The pentose cycle and insulin release in isolated mouse pancreatic islets during starvation.

When islets from mice were incubated with 16.7 mM-glucose, previous starvation for 48 h decreased the rate of insulin release by approx. 50% and glucose utilization was decreased by approx. 35%. The maximally extractable activity of glucose 6-phosphate dehydrogenase was diminished by 28% after starvation. The formation of 14CO2 from both [1-14C]glucose was, however, higher than the rate of oxidation of [6-14C]-glucose in islets from both fed and starved mice. The fraction of glucose utilized that was oxidized (specific 14CO2 yield) ranged from one-fifth to one-third and was higher in islets from starved mice with both [1-14C]glucose and [6-14C]glucose as substrate. The contribution of pentose-cycle oxidation to total glucose metabolism was small (3% in the fed state and 4% in the starved state). The absolute rates of glucose carbon metabolism via the pentose-cycle oxidation to total glucose metabolism was small (3% in the fed state and 4% in the starved state). The absolute rates of glucose carbon metabolism via the pentose cycle and the turnover of NADPH in this pathway were identical in islets from fed and starved animals. After incubation at 16.7 mM-glucose for 30 min the contents of glucose (6-phosphate and 6-phosphogluconate were both unchanged by starvation. It is concluded that there is no correlation between the decreased sensitivity of the insulin secretory mechanism during starvation and the metabolism of glucose via the pentose cycle, the islet content of glucose 6-phosphate or 6-phosphogluconate.     

Mechanism of 3-phenylpyruvate-induced insulin release from isolated pancreatic islets.

3-Phenylpyruvate evoked a monophasic insulin release from perifused mouse islets. L-Phenylalanine was not an insulin secretagogue and was oxidized by islets at a very low rate, suggesting that 3-phenylpyruvate does not trigger insulin release by enhancing production of reducing equivalents. Moreover, allosteric activation of glutamate dehydrogenase does not play a role in 3-phenylpyruvate-induced insulin secretion.     

Differential control of insulin secretion and somatostatin-receptor recruitment in isolated pancreatic islets.

Somatostatin receptors appear to be localized to secretory granules in pancreatic islet homogenates. Recruitment of these receptors to the islet-cell surfaces may mark the contact event between secretory granules and plasma membranes before release of insulin by fission. Isethionate, an impermeant anionic replacement for chloride, blocks the release step but does not affect receptor recruitment. By contrast, low concentrations of phenothiazine drugs, such as trifluoperazine and promethazine, inhibit both receptor recruitment and secretion. Scatchard analysis of phenothiazine effects on somatostatin receptors reveals that these drugs reduce the number of receptors but do not affect the affinity of the receptor for somatostatin. These data indicate that membrane contact and fission steps during exocytosis can be biochemically separated.     

Mechanisms of leucine- and theophylline-stimulated insulin biosynthesis in isolated rat pancreatic islets.

To extend previous observations on the mechanisms of translational regulation of insulin biosynthesis [Welsh, Scherberg, Gilmore & Steiner (1986) Biochem. J. 235, 459-467], we have now compared the intracellular distributions of insulin mRNA after stimulation of insulin biosynthesis by glucose, leucine or theophylline. In comparison with low glucose (3.3 mM) only, the presence of 10 mM-leucine + 3.3 mM-glucose resulted in the transfer of insulin mRNA from the pool of the uninitiated mRNA to the free polysome/monosome fraction and an increase in the amount of insulin mRNA associated with the microsomal fraction. Islets exposed to 5 mM-theophylline + 3.3 mM-glucose also showed a decreased content of uninitiated insulin mRNA in the cytosol, but these islets showed no increase in insulin mRNA in the microsomal fraction. These results suggest that leucine, a nutrient stimulant of insulin biosynthesis, acts essentially by the same mechanisms as those of glucose, whereas theophylline acts only to stimulate initiation rates.     

Inosine-stimulated insulin release and metabolism of inosine in isolated mouse pancreatic islets.

Inosine is a potent primary stimulus of insulin secretion from isolated mouse islets. The inosine-induced insulin secretion was totally depressed during starvation, but was completely restored by the addition of 5 mM-caffeine to the medium and partially restored by the addition of 5 mM-glucose. Mannoheptulose (3 mg/ml) potentiated the effect of 10 mM-inosine in islets from fed mice. The mechanism of the stimulatory effect of inosine was further investigated, and it was demonstrated that pancreatic islets contain a nucleoside phosphorylase capable of converting inosine into hypoxanthine and ribose 1-phosphate. Inosine at 10 mM concentration increased the lactate production and the content of ATP, glucose 6-phosphate (fructose 1,6-diphosphate + triose phosphates) and cyclic AMP in islets from fed mice. In islets from starved mice inosine-induced lactate production was decreased and no change in the concentration of cyclic AMP could be demonstrated, whereas the concentration of ATP and glucose 6-phosphate rose. Inosine (10 mM) induced a higher concentration of (fructose 1,6-diphosphate + triose phosphates) in islets from starved mice than in islets from fed mice suggesting that in starvation the activities of glyceraldehyde 3-phosphate dehydrogenase or other enzymes below this step in glycolysis are decreased. Formation of glucose from inosine was negligible. Inosine had no direct effect on adenylate cyclase activity in islet homogenates. The observed changes in insulin secretion and islet metabolism mimic what is seen when glucose and glyceraldehyde stimulate insulin secretion, and as neither ribose nor hypoxanthine-stimulated insulin release, the results are interpreted as supporting the substrate-site hypothesis for glucose-induced insulin secretion according to which glucose has to be metabolized in the beta-cells before secretion is initiated.     

Stress-induced dissociations between intracellular calcium signaling and insulin secretion in pancreatic islets

In healthy pancreatic islets, glucose-stimulated changes in intracellular calcium ([Ca²⁺]_i) provide a reasonable reflection of the patterns and relative amounts of insulin secretion. We report that [Ca²⁺]_i in islets under stress, however, dissociates with insulin release in different ways for different stressors. Islets were exposed for 48 h to a variety of stressors: cytokines (low-grade inflammation), 28 mM glucose (28G, glucotoxicity), free fatty acids (FFAs, lipotoxicity), thapsigargin (ER stress), or rotenone (mitochondrial stress). We then measured [Ca²⁺]_i and insulin release in parallel studies. Islets exposed to all stressors except rotenone displayed significantly elevated [Ca²⁺]_i in low glucose, however, increased insulin secretion was only observed for 28G due to increased nifedipine-sensitive calcium-channel flux. Following 3–11 mM glucose stimulation, all stressors substantially reduced the peak glucose-stimulated [Ca²⁺]_i response (first phase). Thapsigargin and cytokines also substantially impacted aspects of calcium influx and ER calcium handling. Stressors did not significantly impact insulin secretion in 11 mM glucose for any stressor, although FFAs showed a borderline reduction, which contributed to a significant decrease in the stimulation index (11:3 mM glucose) observed for FFAs and also for 28G. We also clamped [Ca²⁺]_i using 30 mM KCl + 250 μM diazoxide to test the amplifying pathway. Only rotenone-treated islets showed a robust increase in 3–11 mM glucose-stimulated insulin secretion under clamped conditions, suggesting that low-level mitochondrial stress might activate the metabolic amplifying pathway. We conclude that different stressors dissociate [Ca²⁺]_i from insulin secretion differently: ER stressors (thapsigargin, cytokines) primarily affect [Ca²⁺]_i but not conventional insulin secretion and ‘metabolic’ stressors (FFAs, 28G, rotenone) impacted insulin secretion.     

Bombesin inhibits insulin release from isolated pancreatic islets of rats in vitro.

The effect of bombesin on insulin release from isolated pancreatic islets of rats was examined in vitro. Bombesin, at the doses ranging from 10 ng/ml to 1 microgram/ml, significantly inhibited 16.7 mM glucose-induced insulin release, while bombesin had no inhibitory effect on insulin release at 8.3 mM and 3.3 mM glucose. Moreover, bombesin also suppressed insulin release elicited by 10 mM arginine at the doses of 100 ng/ml and 1 microgram/ml. These results indicate that bombesin has a direct inhibitory action on insulin release.     

Separate intracellular pathways for insulin receptor recycling and insulin degradation in isolated rat adipocytes

To gain insight into the sequence of events that follow endocytotic uptake of insulin receptor complexes, we have examined the interrelationship between the degradative pathway of the insulin ligand and the recycling pathway of the insulin receptor. Tris(hydroxymethyl)aminomethane and other nonamphoteric amines were found to selectively impair insulin receptor recycling while leaving the insulin-degradative pathway intact. In contrast, low concentrations of the lysosomotropic agent chloroquine markedly inhibited intracellular insulin degradation but had little or no affect on the recycling of internalized receptors. Thus, we conclude: (1) that insulin dissociates from its receptor after endocytotic uptake and both receptor and ligand follow a separate intracellular pathway; and (2) that receptor recycling and insulin degradation can be selectively inhibited by Tris and chloroquine, respectively, highlighting the potential usefulness of these agents as intracellular probes in the study of receptor-ligand metabolism.     

Propionate inhibits glucose-induced insulin secretion in isolated rat pancreatic islets

Dietary fibers, probably by generating short chain fatty acids (SCFA) through enterobacterial fermentation, have a beneficial effect on the control of glycemia in patients with peripheral insulin resistance. We studied the effect of propionate on glucose-induced insulin secretion in isolated rat pancreatic islets. Evidence is presented that propionate, one of the major SCFA produced in the gut, inhibits insulin secretion induced by high glucose concentrations (11.1 and 16.7 mM) in incubated and perfused pancreatic islets. This short chain fatty acid reduces [U-(14)C]-glucose decarboxylation and raises the conversion of glucose to lactate. Propionate causes a significant decrease of both [1-(14)C]- (84%) and [2-(14)C]-pyruvate (49%) decarboxylation. These findings indicate pyruvate dehydrogenase as the major site for the propionate effect. These observations led us to postulate that the reduction in glucose oxidation and the consequent decrease in the ATP/ADP ratio may be the major mechanism for the lower insulin secretion to glucose stimulus induced by propionate.     

Intracellular degradation of insulin and crinophagy are maintained by nitric oxide and cyclo-oxygenase 2 activity in isolated pancreatic islets

BACKGROUND INFORMATION: Pancreatic beta-cells require an optimal insulin content to allow instantaneous secretion of insulin. This is maintained by insulin biosynthesis and intracellular degradation of insulin. Degradation may be effected by crinophagy, i.e. the fusion of secretory granules with lysosomes. IL-1beta (interleukin 1beta) induces distinct changes of beta-cell lysosomes. To study the mechanisms for intracellular insulin degradation and crinophagy, isolated mouse pancreatic islets were exposed to IL-1beta and known pathways for IL-1beta actions were blocked. Intracellular insulin degradation was determined by following the fate of radioactively labelled insulin. Crinophagy was studied by ultrastructural analysis. The effects of blocking pathways for IL-1beta were monitored by measurements of nitrite and PGE(2) (prostaglandin E(2)). RESULTS: IL-1beta caused an enhancement of islet intracellular insulin degradation and an increase in the lysosomal incorporation of beta-cell secretory granules. The effects of IL-1beta were abolished by aminoguanidine, a selective inhibitor of inducible NOS (nitric oxide synthase), or by rofecoxib, a specific inhibitor of COX-2 (cyclo-oxygenase 2). In the absence of IL-1beta, nitroarginine, which is a selective inhibitor of constitutive NOS, caused a decrease in intracellular degradation of insulin in parallel with a decreased production of NO and PGE(2) by the islets. CONCLUSIONS: The correlation between the enhanced intracellular insulin degradation and lysosomal changes caused by IL-1beta suggests that insulin degradation may be effected by crinophagy. Under physiological conditions, significant beta-cell degradation of insulin may depend on the activity of COX-2, possibly stimulated by endogenous NO.     

Cyproheptadine metabolites inhibit proinsulin and insulin biosynthesis and insulin release in isolated rat pancreatic islets

The contribution of drug metabolites to cyproheptadine (CPH)-induced alterations in endocrine pancreatic -cells was investigated by examining the inhibitory activity of CPH and its biotransformation products, desmethylcyproheptadine (DMCPH), CPH-epoxide and DMCPH-epoxide, on hormone biosynthesis and secretion in pancreatic islets isolated from 50-day-old rats. Measurement of (pro)insulin (proinsulin and insulin) synthesis using incorporation of ³H-leucine showed that DMCPH-epoxide, DMCPH and CPH-epoxide were 22, 10 and 4 times, respectively, more potent than CPH in inhibiting hormone synthesis. The biosynthesis of (pro)insulin was also inhibited by CPH and DMCPH-epoxide in islets isolated from 21-day-old rat fetuses. The inhibitory action of CPH and its metabolites was apparently specific for (pro)insulin, and the synthesis of other islet proteins was not affected. Other experiments showed the metabolites of CPH were active in inhibiting glucose-stimulated insulin secretion but were less potent than the parent drug in producing this effect. CPH and its structurally related metabolites, therefore, have differential inhibitory activities on insulin synthesis and release. The observation that CPH metabolites have higher potency than CPH to inhibit (pro)insulin synthesis, when considered with published reports on the disposition of the drug in rats, indicate that CPH metabolites, particularly DMCPH-epoxide, are primarily responsible for the insulin depletion observed when the parent compound is given to fetal and adult animals.Abbreviations CPH cyproheptadine - CPH-epoxide cyproheptadine-10-11-epoxide - DMCPH desmethylcyproheptadine - DMCPH-epoxide desmethylcyproheptadine-10,11-epoxide - HPLC high-performance liquid chromatography - KBB Krebs biocarbonate buffer Recipient of a Society of Toxicology Predoctoral Research Fellowship.Present address: Department of Biochemistry, The University of Hong Kong, Hong Kong.     

Effects of glucose,exogenous insulin,and carbachol on C-peptide and insulin secretion from isolated perifused rat islets

Isolated perifused rat islets were stimulated with glucose, exogenous insulin, or carbachol. C-peptide and, where possible, insulin secretory rates were measured. Glucose (8-10 mm) induced dose-dependent and kinetically similar patterns of C-peptide and insulin secretion. The addition of 100 nm bovine insulin had no effect on C-peptide release in response to 8-10 mm glucose stimulation. The addition of 100 nm bovine insulin or 500 nm human insulin together with 3 mm glucose had no stimulatory effect on C-peptide secretion rates from perifused rat islets. Stimulation with carbachol plus 7 mm glucose enhanced both C-peptide and insulin secretion, and the further addition of 100 nm bovine insulin had no inhibitory effect on C-peptide secretory rates under this condition. Perifusion studies using pharmacologic inhibitors (genistein and wortmannin) of the kinases thought to be involved in insulin signaling potentiated 10 mm glucose-induced secretion. The results support the following conclusions. 1) C-peptide release rates accurately reflect insulin secretion rates from collagenase-isolated, perifused rat islets. 2) Exogenously added bovine insulin exerts no inhibitory effect on release to several agonists including glucose. 3) In the presence of 3 mm glucose, exogenously added bovine or human insulin do not stimulate endogenous insulin secretion.     

Effect of tetracaine and lidocaine on insulin release in isolated mouse pancreatic islets

The effect of tetracaine and lidocaine on insulin secretion and glucose oxidation by islets of ob/ob-mice was measured. Tetracaine, at a concentration of 1 microM to 0.1 mM, did not markedly influence the basal (3 mM glucose) insulin secretion, whereas 0.5-3.5 mM induced a marked increase. At 7 mM glucose, there was a dose-dependent increase with 0.1-2.5 mM tetracaine. Insulin release induced by 20 mM glucose was potentiated by 0.1 mM and 0.5 mM tetracaine, but this effect disappeared at 1 mM tetracaine. The stimulatory effect of 0.5-1 mM tetracaine on basal insulin release was blocked by the secretory inhibitors, adrenaline (1 microM), clonidine (1 microM) and by Ca2+-deficiency, but the stimulation by 3.5 mM tetracaine was not reduced by 1 microM clonidine or Ca2+ deficiency. Atropine (10 microM) did not affect the stimulation by 0.5 mM tetracaine at 3 mM glucose or by 0.25 mM tetracaine at 20 mM glucose. Tetracaine, at 0.1 mM, potentiated the secretory stimulation of 20 mM L-leucine, 20 mM D-mannose, or 1 microM glibenclamide. Mannoheptulose, 10 mM, abolished the combined effects of 0.1 mM tetracaine and 10 mM glucose. Lidocaine, 1-5 mM, stimulated basal insulin release, but 1 microM-1 mM of the drug did not affect glucose-induced (20 mM glucose) insulin release and 5 mM lidocaine inhibited glucose stimulation. The oxidation of 10 mM D-[U-14C]glucose was slightly enhanced by 0.1 and 1 mM tetracaine. The results indicate that tetracaine and lidocaine, at certain concentrations, can induce insulin release and that tetracaine potentiates secretion induced by other secretagogues. It is concluded that these effects may be associated with beta-cell functions related to the adrenergic receptors but probably not to cholinergic receptors.     

Interaction of somatostatin and calcium in regulating insulin release from isolated pancreatic islets of rats.

The effect of synthetic somatostatin on insulin release was studied in vitro by using isolated islets of rats. Somatostatin, with concentrations from 10 ng/ml to 10μg/ml, inhibited insulin release induced by 16.7 mM glucose. Insulin release elicited by 10 μg/ml glucagon or 2 mM dibutyryl cyclic AMP was likewise inhibited by 100ng/ml somatostatin. By raising the calcium concentration of the incubation medium to 6 mM, glucose-induced insulin release was fully restored even in the presence of somatostatin.However, the same maneuver only partially counteracted the somatostatin inhibition of dibutyryl cyclic AMP-induced insulin release. These results suggest the involvement of calcium mobilization process in the inhibitory action of somatostatin.