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Many arthropods and vertebrates can cling to surfaces using adhesive pads on their legs. These pads are either smooth and characterised by a specialised, soft cuticle or they are hairy, i.e. densely covered with flexible adhesive setae. Animals climbing with adhesive organs are able to control attachment and detachment dynamically while running. The detailed mechanisms of how tarsal pads generate adhesive and frictional forces and how forces are controlled during locomotion are still largely unclear. The aim of this study was to clarify the attachment mechanism of smooth adhesive pads as present in many insects and tree frogs. To understand the function of these fluid-based adhesive systems, I characterized their performance under standardized conditions. To this end, experiments were conducted by simultaneously measuring adhesion, friction, and contact area in single adhesive pads. The first result of this study showed that friction in stick insect attachment pads is anisotropic: Attachment pads regularly detached when slid away from the body. Further analyses of "immobilized" arolia revealed that this anisotropy is not caused by an increased shear stress in the proximal direction, but by the instability of the tarsus when pushed distally. In the second part of this study, I analysed the role of the pad secretion present in insects and tree frogs. In stick insects, shear stress was largely independent of normal force and increased with velocity, seemingly consistent with the viscosity effect of a continuous fluid film. However, measurements of the remaining force two minutes after a sliding movement showed that adhesive pads could sustain considerable static friction in insects and tree frogs. Repeated sliding movements and multiple consecutive pull-offs of stick insect single legs to deplete adhesive secretion showed that on a smooth surface, friction and adhesion strongly increased with decreasing amount of fluid in insects. In contrast, stick insect pull-off forces significantly decreased on a rough substrate. Thus, the secretion does not generally increase attachment but does so only on rough substrates, where it helps to maximize contact area. When slides with stick insect arolia were repeated at one position so that secretion could accumulate, sliding shear stress decreased but static friction remained clearly present. This suggests that static friction in stick insects, which is biologically important to prevent sliding, is based on non-Newtonian properties of the adhesive emulsion rather than on a direct contact between the cuticle and the substrate. % Analogous measurements in toe pads of tree frogs showed that they are also able to generate static friction, even though their pads are wetted by mucus. In contrast to the mechanism proposed for insects, static friction in tree frogs apparently results from the very close contact of toe pads to the substrate and boundary lubrication. In the last section of this study, I investigated adhesive forces and the mode of detachment by performing pull-off measurements at different velocities and preloads. These experiments showed that preload has only an increasing effect on adhesion for faster pull-offs. This can be explained by the viscoelastic material properties of the stick insect arolium, which introduce a strong rate-dependence of detachment. During fast pull-offs, forces can spread over the complete area of contact, leading to forces scaling with area. In contrast, the pad material has sufficient time to withdraw elastically and peel during slow detachments. Under these conditions the adhesive force will concentrate on the circumference of the contact area, therefore scaling with a length, supporting models such as the peeling theory. The scaling of single-pad forces supported these conclusions, but large variation between pads of different stick insects did not allow statistically significant conclusions. In contrast, when detachment forces were quantified for whole insects using a centrifuge, forces scaled with pad contact area and not with length.
Vertebrate and invertebrate visual systems exhibit similarities in early stages of visual processing. For instance, in the human brain, the modalities of color, form and motion are separately processed in parallel neuronal pathways. This basic property is also found in the fly Drosophila melanogaster which has a similar division in color- sensitive and (color blind) motion-sensitive pathways that are determined by two distinct subsets of photoreceptors (the R1-6 and the R7/8 system, respectively). Flies have a highly organized visual system that is characterized by its repetitive, retinotopic organization of four neuropils: the lamina, the medulla, the lobula and the lobula plate. Each of these consists of columns which contain the same set of neurons. In the lamina, axon bundles of six photoreceptors R1-6 that are directed towards the same point in space form columnar structures called cartridges. These are the visual sampling units and are associated with four types of first-order interneuron that receive common input from R1-6: L1, L2, L3 and the amacrine cells (amc, together with their postsynaptic partner T1). They constitute parallel pathways that have been studied in detail at the anatomical level. Little is known, however, about their functional role in processing behaviorally relevant information, e.g. for gaze stabilization, visual course control or the fixation of objects. The availability of a variety of neurogenetic tools for structure-function analysis in Drosophila allowed first steps into the genetic dissection of the neuronal circuitry mediating motion and position detection. In this respect, the choice of the effector turned out to be crucial. Surprisingly, it was found that the clostridial tetanus neurotoxin failed to block mature Drosophila photoreceptor synapses, but caused irreversible damage when expressed during their development. Therefore, the dominant-negative shibire allele shits1 which turned out to be better suited was used for blocking lamina interneurons and thereby analyzing the necessity of the respective pathways. To determine whether the latter were also sufficient for the same behavioral task, the inverse strategy was developed, based on the fact that lamina interneurons express histamine receptors encoded by the ort gene. The specific rescue of ort function in defined channels in an otherwise mutant background allowed studying their sufficiency in a given task. Combining these neurogenetic methods with the optomotor response and object induced orientation behavior as behavioral measures, the aim of the present thesis was to answer the following questions: (a) Which pathways feed into elementary motion detectors and which ones are necessary and/or sufficient for the detection of directional motion? (b) Do pathways exist which specifically mediate responses to unidirectional motion? (c) Which pathways are necessary and/or sufficient for object induced orientation behavior? Some basic properties of the visual circuitry were revealed: The two central cartridge pathways, represented by the large monopolar cells L1 and L2, are key players in motion detection. Under a broad range of stimulatory conditions, the two subsystems are redundant and are able to process motion independently of each other. To detect an impairment when only one of the pathways is intact, one has to drive the system to its operational limits. At low signal to noise ratios, i.e. at low pattern contrast or low background illumination, the L2 pathway has a higher sensitivity. At intermediate pattern contrast, both pathways are specialized in mediating responses to unidirectional motion of opposite stimulus direction. In contrast, neither the L3, nor the amc/T1 pathway is necessary or sufficient for motion detection. While the former may provide position information for orientation, the latter has a modulatory role at intermediate pattern contrast. Orientation behavior turned out to be even more robust than motion vision and may utilize a less sophisticated mechanism, as it does not require a nonlinear comparison of signals from neighboring visual sampling units. The position of objects is processed in several redundant pathways, involving both receptor subsystems. The fixation of objects does not generally require motion vision. However, motion detection improves the fixation of landmarks, especially when these are narrow or have a reduced contrast.
Aggression is a strikingly multi-faceted phenomenon occurring in vertebrates as well as in invertebrates. Despite its omnipresence, the neuronal basis of aggressive behaviours is yet barely understood. Many studies however, imply a role for biogenic amines in aggression. This PhD project aimed at contributing to the understanding of the neuronal correlates of aggression, with a main focus on the biogenic amine octopamine, using Drosophila melanogaster as the model system. In Drosophila, agonistic encounters of males and females are composed of a variety of both offensive and defensive components, some of which are displayed more often in one sex than in the other. To simplify analysis and to standardize evaluation, I chose to focus on a single indicator of aggression: the lunge, a striking feature unique to Drosophila male aggression. By evaluating the lunge I developed in cooperation with Andreas Eckart for the first time an automated, video-based analysis of Drosophila male aggression. The present software program gives the number of lunges for each fly in a certain time interval. In addition, it provides information such as the distance the fly walked and his size among others. In combination with a second software program that we developed, aggressive interactions between two male Drosophila melanogaster of a genotype of choice can now be registered either completely automatically or if preferred semi-automatically. Using these softwares, I demonstrate that (1) body size differences of 8% and higher influence the outcome of a fight in favour of the larger male; (2) walking activity alters lunge frequency with more lunges performed by more active pairs of males; (3) flies mutant for the white gene, one member of the ABC transporter family in Drosophila, are profoundly impaired in aggression, an effect that is partially due to reduced visual performance. (4) Either knocking-down white in various brain regions or chemically ablating the mushroom body located in the central brain by deleting its neuroblast precursors diminishes aggression, indicating that integrity of various neural circuits/brain regions is required for wild-type aggression to occur. Furthermore, I show that (5) flies lacking octopamine signalling but having altered tyramine signalling display hardly any lunge. A quantitative high-speed analysis revealed that lunge execution is almost indistinguishable from wild-type males. The results from the experiments in which octopamine levels and/or tyramine levels were restored suggest that an elaborate pattern of octopamine levels in time and space is required to enable flies to express wild-type aggressive behaviour.
Neural crest cells and sensory neurons are two prominent cell populations which are induced at the border between neural and non-neural ectoderm during early vertebrate development. The neural crest cells are multipotent and highly migratory precursors that give rise to face cartilage, peripheral neurons, glia cells, pigment cells and many other cell types unique to vertebrates. Sensory neurons are located dorsally in the neural tube and are essential for sensing and converting environmental stimuli into electrical motor reflexes. In my PhD thesis, I obtained novel insights into the complex processes of cell induction at the neural plate border by investigating the regulation and function of mdkb in zebrafish. First, it was possible to demonstrate that mdkb expression is spatiotemporally correlated with the induction of neural crest cells and primary sensory neurons at the neural plate border. Second, it became evident that the expression of mdkb is activated by known neural crest cell inducing signals, like Wnts, FGFs and RA, but that it is independent of Delta-Notch signals essential for lateral inhibition. Knockdown experiments showed that mdkb function is necessary for induction of neural crest cells and sensory neurons at the neural plate border, probably through determination of a common pool of progenitor cells during gastrulation. The present study also used the advantages of the zebrafish model system to investigate the in vivo function of all midkine gene family members during early brain development. In contrast to the situation in mouse, all three zebrafish genes show distinct expression patterns throughout CNS development. mdka, mdkb and ptn expression is detected in mostly non-overlapping patterns during embryonic brain development in the telencephalon, the mid-hindbrain boundary and the rhombencephalon. The possibility of simultaneously knocking down two or even three mRNAs by injection of morpholino mixtures allowed the investigation of functional redundancy of midkine factors during brain formation. Knockdown of Midkine proteins revealed characteristic defects in brain patterning indicating their association with the establishment of prominent signaling centers such as the mid-hindbrain boundary and rhombomere 4. Interestingly, combined knockdown of mdka, mdkb and ptn or single knockdown of ptn alone prevented correct formation of somites, either by interfering with the shifting of the somite maturation front or interferance with cell adhesion in the PSM. Thus, Ptn was identified as a novel secreted regulator of segmentation in zebrafish.
B cells play diverse roles in the immunopathogensis of autoimmune diseases several approaches targeting B cell directly or indirectly are in clinical practice in the treatment of autoimmunity. In this regard, temporal B cell depletion by rituximab (anti CD20 antibody) is being appreciated and gaining more importance in recent years. To date, little is known about the regeneration profile of B cells following B cell depletion. We wanted to investigate the early replenishing B cells and examine the dynamic changes in the repertoire. we studied the immunoglobulin receptor (IgR) modulation of Ig-VH4 genes as representative of the heavy chain family. Five patients were included in the study and therapy induced alterations were assessed. Three time points namely before therapy, early regeneration phase (ERP- the early time point during regeneration where just above 1% B cells were found in the peripheral lymphocyte pool) and later regeneration phase (LRP- which commenced 2-3 months following ERP) were chosen. In three patients (A-C), Ig-VH4 genes were amplified from total genomic DNA during the above-mentioned all time points and in another two patients (D and E), Ig genes during ERP were studied by single cell amplification technique. Firstly, B cell regeneration followed the characteristic regeneration pattern as reported by several groups, with a predominant circulation of CD38hi expressing plasma cells and immature B cells in the ERP. During LRP, the proportion of these cells reduced relatively and the levels of naïve B cells rose gradually. On a molecular level, Ig-VH4 variable gene usage prior and post B cell depletion was determined and it was noticed that a diverse set of Ig-VH4 genes were employed in the repertoire before and after therapy. Mini gene segments such as VH4-34 and VH-4-39, which were reported to be connected with autoimmunity, were over expressed in the B cell repertoire before therapy. Profound changes were noticed in the early reemerging repertoire with a relatively increased population of intensely mutated B cells. These B cells acquired >=9 mutations in the Ig genes. Immunophenotyping with specific surface markers revealed that these highly mutated B cells evolve from the isotype-switched memory compartment especially the plasma cells. To support the hypothesis that the highly mutated B cells observed during ERP were plasma cells we carried out single cell amplification of individual plasma cells in another two patients during ERP and compared the mutational load, which remained similar. Actually plasma cells do not express CD20 on their surface and are not eliminated by rituximab therapy. However they were not observed in the peripheral blood following B cell depletion. The earliest time point when plasma cells are found again in peripheral circulation is the early recovery period (ERP). Therefore, it was intriguing to ascertain if the plasma cells were also modulated by rituximab therapy although they were not directly targeted by the therapy. We investigated if there is a therapy mediated mutational modulation of the plasma cells though these are not directly targeted by the therapy. We examined the confinement of mutations to the pre-defined RGYW/WRCY hotspot motifs (R=purine, Y=pyrimidine, W=A/T) in the plasma cells, which provides information on the involvement of T cells in B cell somatic hypermutation (SHM). Plasma cells before rituximab manifested the characteristics of active disease, which was revealed by restricted mutational targeting to the RGYW/WRCY motifs. The reemerging plasma cells during ERP had an increased targeting of the RGYW/WRCY motifs which indicated for a more pronounced T cell mediated B cell mutations which is the scenario observed in the healthy subjects. To further support the hypothesis of rituximab-mediated plasma cell modulation, we delineated the replacement to silent mutations ratio (R/S) in the hypervariable regions (CDRs) of the plasma cell Ig sequences. Within our study, the mean R/S ratio in the plasma cell CDRs of the patient group was relatively low (1.87) before rituximab treatment and interestingly this ratio increased significantly in the recirculating plasma cells to values of 2.67 and 3.60 in ERP and LRP status respectively. The increase in R/S ratios in reemerging plasma cells can be interpreted as a shaping of the Ig-repertoire by positive antigen selection as seen in healthy individuals. To conclude, our study demonstrates temporal B cell depletion by rituximab therapy seems to modulate also the plasma cell compartment, which is not directly targeted by the therapy. Modulation of plasma cells in RA could be also used as a potential biomarker in studying the effective response in RA treatment. This needs to be further explored to gain deeper insights into the underlying processes, which may be influenced by future therapies.
The process of sex-determination can be better understood through examinations of developing organs and cells, which are involved in the formation of undifferentiated gonad. This mechanisms show in fish a broad variety, ranging from hermaphroditism to gonochorism and environmental to genetic sex determination. Hormones and abiotic factors such as temperature and pH can influence teleost development and reproductive traits. These factors are vulnerable to pollutants and climate changes. Therefore, it is important to examine gonad development and sex-determination/differentiation in teleost fish. Teleost fish are the largest known group of vertebrates with approximately 25,000 species and are used for such kind of examinations as model organisms. Recently, in Oryzias latipes (medaka), dmrt1bY (or dmy), a member of the Dmrt gene family, has been described as testis-determining gene. However, this gene is not the universal master sex-determining gene in teleost fish. Although dmrt1bY is present in the most closely related species of the genus, namely Oryzias curvinotous, it is absent from other Oryzias species, like Oryzias celebensis, and other fish. During my thesis, I studied gonad development in medaka and in the closely related species Oryzias celebensis. Germ cell specification in medaka seems to be dependent on maternally provided cytoplasmatic determinants, so called germ plasm. Nanos and vasa are such germ cell specific genes. In zebrafish they are asymmetrically localized in the early embryo. I have shown that nanos mRNA is evenly distributed in the early embryo of medaka. A similar pattern has been already described for the medaka vasa homolog, olvas. This suggests differences in PGC specification in zebrafish and medaka. Further, the vasa homolog was isolated and the expression pattern examined in O. celebensis. The results show that it can be used as a germ cell specific marker. Additionally, the primordial germ cell migration in O. celebensis was followed, which is similar to medaka PGC migration. Primordial germ cell migration in vertebrates is dependent on the chemokine stromal cell-derived factor 1 (Sdf-1). Medaka has two different sdf-1 genes, sdf-1a and sdf-1b. Both genes are expressed in the lateral plate mesoderm (LPM). During late embryonic development, I could show that sdf-1a is expressed in newly formed somites and not longer in the LPM. Sdf-1b expression persisted in the posterior part of the lateral plate mesoderm in the developing gonad. In terms of early and late functions, this suggests subfunctionalization of sdf-1a and sdf-1b. In “higher” vertebrates, genes that are involved in the process of gonad development have been studied in detail, e.g. Wt1, Sox9, and Amh. I have analyzed the expression pattern of wt1 and sox9 co-orthologs and amh. In both, the medaka and O. celebensis, wt1a transcripts were localized in the LPM and its expression was similar to sdf-1a gene expression in medaka. Wt1b expression was restricted to the developing pronephric region. During later embryonic development, wt1a is specifically expressed in the somatic cells of the gonad primordium in both sexes. This is the first time that in fish wt1 gene expression in developing gonads has been described. Therefore, this result suggests that wt1a is involved in the formation of the bipotential gonad. Furthermore, I have analyzed the gonad specific function of the wt1 co-orthologs in medaka. I could show that a conditional co-regulation mechanism between Wt1a and Wt1b ensures PGC maintenance and/or survival. The expression of sox9 genes in medaka and sox9b in O. celebensis were detected in the somatic cells of the gonad primordium of both sexes. Additionally, I have shown that amh and amhrII in medaka are expressed in somatic cells of the gonad primordium of both sexes. This suggests that sox9b, amh and amhrII are involved in gonad development and have specific functions in the adult gonad. In O. celebensis I could detect an expression of dmrt1 already six days after fertilization in half of the embryos, which is similar to the dmrt1bY expression in medaka. Whether the expression of dmrt1 is male specific in O. celebensis is currently under investigation. Altogether, the obtained results provide new insights into gene expression patterns during the processes of gonad development. Furthermore, no differences in the expression pattern of wt1a and sox9b during gonad development between the medaka and O. celebensis could be detected. This might indicate that the genetic mechanisms during gonad development are similar in both species.
Sumoylation of transcription factors modulate their activity (either upregulating or downregulating) by altering protein-protein interactions as well as subcelluar/subnuclear localization. The transcription factor family of NFAT (Nuclear Factor of Activated T cells) plays an important role in cytokine gene regulation in T cells. Due to alternative usage of two promoters (P1 & P2), two polyadenylation sites (pA1 and pA2) and alternative splicing events, NFATc1 is expressed in six isoforms which are NFATc1/alphaA, betaA, alphaB, betaB, alphaC and betaC, where alpha and beta refer to two different 1st exons and A, B, C to the differentially spliced and extended C-termini. The short isoforms of NFATc1 (NF-ATc1/A) contain a relatively short C terminus whereas, the longer isoforms, B and C, span the extra C-terminal peptides of 128 and 246 aa, respectively. To analyze the specific biological effects of NFATc1 isoform, a yeast two hybrid screening of a human spleen cDNA library with extra C-terminal peptide of NFATc1 as a bait, was performed. At the end of the assay, the proteins involved in the sumoylation pathway such as Ubc9, PIAS1 were detected with highest frequencies and subsequently were were able to demonstrate that NFATc1 is sumoylated. The extent of sumoylation is isoform specific. While NFATc1/A, harboring only one sumoylation site, shows very weak sumoylation, the two additional sites within NFATc1/C lead to efficient sumoylation. This modification directs NFATc1/C into SUMO-1 bodies, which in turn colocalize with PML-nbs. Furthermore, sumoylated NFATc1/C recruits the transcriptional co-repressors HDAC (both class I as well as class II HDACs) which results in a significant decrease of the level of histone acetylation on the IL-2 promoter, an important NFATc1 target gene. As a consequence of this, a decrease of IL-2 production was observed, while NFATc1/C, which can no longer be sumoylated due to mutating the target lysines, exhibited dramatic elevated transcriptional potential on the IL2 promoter. This supports our finding from IL-2 promoter-driven reporter gene assay, which shows downregulation of NFATc1/C transactivation upon sumoylation. Hence, sumoylation exerts a negative effect on NFATc1 transcriptioanl activity. Immunofluorescence studies showed SUMO modification to relocate NFATc1/C also into transcriptionally inactive heterochromatin regions, demonstrated by H3K9 m3 (tri-methylated histone lysine 9) colocalization studies. Interestingly, in the absence of sumoylation, NFATc1 was partially colocalized with transcriptional hotspots in the nucleus, which might contribute to the higher transcription potentiality of the non-sumoylated NFATc1. It is important to note that, the transcriptional activity of other NFATc1 target genes (IL-13, IFN-gamma etc.) was positively upregulated upon sumoylation of NFATc1, suggesting a non-universal effect of sumoylation on NFATc1/C function. In conclusion, sumoylation directs NFATc1 into nuclear bodies where it interacts with transcriptional co-repressors and relocalize itself with heterochromatin, leading to repression of NFATc1/C-mediated transcription. Most importantly, the effect of NFATc1/C sumoylation is promoter specific. Taken together, SUMO modification alters the function of NFATc1 from an activator to a site-specific transcriptional repressor. This study unraveled a novel regulatory mechanism, which controls isoform specific NFATc1 function.
Microtubules are a fascinating component of the cellular scaffold protein network, the cytoskeleton. These hollow tubular structures are assembled of laterally associated proto-filaments containing ab-tubulin heterodimers in a head to tail arrangement. Accordingly microtubules have a defined polarity, which sets the base for the polarity of the cell. The microtubule lattice can be arranged in two conformations: In the more abundant B-lattice conformation, where the protofilaments interact laterally through a- to a- and b- to b-tubulin contacts and in the less stable A-lattice conformation, where a-tubulin interacts laterally with b-tubulin. In cells the microtubules generally contain 13 protofilaments of which usually one pair interacts in the A-lattice conformation, forming the so-called lattice seam. Microtubule dynamics and interactions are strongly regulated by micro-tubule associate proteins (MAPs). Structural investigations on MAPs and microtubule associated motor proteins in complex with microtubules have become possible in combination with modern electron microscopy (EM) and image processing. We have used biochemistry and different advanced EM techniques to study the interaction between microtubules and the MAP Mal3p in vitro. Mal3p is the sole member of the end-binding protein 1 (EB1) protein family in the fission yeast Schizosaccharomyces pombe. Previous in vivo studies have shown that Mal3p promotes microtubule growth. Our studies with high-resolution unidirectional shadowing EM revealed that Mal3p interacts with the microtubule lattice in a novel way, using binding sites on the microtubule that are different from those reported for other MAPs or motor proteins. Full-length Mal3p preferentially binds between two protofilaments on the microtubule lattice, leaving the rest of the lattice free. A case where Mal3p was found in two adjacent protofilament, revealed an A-lattice conformation on the microtubules, surprisingly indicating specific binding of Mal3p to the microtubule seam. With a lattice enhancer, in form of a b-tubulin binding kinesin motor domain, it was demonstrated that Mal3p stabilizes the seam which is thought to be the weakest part of a microtubule. Further, the presence of Mal3p during microtubule polymerization enhances the closure of protofilament sheets into a tubular organization. Cryo-EM and 3-D helical reconstruction on a monomeric microtubule binding domain of Mal3p, confirm the localization in between the protofilament and result in an accurate localization on the microtubule lattice. The results also indicate Mal3p’s capacity to influence the microtubule lattice conformation. Together, studies approached in vitro demonstrate that an EB1-family homolog not only interacts with the microtubule plus end, but also with the microtubule lattice. The structure of Mal3p interacting with microtubules reveals a new mechanism for microtubule stabilization and further insight on how plus end binding proteins are able promote microtubule growth. These findings further suggest that microtubules exhibit two distinct reaction platforms on their surface that can independently interact with selected MAPs or motors.
The internal transcribed spacer 2 (ITS2) of the ribosomal gene repeat is an increasingly important phylogenetic marker whose RNA secondary structure is widely conserved across eukaryotic organisms. The ITS2 database aims to be a comprehensive resource on ITS2 sequence and secondary structure, based on direct thermodynamic as well as homology modelled RNA folds. Results: (a) A rebuild of the original ITS2 database generation scripts applied to a current NCBI dataset reveal more than 60,000 ITS2 structures. This more than doubles the contents of the original database and triples it when including partial structures. (b) The end-user interface was rewritten, extended and now features user-defined homology modelling. (c) Other possible RNA structure discovery methods (namely suboptimal and shape folding) prove helpful but are not able to replace homology modelling. (d) A use case of the ITS2 database in conjunction with other tools developed at the department gave insight into molecular phylogenetic analysis with ITS2.
The live sciences currently undergo a paradigm shift to computer aided discoveries. Discoveries in the live sciences were historically made by either direct observation or as a result of chemical assays. Today we see a growing shift toward computer aided analysis and visualization. This gradual process happens in microscopy. Multidimensional laser scanning microscopy can acquire very complex multichannel data from fixed or live specimen. New probes such as visible fluorescent proteins let us observe the expression of genes and track protein localization. Ion sensitive dyes change intensity with the concentration of ions in the cell. The laser scanning confocal allows us to record these processes in three dimensions over time. This work demonstrates the application of software analysis to multidimensional microscopy data. We introduce methods for volume investigation, ion flux analysis and molecular modeling. The visualization methods are based on a multidimensional data model to accommodate complex datasets. The software uses vector processing and multiple processors to accelerate volume rendering and achieve interactive rendering. The algorithms are based on human visual perception and allow the observer a wide range of mixed render modes. The software was used to reconstruct the pituitary development in zebrafish and observe the degeneration of neurons after injury in a mouse model. Calicum indicator dyes have long been used to study calcium fluxes. We optimized the imaging method to minimize impact on the cell. Live cells were imaged continuously for 45 minutes and subjected to increasing does of a drug. We correlated the amplitude of calcium oscillations to increasing doses of a drug and obtain single cell dose response curves. Because this method is very sensitive and measures single cell responses it has potential in drug discovery and characterization. Microtubules form a dynamic cytoskeleton, which is responsible for cell shape, intracellular transport and has an integral role in mitosis. A hallmark of microtubule organization is lateral interactions. Microtubules are bundles by proteins into dense structures. To estimate the contribution of this bundling process, we created a fractal model of microtubule organization. This model demonstrates that morphology of complex microtubule arrays can be explained by bundling alone. In summary we showed that advances in software for visualization, data analysis and modeling lead to new discoveries.
Since the fruit fly Drosophila melanogaster entered the laboratories as a model organism, new genetic, physiological, molecular and behavioral techniques for the functional analysis of the brain rapidly accumulated. Nowadays this concerted assault obtains its main thrust form Gal4 expression patterns that can be visualized and provide the means for manipulating -in unrestrained animals- groups of neurons of the brain. To take advantage of these patterns one needs to know their anatomy. This thesis describes the Virtual Insect Brain (VIB) protocol, a software package for the quantitative assessment, comparison, and presentation of neuroanatomical data. It is based on the 3D-reconstruction and visualization software Amira (Mercury Inc.). Its main part is a standardization procedure which aligns individual 3D images (series of virtual sections obtained by confocal microscopy) to a common coordinate system and computes average intensities for each voxel (volume pixel). The VIB protocol facilitates direct comparison of gene expression patterns and describes their interindividual variability. It provides volumetry of brain regions and helps to characterize the phenotypes of brain structure mutants. Using the VIB protocol does not require any programming skills since all operations are carried out at a (near to) self-explanatory graphical user interface. Although the VIB protocol has been developed for the standardization of Drosophila neuroanatomy, the program structure can be used for the standardization of other 3D structures as well. Standardizing brains and gene expression patterns is a new approach to biological shape and its variability. Using the VIB protocol consequently may help to integrate knowledge on the correlation of form and function of the insect brain. The VIB protocol provides a first set of tools supporting this endeavor in Drosophila. The software is freely available at http://www.neurofly.de.
This thesis extends the classical theoretical work of Macevicz and Oster (1976, expanded by Oster and Wilson, 1978) on adaptive life history strategies in social insects. It focuses on the evolution of dynamic behavioural patterns (reproduction and activity) as a consequence of optimal allocation of energy and time resources. Mathematical modelling is based on detailed empirical observations in the model species Lasioglossum malachurum (Halictidae; Hymenoptera). The main topics are field observations, optimisation models for eusocial life histories, temporal variation in life history decisions, and annual colony cycles of eusocial insects.
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.
DNA microarrays have become a standard technique to assess the mRNA levels for complete genomes. To identify significantly regulated genes from these large amounts of data a wealth of methods has been developed. Despite this, the functional interpretation (i.e. deducing biological hypothesis from the data) still remains a major bottleneck in microarray data analysis. Most available methods display the set of significant genes in long lists, from which common functional properties have to be extracted. This is not only a tedious and time-consuming task, which becomes less and less feasible with increasing numbers of experimental conditions, but is also prone to errors, since it is commonly done by eye. In the course of this work methods have been developed and tested, that allow for a computerbased analysis of functional properties being relevant in the given experimental setting. To this end the Gene Ontology was chosen as an appropriate source of annotation data, because it combines human-readability with computer-accessibility of the annotations term and thus allows for a statistical analysis of functional properties. Here the gene-annotations are integrated in a Correspondence Analysis which allows to visualize genes, hybridizations and functional categories in a single plot. Due to the increasing amounts of available annotations and the fact that in most settings only few functional processes are differentially regulated, several filter criteria have been developed to reduce the number of displayed annotations to a set being relevant in the given experimental setting. The applicability of the presented visualization and filtering have both been validated on datasets of varying complexity. Starting from the well studied glucose-pathway in S. cerevisiae up to the comparison of different tumor types in human. In both settings the method generated well interpretable plots, which allowed for an immediate identification of the major functional differences between the experimental conditions [90]. While the integration of annotation data like GO facilitates functional interpretation, it lacks the capability to identify key regulatory elements. To facilitate such an analysis, the occurrence of transcription factor binding sites in upstream regions of genes has been integrated to the analysis as well. Again this methodology was biologically validated on S. cerevisiae as well human cancer data sets. In both settings TFs known to exhibit central roles for the observed transcriptional changes were plotted in marked positions and thus could be immediately identified [206]. In essence, integration of supplementary information in Correspondence Analysis visualizes genes, hybridizations and annotation data in a single, well interpretable plot. This allows for an intuitive identification of relevant annotations even in complex experimental settings. The presented approach is not limited to the shown types of data, but is generalizable to account for the majority of the available annotation data.
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.
Clonality analysis in B-Cell Chronic Lymphocytic Leukemia (B-CLL) associated with Richter's syndrome
(2006)
B-cell chronic lymphocytic leukemia (B-CLL) comprises 90% of chronic lymphoid leukemias in Western countries and patients with B-CLL have a heterogeneous clinical course. Approximately 3-5% of B-CLL patients encounter transformation to an aggressive lymphoma, mainly diffuse large B-cell lymphoma (DLBCL) or Hodgkin’s lymphoma (HL) which has been defined as Richter’s syndrome and is associated with a poor clinical outcome. The mutational status of the immunoglobulin heavy chain variable region (IgVH) gene not only implies the developmental stage at which the neoplastic transformation occurs in a given B-cell lymphoma, but also constitutes an important prognostic factor in B-CLL, since B-CLL patients with unmutated IgVH genes usually have a poor clinical outcome. Sparse molecular analyses performed in Richter’s syndrome so far suggest that it can occur in B-CLL patients carrying mutated or unmutated IgVH genes, and tumor cells in DLBCL or HL can be clonally identical to the B-CLL clone or arise as an independent, secondary lymphoma. To determine the clonal relationship between DLBCL or Hodgkin/Reed-Sternberg (HRS) cells and pre-existing B-CLL cells in a larger series, to identify the IgVH gene usage and the mutational status and to explore possible prognostic factors in B-CLL undergoing Richter’s transformation, we utilized a PCR-based GeneScan approach with subsequent sequencing of the IgVH genes. In cases with HRS/HRS-like cells laser capture microdissection (LCM) was employed to isolate these cells. In addition, a thorough morphological and immunohistochemical analysis was performed. In total, specimens from 48 patients were investigated including 40 cases of Richter’s syndrome and additional 8 cases of B-CLL cases with the presence of CD30-positive HRS-like cells. Among 40 cases of Richter’s syndrome, 34 B-CLL cases showed transformation to DLBCL and 6 cases transformed from B-CLL to HL. Sequencing was performed in 23 paired B-CLL and DLBCL cases. In 18 cases, B-CLL and DLBCL were clonally identical, whereas DLBCL developed as a clonally independent neoplasm in 5 patients. Among the clonally related pairs, 11 out of 15 cases carried unmutated IgVH genes in both the B-CLL and DLBCL component, whereas 5 of 6 B-CLL cases that showed transformation to HL carried mutated IgVH genes. HRS cells in two samples and HRS-like cells in one sample were clonally distinct from the B-CLL clone and infected by EBV, whereas one sample of HRS-like cells was related to the clone from the surrounding B-CLL cells and did not express latent membrane protein-1 (LMP1). The VH genes VH3-23, VH3-74, VH1-2 and VH3-9 were overused in B-CLL cases that transformed to DLBCL, whereas VH4-34 and VH3-48 were used in over half of the B-CLL cases with transformation to HL. Immunohistochemical staining of ZAP70 was significantly associated with unmutated IgVH genes in B-CLL cases undergoing Richter’s transformation. Clinical follow-up data could be obtained from 24 patients. The median survival times of B-CLL patients with transformation to DLBCL or HL were 7 and 21 months, respectively. No significantly different survival times were found between clonally related or unrelated cases, or between IgVH-mutated or -unmutated cases. We conclude that in Richter’s transformation, DLBCL can evolve by clonal transformation of the pre-existing B-CLL clone or occur as an independent, clonally unrelated neoplasm. In the majority of cases (78% in our series), B-CLL and DLBCL are clonally identical. In a subset of patients, however, DLBCL develops as an independent secondary neoplasm that is not clonally related to the B-CLL. Clonal transformation into DLBCL predominantly occurs in B-CLL patients with unmutated IgVH genes, whereas most B-CLL patients that show transformation to HL or CD30-positive HRS-like cells carry mutated IgVH genes. The tendency that IgVH-unmutated B-CLL transforms to DLBCL and IgVH-mutated B-CLL transforms to HL implies different transformation pathways in the two subtypes of Richter’s syndrome. In addition, important pathogenetic differences are likely to exist between DLBCL cases derived from a pre-existing B-CLL as compared to de novo DLBCL cases, since de novo DLBCL is usually characterized by mutated IgVH genes. The biased usage of IgVH genes in the two subtypes of Richter’s syndrome suggests a possible role for antigen involvement in tumorigenesis also in B-CLL cases that undergo Richter’s transformation. Finally, EBV-association in the HL variant of Richter’s syndrome occurs more frequently in clonally unrelated secondary malignancies.
Best disease, also termed vitelliform macular dystrophy type 2, VMD2, (OMIM #153700), is an autosomal dominant, early onset macular dystrophy associated with a remarkable accumulation of lipofuscin-like material within and beneath the retinal pigment epithelium (RPE). The VMD2 gene mutated in Best disease encodes a 585 amino acid putative transmembrane protein named bestrophin, and is preferentially expressed in the RPE. The protein has a complex membrane topology with 4-6 putative transmembrane domains (TMDs) and is presumably involved in Ca2+-dependent transport of chloride ions across the membrane. The vast majority of known disease-associated alterations are missense mutations nonrandomly distributed across the highly conserved N-terminal half of the protein with clusters near the predicted TMDs. The mechanism connecting Best disease pathology with the identified mutations or the Cl- channel function is not yet clear. To further elucidate the biological function of the bestrophin protein and to identify the molecular mechanisms underlying the disease, a search for interacting partners of bestrophin was performed using the GAL4-based yeast two hybrid system (Y2H). Screening of a bovine RPE cDNA library with various truncated bestrophin baits resulted in the identification of 53 putative interacting partners of bestrophin. However, verification of the interaction has excluded all candidate clones. Our comprehensive Y2H analyses suggest that bestrophin may not be suitable for traditional yeast two hybrid screens likely due to the fact that the protein is integral to the membrane and even fragments thereof may not be transported to the nucleus which is, however a prerequisite for protein interaction in the yeast system. Bestrophin belongs to a large family of integral membrane proteins with more than 100 members identified to date originating from evolutionarily diverse organisms such as mammals, insects and worms. The most distinctive feature of the bestrophin family, besides the invariant RFP (arginine-phenylalanine-proline) domain, is an evolutionarily highly conserved N-terminal region. To clarify the phylogenetic relationship among bestrophin homologues and to identify structural and functional motifs conserved across family members, a bioinformatics/phylogenetic study of the conserved N-terminal region was conducted. Phylogenetic analysis of the bestrophin homologues reveals existence of four evolutionary conserved family members in mammals, with high homology to the human VMD2, VMD2-L1 to L3 proteins. The significant level of protein sequence similarity between divergent species suggests that each of the bestrophin family members has a unique, Chapter One: Summary 2 evolutionarily conserved function and that the divergence of bestrophin into several family members occurred before the divergence of individual mammalian species.
Allergic disease are inflammatory disorders in which aberrant immune regulation occurs, and susceptible individuals mount allergen specific T helper 2 (Th2) responses, which drives disease pathology. Recent studies indicate that Th2 responses that are characteristic of allergic manifestations can be regulated by both naturally occurring CD4+CD25+ regulatory (Treg) cells and antigen-driven IL-10-secreting CD4+ regulatory T cells. Evidence is also emerging that successful Allergen specific immunotherapy (SIT) might work through the induction of IL-10-secreting regulatory T cells. In the first part of this work, I demonstrated the efficiency of allergen specific immunotherapy in the mouse model for allergic airway inflammation. Here I could show that intranasal administration of SIT abrogates allergic symptoms more efficiently, than the subcutaneous treatment. Furthermore, an IL-4/IL-13 (QY) inhibitor was used as an adjuvant for SIT, which has been demonstrated to have an anti-allergic potential, when administered prophylactically during allergic sensitization. However, the combination therapy with SIT and the inhibitory molecule QY did not show any significant enhancement in regards to all measured allergic parameters, when compared to monotherapy with SIT. These results provide the evidence, that shift from Th2 to Th1 cytokine profile might not be a key event in successful SIT. Subsequently, the investigation of immune mechanisms under successful SIT demonstrate that the increase of IL-10 secreting CD4+ T regulatory cells is associated with the suppression of airway inflammation in our mouse system, suggesting that these T cell subsets might be involved in the regulatory mechanisms of allergic disorders. In agreement with these findings is the second part of this work, where superagonistic a-CD28 mAb´s were used for the expansion of T regulatory cell subsets in our murine model for allergic airway inflammation. Here I could show, that the application of a-CD28 mAb during allergic sensitization, resulted in the establishment of a Th2 state, rather than a stimulation of a Treg cell population, supporting the Th2 promoting role of a-CD28 mAb together with TCR engagement. However, interesting findings were obtained by application of the superagonistic a-CD28 mAb in the challenge phase in established allergy. Conversely to the previous experiment, therapeutic administration of a-CD28 mAb lead to the generation of IL-10 secreting CD4+CD25+ T cell population in line with the induction of anti-allergic effects. Taking together the results of this study argue for the anti-inflammatory properties of T regulatory cells in allergic disease and highlights importance of these T cell subsets in the suppression of Th2 cell-driven response to allergen. Moreover, these observations suggest that the induction of IL-10 in vivo by T regulatory cells may represent a novel treatment strategy for allergic disorders.
Herbivorous insects are the major link between primary producers and a multitude of animals at higher trophic levels. Elucidating the causes and consequences of their distribution patterns in the "green world" is thus essential for our understanding of numerous ecological processes on multiple spatial scales. We can ask where and why a certain herbivore can be found in the landscape, within the habitat, on which plant within the habitat and finally, where on that plant. Depending on spatial scale the distribution of herbivores is shaped by different processes (fitness considerations, physiological abilities, population dynamics, dispersal behavior, history of the landscape etc.). Scaling down from fragmented landscapes to individual host plants this thesis analyzes the distribution patterns of the strictly monophagous herbivore Cassida canaliculata Laich. (Coleoptera: Chrysomelidae), which feeds and oviposits exclusively on meadow sage, Salvia pratensis L. (Lamiales: Lamiaceae), and compares it to those of the polyphagous tansy leaf beetle Galeruca tanaceti L. (Coleoptera: Chrysomelidae), which does not oviposit on its host plants, but on dry non-host structures. The specialist Cassida canaliculata depended on all spatial scales (fragmented landscape, microhabitat and host plant individual) mainly on the distribution and quality of its single host plant species Salvia pratensis, whereas enemy-free-space - i.e. avoidance of parasitism and predation of egg clutches, larvae, and pupae - seemed to influence oviposition site choice only on the scale of the host plant individual. On this spatial scale, offspring of Cassida canaliculata had a higher chance of survival on large host plant individuals, which were also preferred for oviposition by the females. In contrast, the distribution patterns of the generalist Galeruca tanaceti was shaped by the interaction with its parasitoid regarding both microhabitat choice and egg distribution within individual host plants. On the microhabitat scale, beetles could escape from their parasitoids by ovipositing into high and dense vegetation. Regarding oviposition site choice within a host plant individual, females oviposited as high as possible in the vegetation and could thus reduce both the risk of parasitism and the probability of winter mortality. The results of my thesis show that the degree of specificity of a herbivore is of central importance for the resulting egg distribution pattern on all spatial scales.