Glucose dependency of arginine vasopressin-induced insulin and glucagon release from the perfused rat pancreas

The purpose of this study was to investigate the glucose dependency of arginine vasopressin (AVP)-induced insulin, glucagon, and somatostatin release from the perfused rat pancreas. AVP (30 or 300 pmol/L) was tested in the presence of a glucose concentration of 0, 1.4, 5.5 (basal level), or 20 mmol/L. The rates of insulin release at 0 and 1.4 mmol/L glucose were approximately 70% to 80% and 60% to 70% less, respectively, than that at the baseline level. AVP (30 or 300 pmol/L) failed to change insulin release at 0 and 1.4 mmol/L glucose. At the basal glucose level, AVP (300 pmol/L) induced a biphasic insulin release, a peak followed by a sustained phase. In addition, the combination of glucose (20 mmol/L) and AVP (300 pmol/L) induced a higher insulin peak and sustained phase than 20 mmol/L glucose alone. The rates of glucagon release at 0 and 1.4 mmol/L glucose were about 3- and 2-fold more, respectively, than that at the baseline level. At 0 and 1.4 mmol/L glucose, both 30 and 300 pmol/L AVP caused a higher glucagon peak and sustained phase than 0 and 1.4 mmol/L glucose alone. At the basal glucose level, AVP (30 or 300 pmol/L) induced a biphasic glucagon release, a peak followed by a sustained phase. The rate of glucagon release at 20 mmol/L glucose was approximately 60% to 70% less than that at the baseline level. When AVP (300 pmol/L) was administered in 20 mmol/L glucose, it induced a transient glucagon peak, which was 2.4-fold of the baseline level. At all glucose concentrations tested, AVP (30 or 300 pmol/L) failed to change somatostatin release. These results suggested that (1) hypoglycemia directly increases glucagon and decreases insulin release; (2) AVP induces insulin and glucagon release by a direct action on beta and alpha cells, respectively; (3) AVP induces insulin and glucagon release in a glucose-dependent manner-the higher the glucose concentration, the greater the enhancement of AVP-induced insulin release, whereas the lower the glucose concentration, the higher the enhancement of AVP-induced glucagon release; and (4) alpha cells are more sensitive to AVP than beta cells in hormone release.     

Effects of gamma-aminobutyric acid on insulin, glucagon, and somatostatin release from isolated perfused dog pancreas

The effects of gamma-aminobutyric acid (GABA) on the secretion of insulin, glucagon, and somatostatin were studied in the isolated dog pancreas. Insulin secretion was inhibited in a dose-related fashion for 10 min or more by as little as 1 microM GABA. A prompt but small and transitory rise in somatostatin secretion, lasting only 1 min, occurred at GABA concentrations of 10 and 100 microM, levels that exert inhibitory effects on nervous tissue. Bicuculline, a GABA antagonist, inhibited insulin secretion and did not antagonize GABA-mediated insulin inhibition. The results suggest that GABA in concentrations that are known to exist in islet tissue can influence the secretion of islet hormones.     

Effects of galanin on the release of insulin, glucagon and somatostatin from the isolated, perfused dog pancreas

Galanin is a 29 amino acid peptide which has been found in intrapancreatic nerves. The effects of galanin, adrenergic and cholinergic blockade as well as somatostatin on the hormone release from the isolated perfused dog pancreas were studied. It was found that galanin dose-dependently inhibited insulin (P less than 0.001) and somatostatin (P less than 0.001) but not glucagon secretion at normal glucose levels. The lowest galanin concentration that caused a significant suppression of insulin and somatostatin secretion was 10(-11) and 10(-10) mol/l, respectively. Similar effects were evident during stimulation with 2.5 mmol/l arginine. Galanin (10(-9) mol/l) caused a more pronounced inhibition of insulin and somatostatin secretion at high (10 mmol/l) and normal (5 mmol/l) than at low glucose (1.3 mmol/l). In contrast, suppression of the glucagon secretion was only seen at low glucose (1.3 mmol/l). Perfusion of 10(-6) mol/l of atropine, phentolamine and propranolol had no effect on the galanin-mediated (10(-10) mol/l) inhibition of insulin and somatostatin secretion. Galanin (10(-12)-10(-10) mol/l) and somatostatin (10(-12)-10(-10) mol/l) were equipotent in inhibiting insulin secretion whereas only somatostatin exerted a suppression of the glucagon secretion at normal glucose. Thus, galanin exerts a differential effect on islet hormone secretion and may participate in the hormonal control of insulin, glucagon and somatostatin secretion.     

Studies on the mechanism of somatostatin action on insulin release. V. Effect of somatostatin analogues on arginine induced release of insulin and glucagon from the perfused rat pancreas.

Eighteen analogues of somatostatin have been used in order to elucidate the structure-activity relationship of the peptide on the release of insulin and glucagon from the isolated perfused rat pancreas. Neither the amino terminal nor a free carboxyl terminal seemed to be essential for the activity of the cyclic peptide. Addition of amino acids to the amino terminal did not decrease the activity. On the other hand, minor changes in the structure of linear somatostatin, which lead to the loss of ability to form a cyclic peptide, impaired the activity. Deletion of Asn5 was accompanied by decreased action on glucagon but not on insulin release. It seems that the major actions of somatostatin on the pancreas are bound to the amino acid sequence 4-13 in the molecule and to the ability of the molecule to cyclize.     

Multiple effects of leucine on glucagon, insulin, and somatostatin secretion from the perfused rat pancreas

The effects of increasing concentrations of leucine (0.2, 2.0, and 15.0 mmol/liter) on glucagon secretion from the perfused rat pancreas were examined at various glucose levels (0, 3.3, or 8.3 mmol/liter) and in the absence or presence of either arginine (5.0 mmol/liter) or glutamine (10.0 mmol/liter). At a low glucose concentration (3.3 mmol/liter), leucine caused a dose-related biphasic increase in glucagon output in the absence of arginine, but only a transient increase in the presence of the latter amino acid. These positive responses were markedly reduced and, on occasion, abolished at a high glucose concentration (8.3 mmol/liter). Moreover, at a low glucose concentration (3.3 mmol/liter) and in the presence of arginine, the highest concentration of leucine (15.0 mmol/liter) provoked a sustained and reversible inhibition of glucagon release. Likewise, leucine (15.0 mmol/liter) reversibly inhibited glucagon secretion evoked by glutamine in the absence of glucose. Thus, leucine exerted a dual effect on the secretion of glucagon, the inhibitory effect of leucine prevailing at a high concentration of the branched chain amino acid and when glucagon secretion was already stimulated by arginine or glutamine. At a physiological concentration (0.2 mmol/liter), however, leucine was a positive stimulus for glucagon release, especially in the absence of another amino acid. Concomitantly, leucine was always a positive stimulus for both insulin and somatostatin secretion. The intimate mechanisms involved in the dual effect of leucine on glucagon secretion remain to be elucidated.     

Effect of glucose/sulfonylurea interaction on release of insulin, glucagon, and somatostatin from isolated perfused rat pancreas.

The effect of a sulfonylurea, glibenclamide, on the release of insulin, glucagon, and somatostatin was studied in the isolated perfused rat pancreas. At glucose concentrations of 1.1 mM or less, the drug stimulated somatostatin release, whereas glucagon release, after 2-3 min of increase, was markedly inhibited. Insulin release was moderately stimulated, and maximal release occurred relatively late. A moderate glucose load (6.7 mM) inhibited glibenclamide-induced release of somatostatin, whereas the two in combination exerted an additive action on insulin release. Greater glucose loads, which by themselves would stimulate somatostatin release, only marginally suppressed glibenclamide-induced somatostatin release. The insulinogenic effect of these glucose levels was not modified by glibenclamide. Glibenclamide may thus stimulate both the alpha and beta as well as delta cells of the pancreas, depending on glucose concentration. We suggest a paracrine (local) interaction of somatostatin with the alpha and beta cells, which has an important role in the kinetics of insulin and glucagon release induced by sulfonylureas.     

Immediate and delayed effects of D-fructose upon insulin, somatostatin, and glucagon release by the perfused rat pancreas

Novel information was recently provided concerning the reciprocal effects of d-glucose and d-fructose upon their respective metabolism in rat pancreatic islets. In the light of such findings, this study aims at comparing the effects of d-glucose and d-fructose on insulin, somatostatin, and glucagon release from the isolated perfused rat pancreas. A rise in d-glucose concentration from 3.3 to 5.0 or 7.3 mM or the administration of d-fructose (17 and 40 mM) in the presence of 3.3 mM d-glucose stimulated insulin release in a concentration-related manner, but failed to affect somatostatin output. The secretion of glucagon was decreased in all cases. The secretory response to l-arginine (5 mM), 25 min after restoring the basal concentration of d-glucose, was more markedly affected, in terms of potentiation of insulin and somatostatin release and reduction of glucagon output, after prior administration of d-fructose than after a prior increase in d-glucose concentration. These findings argue against any major role for a paracrine regulation of hormonal release and, instead, are consistent with a causal link between metabolic and secretory events in the islet cells. Nevertheless, the present results emphasize differences in the response of distinct pancreatic endocrine cell types to the same or distinct hexoses.     

Inhibition of glucagon and insulin secretion from the perfused rat pancreas by a B-cell-selective somatostatin analog

The isolated perfused rat pancreas was used to study the effects of somatostatin and the analog des-Asn⁵-[D-Trp⁸, D-Ser¹³]-somatostatin on arginine-stimulated insulin and glucagon secretion. Even though the analog was found to inhibit glucagon secretion at concentrations of 10 and 100 ng/ml, it had a relatively more inhibitory effect on the B cell than on the A cell than did somatostatin itself. These data suggest that the A- and B-cell receptors for these two peptides differ.     

Kisspeptin-13 inhibits insulin secretion without affecting glucagon or somatostatin release: study in the perfused rat pancreas

Kisspeptins are a family of peptides encoded by the KISS1 gene, which binds to G-protein-coupled receptor (GPR54), an orphan GPR54 related to galanin receptors. Endogenous forms composed of 54, 14, and 13 amino acids have been identified. Kisspeptin and GPR54 mRNAs have been detected in pancreatic B and A cells. Furthermore, kisspeptin-54 has been shown to slightly stimulate the last phase of glucose-induced insulin secretion in mouse and human islets and to inhibit insulin release in MIN6 cells. We have investigated the effect of kisspeptin-13 on insulin, glucagon, and somatostatin secretion. The study was performed in the perfused rat pancreas. Glucose, arginine, carbachol, and exendin-4 were used as secretagogues. Hormones were measured by RIA. Kisspeptin-13 reduced glucose-induced insulin secretion in a dose-dependent manner (IC(50)=1.2 nM) and inhibited the insulin responses to both carbachol and exendin-4. Kisspeptin-13 blocked arginine-induced insulin secretion without affecting the glucagon or somatostatin responses to this amino acid, thus indicating that kisspeptin-13 influences B cells directly, rather than through an A- or D-cell paracrine effect. The reduction of the insulin response to exendin-4 induced by kisspeptin-13 was also observed in pertussis toxin-treated rats, thus suggesting an inhibition independent of G(i) proteins. In view of the potent insulinostatic effect of kisspeptin-13, it is tempting to speculate that kisspeptins may be implicated in the regulation of B-cell secretion.     

Effects of exogenous insulin, glucagon, and somatostatin on islet hormone secretion in the perfused chicken pancreas

The effects of exogenous insulin were examined in the isolated perfused chicken pancreas with the duodenum excluded. At low background glucose (50 mg/dl), exogenous insulin infused at a concentration of 20,000 microU/ml elicited clear stimulation of somatostatin secretion while simultaneously inhibiting glucagon release. When the background glucose concentration was elevated to 750 mg/dl, exogenous insulin, had no effect on either somatostatin or glucagon release. When graded doses of exogenous insulin were infused into the chicken pancreas at low background glucose, low concentrations (200 microU/ml) had little effect on somatostatin or glucagon release, but higher concentrations (2000 and 20,000 microU/ml) had clear effects on both somatostatin and glucagon secretion. Glucagon infused at 100 ng/ml stimulated both insulin and somatostatin release. When somatostatin was infused at 25 ng/ml, clear inhibition of glucagon was seen with insulin inhibited to a lesser extent. This study supports the notion of a negative feedback relation between B and D-cells of the pancreatic islets and suggests a paracrine mediation.     

Interactions of α-ketoisocaproate,glucose and arginine in the secretion of glucagon and insulin from the perfused rat pancreas

Summary The effects of-ketoisocaproate (KIC, 10 mmol/l) on glucagon and insulin release were studied in the in vitro perfused rat pancreas. The experiments were performed at low glucose concentration (3.3 mmol/l) in the absence or presence of arginine (10 mmol/l). In all the experiments KIC induced a marked and not rapidly reversible inhibition of glucagon release. This inhibition was more pronounced in the absence (76 percent) than presence of arginine (61 percent). These inhibitory patterns closely duplicated those which were seen in parallel experiments which included a rise in the concentration of glucose (from 3.3 to 11.1 mmol/l). KIC was also a potent stimulator of insulin release. The results are compatible with the view that the intracellular metabolism of KIC and glucose plays an essential role in the regulation of glucagon release by exogenous substrates.     

The interaction of Vasoactive Intestinal Polypeptide (VIP), glucose and arginine on the secretion of insulin,glucagon and somatostatin in the perfused rat pancreas

Summary Vasoactive Intestinal Polypeptide (VIP) increased the release of insulin, glucagon and somatostatin from the perfused rat pancreas. The amount of these hormones released was dependent upon the prevailing glucose concentration. VIP stimulated glucagon release in the absence of glucose, while insulin and somatostatin release were increased by VIP only in the presence of glucose concentrations of 4.4 mmol/l and above. Glucagon secretion stimulated by arginine in the presence of 4.4 mmol/l glucose was potentiated by VIP. In contrast, VIP did not induce any further increase in the secretion of insulin and somatostatin over that stimulated by arginine. At higher concentrations of glucose (6.7, 16.7, and 33.3 mmol/l) VIP continued to stimulate insulin and somatostatin release, this effect being synergistic on early-phase insulin release. The effects of VIP on islet cells thus depend on the levels of modulating nutrients.     

Effect of ventromedial hypothalamic lesions on the secretion of somatostatin,insulin, and glucagon by the perfused rat pancreas

Somatostatin, insulin, and glucagon secretion by the perfused pancreas were studied in adult female rats 10 days after ventromedial hypothalamic (VMH) lesions and in sham operated controls to assess the role of their hypothalamic control. Insulin secretion was significantly greater in VMH-lesioned rats both under basal conditions and after stimulation by theophylline and arginine plus theophylline. Basal glucagon secretion was greater in VMH-lesioned rats as was the glucagon response to theophylline alone and in combination with arginine. Basal somatostatin secretion was similar in VMH and control rats but somatostatin secretion induced by theophylline and by arginine plus theophylline was significantly increased in VMH-lesioned rats. Both the pancreatic content and concentration of somatostatin were increased in VMH-lesioned rats. These results indicate the presence of hyperresponsiveness of A, B, and D cells following VMH destruction and provide new evidence for a role of the hypothalamus in the regulation of pancreatic somatostatin secretion.     

The effect of growth hormone-releasing factor (GRF) on secretion of insulin, glucagon and somatostatin from perfused rat pancreas

To examine the effects of growth hormone-releasing factor (GRF) on islet hormone release, rat pancreas was perfused. rhGRF at the concentration of 10(-7) M or more enhanced insulin secretion stimulated by 16.7 mM glucose, hpGRF slightly enhanced insulin secretion as well. The insulin secretion induced by 10(-6) M rhGRF was completely inhibited by 10(-6) M propranolol. rhGRF at the concentration of 10(-8) M or more stimulated glucagon secretion even in the presence of 16.7 mM glucose. The glucagon secretion stimulated by 10(-6) M rhGRF was inhibited in the early period but increased thereafter by 10(-6) M propranolol. 10(-6) M rhGRF slightly stimulated glucagon secretion in the presence of 16.7 mM glucose when STZ diabetic rat pancreas was perfused. rhGRF at the concentration of 10(-6) M enhanced somatostatin secretion stimulated with 16.7 mM glucose. We concluded that rhGRF stimulated insulin, glucagon and somatostatin secretion and the insulin secretion was inhibited by beta-blocker. hpGRF stimulated insulin and glucagon secretion as well.     

Effects of endotoxin and interleukin-1 on glucagon and insulin secretion from the perfused rat pancreas.

This study evaluated the in vivo effects of endotoxin and interleukin-1 (IL-1) on the simultaneous secretion of glucagon and insulin. The hypothesis that endotoxin, or IL-1 as a mediator, induces hyperglucagonemia secondary to pancreatic hypersecretion of glucagon was examined. Hormone secretion was measured using the in vitro perfused rat pancreas preparation. In response to an arginine stimulus, glucagon secretion was neither stimulated nor inhibited significantly by endotoxin or IL-1. Insulin secretion was significantly potentiated with both endotoxin and IL-1. In response to a low-glucose stimulus, glucagon secretion was significantly inhibited by endotoxin treatment, while insulin secretion was increased by endotoxin or IL-1. These results indicate that neither endotoxin nor IL-1 treatment resulted in glucagon hypersecretion, although either of these agents could induce insulin hypersecretion. Thus, the mechanism of endotoxin-induced hyperglucagonemia cannot be explained by a hypersecretory state of glucagon secretion. The parallel respective effects of endotoxin and IL-1 on glucagon and insulin secretion are consistent with the concept that IL-1 mediates some of the effects of endotoxin on the endocrine pancreas.     

Effects of arginine and arginine plus somatostatin infusion on insulin release in diabetic patients submitted to pancreas allotransplantation

The present study was aimed at evaluating the role of the Autonomic Nervous System (ANS) in the insulin (IRI) response to arginine in humans. Nine patients who were recipients of simultaneous segmental pancreatic and renal grafts (6 receiving steroids and azathioprine as immuno suppression therapy, 3 treated with Cyclosporine A), 3 non-diabetic patients with kidney grafts (receiving steroid and azathioprine) and 10 normal subjects were studied. Arginine induced a clear IRI release in all subjects with no significant difference among the groups. Somatostatin (SRIF) inhibited IRI release to a similar degree in all subjects. Since the transplanted pancreas is completely denervated, these data suggest that the integrity of the ANS is not essential to the IRI response to arginine, nor for the inhibitory effect of SRIF on IRI release.     

Effects of hydrocortisone on glucose- and cholecystokinin-induced insulin release from the isolated perfused rat pancreas

The acute and chronic effects of hydrocortisone on insulin secretion were examined in the isolated perfused rat pancreas. In the first part of this study, the chronic effects of hydrocortisone on insulin release were examined using isolated perfused pancreas prepared from rats that had been given subcutaneous injections of hydrocortisone at doses of 1.25, 2.5, 5.0, and 10.0 mg/kg body weight once daily for 7 days. Hydrocortisone treatment led to a dose-dependent increase in insulin secretion in response to 8.3 mM glucose. The insulin response to 100 pM cholecystokinin (CCK-8) was also significantly higher in the hydrocortisone-treated rats than in the control group. However, the increment of insulin level over the value before CCK-8 addition in rats treated with hydrocortisone was not significantly different from that in the control rats. In the second part, the acute effects of hydrocortisone on insulin release were studied. Hydrocortisone (17-hydroxycorticosterone) at a concentration of 100 microM caused significant inhibition of the stimulatory effect of CCK-8 on insulin secretion. The inhibition started within 1 min of the beginning of hydrocortisone administration and ceased immediately after the termination of its infusion. We have demonstrated in this study a dual effect of hydrocortisone on insulin release: first, the potentiation of the insulin secretion stimulated by glucose but not by CCK-8 and, second, the inhibition of CCK-8-stimulated insulin secretion.