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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.
Members of the enabled/vasodilator-stimulated phosphoprotein (Ena/VASP) family are important regulators of the actin cytoskeleton dynamics. VASP functions as well as its interactions with other proteins are regulated by phosphorylation at three sites - serine157 (S157), serine239 (S239), and threonine278 (T278) in humans. cAMP- and cGMP- dependent protein kinases phosphorylate S157 and S239, respectively. In contrast, the kinase responsible for T278 was as yet unknown and identified in the first part of this thesis. In a screen for T278 phosphorylating kinases using a phospho-specific antibody against phosphorylated T278 AMP-activated protein kinase (AMPK) was identified in endothelial cells. Mutants of AMPK with altered kinase-activity modulate T278-phosphorylation levels in cells. AMPK-driven T278-phosphorylation impaired stress fiber formation and changed cell morphology in living cells. AMPK is a fundamental sensor of cellular and whole body energy homeostasis. Zucker Diabetic Fatty (ZDF) rats, which are an animal model for type II diabetes mellitus, were used to analyze the impact of phosphorylated T278 in vivo. AMPK-activity and T278-phosphorylation were substantially reduced in arterial vessel walls of ZDF rats in comparison to control animals. These findings demonstrate that VASP is a new AMPK substrate, that VASP phosphorylation mediates the effects of metabolic regulation on actin cytoskeleton rearrangements, and that this signaling system becomes down-regulated in diabetic vessel disorders in rats. In the second part of this thesis, a functional analysis of differential VASP phosphorylations was performed. To systematically address VASP phosphorylation patterns, a set of VASP phosphomimetic mutants was cloned. These mutants enable the mimicking of defined phosphorylation patterns and the specific analysis of single kinase-mediated phosphorylations. VASP localization to the cell periphery was increased by S157- phosphorylation and modulated by phosphorylation at S239 and T278. Latter phosphorylations synergistically reduced actin polymerization. In contrast, S157- phosphorylation had no effect on actin-dynamics. Taken together, the results of the second part show that phosphorylation of VASP serves as a fine regulator of localization and actin polymerization activity. In summary, this study revealed the functions of VASP phosphorylations and established novel links between signaling pathways and actin cytoskeleton rearrangement.