Abstract
BackgroundGlucose modulates β-cell mass and function through an initial depolarization and Ca2+ influx, which then triggers a number of growth regulating signaling pathways. One of the most important downstream effectors in Ca2+ signaling is the calcium/Calmodulin activated serine threonine phosphatase, calcineurin. Recent evidence suggests that calcineurin/NFAT is essential for β-cell proliferation, and that in its absence loss of β-cells results in diabetes. We hypothesized that in contrast, activation of calcineurin might result in expansion of β-cell mass and resistance to diabetes.Methodology/Principal FindingsTo determine the role of activation of calcineurin signaling in the regulation of pancreatic β-cell mass and proliferation, we created mice that expressed a constitutively active form of calcineurin under the insulin gene promoter (caCnRIP). To our surprise, these mice exhibited glucose intolerance. In vitro studies demonstrated that while the second phase of Insulin secretion is enhanced, the overall insulin secretory response was conserved. Islet morphometric studies demonstrated decreased β-cell mass suggesting that this was a major component responsible for altered Insulin secretion and glucose intolerance in caCnRIP mice. The reduced β-cell mass was accompanied by decreased proliferation and enhanced apoptosis.ConclusionsOur studies identify calcineurin as an important factor in controlling glucose homeostasis and indicate that chronic depolarization leading to increased calcineurin activity may contribute, along with other genetic and environmental factors, to β-cell dysfunction and diabetes.
Highlights
The normal response of pancreatic islet b-cells to various conditions associated with Insulin resistance is to increase the mass of Insulin producing cells
Our studies identify calcineurin as an important factor in controlling glucose homeostasis and indicate that chronic depolarization leading to increased calcineurin activity may contribute, along with other genetic and environmental factors, to b-cell dysfunction and diabetes
The idea that chronically elevated intracellular Ca2+ concentrations due to high glucose can result in deleterious effects on b-cell proliferation, survival and/or function is consistent with the Ca2+ set-point hypothesis described in the neuronal literature [16]
Summary
The normal response of pancreatic islet b-cells to various conditions associated with Insulin resistance is to increase the mass of Insulin producing cells. Chronic elevation in plasma glucose, so called glucotoxicity, can have deleterious effects on b-cell function and survival [5,6,7,8,9,10,11,12,13]. The idea that chronically elevated intracellular Ca2+ concentrations due to high glucose can result in deleterious effects on b-cell proliferation, survival and/or function is consistent with the Ca2+ set-point hypothesis described in the neuronal literature [16]. This concept states that very low or high intracellular Ca2+ levels are incompatible with survival and that between these extremes, Ca2+ concentrations have protective and physiological effects on neuronal function. We hypothesized that in contrast, activation of calcineurin might result in expansion of b-cell mass and resistance to diabetes
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