Evaluation of the effects of different dexamethasone concentyrations on physiological parameters in pancreatic islets

Insulin resistance (IR) is a condition that demand increased levels of circulating insulin that are normally provided by increase of ß-cell function and mass. The IR can be observed in several experimental rodent models such as transgenic, pregnancy, high-fat or high-caloric diet and from glucose infusion model. These models have aided in elucidating the compensatory mechanisms observed during the IR. The glucocorticoids are widely used to induce the pharmacological IR in animal models and in humans, with scientific purpose. Activation of insulin signaling and cell cycle proteins are crucial to the function and growth of adult ß-cells. At the present study, we showed models to investigation of pancreatic ß-cell function and growth in vivo from the daily administration of three different dexamethasone (DEX) concentration (0.1, 0.5 e 1.0 mg/kg, body weight, intraperitoneal - DEX 0.1, DEX 0.5 and DEX 1.0, respectively) for 5 consecutive days. The peripheral sensibility to glucose and insulin, insulin secretion and histomorphometrical parameters were investigated. The analyses of proteins related to ß -cell function and growth were done by Western blotting. DEX treatment induced IR in a dose-dependent manner. Incease of glucose-stimulated insulin secretion was observed in vivo as well as ex vivo in the three DEX groups. DEX 1.0 rats, that present moderate hyperglicemya and marked hyperinsulinemia, ehibited a 5.1-fold increase in ß-cell proliferation besides hypertrophy, with significant increase of ß -cell mass compared to CTL rats. DEX 0.5 rats, that are hiperinsulinemic and normoglicemic, also exhibited a significant 3.6-fold increase in ß-cell proliferation as well as ß -cell hypertophy. However, DEX 0.1 rats, which exhibited the lowest degree of insulin resistance, compensate for insulin demand by improving only ß -cell function. No alteration in cell death frequency was noted in ß -cells from the three DEX groups compared to CTL group. Activation of IRS-2/PI3-K/Akt/p70S6K pathway as well as the retinoblastoma protein in islets from DEX 1.0 and, in lesser extend, in DEX 0.5 group was observed compared to islets from CTL group. Therefore, increasing doses of dexamethasone induce three different degrees of insulin requirement in living rats, serving as a model to investigate compensatory beta-cell alterations. The increased insulin demand is compensated by increase of ß-cell function (in all DEX groups) and ß -cell hyperplasia and hypertrophy in DEX 0.5 and DEX 1.0 groups. Based on the present results we concluded that the augmented levels of circulating insulin seem to be the major stimulus for ß-cell proliferation and hypertrophy observed in dexamethasone-induced insulin resistance. (AU)