Refine
Has Fulltext
- yes (4)
Is part of the Bibliography
- yes (4)
Year of publication
- 2012 (4) (remove)
Document Type
- Doctoral Thesis (4)
Keywords
- Knockout <Molekulargenetik> (4) (remove)
Based on genetic association and functional imaging studies, reduced function of tryptophan hydroxylase-2 (TPH2) has been shown to be critically involved in the pathophysiology of anxiety-disorders and depression. In order to elucidate the impact of a complete neuronal 5-HT deficiency, mice with a targeted inactivation of the gene encoding Tph2 were generated. Interestingly, survival of Tph2-/- mice, the formation of serotonergic neurons and the pathfinding of their projections was not impaired. Within this thesis, I investigated the influence of 5-HT deficiency on the γ-amino butyric acid (GABA) system. The GABAergic system is implicated in the pathophysiology of anxiety disorders. Therefore, measurement of GABA concentrations in different limbic brain regions was carried out. These measurements were combined with immunohistochemical estimation of GABAergic cell subpopulations in the dorsal hippocampus and amygdala. In Tph2-/- mice GABA concentrations were increased exclusively in the dorsal hippocampus. In heterozygous Tph2+/- mice concentrations of GABA were increased in the amygdala compared to Tph2-/- and wt control mice, while the reverse was found in the prefrontal cortex. The changes in GABA concentrations were accompanied by altered cell density of GABAergic neurons within the basolateral complex of the amygdala and parvalbumin (PV) neurons of the dorsal hippocampus and by adaptational changes of 5-HT receptors. Thus, adaptive changes during the development on the GABA system may reflect altered anxiety-like and depressive-like behavior in adulthood. Moreover, chronic mild stress (CMS) rescues the depressive-like effects induced by 5-HT deficiency. In contrast, 5-HT is important in mediating an increased innate anxiety-like behavior under CMS conditions. This is in line with a proposed dual role of 5-HT acting through different mechanisms on anxiety and depressive-like behavior, which is influenced by gene-environment interaction effects. Further research is needed to disentangle these complex networks in the future.
Um eine mögliche elektrophysiologische, kardiale Ursache für den plötzlichen Tod von STIM2 Knock-Out Mäusen zu prüfen, wurde eine elektrophysiologische Charakterisierung mittels Ruhe- und Stress-EKG, telemetrischem Langzeit-EKG sowie Elektrophysiologischer Untersuchung durchgeführt. Hierbei konnte keine kardial-elektrophysiologische Grundlage für den plötzlichen Tod dieser Tiere gefunden werden.
Hey1, Hey2 and HeyL are downstream effectors of the Notch signalling pathway. Hey genes play decisive roles during embryonic development for example in cardiovascular development. However, the precise transcriptional programmes and genes, which are affected by each single Hey gene, are still poorly understood. One drawback for the analysis of Hey1, Hey2 or HeyL single gene function is that these genes are co-expressed in many tissues and share a high degree of functional redundancy. Thus, it was necessary to establish a system, which is either devoid of Hey expression, or just comprises one single Hey gene family member. For this, Hey1(fl/fl)/Hey2(-/-)/HeyL(-/-)- as well as Hey-triple- knock out (KO)-ES cells (embryonic stem cells) were generated in this work, because ES cells and their differentiation as EBs (embryoid bodies) represent a valuable tool for the in vitro analysis of embryonic developmental processes. After the establishment of Hey1(fl/fl)/Hey2(-/-)/HeyL(-/-)- and Hey-triple- KO-ES cells, it could be seen by ALP staining and pluripotency marker expression that loss of Hey expression did not affect ES cell pluripotency features. Thus, these ES cells represent bona fide ES cells and could be further used for the differentiation as EBs. Here, differences in gene expression between Hey1(fl/fl)/Hey2(-/-)/HeyL(-/-)- and Hey-triple- KO-ES cells (after the loss of Hey1) could be observed in realtime-RT-PCR analysis for the endodermal marker AFP as well as for neural and myogenic markers in d10 EBs. However, the establishment of inducible Hey1, Hey2 or HeyL ES cell lines will be essential to confirm these findings and to search for novel Hey target genes. To get further insight into the mode of Hey action, the analysis of Hey interaction partners is necessary. One such binding partner, the Bre protein, has previously been found in a yeast-two-hybrid screen. Bre has been described to be a member of two distinct complexes (i.e. the nuclear BRCA1-A complex with a function in DNA damage response and the cytoplasmic BRISC complex), to directly interact with the TNF-receptor and Fas and to interfere with apoptotic signalling. The Hey-Bre interaction could be further corroborated in this work; yet, it was not possible to narrow down the interaction site of Bre with Hey1. It rather seems that non-overlapping parts of the Bre protein may bind to Hey. This interaction may be direct– pointing to more than one interaction site inside the Bre protein – or via a common binding partner such as the endogenous Bre protein itself. Besides the interaction studies, functional assays were performed for a more detailed characterisation of Hey1 and Bre interaction. Here, it could be shown that Hey1 over-expression did not have any influence on Bre sub-cellular localisation. Interestingly, it could be demonstrated that Bre positively interfered with Hey1 repressive function in luciferase assays at three of four promoters analysed. Moreover, interaction with Bre seems to lead to a stabilisation of Hey1. As Bre has been described to modulate the E3-ligase activity intrinsic to the BRCC complex it was analysed whether Bre over-expression results in an ubiquitination of Hey1. Yet, this could not be observed in the present work. Furthermore, an interaction of Bre with ubiquitinated proteins could not be demonstrated in an ubiquitin binding assay. To obtain a better insight into Bre function, Bre LacZ gene trap-ES cells and animals were generated. However, realtime-RT-analyses revealed that these cells and mice did not show a loss of Bre expression on mRNA level indicating that insertion mutagenesis did not occur as expected. However, embryos derived from these mice could nevertheless be used for the detection of tissues with Bre expression by β-galactosidase staining. Bre deficiency on mRNA levels was only achieved after the deletion of the floxed exon 3 resulting in the generation of Bre del-mice. Bre del-mice were fertile and without any obvious phenotype and they were used for the generation of Bre del- and wt-MEFs (murine embryonic fibroblasts). Characterisation of these cells showed that proliferation was not affected after loss of Bre (neither under normal nor under stress conditions). However, loss of Bre notably resulted in a reduction in the BRCA1 DNA damage response, in a slightly increased sensitivity towards apoptosis induction by FasL treatment and in an increase in the K63-poly-ubiquitin content in Bre del-cytoplasmic fractions, probably linked to a change in the BRISC de-ubiquitinase activity. Even though these results have the same tendencies as observed in former studies, the effects in the present work are less striking. Further studies as well as intercrossing of Bre del- to Hey KO-animals will be necessary to further understand the functional relevance of Hey and Bre interaction.
The actin cytoskeleton is essential for many cellular functions, such as the regulation of cell morphology, cell migration and vesicle transport processes. The functional diversity of actin structures is reflected in a variety of distinct molecular mechanisms regulating the polymerization of actin filaments. The spontaneous polymerization of actin however is inhibited, by both the instability of small actin oligomers and by actin monomer binding proteins, which prevent the formation of such oligomers. Actin nucleation factors help to overcome this kinetic barrier of filament initiation and are essential for the generation of novel actin filaments at specified subcellular compartments. Spir proteins are the founding members of the novel class of WH2 domain containing actin nucleation factors. They initiate actin polymerization by binding of actin monomers to four WH2 domains in the central part of the protein. Despite their ability to nucleate actin polymerization in vitro by themselves, Spir proteins form a regulatory complex with the distinct actin nucleators of the formin subgroup of formins. Spir functions in the regulation of vesicular originated filamentous actin structures, vesicle transport processes and the assembly of the cleavage furrow during asymmetric meiotic cell divisions. The mammalian genome encodes two spir genes, spir-1 and spir-2. The corresponding proteins have an identical structural array and share a high degree of homology. In order to elucidate the Spir function in developing and adult mouse tissues, the yet unknown expression of the mouse spir-2 gene was addressed. Real-time PCR analysis revealed highest expression of spir-2 in oocytes, the brain, throughout the gastrointestinal tract, testis and kidney of adult mice. In situ hybridizations were performed to substantiate the cellular nature of spir gene expression. During embryogenesis in situ hybridizations show spir-2 to be expressed in the developing nervous system and intestine. In adult mouse tissues highest expression of spir-2 was detected in the epithelial cells of the digestive tract, in neuronal cells of the nervous system and in spermatocytes. In contrast to the more restricted expression of the mouse spir-1 gene, which is mainly found in the nervous system, oocytes and testis, the data presented here show a distinct and broader expression pattern of the spir-2 gene and by this support a more general cell biological function of the novel actin nucleators. In order to address the function of Spir proteins in the developing and adult nervous system, Spir-1 deficient mice were generated by a gene trap method. Spir-1 deficient mice are viable and provide a perfect tool to address the neurobiological function of the Spir-1 protein. Analyses of primary cortical neurons from Spir-1 deficient mice revealed a specific reduction of dendritic branchpoints and are the first description of a neuronal Spir-1 function. Further, a transgenic mouse line (thy1-GFP-M) was employed that expresses the green fluorescent protein (GFP) under the control of neuron specific elements from the thy1 promoter. GFP is thereby expressed in only a subset of neurons and labels the neurons in their entirety. Spir-1 deficient mice carrying the GFP transgene were generated and analyzed. It was found that Spir-1 deficient mice exhibit a reduced number of dendritic spines in the entorhinal cortex compared to wildtype littermates. All together this study gives novel information about the cell biological function of Spir and provides insights how cytoskeletal functions structure the mammalian neuronal network.