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Cell Biology of the ICA69 protein family in Neurosecretory cellsBuffa, Laura 16 March 2007 (has links) (PDF)
In type 1 diabetes (T1D), an autoimmune disease, autoantibodies are preferentially directed against proteins associated with Golgi and post-Golgi secretory vesicles, including insulin secretory granules and synaptic-like microvesicles. Thus, the study of beta-cell autoantigens with yet unknown function may provide novel insight into the secretory machinery of beta-cells and led to the discovery of novel pathways. Islet cell autoantigen of 69 kDa (ICA69) is a T1D autoantigen. It is a cytosolic protein of still unknown function. An impairment in neurotransmitter release upon mutation of its homologue in C. elegans suggests, however, an involvement of ICA69 in neurosecretion. Interestingly, ICA69 contains a BAR domain, present in several proteins involved in intracellular transport. The BAR domain functions as a dimerization motif, provides a general binding interface for different types of GTPases, and is a membrane binding/bending module. Its presence in ICA69 is a further hint supporting the putative involvement of ICA69 in intracellular membrane trafficking. The first part of this thesis was concerned with the characterization of ICA69, and the elucidation of its role in membrane traffic in pancreatic beta-cells. ICA69 was shown to be enriched in the perinuclear region, where also markers of the Golgi region are found. ICA69 was shown to interact with several membrane lipids, preferentially with PI(4)P, enriched on the Golgi complex. During the course of this thesis a combination of biochemical and imaging techniques were applied to investigate the interaction between ICA69 and Rab2, a small GTPase associated with the intermediate compartment and involved in the trafficking between the ER and the Golgi complex. ICA69 was shown to co-immunoprecipitate with Rab2 from INS-1 cells extracts. GST-pull down assays demonstrated that this interaction is GTP-dependent. Furthermore, confocal microscopy indicated that ICA69 and Rab2 extensively colocalize in particulate structures throughout the cytoplasm. Immunocytochemistry and subcellular fractionation experiments suggested that Rab2 recruits ICA69 to membranes. Functional studies indicated that ICA69 over-expression in INS-1 cells has effects that resemble, and in some cases amplify those observed upon Rab2 over-expression. Specifically, it impairs the trafficking between ER and Golgi, measured through the appearance and the conversion of the pro-form of ICA512 in the mature form of the protein. Moreover, it correlates with a redistribution of the beta-COP subunit of the coatomer, participating in the early secretory pathway, between membrane-bound compartments and the cytosol and it reduces stimulated insulin secretion. The data reported in this thesis conclusively point to ICA69 as a novel Rab2 effector, and may therefore contribute to the elucidation the yet poorly understood mechanism of action of Rab2 in the secretory pathway. The second part of the thesis was devoted to the study of an ICA69 paralogue gene, called ICA69-RP. Similarly to ICA69, ICA69-RP mRNA was shown to be primarily present in tissues such as brain and pancreatic islets, showing the expression pattern of a gene preferentially expressed in neuroendocrine cells. Unlike ICA69, however, and similar to other genes associated with the secretory machinery of beta-cells, ICA69-RP appeared to be glucose regulated, as shown by a 1.55 fold increase in mRNA levels upon stimulation of the cells with 25 mM glucose for two hours.Glucose stimulation of beta-cells prompts the activation of post-transcripional mechanisms which quickly up-regulate the expression of secretory granule genes and consequently renew granule stores. The increased expression of ICA69-RP upon glucose stimulation of cells may be part of this process. Unfortunately, all attempts to elucidate the intracellular localization of endogenous ICA69-RP failed, and it was not possible to obtain significant insights about its localization by over-expressing a fusion protein between ICA69-RP and GFP. Unlike other paralogues containing the BAR domain, such as amphiphysin 1 and 2 or Rvs167p and Rvs161p, ICA69 and ICA69-RP were shown not to form heterodimers. Furthermore, ICA69-RP did not show any interaction with Rab2 or Rab1, involved in the anterograde transport between ER and Golgi. Thus, its physiological role remains to be investigated.
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Cell Biology of the ICA69 protein family in Neurosecretory cellsBuffa, Laura 22 February 2007 (has links)
In type 1 diabetes (T1D), an autoimmune disease, autoantibodies are preferentially directed against proteins associated with Golgi and post-Golgi secretory vesicles, including insulin secretory granules and synaptic-like microvesicles. Thus, the study of beta-cell autoantigens with yet unknown function may provide novel insight into the secretory machinery of beta-cells and led to the discovery of novel pathways. Islet cell autoantigen of 69 kDa (ICA69) is a T1D autoantigen. It is a cytosolic protein of still unknown function. An impairment in neurotransmitter release upon mutation of its homologue in C. elegans suggests, however, an involvement of ICA69 in neurosecretion. Interestingly, ICA69 contains a BAR domain, present in several proteins involved in intracellular transport. The BAR domain functions as a dimerization motif, provides a general binding interface for different types of GTPases, and is a membrane binding/bending module. Its presence in ICA69 is a further hint supporting the putative involvement of ICA69 in intracellular membrane trafficking. The first part of this thesis was concerned with the characterization of ICA69, and the elucidation of its role in membrane traffic in pancreatic beta-cells. ICA69 was shown to be enriched in the perinuclear region, where also markers of the Golgi region are found. ICA69 was shown to interact with several membrane lipids, preferentially with PI(4)P, enriched on the Golgi complex. During the course of this thesis a combination of biochemical and imaging techniques were applied to investigate the interaction between ICA69 and Rab2, a small GTPase associated with the intermediate compartment and involved in the trafficking between the ER and the Golgi complex. ICA69 was shown to co-immunoprecipitate with Rab2 from INS-1 cells extracts. GST-pull down assays demonstrated that this interaction is GTP-dependent. Furthermore, confocal microscopy indicated that ICA69 and Rab2 extensively colocalize in particulate structures throughout the cytoplasm. Immunocytochemistry and subcellular fractionation experiments suggested that Rab2 recruits ICA69 to membranes. Functional studies indicated that ICA69 over-expression in INS-1 cells has effects that resemble, and in some cases amplify those observed upon Rab2 over-expression. Specifically, it impairs the trafficking between ER and Golgi, measured through the appearance and the conversion of the pro-form of ICA512 in the mature form of the protein. Moreover, it correlates with a redistribution of the beta-COP subunit of the coatomer, participating in the early secretory pathway, between membrane-bound compartments and the cytosol and it reduces stimulated insulin secretion. The data reported in this thesis conclusively point to ICA69 as a novel Rab2 effector, and may therefore contribute to the elucidation the yet poorly understood mechanism of action of Rab2 in the secretory pathway. The second part of the thesis was devoted to the study of an ICA69 paralogue gene, called ICA69-RP. Similarly to ICA69, ICA69-RP mRNA was shown to be primarily present in tissues such as brain and pancreatic islets, showing the expression pattern of a gene preferentially expressed in neuroendocrine cells. Unlike ICA69, however, and similar to other genes associated with the secretory machinery of beta-cells, ICA69-RP appeared to be glucose regulated, as shown by a 1.55 fold increase in mRNA levels upon stimulation of the cells with 25 mM glucose for two hours.Glucose stimulation of beta-cells prompts the activation of post-transcripional mechanisms which quickly up-regulate the expression of secretory granule genes and consequently renew granule stores. The increased expression of ICA69-RP upon glucose stimulation of cells may be part of this process. Unfortunately, all attempts to elucidate the intracellular localization of endogenous ICA69-RP failed, and it was not possible to obtain significant insights about its localization by over-expressing a fusion protein between ICA69-RP and GFP. Unlike other paralogues containing the BAR domain, such as amphiphysin 1 and 2 or Rvs167p and Rvs161p, ICA69 and ICA69-RP were shown not to form heterodimers. Furthermore, ICA69-RP did not show any interaction with Rab2 or Rab1, involved in the anterograde transport between ER and Golgi. Thus, its physiological role remains to be investigated.
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