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Spatial, temporal and functional molecular architecture of the munc18-syntaxin interactionSmyth, Annya Mary January 2012 (has links)
Regulation of soluble N-ethylmaleimide-sensitive fusion protein attachment protein receptors (SNARE) mediated exocytosis is dependent upon four key proteins; the vesicular SNARE synaptobrevin, target SNAREs SNAP-25 and syntaxin and the Sec1/Munc18 (SM) protein munc18-1. Despite the munc18-1-syntaxin interaction being central to regulated vesicle exocytosis the spatial and temporal pattern of their molecular distribution and interaction in neuroendocrine and neuronal cells remains undefined. Using in vitro and molecular approaches this thesis shows that disruption of the munc18- 1-syntaxin-N-terminal interaction results in significant changes in syntaxin localisation, membrane-proximal vesicle dynamics and fusion efficiency within neuroendocrine cells. Using the super-resolution techniques Ground State Depletion-Individual molecule return (GSDIM) Microscopy and Photoactivation Localisation Microscopy (PALM) this thesis has demonstrated that the spatial distribution of single munc18-1 molecules is non-random and that few munc18-1 molecules are required for exocytosis to proceed in neuroendocrine cells. Furthermore, targeted disruption of the N-terminal interaction resulted only in a reorganisation of interaction with syntaxin with no change in the molecular spatial pattern of secretory vesicles, syntaxin or munc18-1. Single molecule imaging PALM (sptPALM) enabled the investigation of the complex spatio-temporal behaviours of single munc18-1 molecules in living neuroendocrine cells. Spatially resolved maps of single munc18-1 molecules demonstrated that munc18-1 exhibits a caged motion within areas of the plasma membrane and were found to move between molecular storage depots distinct from vesicle docking sites. To explore the precise spatial and temporal sequence of interactions between syntaxin and munc18-1 in living neurons, super-resolution imaging techniques PALM and sptPALM were employed. Two kinetically and spatially distinct populations of munc18-1 molecules co-exist within a living neuron and munc18-1 requires syntaxin to traffic efficiently in axons but not for its retention in nerve terminals. Moreover, Fluorescence Correlation Spectroscopy (FCS) revealed that the majority of munc18-1 molecules do not interact with syntaxin in nerve terminals and the diffusion rate of syntaxin is significantly slowed down upon neuronal depolarisation.
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Ras Opposite, the Drosophila Homologue of Munc18-1, is Important for Motor Axon Maintenance.Carlson, Nicole E 03 May 2011 (has links)
Amyotrophic Lateral Sclerosis (ALS) is a fatal disease characterized by the progressive degeneration of motor neurons. Although there has been some progress in the identification of genes linked to inherited cases of ALS, the etiology of this disease remains largely unknown. Clinical progression of motor neuron diseases is associated with the degeneration of the axon preceding cell death. Elucidating novel mechanisms important for motor axon maintenance will help gain greater insight into disease pathogenesis. Here, I report that mutations in ras-opposite (rop), which encodes the Drosophila homologue of mammalian Sec1/Munc18, cause progressive degeneration of motor axons while sensory axons are largely unaffected. While mutations in mammalian munc18-1 have been linked to degeneration of the spinal cord, the mechanisms by which this occurs are unknown. Using Drosophila, I found that RNAi-induced knockdown of rop leads to severe motor deficits in adult flies. In addition, I discovered that motor axon degeneration in rop mutants could be delayed by overexpression of the neuronal maintenance factor Nmnat. Interestingly, I found that Rop is localized with Nmnat at the neuromuscular junction and that Rop physically interacts with Nmnat in vivo. These data indicate a novel role for Rop in motor axon maintenance and provide insight into the pathogenesis of neurodegenerative diseases targeting motor neurons, such as ALS.
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The Role of Munc18 Proteins in Physiologic and Pathologic Exocytoses in the Pancreatic Acinar CellLam, Patrick Pak Ling 18 February 2010 (has links)
Distinct membrane fusion events in the polarized pancreatic acinar cell involve highly specific interactions between distinct sets of SNARE proteins forming exocytotic complexes, whose assembly is modulated by distinct Munc18 proteins. The Munc18 isoform responsible for these exocytotic events in the acinar cell is unknown. Here, I postulate Munc18b to regulate apical exocytosis in the acinar cell. Current dogma for the pathogenesis of acute pancreatitis, including alcoholic pancreatitis, is mis-targeting and deregulated fusion of zymogen granules with lysosomal bodies in the acinar cells. This derangement results in premature activation of proteolytic zymogens and autophagic digestion of cellular contents. I have hypothesized an alternate mechanism, which is pathologic exocytosis occurring at the basolateral plasma membrane, and further propose Munc18c to mediate this process in alcoholic pancreatitis. The aims of this thesis are to demonstrate the roles of Munc18b and Munc18c in regulated apical exocytosis and pathologic basolateral exocytosis underling alcoholic pancreatitis, respectively.
In Chapter Three, using both real-time and static imaging techniques and biochemical tools, I demonstrated that Munc18c is dissociated from the acinar basal plasma membrane (BPM) when stimulated with postprandial CCK8 preceding preincubation of acini with postprandial 20-50mM ethanol concentrations. This activated Syntaxin (Syn)-4 and SNAP-23 on the BPM to complex with VAMP proteins on the granule to form the exocytotic SNARE complex that triggered basolateral exocytosis. This molecular mechanism of pathologic basolateral exocytosis was recapitulated in an Ethanol-diet rat model of pancreatitis. In Chapter Four, I determined Munc18b to be in the apical pole of the acinar cell to appropriately bind cognate Syn-2 and Syn-3 in the apical PM and ZGs. Here, I examined the structure-function of Munc18b on amylase secretion by employing Munc18b mutants with distinct affinities to Syn-2 and Syn-3. In Chapter Five, I discovered a novel EF-hand Ca2+-binding protein called Cab45b, which binds Munc18b to regulate its membrane targeting and interactions with Syntaxins in the acinar cell in a manner that influenced Ca2+-induced amylase release.
Taken together, these studies clarify our understanding of the role of Munc18 proteins involved in regulated and pathologic membrane fusion events underlying physiologic digestive enzyme secretion and clinical alcoholic pancreatitis.
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Identification and Characterization of the Interaction between VPS33B and SNAREsPuhacz, Michael 19 December 2011 (has links)
VPS33B is a Sec1/Munc18 protein required for the biogenesis of α-granules in megakaryocytes, which give rise to platelets. Mutations in VPS33B cause arthrogryposis, renal dysfunction and cholestasis (ARC) syndrome. Platelets from ARC patients completely lack α-granules, causing a bleeding disorder. VPS33B plays a role in vesicular fusion events through its interaction with the SNARE proteins, though no such interactions have been identified. Here, it is shown that VPS33B interacts with STX6, a member of the syntaxin subfamily of SNAREs. The introduction of ARC mutations into VPS33B completely abrogated binding to STX6. Confocal microscopy studies revealed STX6 co-localizes well with markers of the α-granule biogenesis pathway. This implies a role for the interaction of VPS33B with STX6 in α-granule biogenesis. Based on the known structure of STX6 and that predicted of VPS33B, suggests a novel and unique mode of binding between VPS33B and STX6 compared to other identified SM-STX pairs.
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Identification and Characterization of the Interaction between VPS33B and SNAREsPuhacz, Michael 19 December 2011 (has links)
VPS33B is a Sec1/Munc18 protein required for the biogenesis of α-granules in megakaryocytes, which give rise to platelets. Mutations in VPS33B cause arthrogryposis, renal dysfunction and cholestasis (ARC) syndrome. Platelets from ARC patients completely lack α-granules, causing a bleeding disorder. VPS33B plays a role in vesicular fusion events through its interaction with the SNARE proteins, though no such interactions have been identified. Here, it is shown that VPS33B interacts with STX6, a member of the syntaxin subfamily of SNAREs. The introduction of ARC mutations into VPS33B completely abrogated binding to STX6. Confocal microscopy studies revealed STX6 co-localizes well with markers of the α-granule biogenesis pathway. This implies a role for the interaction of VPS33B with STX6 in α-granule biogenesis. Based on the known structure of STX6 and that predicted of VPS33B, suggests a novel and unique mode of binding between VPS33B and STX6 compared to other identified SM-STX pairs.
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The Role of Munc18 Proteins in Physiologic and Pathologic Exocytoses in the Pancreatic Acinar CellLam, Patrick Pak Ling 18 February 2010 (has links)
Distinct membrane fusion events in the polarized pancreatic acinar cell involve highly specific interactions between distinct sets of SNARE proteins forming exocytotic complexes, whose assembly is modulated by distinct Munc18 proteins. The Munc18 isoform responsible for these exocytotic events in the acinar cell is unknown. Here, I postulate Munc18b to regulate apical exocytosis in the acinar cell. Current dogma for the pathogenesis of acute pancreatitis, including alcoholic pancreatitis, is mis-targeting and deregulated fusion of zymogen granules with lysosomal bodies in the acinar cells. This derangement results in premature activation of proteolytic zymogens and autophagic digestion of cellular contents. I have hypothesized an alternate mechanism, which is pathologic exocytosis occurring at the basolateral plasma membrane, and further propose Munc18c to mediate this process in alcoholic pancreatitis. The aims of this thesis are to demonstrate the roles of Munc18b and Munc18c in regulated apical exocytosis and pathologic basolateral exocytosis underling alcoholic pancreatitis, respectively.
In Chapter Three, using both real-time and static imaging techniques and biochemical tools, I demonstrated that Munc18c is dissociated from the acinar basal plasma membrane (BPM) when stimulated with postprandial CCK8 preceding preincubation of acini with postprandial 20-50mM ethanol concentrations. This activated Syntaxin (Syn)-4 and SNAP-23 on the BPM to complex with VAMP proteins on the granule to form the exocytotic SNARE complex that triggered basolateral exocytosis. This molecular mechanism of pathologic basolateral exocytosis was recapitulated in an Ethanol-diet rat model of pancreatitis. In Chapter Four, I determined Munc18b to be in the apical pole of the acinar cell to appropriately bind cognate Syn-2 and Syn-3 in the apical PM and ZGs. Here, I examined the structure-function of Munc18b on amylase secretion by employing Munc18b mutants with distinct affinities to Syn-2 and Syn-3. In Chapter Five, I discovered a novel EF-hand Ca2+-binding protein called Cab45b, which binds Munc18b to regulate its membrane targeting and interactions with Syntaxins in the acinar cell in a manner that influenced Ca2+-induced amylase release.
Taken together, these studies clarify our understanding of the role of Munc18 proteins involved in regulated and pathologic membrane fusion events underlying physiologic digestive enzyme secretion and clinical alcoholic pancreatitis.
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Regulation of the neuronal SNARE-complex by accessory proteinsJakhanwal, Shrutee 13 July 2017 (has links)
No description available.
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Vergleichende Untersuchungen zur Regulation der SNARE-Komplexbildung durch Sec1/Munc18-Proteine / Comparative investigations on the regulation of SNARE complex assembly by Sec1/Munc18-like proteinsBurkhardt, Pawel 25 March 2009 (has links)
No description available.
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Functional charaterization of symaptic proteins in calcium triggered exocytosisChang, Wen-Pin. January 2008 (has links)
Thesis (Ph. D.)--University of Texas Southwestern Medical Center at Dallas, 2008. / Vita. Includes bibliographical references (p. 95-106).
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Biochemical and biophysical characterization of Ca2+ channel complexes in neurotransmission / 神経伝達に関わるCa2+チャネル複合体の生化学・生物物理学的解明Uriu, Yoshitsugu 24 September 2010 (has links)
Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第15675号 / 工博第3333号 / 新制||工||1503(附属図書館) / 28212 / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 森 泰生, 教授 跡見 晴幸, 教授 濵地 格 / 学位規則第4条第1項該当
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