Developmental patterns for pancreatic opioids in the rat.

Developmental patterns for rat pancreatic opioid peptides and islet hormones were studied from gestational day 20 through adulthood. Fetal tissue was obtained as well as pancreas at birth (day 0), and postnatal days 3, 7, 14, and 21, and 7 weeks. The hormones measured included insulin, glucagon, and somatostatin. The opioids measured were beta-endorphin, Met- and Leu-enkephalins, and the high molecular weight enkephalin precursors. Pancreata were pooled as necessary and extracted (acid alcohol, or hot acetic acid), and opioids were further purified on reversed-phase C-18 (Sep-pak) cartridges. In all instances measurements were made by radioimmunoassays. Precursor peptides were first digested (with trypsin and carboxypeptidase B) prior to immunoassay. All opioids and hormones except the precursors for enkephalins showed a well-defined surge in pancreatic concentration during the first postnatal week. In contrast, the precursors had the highest concentration in the fetus, and by the seventh day of life had decreased by greater than 50%. This progressive decrease may represent maturation of the enkephalin convertase and trypsin-like enzymes in the islets. The opioid and hormonal surges that we have described are similar to the surge in islet concentration of thyroid-releasing hormone (TRH) previously described in neonatal rat islets. It is suggested that these postnatal alterations in opioid and hormone concentration relate to a specific function in the development of the endocrine pancreas.

Tissue somatostatin levels in three models of genetic obesity in rats.

A potential role for somatostatin (SRIF) in the pathogenesis of the hyperinsulinemia of obese rats was considered. SRIF like immunoreactivity (ng/mg protein) was therefore measured in hot 2 N acetic acid extracts of pancreas, stomach, pituitary, and hypothalamus in tissues obtained from three models of genetic obesity in rats. These models included the obese and lean controls of LA/N-cp, SHR/N-cp, and Zucker rats. To assess the effects of diet on SRIF levels, mixed diets were provided ad lib which contained a carbohydrate as either sucrose or starch. Some groups were fed chow diets. No significant dietary effects on tissue levels of SRIF were obtained. However, two of the three models (Zucker and SHR/N-cp) showed phenotypic effects on SRIF levels in pancreas; namely, obese rats showed a significantly greater concentration of SRIF (P less than 0.0005 and less than 0.0002, respectively) than did the lean littermates. These findings were confirmed by measurement of total pancreas SRIF content. Gastric levels were significantly altered only in the obese Zucker rats (P less than 0.005) where obese tissues had lower concentrations than those of lean animals. However similar directional changes in pancreas and stomach were observed in all models. It is concluded that the hyperinsulinemia of the obese animals studied is not due to absolute deficiency in pancreatic SRIF content. It is postulated however that decreased pancreatic SRIF secretion (paracrine or otherwise) relative to pancreatic insulin content could still play a role.