Glucose promotes survival of rat pancreatic beta cells by activating synthesis of proteins which suppress a constitutive apoptotic program.

This study demonstrates that rat islet beta cells constitutively express an apoptotic program which is activated when mRNA or protein synthesis is blocked. Apoptotic beta cells were detectable by electron microscopy after treatment with actinomycin D or cycloheximide. With a fluorescence microscopic assay both agents were found to increase the number of apoptotic beta cells dose- and time-dependently, up to 70% after 1 wk of culture; virtually no apoptotic beta cells occurred in control preparations or in conditions leading to primary necrosis. Thus, survival of beta cells seems dependent on synthesis of proteins which suppress an endogenous suicide program. This mechanism explains earlier observed effects of glucose on survival of cultured beta cells. Glucose is known to dose-dependently increase the percentage of beta cells in active biosynthesis and the percentage that survives during culture. It is now demonstrated that the glucose-induced survival of beta cells cultured for 1 wk results from a dose-dependent reduction in the percentage of beta cells dying in apoptosis (49% at 3 mM glucose, 40% at 6 mM, 9% at 10 mM). Thus, intercellular differences in glucose sensitivity appear responsible for the heterogeneity in beta cell sensitivity to apoptotic conditions. These data indicate that glucose promotes survival of beta cells by activating synthesis of proteins which suppress apoptosis. The present model allows for further investigation of the regulation of apoptosis in beta cells and the identification of agents which induce or prevent beta cell death.