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Membrane binding properties of Disabled-2Alajlouni, Ruba 10 May 2011 (has links)
Disabled-2 (Dab2) is an adapter protein that interacts with cell membranes and it is involved in several biological processes including endocytosis and platelet aggregation. During endocytosis, the Dab2 phosphotyrosine-binding (PTB) domain mediates protein binding to phosphatidylinositol 4,5-bisphosphate (PIP2) at the inner leaflet of the plasma membrane and helps co-localization with clathrin coats. Dab2, released from platelet alpha granules, inhibits platelet aggregation by binding to the °IIb? integrin receptor on the platelet surface through an Arg-Gly-Asp (RGD) motif located within the PTB domain. Alternatively, Dab2 binds sulfatides on the platelets surface, and this binding partition Dab2 in two pools (sulfatide and integrin receptor-bound states), but the biological consequences of lipid binding remain unclear. Dab2 binds sulfatides through two basic motifs located on its N-terminal region including the PTB domain (N-PTB). We have characterized the binding of Dab2 to micelles, which are widely used to mimic biological membranes. These micellar interactions were studied in the absence and presence of Dab2 lipid ligands, sulfatides and PIP2. By applying multiple biochemical, biophysical, and structural techniques, we found that whereas Dab2 N-PTB binding to PIP2 stabilized the protein but did not contribute to the penetration of the protein into micelles, sulfatides induced conformational changes and facilitated penetration of Dab2 N-PTB into micelles. This is in agreement with previous observation that sulfatides, but not PIP2, protect Dab2 N-PTB from thrombin cleavage. By studying the mechanism by which Dab2 targets membranes, we will have the opportunity to manipulate its function in different lipid-dependent biological processes. / Master of Science
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Biochemical and Biophysical Studies of Human SUR1 NBD1, Rat SUR2A NBD2 and the Role of the C-terminal Extension in Rat SUR2A NBD1Alvarez, Claudia Paola 18 March 2013 (has links)
SUR2A-mediated regulation of KATP channels is affected by residues belonging to the C terminus of the first nucleotide binding domain (NBD1). We studied the C-terminal region of NBD1 by comparing experiments using NBD1 S615-D914 and NBD1 S615-K972 constructs to studies of NBD1 S615-L933 also performed in our laboratory. Our NMR data suggests that the C-terminal region of NBD1 from residues Q915 to L933 is disordered and transiently contacts the NBD1 core, which may affect NBD1 phosphorylation. Tryptophan quenching fluorescence experiments corroborate that the Q915-L933 C-terminal tail contacts the NBD1 core. Fluorescence thermal denaturation experiments suggest that NBD1 S615-D914 has a higher affinity for MgATP compared with NBD1 S615-L933, implying that the C-terminal tail varies MgATP binding.
Additional experiments were performed to identify soluble constructs of hSUR1 NBD1 and rSUR2A NBD2 that would allow detailed biophysical studies of these domains. Some of the constructs studied showed improved solubility and stability.
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Biochemical and Biophysical Studies of Human SUR1 NBD1, Rat SUR2A NBD2 and the Role of the C-terminal Extension in Rat SUR2A NBD1Alvarez, Claudia Paola 18 March 2013 (has links)
SUR2A-mediated regulation of KATP channels is affected by residues belonging to the C terminus of the first nucleotide binding domain (NBD1). We studied the C-terminal region of NBD1 by comparing experiments using NBD1 S615-D914 and NBD1 S615-K972 constructs to studies of NBD1 S615-L933 also performed in our laboratory. Our NMR data suggests that the C-terminal region of NBD1 from residues Q915 to L933 is disordered and transiently contacts the NBD1 core, which may affect NBD1 phosphorylation. Tryptophan quenching fluorescence experiments corroborate that the Q915-L933 C-terminal tail contacts the NBD1 core. Fluorescence thermal denaturation experiments suggest that NBD1 S615-D914 has a higher affinity for MgATP compared with NBD1 S615-L933, implying that the C-terminal tail varies MgATP binding.
Additional experiments were performed to identify soluble constructs of hSUR1 NBD1 and rSUR2A NBD2 that would allow detailed biophysical studies of these domains. Some of the constructs studied showed improved solubility and stability.
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