Regulation of insulin exocytosis by Munc13-1.

The slower kinetics of insulin release from pancreatic islet beta cells, as compared with other regulated secretory processes such as chromaffin granule secretion, can in part be explained by the small number of the insulin granules that are docked to the plasma membrane and readily releasable. In type-2 diabetes, the kinetics of insulin secretion become grossly distorted, and, to therapeutically correct this, it is imperative to elucidate the mechanisms that regulate priming and secretion of insulin secretory granules. Munc13-1, a synaptic protein that regulates SNARE complex assembly, is the major protein determining the priming of synaptic vesicles. Here, we demonstrate the presence of Munc13-1 in human, rat, and mouse pancreatic islet beta cells. Expression of Munc13-1, along with its cognate partners, syntaxin 1a and Munc18a, is reduced in the pancreatic islets of type-2 diabetes non-obese Goto-Kakizaki and obese Zucker fa/fa rats. In insulinoma cells, overexpressed Munc13-1-enhanced green fluorescent protein is translocated to the plasma membrane in a temperature-dependent manner. This, in turn, greatly amplifies insulin exocytosis as determined by patch clamp capacitance measurements and radioimmunoassay of the insulin released. The potentiation of exocytosis by Munc13-1 is dependent on endogenously produced diacylglycerol acting on the overexpressed Munc13-1 because it is blocked by a phospholipase C inhibitor (U73122) and abrogated when the diacylglycerol binding-deficient Munc13-1H567K mutant is expressed instead of the wild type protein. Our data demonstrate that Munc13-mediated vesicle priming is not restricted to neurotransmitter release but is also functional in insulin secretion, where it is subject to regulation by the diacylglycerol second messenger pathway. In view of our findings, Munc13-1 is a potential drug target for therapeutic optimization of insulin secretion in diabetes.

Expression of cystic fibrosis transmembrane conductance regulator during early human embryo development.

Formation of the blastocyst is one of the first morphological changes in early embryonic development. Ion transport has been shown to be crucial for blastocoele cavity formation and expansion, although the mechanisms that underlie this process are presently unknown. As a transmembrane Cl(-) channel, the cystic fibrosis transmembrane conductance regulator (CFTR) may participate in ion transport and early blastocoele formation. CFTR mRNA was detected throughout preimplantation embryo development and in the unfertilized oocyte. Immunocytochemistry disclosed the presence of CFTR protein from the 8-cell stage, reaching maximum immunoreactivity at early blastocyst stage embryos. Patch clamp electrophysiology of morulae and blastocysts demonstrated typical CFTR Cl(-) channel activities in the apical membrane of trophectoderm cells. Thus CFTR is expressed both at mRNA and protein levels in human morulae and blastocysts, and functions as a cAMP-regulated apical membrane Cl(-) channel. These data suggest that CFTR may contribute to blastocoele formation in the early human embryo.