In type 2 diabetes, chronic hyperglycemia is suggested to be detrimental to pancreatic β cells, causing impaired insulin secretion. IL-1β is a proinflammatory cytokine acting during the autoimmune process of type 1 diabetes. IL-1β inhibits β cell function and promotes Fas-triggered apoptosis in part by activating the transcription factor NF-κB. Recently, we have shown that increased glucose concentrations also induce Fas expression and β cell apoptosis in human islets. The aim of the present study was to test the hypothesis that IL-1β may mediate the deleterious effects of high glucose on human β cells. In vitro exposure of islets from nondiabetic organ donors to high glucose levels resulted in increased production and release of IL-1β, followed by NF-κB activation, Fas upregulation, DNA fragmentation, and impaired β cell function. The IL-1 receptor antagonist protected cultured human islets from these deleterious effects. β cells themselves were identified as the islet cellular source of glucose-induced IL-1β. In vivo, IL-1β–producing β cells were observed in pancreatic sections of type 2 diabetic patients but not in nondiabetic control subjects. Similarly, IL-1β was induced in β cells of the gerbil Psammomys obesus during development of diabetes. Treatment of the animals with phlorizin normalized plasma glucose and prevented β cell expression of IL-1β. These findings implicate an inflammatory process in the pathogenesis of glucotoxicity in type 2 diabetes and identify the IL-1β/NF-κB pathway as a target to preserve β cell mass and function in this condition
In autoimmune type 1 diabetes, Fas-to-Fas-ligand (FasL) interaction may represent one of the essential proapoptotic pathways leading to a loss of pancreatic -cells. In the advanced stages of type 2 diabetes, a decline in -cell mass is also observed, but its mechanism is not known. Human islets normally express FasL but not the Fas receptor. We observed upregulation of Fas in -cells of type 2 diabetic patients relative to nondiabetic control subjects. In vitro exposure of islets from nondiabetic organ donors to high glucose levels induced Fas expression, caspase-8 and -3 activation, and -cell apoptosis. The effect of glucose was blocked by an antagonistic anti-Fas antibody, indicating that glucose-induced apoptosis is due to interaction between the constitutively expressed FasL and the upregulated Fas. These results support a new role for glucose in regulating Fas expression in human -cells. Upregulation of the Fas receptor by elevated glucose levels may contribute to -cell destruction by the constitutively expressed FasL independent of an autoimmune reaction, thus providing a link between type 1 and type 2 diabetes.
High concentrations of glucose induce  cell production of IL-1, leading to impaired  cell function and apoptosis in human pancreatic islets. IL-1 receptor antagonist (IL-1Ra) is a naturally occurring antagonist of IL-1 and protects cultured human islets from glucotoxicity. Therefore, the balance of IL-1 and IL-1Ra may play a crucial role in the pathogenesis of diabetes. In the present study, we observed expression of IL-1Ra in human pancreatic  cells of nondiabetic individuals, which was decreased in tissue sections of type 2 diabetic patients. In vitro, chronic exposure of human islets to leptin, a hormone secreted by adipocytes, decreased  cell production of IL-1Ra and induced IL-1 release from the islet preparation, leading to impaired  cell function, caspase-3 activation, and apoptosis. Exogenous addition of IL-1Ra protected cultured human islets from the deleterious effects of leptin. Antagonizing IL-1Ra by introduction of small interfering RNA to IL-1Ra into human islets led to caspase-3 activation, DNA fragmentation, and impaired  cell function. Moreover, siIL-1Ra enhanced glucose-induced  cell apoptosis. These findings demonstrate expression of IL-1Ra in the human  cell, providing localized protection against leptin-and glucose-induced islet IL-1.A major factor determining the amount of insulin that can be secreted is  cell mass, which increases during obesity (1, 2). In individuals who lose the ability to produce sufficient quantities of insulin to maintain normoglycemia in the face of insulin resistance, type 2 diabetes mellitus manifests (3). Increasing evidence suggests that not only  cell function but also a progressive decrease in  cell mass contributes to this (2). The deficit of  cell mass in type 2 diabetes seems to be due in major part to increased  cell apoptosis (2, 4). Possible mediators of the process of  cell destruction include increased serum concentrations of cell nutrients. Indeed, increased free fatty acid (FFA) levels per se are known to be toxic for  cells, leading to the concept of lipotoxicity (5-10). However, not all obese individuals or pretype 2 diabetes patients exhibit dyslipidemia. Thus, lipotoxicity may play an important role in the process of  cell destruction but probably does not act alone. Elevated glucose concentrations induce  cell apoptosis in cultured islets from diabetes-prone Psammomys obesus, an animal model of type 2 diabetes (4), in human islets (11)(12)(13)(14), and at higher concentrations also in rodent islets (9, 15). In human islets, glucoseinduced  cell apoptosis and dysfunction are mediated by  cell production and secretion of IL-1 (13). Probably already in the pretype 2 diabetic stage, insulin resistance diminishes glucose uptake, resulting in transient postprandial hyperglycemic excursions. However, it is unlikely that transient hyperglycemia is sufficient to cause progression from obesity to diabetes.Leptin is expressed primarily in the adipose tissue, and this peptide hormone plays a major role in interorgan signaling emanati...
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