Browsing by Subject "Vesicle fusion"
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Item Defining the function of the Chediak-Higashi syndrome related protein, LvsB, in Dictyostelium discoideum : functional interactions that antagonize vesicle fusion(2013-08) Falkenstein, Kristin Nicole; De Lozanne, ArturoLesions in the human Lyst gene are associated with the lysosomal disorder Chediak Higashi Syndrome. The absence of Lyst causes the formation of enlarged lysosome related compartments in all cells. This defect results in severe immunodeficiency, neurological dysfunction, and ultimately in death. Despite decades of research, the mechanism for how these enlarged compartments arise is not well established. Two opposing models have been proposed for Lyst function. The fission model describes Lyst as a positive regulator of fission from lysosomal compartments, while the fusion model identifies Lyst as a negative regulator of fusion between lysosomes. To date, a consensus on which model is correct has not been reached. This thesis details my investigation of Lyst function using Dictyostelium discoideum. To establish a definitive model for the function of the Dictyostelium Lyst ortholog, LvsB, we used assays that distinguish between defects in vesicle fusion versus fission. We compared the phenotype of cells defective in LvsB with that of two known fission defect mutants ([mu]3 and WASH null mutants). The temporal localization characteristics of the post-lysosomal marker vacuolin, as well as vesicular acidity and fusion dynamics of LvsB null cells are distinct from those of both fission defect mutants. These distinctions are predicted by the fusion defect model and implicate LvsB as a negative regulator of vesicle fusion. This work also presents evidence that LvsB antagonizes the function of two fusion regulatory proteins, Rab14 and dLIP5. The Dictyostelium Rab14 GTPase is known to stimulate lysosome fusion, and here we implicate dLIP5 as a promoter of Rab14 activity. Constitutive activation of Rab14 increases vesicle fusion in wild type cells but not in dLIP5 mutant cells. Thus, Rab14 activity is dependent on dLIP5. Additionally, the aberrant vesicle morphology and fusion phenotypes of LvsB mutant cells are suppressed by expression of dominant inactive Rab14 or disruption of dLIP5. This suppression suggests that LvsB antagonizes Rab14 activity to negatively regulate vesicle fusion. These studies validate the fusion model for LvsB function and provide new insights into the relationships that dictate vesicle fusion regulation. By extension, we propose that Lyst negatively regulates vesicle fusion by antagonizing the activity of a RabGTPase.Item Mechanisms of benzyl alcohol tolerance in Drosophila melanogaster(2009-12) Alhasan, Yazan Mahmoud; Atkinson, Nigel (Nigel S.); Zakon, Harold; Gonzales, Rueben A.; Singer, Michael C.; Bergeson, Susan E.Proper neuronal function requires the preservation of appropriate neural excitability. An adaptive increase in neural excitability after exposure to agents that depress neuronal signaling blunts the sedative drug effects upon subsequent drug exposure. This adaptive response to drug exposure leads to changes in drug induced behaviors such as tolerance, withdrawal and addiction. Here I use Drosophila melanogaster to study the cellular and neuronal components which mediate behavioral tolerance to the anesthetic benzyl alcohol. I demonstrate that rapid tolerance to benzyl alcohol is a pharmacodynamic mechanism independent of drug metabolism. Furthermore, tolerance is a cell autonomous response which occurs in the absence of neural signaling. Using genetic and pharmacological manipulations I find the synapse to play an important role in the development of tolerance. In addition, the neural circuits that regulate arousal and sleep also alter benzyl alcohol sensitivity. Beyond previously described transcriptional mechanisms I find a post-translational role of the Ca2+-activated K+-channel, slowpoke in the development of tolerance. Finally, I explore a form of juvenile onset tolerance, which may have origins that differ from rapid tolerance. The implications of this study go beyond tolerance in Drosophila melanogaster to benzyl alcohol and can shed light on human drug tolerance, withdrawal and addiction.Item Modification of a Hydrophobic Layer by a Point Mutation in Syntaxin 1A Regulates the Rate of Synaptic Vesicle Fusion(Public Library of Science, 2007-03-06) Lagow, Robert D; Bao, Hong; Cohen, Evan N; Daniels, Richard W; Zuzek, Aleksej; Williams, Wade H; Macleod, Gregory T; Sutton, R. Bryan; Zhang, BingBoth constitutive secretion and Ca2+-regulated exocytosis require the assembly of the soluble N-ethylmaleimide–sensitive factor attachment protein receptor (SNARE) complexes. At present, little is known about how the SNARE complexes mediating these two distinct pathways differ in structure. Using the Drosophila neuromuscular synapse as a model, we show that a mutation modifying a hydrophobic layer in syntaxin 1A regulates the rate of vesicle fusion. Syntaxin 1A molecules share a highly conserved threonine in the C-terminal +7 layer near the transmembrane domain. Mutation of this threonine to isoleucine results in a structural change that more closely resembles those found in syntaxins ascribed to the constitutive secretory pathway. Flies carrying the I254 mutant protein have increased levels of SNARE complexes and dramatically enhanced rate of both constitutive and evoked vesicle fusion. In contrast, overexpression of the T254 wild-type protein in neurons reduces vesicle fusion only in the I254 mutant background. These results are consistent with molecular dynamics simulations of the SNARE core complex, suggesting that T254 serves as an internal brake to dampen SNARE zippering and impede vesicle fusion, whereas I254 favors fusion by enhancing intermolecular interaction within the SNARE core complex.