidate was singled out for detailed characterisation, given that the 16mer story had reached a natural end point. Ribosome biogenesis is a major cellular process in eukaryotes involving ribosomal RNA, ribosomal proteins and several non-ribosomal trans-acting protein factors. The DExD/H box proteins are the most important trans-acting protein factors involved in the biosynthesis of ribosomes. Several DExD/H box proteins have been directly implicated in this process in yeast. In trypanosomes, very few of this family of proteins have been characterised and therefore little is known about the specific roles they play in RNA metabolism. Here, it was shown that Hel66 is involved in rRNA processing during ribosome biogenesis. Hel66 localises to the nucleolus and depleting the protein led to a severe growth defect. Loss of the protein also resulted in a reduced rate of global translation and accumulation of rRNA processing intermediates of both the small and large ribosomal subunits. Hel66 is therefore an essential nucleolar DExD/H protein involved in rRNA processing during ribosome biogenesis. As very few protein factors involved in the processing of rRNAs have been described in trypanosomes, this finding represents an important platform for future investigation of this topic.
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.
Colon carcinomas (CRC) are statistically among the most fatal cancer types and hence one of the top reasons for premature mortality in the developed world. CRC cells are characterized by high proliferation rates caused by deregulation of gene transcription of proto-oncogenes and general chromosomal instability. On macroscopic level, CRC cells show a strongly altered nutrient and energy metabolism.
This work presents research to understand general links between the metabolism and transcription alteration. Mainly focussing on glutamine dependency, shown in colon carcinoma cells and expression pathways of the pro-proliferation protein c-MYC.
Previous studies showed that a depletion of glutamine in the cultivation medium of colon carcinoma cell lines caused a proliferation arrest and a strong decrease of overall c-MYC levels. Re-addition of glutamine quickly replenished c-MYC levels through an unknown mechanism. Several proteins altering this regulation mechanism were identified and proposed as possible starting point for further in detail studies to unveil the precise biochemical pathway controlling c-MYC translation repression and reactivation in a rapid manner.
On a transcriptional level the formation of RNA:DNA hybrids, so called R-loops, was observed under glutamine depleted conditions. The introduction and overexpression of RNaseH1, a R-loop degrading enzyme, in combination with an ectopically expressed c-MYC variant, independent of cellular regulation mechanisms by deleting the regulatory 3’-UTR of the c-MYC gene, lead to a high rate of apoptotic cells in culture. Expression of a functionally inactive variant of RNaseH1 abolished this effect. This indicates a regulatory function of R-loops formed during glutamine starvation in the presence of c-MYC protein in a cell. Degradation of R-loops and high c-MYC levels in this stress condition had no imminent effect on the cell cycle progression is CRC cells but disturbed the nucleotide metabolism. Nucleotide triphosphates were strongly reduced in comparison to starving cells without R-loop degradation and proliferating cells.
This study proposes a model of a terminal cycle of transcription termination, unregulated initiation and elongation of transcription leading to a depletion of energy resources of cells. This could finally lead to high apoptosis of the cells. Sequencing experiments to determine a coinciding of termination sites and R-loop formation sides failed so far but show a starting point for further studies in this essential survival mechanism involving R-loop formation and c-MYC downregulation.
Das menschliche MHS2 Gen ist eine sehr gut charakterisierte Komponente des Mismatch-Reparatur-Systems (MMR) und häufig mit der HNPCC Erkrankung assoziiert. Der Mechanismus über den MSH2 an der Karzinomentwicklung beteiligt ist, sind Defekte in der DNA-Reparatur. Es konnte gezeigt werden, dass Mutationen in den kodierenden Regionen dieses Gens direkt in die Mikrosatelliteninstabilität involviert sind. Generell ist MSH2 ein Teil des postreplikativen Reparatursystems der Zellen, und schützt so vor der Akkumulation von Mutationen. Dadurch wird die genetische Stabilität und Integrität gewährleistet. Ein anderer Teil der zellulären Krebsabwehr ist das p53 Tumorsuppressorgen. Ein möglicher DNA Schaden, der in der Lage ist, p53 zu aktivieren, ist UV-Licht. Eine weitere gut charakterisierte Komponente der zellulären UV Reaktion ist der Transkriptionsfaktor c-Jun. Ziel der Arbeit war es die Regulation und Signalfunktion von MSH2 näher zu charakterisieren. Dazu wurde der Promotor des Gens in ein Luziferase Promotorgenkonstrukt kloniert. Dieses Konstrukt wurde in menschliche Keratinozyten transfiziert, die nachfolgend mit UV bestrahlt wurden. Es konnte eine zeit- und dosisabhängige Hochregulation von MSH2 gezeigt werden. Diese Transkriptionserhöhung wurde von p53 initiiert, denn durch eine gezielte Mutation der p53-Bindungsstelle im MSH2 Promotor war dieser Effekt vollkommen aufgehoben. Interessanterweise war dieser Effekt von einem zusätzlichen Faktor abhängig, ohne den keine Hochregulation erkennbar war. Verantwortlich hierfür war der Transkriptionsfaktor c-Jun. Dadurch konnte eine funktionelle Interaktion von p53 und c-Jun in der transkriptionellen Aktivierung von hMSH2 gezeigt werden. Dieser zeit- und dosisabhängige Effekt war sowohl auf RNA als auch auf Proteinebene nachvollziehbar. Der größte Anstieg war bei 50 J/m2 zu verzeichnen, wohin gegen bei Verwendung von 75 J/m2 die Transkriptmenge geringer wurde, um bei 100 J/m2 erneut anzusteigen. Um diesen erneuten Anstieg des Proteins näher zu beschreiben wurden bei den stark bestrahlten Zellen TUNEL-Untersuchungen durchgeführt. Hierbei zeigte sich eine positive Korrelation zwischen der Menge an MSH2 Protein und an TUNEL-positiven apoptotischen Zellen. Um weiter zu zeigen, dass der zweite Anstieg des Proteins nicht mit einer Reparaturfunktion verbunden ist, wurde ein biochemisch basierter Test durchgeführt, welcher die Reparaturkapazität semiquantitativ beschreibt. Dabei konnte klar gezeigt werden, dass die mit 100 J/m2 bestrahlten Zellen keine Reparaturfunktion mehr erfüllen. FACS-Analysen und Zellfärbungen gegen Annexin V und mit Propidiumiodid bestätigten die stattfindende Apoptose in den Zellen. Eine weitere Komponente des MMR-Systems ist MSH6. MSH6 bildet mit MSH2 ein Dimer, welches den Fehler in der DNA erkennt und das weitere Reparaturprogramm einleitet. Die Expression dieses Proteins konnte nur bis zu einer Dosis von 50-75 J/m2 UV nachgewiesen werden. Im Gegensatz zu MSH2 war MSH6 nicht in 100 J/m2 bestrahlten Keratinozyten detektierbar. Um über die Lokalisation dieser Proteine mehr zu erfahren wurden Immunfärbungen gegen MSH2 durchgeführt. Es zeigte sich eine Translokation des Proteins vom Kern in das Zytoplasma in Korrelation zum zunehmenden DNA-Schaden durch höhere Dosen an UV-Licht. Dies stellt eine mögliche Verbindung zwischen dem Mismatch-Reparatursystem und apoptotischen Signalwegen dar.
Ca2+-empfindliche K+-Kanäle mittlerer Leitfähigkeit (IK1-Kanäle) übernehmen wichtige Funktionen bei vielen physiologischen Prozessen wie z.B. bei der Zell-Proliferation, der epithelialen Salz- und Wasser-Sekretion und der Zellmigration. Die Kanäle werden durch die intrazeluläre Ca2+-Konzentration reguliert, wobei ihre Ca2+-Sensitivität durch Phosphorylierungsreaktionen moduliert werden kann. Ziel dieser Arbeit war die funktionelle Charakterisierung des aus transformierten Nierenepithelzellen (MDCK-F-Zellen) klonierten Ca2+-sensitiven K+-Kanals mittlerer Leitfähigkeit (cIK1) und die Untersuchung seiner Regulierung durch die Proteinkinase C (PKC). Dazu wurde der Kanal heterolog in CHO- und HEK293-Zellen exprimiert. Seine biophysikalischen und pharmakologischen Eigenschaften sowie der Einfluß der Proteinkinase C auf die Kanalaktivität wurden mit Hilfe der Patch-Clamp-Technik untersucht. Die cIK1-Ströme sind schwach einwärtsrektifizierend, zeigen keine Aktivierungs- oder Inaktivierungskinetik und weisen im physiologischen Bereich keine Spannungsabhängigkeit auf. Der cIK1 ist K+-selektiv und wird durch einen Anstieg der intrazellulären Ca2+-Konzentration aktiviert. Der Kanal wird durch Barium, Charybdotoxin und Clotrimazol blockiert und durch 1-Ethyl-2-Benzimidazolon aktiviert. Die funktionellen und pharmakologischen Eigenschaften des klonierten cIK1 entsprechen damit denen des nativen Kanals aus MDCK-F-Zellen und stimmen mit denen anderer Mitglieder der IK1-Kanalfamilie überein. Neben der Regulierung durch die intrazelluläre Ca2+-Konzentration wird der cIK1 auch durch eine PKC-abhängige Phosphorylierung reguliert. Sowohl ATP als auch ATP?S stimulieren die Kanalaktivität. Die ATP-abhängige Aktivierung wird durch Inhibitoren der Proteinkinase C (Bisindolylmaleimid, Calphostin C) gehemmt, während die mit ATP?S induzierte Kanalaktivität weitgehend resistent gegen diese PKC-Inhibitoren ist. Eine Stimulierung der Proteinkinase C mit Phorbol 12-Myristat 13-Acetat (PMA) führt zu einer sofortigen Aktivierung des cIK1. Im Gegensatz dazu sind die cIK1-Kanäle nach fast vollständigem Abbau der Proteinkinase C durch eine langfristige Inkubierung der Zellen mit PMA nicht mehr aktiv. Um zu untersuchen, ob diese Regulierung eine direkte Interaktion der Proteinkinase C mit dem Kanalprotein erfordert, wurden die drei putativen PKC-Konsensussequenzen des cIK1 mittels zielgerichteter Mutagenese so verändert, daß eine Phosphorylierung an diesen Stellen nicht mehr möglich ist. Weder die einzelne Mutation der PKC-Konsensussequenzen (T101, S178, T329) noch die gleichzeitige Mutation aller drei Phosporylierungsstellen zu Alanin beeinflußt die akute Regulierung des cIK1 durch die Proteinkinase C. Die cIK1-Mutante T329A und die Dreifachmutante reagieren jedoch nach einem Abbau der Proteinkinase C mit einem extremen Anstieg der Kanalaktivität und demaskieren damit einen zweiten Weg der Kanalregulierung. Die Ergebnisse zeigen, daß der cIK1 durch zwei voneinander unabhängige Mechanismen reguliert wird. Eine PKC-abhängige Phosphorylierung erhöht die Aktivität der Kanäle, findet jedoch nicht an den bekannten PKC-Konsensusesquenzen des Kanalproteins statt. Dagegen werden die cIK1-Kanäle über einen zweiten ATP-abhängigen Mechanismus, der wahrschenlich eine direkte Interaktion mit dem Kanalprotein erfordert, gehemmt.
Im Katabolismus methylverzweigter Fettsäuren spielt die alpha-Methylacyl-CoA-Racemase eine wichtige Rolle, indem sie die (R)- und (S)-Isomere von alpha-methylverzweigten Fettsäuren als Coenzym A Thioester racemisiert. Methylverzweigte Fettsäuren entstehen beim Abbau von Isoprenoiden und werden darüber hinaus auch von vielen Organismen, wie z.B. Mycobakterien, synthetisiert. Die Hauptaufgabe der Racemase ist aber vermutlich in der Biosynthese von Gallensäuren zu sehen. Das Ziel der vorliegenden Arbeit war es, die alpha-Methylacyl-CoA-Racemase aus humanem Gewebe zu reinigen und zu charakterisieren sowie ihre physiologische Rolle im Katabolismus verzweigtkettiger Fettsäuren und der Gallensäurebiosynthese zu untersuchen. Die alpha-Methylacyl-CoA-Racemase wurde aus humanem Gewebe zur Homogenität gereinigt, umfassend biochemisch charakterisiert und zur genauen molekularbiologischen Analyse in E.coli kloniert. Die Aktivität der Racemase wurde anhand der [³H]H2O-Freisetzung aus [alpha-³H]-a-Methylacyl-CoAs bestimmt. Die humane Racemase ist in der aktiven Form ein monomeres Protein und besteht aus 382 Aminosäuren. Als Substrate akzeptiert das Enzym ein breites Spektrum von alpha-Methylacyl-CoAs. Neben den Coenzym A-Thioestern alpha-methylverzweigter Fettsäuren, wie Pristansäure, werden auch CoA-Ester von Steroidderivaten, z.B. des Gallensäureintermediats Trihydroxycoprostansäure, und aromatischen Phenylpropionsäuren, wie dem Analgetikum Ibuprofen, umgesetzt. Freie Fettsäuren, geradkettige oder beta-methylverzweigte Acyl-CoAs werden nicht racemisiert. Die alpha-Methylacyl-CoA-Racemase ist im Menschen zu ca. 80 Prozent auf die Peroxisomen und ca. 20 Prozent auf die Mitochondrien verteilt, wobei entsprechende peroxisomale (PTS 1) und mitochondriale (MTS) Transportsignale die Lokalisation bestimmen. Die vollständige cDNA-Sequenz der humanen a-Methylacyl-CoA-Racemase hat eine Gesamtlänge von 2039 Basenpaaren mit einem offenen Leseraster von 89 - 1237 bp. Das Startcodon ATG ist in eine klassische Kozak-Sequenz zum Translationsstart eingebettet. Die Protein endet am C-Terminus mit dem Sequenzmotiv –KASL, das dem peroxisomalen Transportsignal (PTS I) einiger Säugetierkatalasen entspricht. Aufgrund alternativer Polyadenylierung sind in allen untersuchten menschlichen Geweben Transkripte von 1,6 kb bzw. 2,0 kb zu finden. Es liegt keine gewebsabhängige Polyadenylierung vor, die Racemase wird aber gewebsspezifisch exprimiert (besonders stark in Leber und Niere). Das humane Racemasegen liegt auf dem kurzen Arm des Chromosoms 5 nahe am Centromer (5p1.3), im Intervall von D5S651 (46,6 cM) und D5S634 (59.9 cM).
Die Zusammenlageurng spleißosomaler UsnRNPs erfolgt beim Menschen und anderen Vertebraten durch den makromolekularen SMN-Komplex. Dieser besteht aus insgesamt neun Proteinen, genannt SMN und Gemin2-8. In dieser Arbeit wurde die Evolution dieser molekularen Maschine untersucht. Dazu wurden die Genome mehrerer Modellorganismen bioinformatisch nach Orthologen von SMN und seinen Komplexpartnern durchsucht. Es zeigte sich, dass SMN und Gemin2 die Kernkomponenten des Komplexes darstellen. Von diesen ausgehend kamen weitere Komponenten im Laufe der Evolution hinzu und zwar blockweise, wie es ihrer physischen Assoziation im humanen Komplex entspricht. Um diese Befunde einer biochemischen Überprüfung zu unterziehen, wurde ein neues Affinitätsepitop, das TagIt-Epitop, entwickelt. Nach stabiler Transfektion von Drosophila Schneider2-Zellen konnte das Fusionsprotein effizient exprimiert und der Drosophila-SMN-Komplex nativ aufgereinigt werden. Die massenspektrometrische Untersuchung des Komplexes zeigte, dass SMN und Gemin2 seine einzigen stöchiometrischen Komponenten sind. Dies ist in eindrucksvoller Übereinstimmung mit den bioinformatischen Daten. Der aufgereinigte Komplex lagert in vitro Sm-Proteine mit der entsprechenden UsnRNA zum UsnRNP-core-Komplex zusammen. Diese Ergebnisse ließen sich nach rekombinanter Rekonstitution des SMN/Gemin2-Dimers rekapitulieren. Dabei zeigte sich, dass der SMN-Komplex die unkoordinierte Bindung der Sm-Proteine an „falsche“ RNAs verhindert. Folglich genügen SMN und Gemin2 zur Zusammenlagerung des Sm-core-Komplexes, während die übrigen Gemine weitere Funktionen im Kontext der UsnRNP-Biogenese spielen könnten. Aus evolutionsbiologischer Sichtweise ist der SMN-Komplex aus Drosophila ein eindrückliches Beispiel, wie die Vereinfachung eines biochemischen Prozesses zur Kompaktierung des Genoms beitragen kann.
Das Renin-Angiotensin-Aldosteron-System (RAAS) reguliert den Blutdruck sowie den Elektrolyt- und Wasserhaushalt. Das aktive Peptid, Angiotensin II (AngII), führt dabei zur Vasokonstriktion und in höheren Konzentrationen zu Bluthochdruck. Hypertensive Patienten haben ein erhöhtes Risiko an Krebs zu erkranken, vor allem an Nierenkrebs. Wir konnten bereits in vivo zeigen, dass AngII in der Lage ist, den Blutdruck zu steigern und dosisabhängig zu DNA-Schäden über den Angiotensin II Typ 1-Rezeptor (AT1R) führt. Ein stimuliertes RAAS kann ferner über die Aktivierung der NADPH-Oxidase, einer Hauptquelle der Generierung reaktiver Sauerstoffspezies (ROS) in der Zelle, zu oxidativem Stress führen. Zielsetzung dieser Arbeit war es zum einen, mit Hilfe von AT1a-Rezeptor-defizienten Mäusen in vivo zu prüfen, ob die Bildung von ROS, sowie die Bildung von DNA-Schäden in der Niere und im Herzen unabhängig von einem erhöhten Blutdruck auftreten. Zum anderen sollte, ebenfalls in vivo, untersucht werden, ob eine oder beide von zwei untersuchten Isoformen der NADPH-Oxidase (Nox) für die Auslösung oxidativen Stresses in der Niere verantwortlich ist.
Zunächst wurden für den Versuch zur Überprüfung der Abhängigkeit AngII-induzierter DNA-Schäden vom Blutdruck männliche C57BL/6-Mäuse und AT1a-Knockout (KO)-Mäuse mit osmotischen Minipumpen ausgestattet, die AngII in einer Konzentrationen von 600 ng/kg min über einen Zeitraum von 28 Tagen abgaben. Zusätzlich wurde eine Gruppe von AngII-behandelten Wildtyp (WT)-Mäusen mit dem AT1-Rezeptor-Blocker Candesartan (Cand) behandelt. Während des Versuchszeitraumes fanden regelmäßige, nicht-invasive Blutdruckmessungen an den wachen Mäusen statt. In WT-Mäusen induzierte AngII Bluthochdruck, verursachte erhöhte Albumin-Level im Urin und führte zur Bildung von ROS in Niere und im Herzen. Außerdem traten in dieser Gruppe DNA-Schäden in Form von Einzel- und Doppelstrangbrüchen auf. All diese Reaktionen auf AngII konnten jedoch durch gleichzeitige Behandlung mit Cand verhindert werden. AT1a-KO-Mäuse hatten, verglichen mit WT-Kontrollmäusen, einen signifikant niedrigeren Blutdruck und normale Albumin-Level im Urin. In AT1a-KO-Mäusen, die mit AngII behandelt wurden, konnte kein Anstieg des systolischen Blutdrucks sowie kein Einfluss auf die Nierenfunktion gefunden werden. Jedoch führte AngII in dieser Gruppe zu einer Steigerung von ROS in der Niere und im Herzen. Zusätzlich wurden genomische Schäden, vor allem in Form von Doppelstrangbrüchen signifikant in dieser Gruppe induziert. Auch wenn AT1a-KO-Tiere, unabhängig von einer AngII-Infusion, keine eingeschränkte Nierenfunktion zeigten, so wiesen sie erhebliche histopathologische Schäden im Hinblick auf die Glomeruli und das Tubulussystem auf. Diese Art von Schäden deuten auf eine besondere Bedeutung des AT1aR im Hinblick auf die embryonale Entwicklung der Niere hin. Zusammenfassend beweisen die Ergebnisse dieses Experiments eindeutig, dass eine AngII-induzierte ROS-Produktion und die Induktion von DNA-Schäden unabhängig von einem erhöhten Blutdruck auftreten. Da in der AngII-behandelten AT1a-KO-Gruppe eine signifikant höhere Expression des AT1b-Rezeptors zu finden war und die Blockade von beiden Rezeptorsubtypen mit Cand zu einer Verhinderung der schädlichen Effekte durch AngII führte, scheint der AT1bR im Falle einer AT1aR-Defizienz für die Entstehung der Schäden zuständig zu sein.
Ziel des zweiten Experimentes war es, den Beitrag der Nox2 und Nox4 zum oxidativen DNA-Schaden in vivo zu untersuchen. Hierfür wurden männliche C57BL/6-Mäuse und Nox2- oder Nox4-defiziente Mäuse mit osmotischen Minipumpen ausgestattet, die AngII in einer Konzentration von 600 ng/kg min über einen Zeitraum von 28 Tagen abgaben. Im WT-Stamm und in beiden Nox-defizienten Stämmen induzierte AngII Bluthochdruck, verursachte erhöhte Albumin-Level im Urin und führte zur Bildung von ROS in der Niere. Außerdem waren in allen AngII-behandelten Gruppen genomische Schäden, vor allem in Form von Doppelstrangbrüchen, erhöht. Auch in Abwesenheit von AngII wiesen Nox2- und Nox4-defiziente Mäuse mehr Doppelstrangbrüche im Vergleich zu WT-Kontrollmäusen auf. Interessanterweise kompensieren allerdings weder Nox2 noch Nox4 das Fehlen der jeweils anderen Isoform auf RNA-Basis. Aufgrund dieser Ergebnisse schließen wir, dass bislang keine Isoform alleine für die Generierung von oxidativen DNA-Schäden in der Niere verantwortlich gemacht werden kann und dass eine Beteiligung einer weiteren Nox-Isoform sehr wahrscheinlich ist. Möglicherweise könnten aber auch andere ROS-generierende Enzyme, wie Xanthinoxidase oder Stickoxidsynthase involviert sein. Da genomische Schäden in Nieren von Nox2- und Nox4-defizienten Mäusen in Abwesenheit von AngII gegenüber den Schäden in WT-Kontrollmäusen erhöht waren, könnten die beiden Isoformen auch eine schützende Funktion im Bereich von Nierenkrankheiten übernehmen. Da dies aber bislang nur für Nox4 beschrieben ist, ist es wahrscheinlicher, dass das Fehlen von einer der beiden Isoformen eher einen Einfluss auf die Embryonalentwicklung hat. Um dies jedoch abschließend zu klären wäre es sinnvoll mit induzierbaren Knockout-Modellen zu arbeiten, bei denen mögliche entwicklungsbedingte Effekte minimiert werden können.
Schlagwörter: Salmonella , Salmonella enterica , Salmonella typhimurium , Salmonellose , Escherichia coli , Shigella , Infektion , Bakterielle Infektion , Zellkultur , HeLa-Zelle , Apoptosis , Metabolismus , Stoffwechsel , Glucose , Glucosetransport , Glucosestoffwechsel , Katabolismus , Kohlenstoff , Kohlenstoffbedarf , Kohlenstoffhaushalt , Kohlenstoffstoffwechsel , Kohlenstoff-13 , Kohlenstoffisotop Salmonella Typhimurium und enteroinvasive E. coli (EIEC) sind fakultativ intrazelluläre Bakterien aus der Familie der Enterobacteriaceae. Während erstere sich nach der Internalisierung durch eukaryotische Zellen normalerweise in einem spezialisierten Phagosom, der Salmonella-enthaltenden Vakuole (SCV), vermehren, replizieren EIEC im Zytoplasma der Wirtszellen. In der vorliegenden Arbeit wurde zunächst durch Mikroinjektion die Fähigkeit von S. Typhimurium 14028s untersucht, ebenfalls im Zytoplasma von Caco-2-Zellen replizieren zu können. Dabei wurde festgestellt, daß ein früher als S. Typhimurium 14028s WT bezeichneter Stamm eine Insertion eines Desoxythymidins an Position 76 des offenen Leserasters von rfbP trägt, einem Gen, dessen Protein an der LPS-Synthese beteiligt ist. Weiterhin synthetisierte dieser Stamm ein rauhes LPS. Aufgrund von Agglutination konnte der Rauh-Stamm nur mit geringem Erfolg mikroinjiziert werden. Hingegen lag 5 h nach der Mikroinjektion einer nicht invasiven Mutante von Salmonella mit vollständigem LPS der Anteil an Caco-2-Zellen, die mehr als 32 Bakterien enthielten, bei etwa 30 %. Der Anteil war 2-3 mal höher als bei früheren Mikroinjektionen in HeLa-Zellen. Daher wurde das Verhalten von HeLa-Zellen nach einer Infektion durch S. Typhimurium ΔsifA - einer Mutante, die aus der SCV ins Zytoplasma entkommt - untersucht. Dabei wurde festgestellt, daß die sifA-Mutante 10 h nach der Infektion die Aktivität der Caspasen 9 und 3 in HeLa-Zellen, aber nicht in Caco-2-Zellen induziert. In weiteren Versuchen wurde die Bedeutung von Glukose, Glukose-6-phosphat und Mannose als Kohlenstoffquellen für die extra- und intrazelluläre Replikation zweier Isolate enteroinvasiver E. coli und eines S. Typhimurium Stammes analysiert. Zu diesem Zweck wurden zunächst definierte Mutanten in den beiden wichtigsten Phosphoenolpyruvat-abhängigen Phosphotransferasesystemen (PTS) für die Aufnahme von Glukose und Mannose, ptsG und manXYZ, sowie im Antiporter für die Aufnahme von Glukose-6-phosphat, uhpT, konstruiert. Bei Wachstum im Minimalmedium mit Glukose als einziger C-Quelle waren die Generationszeiten aller ΔptsG- und ΔptsG, manXYZ-Mutanten im Vergleich zu den Wildstämmen deutlich verlängert. Ebenso wuchsen ΔmanXYZ-Mutanten bzw. ΔuhpT-Mutanten deutlich langsamer auf Mannose bzw. Glukose-6-phosphat. Jedoch ergaben sich hierbei Stamm-spezifische Unterschiede. So erreichte EIEC 4608-58 ΔuhpT in der stationären Phase eine ähnliche Zelldichte wie der Wildstamm in Gegenwart von Glukose-6-phosphat und eine ΔptsG, manXYZ-Mutante von S. Typhimurium 14028s konnte immer noch effizient mit Glukose wachsen. Infektionsversuche mit Caco-2-Zellen zeigten weiterhin, daß die Deletion von ptsG zu einer signifikanten Erhöhung der Adhärenz und Invasivität von EIEC 4608-58 führt, während sich die intrazellulären Generationszeiten aller hier untersuchten Mutanten kaum veränderten. Selbst die ΔptsG, manXYZ, uhpT-Dreifachmutanten der drei hier verwendeten Enterobakterien und die ΔptsG, manXYZ, glk-Mutante von S. Typhimurium 14028s konnten immer noch in Caco-2-Zellen replizieren, wenn auch mit Stamm-spezifisch verringerten Geschwindigkeiten. 13C-Markierungsexperimente mit [U-13C6]-Glukose als Substrat ergaben jedoch, daß in der Tat alle hier untersuchten enterobakteriellen Wildstämme Glukose während der Replikation in Caco-2-Zellen unter Zellkulturbedingungen verwerten. Glukose-6-phosphat, Glukonat oder Fettsäuren konnten dagegen als wichtigste Kohlenstoffquellen für das intrazelluläre Wachstum ausgeschlossen werden. EIEC 4608-58 metabolisierte Glukose jedoch weniger effizient als EIEC HN280 und schien zudem noch zusätzlich C3-Substrate aus der Wirtszelle aufzunehmen. Das Markierungsmuster zeigte einen Stamm-spezifischen Kohlenstofffluß durch Glykolyse und/oder Entner-Doudoroff-Weg, Pentosephosphatzyklus, Citratzyklus und den anaplerotischen Reaktionen zwischen PEP und Oxalacetat. Mutanten mit Deletionen in ptsG und manXYZ konnten auf alternative C3-Substrate wechseln und glichen dies durch eine erhöhte Aufnahme von Aminosäuren aus den Wirtszellen aus.