Evidence for a deficient pancreatic beta-cell response in a rat model of hyperthyroidism.

To clarify mechanism behind the abnormal glucose tolerance, observed in hyperthyroidism, we studied genomic and nongenomic effects of thyroid hormone on insulin secretion using a rat model of hyperthyroidism. Male Sprague-Dawley rats were intraperitoneally injected with vehicle, low (100 microg/kg) or high dose (600 microg/kg) of thyroxin (T(4)) for 2 weeks. Rats treated with high dose, but not low dose, of T(4), showed an increase in serum T(3) levels, and a decrease in body weight as compared to control rats. In rats treated with either dose of T(4), fasting blood glucose levels were increased, but serum insulin levels were similar to those of controls. After an oral glucose load, blood glucose levels were increased in rats treated with high dose, but not low dose, of T(4). Serum insulin levels after the oral glucose load were decreased in rats treated with either dose of T(4). After an intravenous glucose load, blood glucose levels were comparable among groups, but serum insulin levels tended to be low in T(4)-treated rats. Steady-state blood glucose levels were comparable among groups. The insulin secretory responses to high glucose (20mM) or arginine (10mM) of the isolated pancreas was decreased in rats treated with high dose, but not low dose, of T(4). Mean insulin secretory response to glucose and arginine were decreased by 40.1% and by 60.4% in high-dose-T(4)-treated rats. Addition of T(3) in the perfusion medium decreased glucose-induced insulin release. Ratios of proinsulin mRNA levels to beta-actin mRNA were decreased in the islets of T(4)-treated rats (0.45 +/- 0.07 vs control 0.61 +/- 0.03, p < 0.05). Levels of TR (thyroid hormone nuclear receptor) alpha1 + cErb Aalpha2 mRNA, but not TRbeta1, were decreased in the pancreatic islets of T(4)-treated rats. Calculated islet area was increased, but the number of beta-cells determined immunohistochemically was not increased in T(4)-treated rats, nor the volume density of insulin positive islets. We concluded that a deficient pancreatic beta-cell response to glucose, rather than insulin resistance, was responsible for abnormal glucose tolerance in this model of hyperthyroidism. Thyroid hormone causes a decrease in glucose-induced insulin secretion. We observed nongenomic and genomic effects of thyroid hormone on glucose-induced insulin secretion.

Atrophic change of rat salivary gland during adenovirus-induced hyperleptinemia.

Sustained hyperleptinemia in normal rats induced by infusing a recombinant adenovirus containing the rat leptin cDNA (AdCMV-leptin) exhibited a remarkable reduction in food intake (AdCMV-leptin, 9.3 +/- 2.6 vs untreated, 20.6 +/- 1.0 g/day) and ablated body fat without any significant changes in wet weight of liver and left ventricle. In those hyperleptinemic rats, we found a 52% reduction in wet weight of salivary gland compared with that in the pair-fed AdCMV-beta-gal-treated rats, which received a recombinant virus containing the beta-galactosidase gene (AdCMV-beta-gal) and were fed on the same amount of food as had been consumed by the AdCMV-leptin-treated group on the previous day. Microscopic examination with hematoxylin-eosin staining revealed that atrophic change was induced in both serous and mucous gland only in the AdCMV-leptin-treated group, but not in the pair-fed controls. Thus, the atrophic changes in hyperleptinemic rats were due to neither a decrease of food intake nor disuse of the salivary gland related with anorexia. Our data suggested that size of the salivary gland was controlled, at lease in part, by "non-anorexic" effect of leptin.