Impaired glucose priming of insulin secretion from perfused pancreas in aged female rats.

Effects of age and glucose levels on insulin secretion and synthesis were studied in the perfused pancreas of young (2-month-old) and older (10-month-old) female Wistar rats. Insulin secretion induced by 16.7 mM glucose showed a triphasic pattern: an early spike and fall (first phase, 0-6 min), followed by a sustained gradual increase (second phase, 7-120 min) and a gradual decreased release thereafter (third phase, 121-360 min) during the perfusion period of 360 min. First and second phase insulin secretion, but not third phase, were lower in older rats than in young rats. Insulin synthesis in old rat pancreas perfused with 16.7 nM glucose for 360 min was much greater than that of young rats. Second phase insulin secretion was restored to comparable levels by 28 mM glucose in older rats. Repeated pulses of 28 mM glucose potentiated subsequent insulin secretion in young rats, but not in older rats. These findings provide further evidence that sensitivity to glucose in pancreatic B cells is altered by aging.     

Differential sensitivity of pancreatic beta-cells to phorbol ester TPA and C-kinase inhibitor H-7 in nonpregnant and pregnant rats

In order to elucidate the possible role of C-kinase in exaggerated insulin release in pregnancy, the effects of phorbol ester TPA and a C-kinase inhibitor H-7 were investigated using the isolated perfused pancreas from nonpregnant and pregnant rats. At the termination of perfusion, the insulin content of the perfused pancreas was determined to estimate insulin biosynthesis. Insulin release from the perfused pancreas was markedly augmented by 20 nM TPA in the presence of 4.4 mM glucose in pregnant rats, but not in nonpregnant rats. When glucose concentrations in the perfusate were raised to 16.7 mM, insulin release from the perfused pancreas was profoundly enhanced in pregnant rats. TPA further augmented insulin release, but the insulin content was not affected by TPA. In contrast to the considerable effect of TPA in the presence of 4.4 mM glucose, the potentiating effect of TPA on insulin release was rather weaker in pregnant than in non-pregnant rats in the presence of 16.7 mM glucose. The release of insulin induced by 16.7 mM glucose was inhibited by the addition of 100 microM H-7 in nonpregnant rats, whereas insulin release from pregnant rat pancreases was not altered. Thus, the effect of TPA and H-7 on insulin release can be more clearly observed in the beta-cells of nonpregnant rats than those of pregnant ones when maximal concentrations of glucose are used as a stimulant. Exaggerated insulin release caused by glucose in pregnancy may be due to already fully activated C-kinase in the beta-cells.     

Insulin secretion: Combined tolbutamide, forskolin and TPA mimic action of glucose

We have proposed that the two phases of glucose-induced insulin secretion are regulated by two distinct branches of the calcium messenger system: the initial phase by a calmodulin branch, and the sustained phase by a C-kinase branch. To provide further support for this concept, we examined the separate and combined effects of tolbutamide, TPA, and forskolin upon insulin secretion from rat islets perifused in the absence of added fuels. Addition of 200 μM tolbutamide to the perifusate induces only a first phase of insulin secretion, addition of 200 nM TPA only a second phase, and addition of 10 μM forskolin only a small elevation in the basal rate of secretion. The combination of tolbutamide and TPA induces a biphasic secretory response qualitatively and quantitatively similar to that evoked by an increase in glucose concentration from 2.75 to 7 mM. The combination of TPA, tolbutamide, and forskolin evokes a biphasic pattern of insulin secretion qualitatively and quantitatively similar to that evoked by an increase in glucose concentration from 2.75 to 10 mM.     

Effect of adenosine triphosphate (ATP) on the secretion of insulin induced by tolbutamide in the absence of glucose

Our experiments were carried out on the isolated perfused rat pancreas. The effect of ATP on insulin secretion induced by tolbutamide (a hypoglycemic sulfonylurea) was studied in the absence of glucose. The addition of ATP (0.165 mmol/l) to the perfusion medium did not significantly modify the first phase induced by tolbutamide (0.4 mmol/l) but potentiated the second phase.     

Cyproheptadine and beta cell function in the rat: insulin secretion from pancreas segments in vitro.

Pancreatic islet cell vacuolization, hyperglycemia, and glucose intolerance develop in rats after oral administration of cyproheptadine (CPH). In order to determine whether these effects were associated with abnormal insulin secretion, pancreas segments from CPH-treated and control rats were compared for their ability to secrete insulin in response to several stimuli. Oral administration of CPH (45 mg/kg/day) to rats for 1 or 8 days inhibited glucose-mediated insulin secretion from pancreas segments obtained 3 and 24 hr after the last dose of the drug. Insulin secretion had returned to normal by 48 hr after drug administration. Intraperitoneal administration of the drug was less effective than oral administration in inhibiting in vitro insulin secretion. Other stimuli for insulin secretion (tolbutamide, glucagon, L-leucine, and dibutyryl 3',5'cyclic AMP), like glucose, were incapable of releasing normal amounts of insulin from pancreas segments of CPH-treated rats. CPH and a metabolite, desmethyl-CPH, inhibited glucose-stimulated insulin secretion when added in vitro to pancreas segments from control rats. This suggests that the inhibition of insulin secretion in pancreas segments taken from animals treated with CPH could be due, at least in part, to the presence of drug and its metabolite in the tissue. A previously observed reduction in the pancreatic content of insulin in CPH-treated rats may also contribute to the abnormal insulin release in animals given the drug.     

Selective potentiation of 5-methyl-2-(1-methylcyclohexyl)-4-oxazoleacetic acid (AD-4610) on glucose-induced insulin secretion

In the perfused pancreas from normal SD rats, AD-4610 (0.01-0.1 mM) potentiated biphasic insulin secretion induced by 7.5 mM of glucose. The concentration-response curve of insulin secretion to glucose was shifted leftwards with AD-4610 (0.1 mM) without altering either the threshold concentration of glucose to induce insulin secretion or the maximal insulin response to glucose, indicating increased sensitivity of the pancreatic B-cells to glucose. On the other hand, AD-4610 was 10-fold less effective in altering insulin secretion induced by arginine and glyceraldehyde. The effect of AD-4610 on insulin secretion and glucose metabolism was compared with that of tolbutamide in vivo. AD-4610 (100 mg/kg) potentiated insulin secretion induced by an intravenous glucose load, and also accelerated glucose metabolism without altering basal insulin secretion in normal rats. On the other hand, tolbutamide (20 mg/kg) increased basal insulin secretion, but slightly decreased glucose-induced insulin secretion. In yellow KK mice with hyperglycemia, AD-4610 (10-100 mg/kg) had a dose-dependent hypoglycemic action, but tolbutamide did not. Thus, AD-4610 stimulated insulin secretion in a glucose-dependent fashion and enhanced glucose metabolism in vivo. These results suggest that AD-4610 selectively potentiates glucose-induced insulin secretion by increasing the sensitivity of pancreatic B-cells to glucose and may be useful for treating human NIDDM through a different mechanism than that of tolbutamide.     

Insulin secretion: Combined effects of phorbol ester and A23187

The effect of the ionophore, A23187, and/or the phorbol ester, 12-0-tetradecanoyl-phorbol-13-acetate (TPA), on insulin secretion were compared with those of glucose. Glucose induces a biphasic pattern of insulin secretion; A23187 a comparable initial spike but no second phase; and TPA a slowly progressive increase. Combined A23187 and TPA evoke a pattern similar to that induced by glucose. Forskolin enhances both phases of glucose-induced and of TPA-A23187-induced insulin secretion. These results are interpreted in terms of a model of cell activation in which two branches of the calcium messenger system, the calmodulin branch and the C-kinase branch, control, respectively, the initial and sustained phases of insulin secretion.     

Effects of inhibitors on aldolase breakdown after its microinjection into HeLa cells.

The tumour-promoting phorbol ester 12-O-tetradecanoylphorbol 13-acetate (TPA) induces insulin secretion from isolated pancreatic islets, and this suggests a potential role for protein kinase C in the regulation of stimulus-secretion coupling in islets. In the present study, the hypothesis that the insulinotropic effect of TPA is mediated by activation of protein kinase C in pancreatic islets has been examined. TPA induced a gradual translocation of protein kinase C from the cytosol to a membrane-associated state which correlated with the gradual onset of insulin secretion. The pharmacologically inactive phorbol ester 4 alpha-phorbol 12,13-didecanoate did not mimic this effect. TPA also induced a rapid time-dependent decline of total protein kinase C activity in islets and the appearance of a Ca2+- and phospholipid-independent protein kinase activity. Insulin secretion induced by TPA was completely suppressed (IC50 approximately 10 nM) by staurosporine, a potent protein kinase C inhibitor. Staurosporine also inhibited islet cytosolic protein kinase C activity at similar concentrations (IC50 approximately 2 nM). In addition, staurosporine partially (approximately 60%) inhibited glucose-induced insulin secretion at concentrations (IC50 approximately 10 nM) similar to those required to inhibit TPA-induced insulin secretion, suggesting that staurosporine may act at a step common to both mechanisms, possibly the activation of protein kinase C. However, stimulatory concentrations of glucose did not induce down-regulation of translocation of protein kinase C, and the inhibition of glucose-induced insulin release by staurosporine was incomplete. Significant questions therefore remain unresolved as to the possible involvement of protein kinase C in glucose-induced insulin secretion.     

Glucose regulation of arginine-induced pancreatic somatostatin release from the isolated perfused rat pancreas

The effects of glucose alone, combinations of glucose with arginine or tolbutamide and either arginine or tolbutamide alone, on somatostatin, insulin, and glucagon secretion were investigated using the isolated perfused rat pancreas. When glucose alone was raised in graded increments at 15-min intervals from an initial concentration of 0 mM to a maximum of 16.7 mM, somatostatin as well as insulin in the perfusate increased with the glucose, while glucagon decreased. The similarity of the glucose stimulated somatostatin and insulin release was especially evident when the perfusate glucose was increased from an initial dose of 4.4 mM rather than 0 mM to 8.8 mM or 16.7 mM. In addition, glucose at concentrations varying from 4.4 mM to 11 mM dose-dependently enhanced arginine-induced somatostatin and insulin release and suppressed glucagon release dose-dependently as before. Arginine in the absence of glucose was not capable of stimulating somatostatin secretion whereas tolbutamide, in contrast, was capable of stimulating somatostatin secretion even in the absence of glucose.     

Neural regulation of glucose-stimulated insulin secretion in younger and older Fischer 344 rats

Neural regulation of insulin secretion of in situ innervated perfused pancreases was evaluated in younger (5 months) and older (26 months) Fischer 344 rats. In one protocol, the central nervous system (CNS) was intact throughout the entire 120-min perfusion period. In the other protocol, the CNS was intact only through the first 20 min of the 120-min perfusion, whereupon the CNS was ablated via anoxia. In both protocols, a modified Krebs-Ringer buffer containing glucose at 200 mg/dl was perfused through the pancreas at a rate of 4.8 ml/min by using a constant flow perfusion pump. Insulin secretion (ng.min-1) of younger and older CNS-intact rats did not differ significantly. After the ablation of the neural regulation of the pancreas, glucose-stimulated insulin secretion of younger rats was significantly lower, relative to the average insulin secretion before ablation (i.e., min 1-20) of CNS-intact animals. This would suggest that the nature of neural control of insulin secretion in younger rats is potentiation. In contrast, insulin secretion of older CNS-ablated animals was similar, or generally increased, when the data were expressed either on an absolute or a relative basis to preablation values, respectively. Thus, these data suggest that the neural regulation of glucose-stimulated insulin secretion in younger versus older rats is significantly different.     

Secretion of glucagon and insulin in hypophysectomized rats: effect of tolbutamide.

Normal and hypophysectomized (hypox) rats, fed ad libitum, received intraperitoneal injections of tolbutamide (75 mg/kg/day) or of saline for 6 weeks. 24 h after the last injection, blood samples were taken for glucose, insulin and glucagon determinations. In normal rats, tolbutamide treatment did not alter serum glucose, insulin and glucagon, although it suppressed the secretion of insulin and glucagon by the pancreatic islets. In hypox rats, tolbutamide decreased serum glucose and insulin, elevated serum glucagon and stimulated the secretion of glucagon, but not that of insulin by the pancreatic islets. In addition, tolbutamide treatment increased the glucagon response to arginine in normal, but not in hypox rats. The serum glucose response to arginine was decreased by tolbutamide treatment and by hypophysectomy and, thus, appeared independent of the glucagon rise or preexisting glucagon level. We conclude that tolbutamide treatment decreased the secretion of glucagon and insulin in normal rats and stimulated that of glucagon in hypox rats, perhaps because of the low levels of insulin in the serum and in the pancreas of the latter. Our results are compatible with the hypothesis that the pancreatic action of tolbutamide is influenced by the pituitary.     

Potassium ions and the secretion of insulin by islets of Langerhans incubated in vitro

1. A method was devised for the isolation of islets of Langerhans from rabbit pancreas by collagenase digestion in order to study the influx and efflux of K(+) in islets during insulin secretion. 2. Glucose-induced insulin release was accompanied by an increased rate of uptake of (42)K(+) by the islets of Langerhans, though this was not the case for secretion in response to tolbutamide. Ouabain significantly inhibited the uptake of (42)K(+) by islet tissue. 3. No significant increase in the rate of efflux of (42)K(+) was demonstrated during active insulin secretion. 4. Slices of rabbit pancreas were incubated in media of different K(+) content, and rates of insulin release were determined. Alteration of the K(+) concentration of the medium between 3 and 8mm had no effect on the rate of insulin release by pancreas slices. However, decrease of the K(+) concentration to 1mm resulted in inhibition of secretion in response to both glucose and to tolbutamide. Conversely, an increase in K(+) concentration increased rates of insulin release in response to both these stimuli. 5. It is concluded that, though unphysiological concentrations of K(+) may influence the secretion of insulin, fluxes of K(+) in the islets do not appear to be important in the initiation of insulin secretion.     

Effect of leptin on insulin, glugacon and somatostatin secretion in the perfused rat pancreas.

We have investigated the effect of rat leptin as well as the 22-56 fragment of this molecule on pancreatic hormone secretion in the perfused rat pancreas. In pancreases from fed rats, leptin failed to alter the insulin secretion elicited by glucose, arginine or tolbutamide, but inhibited the insulin response to both CCK-8 and carbachol, secretagogues known to act on the B-cell by increasing phospholipid turnover. This insulinostatic effect was also observed with the 22-56 leptin fragment. In pancreases obtained from 24-hour fasted rats, no effect of leptin on carbachol-induced insulin output was found, perhaps as a consequence of depressed B-cell phospholipid metabolism. Leptin did not influence glucagon or somatostatin release. Our results do not support the concept of leptin as a major regulator of B-cell function. Leptin inhibition of carbachol-induced insulin output might reflect a restraining effect of this peptide on the cholinergic stimulation of insulin release.     

Biotin enhances glucose-stimulated insulin secretion in the isolated perfused pancreas of the rat

The effects of biotin on insulin secretion in pair-fed control rats and biotin-deficient rats were investigated using the method of isolated pancreas perfusion. Isolated pancreas perfusion was performed using 20 mM glucose, 10 mM arginine, and 20 mM glucose plus various concentrations of biotin (20 mM glucose + biotin solution) as stimulants of insulin secretion. The insulin response to 20 mM glucose in biotin-deficient rats was approximately 22% of that seen in control rats. The level of the insulin response to 10 mM arginine was also significantly lower in biotin-deficient rats than in control rats. These results indicate that insulin release from the pancreas was disturbed in biotin-deficient rats. The insulin responses to 20 mM glucose + 1 mM biotin in biotin-deficient and control rats increased to 165% and 185%, respectively, of that to 20 mM glucose. These biotin-induced increases in glucose-stimulated insulin release were evident within the first few minutes of the infusion. An enhancement of the arginine-induced insulin response in control rats was not found when arginine and biotin was administered. These results suggest that biotin may play an important role in the mechanism by which glucose stimulates insulin secretion from the beta cells of the pancreatic islets.     

Effects of porcine diazepam-binding inhibitor on insulin and glucagon secretion in vitro from the rat endocrine pancreas.

Porcine diazepam-binding inhibitor (pDBI) is a novel peptide that has been isolated from the small bowel of the pig, and that occurs also in the islet D-cells. We have studied its effects on hormone release in vitro from the endocrine pancreas of the rat. In isolated islets, pDBI (10(-9)-10(-6)M) did not affect basal insulin release at 3.3 mM glucose, whereas stimulated release at 8.3 mM glucose was dose-dependently suppressed by 32-69% (P less than 0.01). Furthermore, insulin secretion stimulated by either 16.7 mM glucose or 1 mM IBMX (3-isobutyl-1-methylxanthine) or 1 micrograms/ml glibenclamide was suppressed by pDBI at 10(-8) M (by 28-30%, P less than 0.05) and 10(-7) M (by 43-47%, P less than 0.01). In contrast, islet insulin secretion induced by 20 mM arginine was unaffected by these concentrations of pDBI. In the perfused rat pancreas, pDBI (10(-8) M) enhanced by 30% (P less than 0.05) the first phase (0-5 min) of arginine-stimulated insulin release, whereas the second phase (5-20 min) was unchanged. Moreover, pDBI suppressed by 28% (P less than 0.05) the second phase of arginine-induced glucagon release. Arginine-induced somatostatin release was not significantly affected by the peptide. Since pDBI immunoreactivity has been localized also to islet D-cells, the present results suggest that pDBI may act as a local modulator of islet hormone release.     

Effectiveness of hypoglycemic agents in guinea pigs exposed to mixed gamma-neutron radiations

The effect of 200, 1000, and 5000 rads of mixed gamma-neutron radiations on total blood reducing sugar and blood glucose levels in guinea pigs was investigated 2 and 24 hours, and 9, 22, and 60 days postirradiation. In addition, the effectiveness of insulin and tolbutamide in these animals was evaluated before and after irradiation. Glucose increased to a lesser degree and later than did the nonglucose fraction of the blood sugar. Insulin and tolbutamide were at least as effective in irradiated animals as in unirradiated ones except after 5000 rads, when tolbutamide was significantly less effective. These results suggest that: (1) insufficient insulin is released by the pancreas in response to elevated blood sugar levels following irradiation; (2) the pancreas does produce insulin at these times and is able to release it in response to tolbutamide; and (3) a decrease in insulin production occurs following supralethal doses of radiation.     

Effects of protein kinase C activation on the regulation of the stimulus-secretion coupling in pancreatic beta-cells.

Effects of protein kinase C (PKC) activation on the insulin-secretory process were investigated, by using beta-cell-rich suspensions obtained from pancreatic islets of obese-hyperglycaemic mice. The phorbol ester 12-O-tetradecanoylphorbol 13-acetate (TPA), which is known to activate PKC directly, the muscarinic-receptor agonist carbamoylcholine and high glucose concentration enhanced the phosphorylation of a specific 80 kDa PKC substrate in the beta-cells. At a non-stimulatory glucose concentration, 10 nM-TPA increased insulin release, although there were no changes in either the cytoplasmic free Ca2+ concentration ([Ca2+]i) or membrane potential, as measured with the fluorescent indicators quin-2 and bisoxonol respectively. At a stimulatory glucose concentration TPA caused a lowering in [Ca2+]i, whereas membrane potential was unaffected. Despite the decrease in [Ca2+]i, there was a large stimulation of insulin release. Addition of TPA lowered [Ca2+]i also in beta-cells stimulated by tolbutamide or high K+, although to a lesser extent than in those stimulated by glucose. There was no effect of TPA on either Ca2+ buffering or the ability of Ins(1,4,5)P3 to release Ca2+ in permeabilized beta-cells. However, the phorbol ester inhibited the rise in [Ca2+]i in response to carbamoylcholine, which stimulates the formation of InsP3, in intact beta-cells. Down-regulation of PKC influenced neither glucose-induced insulin release nor the increase in [Ca2+]i. Hence, although PKC activation is of no major importance in glucose-stimulated insulin release, this enzyme can serve as a modulator of the glucose-induced insulin-secretory response. Such a modulation involves mechanisms promoting both amplification of the secretory response and lowering of [Ca2+]i.     

Insulin release from a cloned hamster B-cell line (HIT-T15). The effects of glucose, amino acids, sulphonylureas and colchicine

Insulin release from statically incubated HIT-T15 cells was maximally stimulated by glucose, L-arginine and L-leucine. L-arginine stimulated insulin release in the absence of glucose. Glucose induced insulin release was potentiated by the addition of L-leucine, L-arginine and the two in combination. Both glibenclamide and chlorpropamide stimulated insulin release from HIT-T15 cells. Glibenclamide was the more potent and equivalent in insulinotrophic action to 7.5 mmol/l glucose. Only chlorpropamide significantly potentiated glucose induced insulin release. Perifused HIT-T15 cells produced a reproducible biphasic insulin response to glucose challenge which was characterised by a pronounced and sustained first phase and a reduced second phase. The stimulation of phase I by glibenclamide alone and the inhibition of phase II of glucose induced insulin release by colchicine suggested the presence of a readily available pool of insulin granules which was not rapidly restored by insulin biosynthesis and granule margination.     

Extracellular ATP potentiates the secretion of insulin induced by tolbutamide

Our experiments were carried out on the isolated perfused rat pancreas. The effect of extracellular ATP (8 microM) on insulin secretion induced by tolbutamide (0.04 mM) was studied in the presence of substimulating glucose concentration 4.2 mM (0.75 g/l). ATP (8 microM), ineffective per se at this concentration, highly potentiated the insulin secretion induced by tolbutamide (0.04 mM).     

Insulin release from the pancreas and fuel metabolism during late gestation in chemically diabetic rats

The effects of chemical diabetes and fasting on fuel metabolism and insulin secretory activity in late pregnancy were investigated. Female Wistar rats were made chemically diabetic (CD) by intravenous injection of streptozotocine (30 mg/kg) 2 weeks before conception. When CD pregnant rats were fed, plasma glucose and insulin levels were not significantly different from those of normal pregnant rats. Ketone body levels, however, were higher in CD pregnant rats than in normal pregnant rats, indicating insulin resistance in CD rats. Insulin secretion from the perfused pancreas caused by arginine or glucose was markedly decreased in CD pregnant rats. The pregnant rats were fasted for 2 days, from day 19 to 21 of gestation. Plasma glucose and insulin concentrations decreased similarly in the two groups, whereas ketone body concentrations in CD pregnant rats were significantly higher than those in normal pregnant rats. Glucose-induced insulin secretion by the perfused pancreas was markedly attenuated by fasting and was not significantly different in normal and CD pregnant rats. These observations suggest that diabetes mellitus accelerates starvation in late gestation, due to increased insulin resistance and poor insulin secretion, and that fasting in diabetic pregnancy amplifies ketogenesis.