Altered beta-endorphin, Met- and Leu-enkephalins, and enkephalin-containing peptides in pancreas and pituitary of genetically obese diabetic (db/db) mice during development of diabetic syndrome.

We have recently shown that in addition to beta-endorphin the opioid peptides Met- and Leu-enkephalin and their apparent precursors are localized in islet endocrine cells of the rat pancreas. To begin evaluating a possible role for these pancreatic opiates in the pathophysiology of genetic diabetes in rodents, immunoreactive beta-endorphin and Met- and Leu-enkephalins were measured in acetic acid extracts of pancreas and pituitary of C57BL/KsJ db/db mice and their lean littermates. Groups of animals were studied during three phases of development of the diabetic syndrome in the mutant mice: at 4 (hyperinsulinemic and prediabetic); 6, 9, and 12 (frankly obese and diabetic); and 30 (hypoinsulinemic) wk of age. Elevations or decreases (P less than .05) were found in db/db mice (vs. lean littermates) as follows: pituitary content of Met-enkephalin was twofold higher at all ages studied; pituitary free Leu-enkephalin was lower at 4 wk and reversed to higher at 6-30 wk; pancreatic beta-endorphin was 30% lower at 4 wk and reversed to threefold higher at 6-12 wk; Met- and Leu-enkephalin-containing larger peptides were elevated at one or more points between 6 and 12 wk in both the pancreas and the pituitary. Thus, the onset of overt obesity between 4 and 6 wk of age was accompanied by a marked rise in both pancreatic beta-endorphin and pituitary Leu-enkephalin; similar elevations in these parameters have been reported previously in C57BL/6J ob/ob mice at approximately 12 wk of age.(ABSTRACT TRUNCATED AT 250 WORDS)

Copper deficiency in rats increases pancreatic enkephalin-containing peptides and insulin.

Free enkephalins (enk) and higher molecular weight enkephalin-containing peptides (enk-c-p) are present in the endocrine pancreas of rats, presumably in B cells. To determine whether these opioid peptides show dynamic alterations as insulin content of pancreas changes, we utilized a copper deficient rat model, in which the exocrine pancreas atrophies and the endocrine pancreas is "intact" and insulin (IRI) content increases. Dietary copper deficiency (-C) was produced in weanling male rats for 4 and 7 weeks. The deficient and copper supplemented (+C) groups were further subdivided to receive all dietary carbohydrate as either 62% fructose (F) or 62% starch (S). -CF rats showed the most severe deficiency. After 7 weeks, total units of pancreatic IRI in -CF were 7.5 +CF 2.1, -CS 7.9 and in +CS 2.8 (p less than 0.001). Pancreatic content of Met5- and Leu5-enk was measured in extracts which were purified on C-18 Seppaks with and without prior treatment with trypsin and carboxypeptidase B. -C animals showed progressive, significant increases in pancreatic content of Leu-enk-c-p, with a decrease in free Leu- and Met-enk (p less than 0.02-0.01). The pancreatic findings are compatible with a co-localization of enkephalins and insulin in the endocrine pancreas and are suggestive of co-regulation.

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.

Dissociation and rate constants of some human liver alcohol dehydrogenase isoenzymes.

ADH from human liver forms binary complexes with NADH, associated with a blue shift of the peak of the fluorescence emission of NADH. The wavelength shift is the same for all isoenzymes but the accompanying intensification of the fluorescence is different. The fluorescence is further increased by the formation of the very tight ternary enzyme-NADH-isobutyramide complexes. These properties are similar to those for the horse liver ADH, as well as the molecular weight of E=40 000 per active site of the dimer molecule (EE). "Stopped-flow" determined velocity constants (ER in equilibrium E+R) were found to be in good agreement with ethanol activity constants previously determined by activity measurement, confirming the validity of the ordered ternary complex mechanism also for the human ADH. No single isoenzyme activity as high as that reported by Mourad and Woronick or Drum has been found.

Human liver alcohol dehydrogenase. 2. The primary structure of the gamma 1 protein chain.

The primary structure of the gamma 1 subunit of human liver alcohol dehydrogenase isoenzyme gamma 1 gamma 1 was deduced by characterization of 36 tryptic and 2 CNBr peptides. The polypeptide chain is composed of 373 amino acid residues. gamma 1 differs from the beta 1 subunit of human liver alcohol dehydrogenase at 21 positions, and from the E subunit of horse liver alcohol dehydrogenase at 43 positions including a gap at position 128 as in the beta 1 subunit. All zinc-liganding residues from the E subunit of the horse protein and the beta 1 subunit of the human enzyme are conserved, but like beta 1, gamma 1 also has an additional cysteine residue at position 286 (in the positional numbering system of the horse enzyme) due to a Tyr----Cys exchange. Most amino acid exchanges preserve the properties of the residues affected and are largely located on the surface of the molecules, away from the active site and the coenzyme binding region. However, eight positions with charge differences in relation to the E subunit of the horse enzyme are noticed. These result in a net positive charge increase of one in gamma 1 versus E, explaining the electrophoretic mobilities on starch gels. Of functional significance is the conservation of Ser-48 in gamma 1 relative to E. The residue is close to the active site but different (Thr-48) in the beta 1 subunit of the human enzyme. Thus, the closer structural relationship between human gamma 1 and horse E enzyme subunit than between beta 1 and E is also reflected in functionally important residues, explaining a greater similarity between gamma 1 gamma 1 and EE than between beta 1 beta 1 and EE.

Human liver alcohol dehydrogenase. 1. The primary structure of the beta 1 beta 1 isoenzyme.

Determination of the amino acid sequence of the beta 1 subunit from the class I (pyrazole-sensitive) human liver alcohol dehydrogenase isoenzyme beta 1 beta 1 revealed a 373-residue structure differing at 48 positions (including a gap) from that of the subunit of the well studied horse liver alcohol dehydrogenase EE isoenzyme. The structure deduced is compatible with known differences in composition, ultraviolet absorbance, electrophoretic mobility and catalytic properties between the horse and human enzymes. All zinc-liganding residues of the horse E subunit are strictly conserved in the human beta 1 subunit, despite an earlier report of a mutation involving Cys-46. This residue therefore remains conserved in all known alcohol dehydrogenase structures. However, the total cysteine content of the beta 1 structure is raised from 14 in the subunit of the horse enzyme to 15 by a Tyr----Cys exchange. Most exchanges are on the surface of the molecule and of a well conserved nature. Substitutions close to the catalytic centre are of interest to explain the altered substrate specificity and different catalytic activity of the beta 1 homodimer. Functionally, a Ser----Thr exchange at position 48 appears to be of special importance, since Thr-48 in beta 1 instead of Ser-48 in the horse enzyme can restrict available space. Four other substitutions also line the active-site pocket, and appear to constitute partly compensated exchanges.

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.