The peptide hormone, insulin, regulates metabolism to homeostatically maintain blood glucose levels within a narrow physiological range. In pancreatic ss-cells, insulin is made and stored at high concentration within secretory granules. Physiological stimulation of insulin secretion (multiple times per day) requires very active synthesis of new insulin to replenish secretory granule reserves. Insulin synthesis begins with translation of preproinsulin for delivery into the lumen of the endoplasmic reticulum (ER). Therein, proinsulin must properly fold, which is easier than it sounds: proinsulin is a """"""""disulfide-challenged"""""""" protein. Moreover, when beta cells are forced to synthesize higher levels of proinsulin than they are genetically-programmed to handle, they risk further proinsulin misfolding/disulfide mispairing, which leads to secretory pathway stress. The objective of this new grant cycle is to better understand proinsulin folding and export from the ER. We hypothesize that misfolding of a subfraction of proinsulin in the ER can block insulin production derived from the other subfracton of """"""""bystander"""""""" proinsulin molecules, backlogging the protein in the ER, and driving ER stress, beta cell failure, loss of pancreatic insulin content, and diabetes. We propose four Specific Aims: 1) To elucidate the molecular mechanism(s) by which newly-described point mutations in the coding sequence of preproinsulin lead to human diabetes in neonates and adults. 2) To characterize ss-cell ER oxidoreductases. 3) To develop a new cell culture-based system to dissect steps leading to beta cell death. 4) To develop an in vivo analysis of pancreatic insulin production in diabetes.
Insulin regulates metabolism to maintain normal blood glucose levels. Synthesis of new insulin begins with translation of proinsulin in the endoplasmic reticulum. In the past year, more than 20 new proinsulin mutations have been found to be associated with neonatal onset diabetes. Evidence suggests that these mutant proinsulins are made as proteins but it is not known how they cause diabetes. Each patient also havs another allele of perfectly normal proinsulin which should be more than enough proinsulin synthesis to satisfy the body's need for insulin. This new grant cycle proposes experiments to better understand proinsulin folding and export in order to see how misfolding of a subfraction of proinsulin in the ER can block insulin production derived from bystander proinsulin molecules, causing ER stress, beta cell failure, and diabetes.
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