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The mechanism of death evoked by human amylin in pancreatic islet B cellsBai, Ji Zhong January 1999 (has links)
Whole document restricted, see Access Instructions file below for details of how to access the print copy. Subscription resource available via Digital Dissertations / Amylin is a 37-amino acid peptide usually cosecreted with insulin from pancreatic islet β-cells. It is implicated in the regulation of normal glucose metabolism and thought to induce pathological features of non-insulin-dependent diabetes mellitus (NIDDM). In particular, human amylin (hA) deposits as islet amyloid, and is associated with the loss of insulin-producing islet β-cells in NIDDM. The biochemical mechanism of hA-evoked death in cultured RINm5F pancreatic islet β-cells has been investigated in this thesis. Synthetic hA but not rat amylin (rA) aggregated in aqueous solution, formed fibrils, and evoked β-cell death in a time- and concentration-dependent manner. The cell death exhibited apoptotic features, including inter-nucleosomal DNA fragmentation, mitochondrial dysfunction, delayed membrane lysis, aurintricarboxylic acid suppression and cell membrane blebbling. Cytotoxicity of hA was inhibited by Congo red (an amyloid-binding dye), 8-37hA fragment (fibril-forming but non-toxic), 1-40βA or 25-35βA (Alzheimer-associated peptide), but neither by sorbitol (inhibitory to hA fibril formation), rA nor its 8-37rA peptide (non-fibril-forming and non-toxic). Preformed large amyloid deposits of hA were less potent in causing β-cell death than small aggregates. These data suggest that hA induces β-cell apoptosis via small aggregates through a possible membrane receptor pathway. Inhibitors of protein and mRNA synthesis did not inhibit hA-evoked apoptosis, but rather enhanced or directly triggered β-cell death during prolonged exposure. Likewise, Ca2+ modulators, which alter intracellular free Ca2+ concentration ([Ca2+]i), failed to prevent hA cytotoxicity and were ultimately cytotoxic themselves. Fura-2 loading and 45Ca2+ uptake studies indicated that hA did not mobilise intracellular Ca2+ during its toxicity. These results indicate a protein synthesis- and Ca2+-independent process of hA toxicity RINm5F islet β-cells. The studies reported in this thesis have established a new in vitro model of hA-evoked apoptosis using cultured RINm5F pancreatic islet β-cells. A new model of NIDDM pathogenesis is presented and discussed.
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The mechanism of death evoked by human amylin in pancreatic islet B cellsBai, Ji Zhong January 1999 (has links)
Whole document restricted, see Access Instructions file below for details of how to access the print copy. Subscription resource available via Digital Dissertations / Amylin is a 37-amino acid peptide usually cosecreted with insulin from pancreatic islet β-cells. It is implicated in the regulation of normal glucose metabolism and thought to induce pathological features of non-insulin-dependent diabetes mellitus (NIDDM). In particular, human amylin (hA) deposits as islet amyloid, and is associated with the loss of insulin-producing islet β-cells in NIDDM. The biochemical mechanism of hA-evoked death in cultured RINm5F pancreatic islet β-cells has been investigated in this thesis. Synthetic hA but not rat amylin (rA) aggregated in aqueous solution, formed fibrils, and evoked β-cell death in a time- and concentration-dependent manner. The cell death exhibited apoptotic features, including inter-nucleosomal DNA fragmentation, mitochondrial dysfunction, delayed membrane lysis, aurintricarboxylic acid suppression and cell membrane blebbling. Cytotoxicity of hA was inhibited by Congo red (an amyloid-binding dye), 8-37hA fragment (fibril-forming but non-toxic), 1-40βA or 25-35βA (Alzheimer-associated peptide), but neither by sorbitol (inhibitory to hA fibril formation), rA nor its 8-37rA peptide (non-fibril-forming and non-toxic). Preformed large amyloid deposits of hA were less potent in causing β-cell death than small aggregates. These data suggest that hA induces β-cell apoptosis via small aggregates through a possible membrane receptor pathway. Inhibitors of protein and mRNA synthesis did not inhibit hA-evoked apoptosis, but rather enhanced or directly triggered β-cell death during prolonged exposure. Likewise, Ca2+ modulators, which alter intracellular free Ca2+ concentration ([Ca2+]i), failed to prevent hA cytotoxicity and were ultimately cytotoxic themselves. Fura-2 loading and 45Ca2+ uptake studies indicated that hA did not mobilise intracellular Ca2+ during its toxicity. These results indicate a protein synthesis- and Ca2+-independent process of hA toxicity RINm5F islet β-cells. The studies reported in this thesis have established a new in vitro model of hA-evoked apoptosis using cultured RINm5F pancreatic islet β-cells. A new model of NIDDM pathogenesis is presented and discussed.
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The mechanism of death evoked by human amylin in pancreatic islet B cellsBai, Ji Zhong January 1999 (has links)
Whole document restricted, see Access Instructions file below for details of how to access the print copy. Subscription resource available via Digital Dissertations / Amylin is a 37-amino acid peptide usually cosecreted with insulin from pancreatic islet β-cells. It is implicated in the regulation of normal glucose metabolism and thought to induce pathological features of non-insulin-dependent diabetes mellitus (NIDDM). In particular, human amylin (hA) deposits as islet amyloid, and is associated with the loss of insulin-producing islet β-cells in NIDDM. The biochemical mechanism of hA-evoked death in cultured RINm5F pancreatic islet β-cells has been investigated in this thesis. Synthetic hA but not rat amylin (rA) aggregated in aqueous solution, formed fibrils, and evoked β-cell death in a time- and concentration-dependent manner. The cell death exhibited apoptotic features, including inter-nucleosomal DNA fragmentation, mitochondrial dysfunction, delayed membrane lysis, aurintricarboxylic acid suppression and cell membrane blebbling. Cytotoxicity of hA was inhibited by Congo red (an amyloid-binding dye), 8-37hA fragment (fibril-forming but non-toxic), 1-40βA or 25-35βA (Alzheimer-associated peptide), but neither by sorbitol (inhibitory to hA fibril formation), rA nor its 8-37rA peptide (non-fibril-forming and non-toxic). Preformed large amyloid deposits of hA were less potent in causing β-cell death than small aggregates. These data suggest that hA induces β-cell apoptosis via small aggregates through a possible membrane receptor pathway. Inhibitors of protein and mRNA synthesis did not inhibit hA-evoked apoptosis, but rather enhanced or directly triggered β-cell death during prolonged exposure. Likewise, Ca2+ modulators, which alter intracellular free Ca2+ concentration ([Ca2+]i), failed to prevent hA cytotoxicity and were ultimately cytotoxic themselves. Fura-2 loading and 45Ca2+ uptake studies indicated that hA did not mobilise intracellular Ca2+ during its toxicity. These results indicate a protein synthesis- and Ca2+-independent process of hA toxicity RINm5F islet β-cells. The studies reported in this thesis have established a new in vitro model of hA-evoked apoptosis using cultured RINm5F pancreatic islet β-cells. A new model of NIDDM pathogenesis is presented and discussed.
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The mechanism of death evoked by human amylin in pancreatic islet B cellsBai, Ji Zhong January 1999 (has links)
Whole document restricted, see Access Instructions file below for details of how to access the print copy. Subscription resource available via Digital Dissertations / Amylin is a 37-amino acid peptide usually cosecreted with insulin from pancreatic islet β-cells. It is implicated in the regulation of normal glucose metabolism and thought to induce pathological features of non-insulin-dependent diabetes mellitus (NIDDM). In particular, human amylin (hA) deposits as islet amyloid, and is associated with the loss of insulin-producing islet β-cells in NIDDM. The biochemical mechanism of hA-evoked death in cultured RINm5F pancreatic islet β-cells has been investigated in this thesis. Synthetic hA but not rat amylin (rA) aggregated in aqueous solution, formed fibrils, and evoked β-cell death in a time- and concentration-dependent manner. The cell death exhibited apoptotic features, including inter-nucleosomal DNA fragmentation, mitochondrial dysfunction, delayed membrane lysis, aurintricarboxylic acid suppression and cell membrane blebbling. Cytotoxicity of hA was inhibited by Congo red (an amyloid-binding dye), 8-37hA fragment (fibril-forming but non-toxic), 1-40βA or 25-35βA (Alzheimer-associated peptide), but neither by sorbitol (inhibitory to hA fibril formation), rA nor its 8-37rA peptide (non-fibril-forming and non-toxic). Preformed large amyloid deposits of hA were less potent in causing β-cell death than small aggregates. These data suggest that hA induces β-cell apoptosis via small aggregates through a possible membrane receptor pathway. Inhibitors of protein and mRNA synthesis did not inhibit hA-evoked apoptosis, but rather enhanced or directly triggered β-cell death during prolonged exposure. Likewise, Ca2+ modulators, which alter intracellular free Ca2+ concentration ([Ca2+]i), failed to prevent hA cytotoxicity and were ultimately cytotoxic themselves. Fura-2 loading and 45Ca2+ uptake studies indicated that hA did not mobilise intracellular Ca2+ during its toxicity. These results indicate a protein synthesis- and Ca2+-independent process of hA toxicity RINm5F islet β-cells. The studies reported in this thesis have established a new in vitro model of hA-evoked apoptosis using cultured RINm5F pancreatic islet β-cells. A new model of NIDDM pathogenesis is presented and discussed.
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Biophysical characterization of branched amphiphilic peptide capsules and their potential applications in radiotherapySukthankar, Pinakin Ramchandra January 1900 (has links)
Doctor of Philosophy / Department of Biochemistry and Molecular Biophysics / John M. Tomich / Branched Amphiphilic Peptide Capsules (BAPCs) are peptide nano-spheres comprised of equimolar proportions of two branched peptide sequences bis(FLIVI)-K-KKKK and bis(FLIVIGSII)-K-KKKK that self-assemble in water to form bilayer delimited poly-cationic capsules capable of trapping solutes. We examined the lipid-like properties of this system including assembly, fusion, solute encapsulation, and resizing by membrane extrusion as well as their capability to be maintained at a specific size by storage at 4˚C. These studies along with earlier work from the lab (Gudlur et al. (2012) PLOS ONE 7(9): e45374) demonstrated that the capsules, while sharing many properties with lipid vesicles, were much more robust. We next investigated the stability, size limitations of encapsulation, cellular localization, retention and, bio-distribution of the BAPCs. We demonstrated that the BAPCs are readily taken up by epithelial cells in culture, escape or evade the endocytotic pathway, and accumulate in the peri-nuclear region where they persist without any apparent degradation. The stability and persistence of the capsules suggested they might be useful in delivering radionuclides. The BAPCs encapsulated alpha particle emitting radionuclides without any apparent leakage, were taken up by cells and were retained for extended periods of time. Their potential in this clinical application is being currently pursued. Lastly we studied the temperature dependence of capsule formation by examining the biophysical characteristics of temperature induced conformational changes in BAPCs and examined the structural parameters within the sequences that contribute to their remarkable stability. A region in the nine-residue sequence was identified as the critical element in this process. The ability to prepare stable uniform nano-scale capsules of desired sizes makes BAPCs potentially attractive as delivery vehicles for various solutes/drugs.
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