Global ETD Search

41	Function of Nck-1 adaptor protein as modulator of elF2alpha phosphorylation by specific elF2alpha kinases and PKR activity Cardin, Eric. January 2008 (has links) No description available. Serine -- metabolism. Oncogene Proteins -- physiology. eIF-2 Kinase -- metabolism.
42	The role of the Gab family of docking proteins in Met mediated membrane ruffle formation / Frigault, Melanie M. (Melanie Mae), 1979- January 2008 (has links) No description available. Epithelial Cells -- cytology. Cell Membrane -- metabolism. Cell Shape.
43	Trafficking of lysosomal proteins via the sortilin sorting receptor Canuel, Maryssa. January 2007 (has links) No description available. Lysosomes -- enzymology. RNA, Small Interfering -- genetics. Receptor, IGF Type 2 -- metabolism. Cathepsins -- metabolism.
44	Biochemická a funkční charakterizace nového transmembránového adaptorového proteinu NVL / Biochemická a funkční charakterizace nového transmembránového adaptorového proteinu NVL Vonková, Ivana January 2010 (has links) In T cells, signalling events initiated at the immunological synapse by T cell receptor (TCR) have been already thoroughly studied. In contrast, signalling pathways involved in MHCII-mediated signal transduction on the APC side of this structure are still rather poorly understood. Transmembrane adaptor proteins (TRAPs) are a class of proteins with an essential role in signalling triggered by TCR and other immunoreceptors. So far no TRAPs involved in MHCII signalling have been identified. In this work a new TRAP, highly enriched in the immunological synapse in APCs is described and termed Nvl. Nvl is expressed exclusively in professional antigen presenting cells - B cells, monocytes/macrophages and dendritic cells, and the level of its expression positively correlates with the expression of MHCII. Nvl is present in tetraspanin microdomains and together with tetraspanins it is localized to the polarized structures of the cell, including uropod, cleavage furrow, and, most interestingly, the immunological synapse. The presence in the immunological synapse indicates possible role for Nvl in MHCII- mediated signal transduction. Indeed, Nvl becomes tyrosine-phosphorylated after stimulation via MHCII, although strong phosphorylation has also been observed after FcγR stimulation or treatment with...
45	Expression of the formin Daam 1 in pyramidal neurons of the hippocampus affects spine morphology Salomon, Steven. January 2006 (has links) Formins, also known as formin homology (FH) proteins, are involved in a wide range of actin-mediated processes. The Diaphanous-related formin Daam1 (Dishevelled-associated activator of morphogenesis) interacts with the PDZ domain protein Dishevelled, and is required to establish planar cell polarity in Xenopus. Through a yeast two-hybrid screen, I characterized a PDZ-mediated interaction between the C-terminus of Daam1 and the PDZ domains 456 of GRIP1. In dissociated rat hippocampal cultures, Daam1 expression was seen throughout the soma and dendrites in a punctate pattern. Furthermore, co-staining with a synaptic marker suggests that Daam1 could be associated with post-synaptic specializations. Dendritic spines are enriched with actin filaments, and based on the subcellular localization of Daam1 and the evidence that formins are involved in regulating actin polymerization, I hypothesized that Daam1 might play a role in dendritic spine morphology. In order to investigate the functional roles for Daam1, viral vectors were developed using the Semliki-Forest defective viral vector to over-express the full-length Daam1 protein and a Daam1 lacking the PDZ-binding motif. The over-expression of the full-length Daam1 in organotypic hippocampal slices showed a punctate distribution throughout the dendritic shaft, with the occasional appearance in spines, resulting in an overall increase in dendritic spine length. This suggests that formins, such as Daam1, could potentially regulate spine morphology. Adaptor Proteins, Signal Transducing. Carrier Proteins. Nerve Tissue Proteins. Pyramidal Cells. Dendritic Spines. Carrier proteins. Nerve tissue proteins. Cellular signal transduction.
46	The role of integrin-dependent cell matrix adhesion in muscle development / Jani, Klodiana. January 2009 (has links) Cell adhesion is essential to cell motility and tissue integrity and is regulated by the Integrin family of transmembrane receptors. Integrin binds to ligand extracellularly and provide anchor to the intracellular cytoskeleton via adhesion scaffolding proteins. In order to link cell to the surrounding matrix Integrin needs to be activated. Intracellular activation signals induce perturbations in Integrin cytoplasmic domain that are translated into a conformational change in extracellular region for high affinity ligand binding. Integrin engagement by matrix, in turn, triggers the assembly of adhesion complexes. Such early adhesions promote cytoskeletal organization with subsequent contractile activity that exerts forces against initial Integrin-matrix adhesions. In response to force, Integrin strengthens the interaction with matrix through its clustering and successive recruitment of additional adhesion components. These bidirectional regulatory loops mediated by such interactions are largely dependent on the unique function of Integrin adhesion components. / We demonstrate a novel role for the PDZ/LIM domain protein Zasp as a core component of Integrin adhesions. Specifically, Zasp colocalizes with Integrins at focal adhesion in cultured cells and myotendinous junctions in Drosophila embryos. In both cases elimination of Zasp modifies Integrin function causing consequently defects in cell spreading and muscle attachment. Zasp supports Integrin adhesion to the extracellular matrix that is required to withstand tensile forces exerted during cell spreading and muscle contraction. Furthermore, we found that the distribution of Zasp in muscle Z-lines is essential to orchestrate the cross-linking of alpha-Actinin and Actin filaments. Disruption of Zasp leads to loss of muscle cytoarchitecture, pointing to a larger role for Zasp in sarcomere assembly. Finally, we demonstrate that Zasp, in addition to alpha-Actinin, physically interacts with the Integrin- and Actin-bound cytoskeletal protein Talin. / Collectively, our results point to a dual role for Zasp as a structural scaffold. First it regulates Integrin adhesion to the extracellular matrix by interacting with the head domain of Talin at the myotendinous junctions. Second, Zasp controls sarcomere assembly by tethering the presarcomeric alpha-Actinin component to the tail domain of Talin. Zasp finding as a crucial adhesion component provides further insights on the mechanism underlying Integrin-mediated adhesion. Striated muscle -- Metabolism. Integrins -- Metabolism. Cell adhesion. Muscle, Skeletal -- metabolism. Integrins -- metabolism. Drosophila Proteins -- metabolism. Carrier Proteins -- metabolism. Cell Adhesion -- physiology.
47	Localized calcineurin controls L-type Ca²⁺ channel activity and nuclear signaling / Oliveria, Seth F. January 2008 (has links) Thesis (Ph.D. in Neuroscience) -- University of Colorado Denver, 2008. / Typescript. Includes bibliographical references (leaves 110-125). Online version available via ProQuest Digital Dissertations.
48	PI(4)-dependent recruitment of clathrin adaptors to the trans-Golgi Network Wang, Jing. January 2005 (has links) (PDF) Thesis (Ph. D.) -- University of Texas Southwestern Medical Center at Dallas, 2005. / Vita. Bibliography: 106-116.
49	Regulation of Cell Polarization and Map Kinase Signaling in the Saccharomyces Cerevisiae Pheromone Response Pathway: a Dissertation Strickfaden, Shelly Catherine 13 March 2007 (has links) Exposure to external stimuli promotes a variety of cellular responses including changes in morphology, gene expression and cell division status. These responses are promoted by signaling pathways composed of modules that are conserved from lower to higher eukaryotes. In Saccharomyces cerevisiae response to the external stimuli provided by mating pheromone is governed by the pheromone response pathway. This pathway is composed of a G protein coupled receptor/heterotrimeric G protein (Gαβγ) module and a MAP kinase cascade. Activation of this pathway allows the heterotrimeric G protein βγ dimer (Gβγ) to recruit polarity proteins to promote changes in cell morphology and to activate signaling through the MAP kinase cascade. Here we investigate the regulation of these pheromone-induced responses. We first examine how an asymmetric polarization response is generated. Normally, a gradient of pheromone serves as a spatial cue for formation of a polarized mating projection, but cells can still polarize when pheromone is present uniformly. Here we show that an intact receptor/Gαβγ module is required for polarization in response to both a gradient and uniform concentration of pheromone. Further investigation into regulation of Gβγ by Gα revealed that the two interaction interfaces between Gα and Gβ have qualitatively different roles. Our results suggest that one interface controls signaling whereas the other governs coupling to the receptor. Overall our results indicate that communication between the receptor and Gαβγ is required for proper polarization. We then examine how G1 CDKs regulate MAP kinase signaling. Response to pheromone is restricted to the G1 stage of the cell cycle. Once cells commit to a round of division they become refractory to mating pheromone until that round of division is complete. One contributor to this specificity involves inhibition of signaling through the MAP kinase cascade by G1 CDKs, but it was not known how this occurs. Here, we show that the MAP kinase cascade scaffold Ste5 is the target of this inhibition. Cln/CDKs inhibit signaling by phosphorylating sites surrounding a small membrane-binding domain in Ste5, thereby disrupting the membrane localization of Ste5. Furthermore, we found that disrupting this regulation allows cells to arrest at an aberrant non-G1 position. Our findings define a mechanism and a physiological benefit for restricting pheromone-induced signaling to G1. This thesis describes findings related to generation of an asymmetric polarization response, heterotrimeric G protein function, and coordination of differentiation signaling with cell division status. Lessons learned here might be applicable to the regulation of polarization and differentiation responses in other systems as the signaling modules are conserved. Adaptor Proteins Signal Transducing G1 Phase MAP Kinase Signaling System Mitogen-Activated Protein Kinases Saccharomyces cerevisiae Saccharomyces cerevisiae Proteins Amino Acids, Peptides, and Proteins Enzymes and Coenzymes Fungi
50	Requirement and Function of Hippo Pathway Signaling in the Mammalian Gastrointestinal Tract: A Dissertation Cotton, Jennifer L. 21 October 2016 (has links) In cancer, aberrant activation of developmental signaling pathways such as the Hippo Pathway has been shown to drive proliferation and invasion of cancer cells. Therefore, understanding the normal function of the Hippo Pathway during embryonic development can provide critical insight into how aberrant activity contributes to tumorigenesis. This dissertation explores the role of the Hippo Pathway members YAP and TAZ in gastrointestinal (GI) development and tumorigenesis. I use mouse genetics to systematically dissect the roles of YAP/TAZ in the endoderm-derived gastrointestinal epithelia and mesoderm-derived gastrointestinal mesenchyme during mammalian development. In the GI epithelium, I demonstrate that YAP/TAZ are dispensable for development and homeostasis. However, YAP/TAZ are required for Wnt pathway-driven tumorigenesis. I find that YAP/TAZ are direct transcriptional targets of Wnt/TCF4 signaling. In the GI mesenchyme, I describe a previously unknown requirement for YAP/TAZ activity during mammalian GI development. YAP/TAZ are involved in normal GI mesenchymal differentiation and function as transcriptional co-repressors in a progenitor cell population. In this way, YAP/TAZ act as molecular gatekeepers prior to Hedgehog-mediated differentiation into smooth muscle cells. This work unveils a previously unknown requirement for Hippo pathway signaling in the mammalian GI tract and a novel mechanism wherein YAP/TAZ function as transcriptional co-repressors to maintain a mesenchymal progenitor cell population. Gastrointestinal Tract Neoplastic Cell Transformation Mesenchymal Stromal Cells Phosphoproteins Signal Transducing Adaptor Proteins Transcription Factors Protein-Serine-Threonine Kinases Hippo Pathway Mammals Cancer Biology Cell Biology Developmental Biology

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