Acute effects of alloxan- and streptozotocin-induced insulin deficiency on somatostatin and glucagon secretion by the perfused isolated rat pancreatico-duodenal preparation

Summary The secretion of somatostatin and glucagon by the perfused rat pancreatico-duodenal preparation was examined in situ under control conditions and after the induction of acute insulin deficiency by alloxan or streptozotocin. A 10 min 0.625 mmol/l alloxan perfusion resulted in an immediate and transient increase in basal insulin and glucagon release and a slightly delayed and persistent increase in basal somatostatin secretion. The insulin responses to 16.7 mmol/l glucose, 1 mmol/l theophylline, and 19 mmol/l arginine alone or in combination were virtually eliminated by alloxan treatment, Somatostatin secretion in response to the stimuli was completely inhibited or markedly attenuated. The glucagon-suppressive effect of glucose was unaltered by alloxan and the stimulatory effect of arginine was enhanced. Addition of 1 g/ml porcine insulin to the perfusion medium did not modify the alterations in somatostatin and glucagon responses to arginine. Streptozotocin treatment 90 min prior to the onset of perfusion resulted in changes in somatostatin, glucagon, and insulin responses to glucose and arginine similar to those of alloxan. The present results are consistent with an effect of alloxan and streptozotocin on the D cell similar to that on the B cell, namely, interference with a glucose-mediated effect on hormone secretion.     

Effects of a thiazide diuretic (hydroflumethiazide) and a loop diuretic (bumetanide) on the endocrine pancreas: studies in vitro

Treatment with thiazide diuretics causes an impairment of the glucose metabolism. To study whether this is due to a direct effect on the endocrine pancreas, the effects of the thiazide hydroflumethiazide on the release of glucagon, insulin, and somatostatin from the isolated perfused pancreas of normal and alloxan diabetic dogs were examined. Hydroflumethiazide at concentrations ranging from 1 to 50 micrograms/mL stimulated the normal secretion of glucagon (P less than 0.001), insulin (P less than 0.001), and somatostatin (P less than 0.001) in a dose-dependent manner. The normal hormone responses evoked by 50 micrograms/mL of the thiazide were, however, modified by the prevailing glucose level: higher insulin (P less than 0.05) and somatostatin (P less than 0.05) and lower glucagon (P less than 0.05) were obtained at the high glucose concentration of 11 mmol/L rather than at the low glucose concentration of 1.3 mmol/L. In alloxan diabetes, insulin secretion was almost extinct and did not respond to hydroflumethiazide, whereas glucagon was dose-dependently stimulated (P less than 0.001). In addition, we looked at the effect of the loop diuretic, bumetanide. The infusion of bumetanide at doses ranging from 0.5 to 3 micrograms/mL did not alter the release of glucagon, insulin, and somatostatin in the presence of 5.5 mmol/L glucose. The results suggest that hydroflumethiazide possesses the ability to directly stimulate A cell secretion in the normal and alloxan diabetic pancreas. Whether this effect is of clinical importance for the diminution in glucose tolerance observed during thiazide therapy remains, however, uncertain.     

Long-term exposure of mouse pancreatic islets to oleate or palmitate results in reduced glucose-induced somatostatin and oversecretion of glucagon

AIMS/HYPOTHESIS: Long-term exposure to NEFAs leads to inhibition of glucose-induced insulin secretion. We tested whether the release of somatostatin and glucagon, the two other major islet hormones, is also affected. METHODS: Mouse pancreatic islets were cultured for 72 h at 4.5 or 15 mmol/l glucose with or without 0.5 mmol/l oleate or palmitate. The release of glucagon and somatostatin during subsequent 1 h incubations at 1 or 20 mmol/l glucose as well as the islet content of the two hormones were determined. Lipid-induced changes in islet cell ultrastructure were assessed by electron microscopy. RESULTS: Culture at 15 mmol/l glucose increased islet glucagon content by approximately 50% relative to that observed following culture at 4.5 mmol/l glucose. Inclusion of oleate or palmitate reduced islet glucagon content by 25% (at 4.5 mmol/l glucose) to 50% (at 15 mmol/l glucose). Long-term exposure to the NEFA increased glucagon secretion at 1 mmol/l glucose by 50% (when islets had been cultured at 15 mmol/l glucose) to 100% (with 4.5 mmol/l glucose in the culture medium) and abolished the inhibitory effect of 20 mmol/l glucose on glucagon secretion. Somatostatin content was unaffected by glucose and lipids, but glucose-induced somatostatin secretion was reduced by approximately 50% following long-term exposure to either of the NEFA, regardless of whether the culture medium contained 4.5 or 15 mmol/l glucose. Ultrastructural evidence of lipid deposition was seen in <10% of non-beta cells but in >80% of the beta cells. CONCLUSIONS/INTERPRETATION: Long-term exposure to high glucose and/or NEFA affects the release of somatostatin and glucagon. The effects on glucagon secretion are very pronounced and in type 2 diabetes in vivo may aggravate the hyperglycaemic effects due to lack of insulin.     

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.     

Modulation by alloxan of glucagon and insulin secretion in the isolated perfused rat pancreas.

The acute in vitro effect of alloxan on glucagon and insulin secretion from the isolated perfused rat pancreas was examined. Alloxan alone produced transient insulin secretion. Pretreatment with alloxan attenuated both the stimulatory effect of glucose on insulin secretion and the inhibitory effect of glucose on glucagon secretion. Exposure to alloxan in varying doses either partially or completely inhibited insulin secretion induced by arginine in the presence or absence of glucose. On the contrary, pretreatment with alloxan produced complex effects on arginine-induced glucagon secretion. In the absence of glucose, the response of glucagon to arginine infusion was lower in the pancreas exposed to alloxan than in the control experiment. In the presence of glucose, however, an apparently augmented response of glucagon to arginine was observed after exposure to higher doses of alloxan, suggesting an impaired inhibitory effect of glucose on arginine-induced glucagon secretion. These effects of pretreatment with alloxan on glucagon secretion can not be explained by earlier or simultaneous insulin secretion. Therefore, we conclude that alloxan acts not only on beta-cells, but also directly on alpha-cells, although the latter are less sensitive to this agent.     

Sulfonylurea-induced inhibition of glucagon secretion from the perfused rat pancreas: evidence for a direct,non-paracrine effect

Summary The effects of sulfonylurea on glucagon secretion were characterized in the perfused rat pancreas using glibenclamide (1 g/ml) or tolazamide (10 g/ml) in the presence of 3.3 mmol/1 glucose. Glucagon release, which was unaffected by glibenclamide at 2.75 mmol/1 calcium, was suppressed at 1.19 and 0.64 mmol/l but transiently stimulated at 0.25 mmol/l extracellular calcium. The insulinogenic effect of glibenclamide at 0.64 and 0.25 mmol/1 calcium was enhanced by 35% and 89%, respectively, compared to the response at 2.75 mmol/1 calcium. The stimulatory effect of the compound on somatostatin secretion, however, was lost at the lower calcium levels. The effects of tolazamide at 2.75 and 0.64 mmol/1 calcium mimicked those of glibenclamide, thus indicating that our results with the latter compound may be representative for all sulfonylureas. In pancreata from insulin-deficient alloxan diabetic rats, glibenclamide completely lost its inhibitory effect on glucagon release at 0.64 mmol/1 calcium. Inhibition was not restored by adding insulin (25 U/1) to the perfusate. However, when diabetic rats had been treated with insulin for 6–7 days, glibenclamide suppressed glucagon release at low calcium levels in the absence of stimulated insulin and somatostatin release. It is concluded that, at low calcium concentrations, sulfonylureas suppress glucagon secretion by a direct action on the A cell and not through paracrine interactions by insulin and somatostatin. Prolonged insulin deficiency impairs the sulfonylurea action on glucagon secretion.     

Difference in calcium dependency of insulin,glucagon and somatostatin secretion in response to glibenclamide in perfused rat pancreas

Summary The extracellular calcium requirements for insulin, glucagon and somatostatin release induced by 1 g/ml of glibenclamide have been compared in the perfused, isolated rat pancreas. In the absence of glucose, the drug evoked insulin release equally well at physiological (2.6 mmol/l) and low (0.25 mmol/l) levels of total calcium. In contrast, glibenclamide evoked somatostatin release at 2.6 but not at 0.25 mmol/l of calcium. At 2.6 mmol/l of calcium, glibenclamide evoked bimodal effects (stimulation followed by inhibition) on glucagon secretion. At 0.25 mmol/l of calcium, basal secretory rates of glucagon were elevated and a small stimulatory effect of glibenclamide was seen. Addition of 0.5 mmol/l of EGTA to media with low calcium concentrations uniformly abolished the A, B and D cell secretory responses to glibenclamide. The possible modulation of calcium dependency by a non-stimulatory concentration of glucose was tested by its addition at 3.3 mmol/l to the perfusion media. Glucose enhanced glibenclamide-induced insulin secretion, both at 0.25 and 2.6 mmol/l of calcium. However, at 0.25 mmol/l of calcium, the enhancing effect of glucose was more pronounced than at 2.6 mmol/l. At 2.6 mmol/l of calcium, glucose diminished the somatostatin and abolished the glucagon response to glibenclamide. At 0.25 mmol/l of calcium, glucose did not influence somatostatin release while the presence of the sugar diminished basal and glibenclamide-induced glucagon secretion. The present data confirm the requirement of extracellular calcium for A, B and D cell secretion, demonstrating different calcium dependencies for the cell types and indicate that this dependency can, in part, be modulated by glucose.     

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.     

Neurotransmitters partially restore glucose sensitivity of insulin and glucagon secretion from perfused streptozotocin-induced diabetic rat pancreas

Summary To elucidate the mechanisms of insensitivity of hormone secretion to glucose in streptozotocin-induced diabetic rat islets, we investigated the effects of acetylcholine (ACh) and norepinephrine on insulin and glucagon secretion in response to changes in glucose concentration, using perfused pancreas preparations. Basal insulin secretion at a blood glucose level of 5.6 mmol/l was significantly higher and basal glucagon secretion significantly lower in streptozotocin-induced diabetic rats than in controls, and neither high (16.7 mmol/l) nor low (1.4 mmol/l) blood glucose concentrations influenced insulin or glucagon secretion. Addition of 10^–6 mol/l ACh to the perfusate increased glucose-stimulated insulin secretion. Also, 10^–6 mol/l ACh, 10^–7 mol/l norepinephrine, as well as a combination of both, induced marked glucagon secretion, this was suppressed by high blood glucose level. Although simultaneous addition of 10^–6 mol/l ACh and 10^–7 mol/l norepinephrine induced only a slight increase in glucagon secretion in response to glucopenia, there was a significant increase in glucagon secretion in conjunction with an ambient decrease in insulin. Histopathological examination revealed a marked decline in acetylcholinesterase and monoamine-oxidase activities in the islets of streptozotocin-induced diabetic rats. We speculate that reduction of the potentiating effects of ACh and norepinephrine lessens glucose sensitivity of islet beta and alpha cells in this rat model of diabetes.Abbreviations STZ Streptozotocin - STZD streptozotocin-induce diabetic - ACh acetylcholine - AChE acetylcholinesterase - NE norepinephrine - MAO monoamine-oxidase     

Effects of alloxan on glucose-stimulated insulin secretion,glucose metabolism,and cyclic adenosine 3′, 5′-monophosphate levels in rat isolated islets of Langerhans

Summary Insulin secretion was stimulated and cyclic adenosine 3, 5-monophosphate (cAMP) levels were elevated in isolated rat islets by 27.5 mmol/l glucose. Alloxan caused a dose-dependent decrease in both variables with complete obliteration of insulin release at a concentration of 1.25 mmol/l. D-glucose, in the presence or absence of extracellular calcium, or 3-0-methyl-D-glucose (both at 27.5 mmol/l) protected completely against the effects of alloxan on both glucose-induced insulin release and cAMP levels. 3-0-Methylglucose did not stimulate insulin secretion or elevate cAMP and did not interfere with glucose-stimulated secretion or elevation of cAMP. When glucose-stimulated insulin release was abolished by alloxan, the metabolism of glucose, determined by the rate of³H₂O formation from [5-³H] glucose, was depressed by 20%. It is concluded that alloxan altered the adenylate cyclase system such that it could no longer be stimulated by glucose. Glucose-stimulated insulin secretion or elevation of cAMP did not appear essential for glucose to protect against alloxan. Protection by 3-0-methylglucose did not appear to be mediated through an alteration of cAMP metabolism. Alloxan did not inhibit glucose-induced insulin secretion by grossly altering glycolysis.     

Modulation by IBMX, fasting and experimental diabetes of glibenclamide-induced islet hormone release from the perfused rat pancreas

The impact of increased c-AMP levels, short-term fasting as well as experimental diabetes on glibenclamide-induced secretion of somatostatin, insulin and glucagon was studied in the isolated perfused rat pancreas. Dose-response curves revealed that 1 microgram/ml of glibenclamide (in the presence of 3.3 mmol/l of glucose) induced maximal stimulation of insulin and near maximal stimulation of somatostatin release, but did not significantly affect glucagon release. A combination of glibenclamide and the phosphodiesterase inhibitor IBMX synergistically and equally increased both B- and D-cell secretion. Fasting the rats for 24 h significantly suppressed the insulin and glucagon responses to glibenclamide while the concomitant somatostatin response was slightly enhanced. Rats injected with alloxan 3 days prior to perfusion were rendered either moderately diabetic or severely ill with ketoacidosis. Their insulin responses were poor or absent, respectively. In the moderately diabetic rats glibenclamide-induced somatostatin release was blunted while it was abolished in the ketotic rats. The results indicate that glibenclamide-induced B- and D-cell secretion are both modulated by c-AMP, that short-term fasting differentially affects B- and D-cell secretion and that D-cell secretion is inhibited in alloxan diabetes of short duration. It is concluded that the balance of effects by glibenclamide on hormones of the endocrine pancreas may depend on the nutritional and metabolic environment.     

Insulin and glucagon secretion in essential fatty acid deficient rats

Summary Insulin and glucagon secretion in response to common secretagogues were ascertained in the perfused pancreas isolated from essential fatty acid deficient rats. The pattern of insulin secretory response to glucose (16.7 mmol/l) by isolated rat pancreas perfused for 30 min was biphasic in EFA-deficient and control rat pancreas. The amplitude of glucose-stimulated acute secretion (phase I) was significantly greater (p<0.01) in magnitude and amplitude in EFA-deficient rats than in the control rats. There was no significant difference in the second phase of glucosestimulated insulin secretion in the two groups. Glucagon secretion in EFA-deficient and control rats was inhibited by glucose (16.7 mmol/l). Glucagon secretion induced by L-arginine (10 mmol/l) was not significantly different in EFA-deficient and in control rat pancreata (p>0.05). However, arginine (10 mmol/l)-stimulated insulin release was significantly higher in EFA-deficient than in control rats. Growth hormone (100 nmol/l)-induced glucagon and insulin secretion was variable in the two groups but significantly higher than basal secretion. The level of L-leucine (10 mmol/l)-stimulated glucagon and insulin secretion in EFA-deficient rats was minimal but significant. Our results show that isolated pancreata of rats devoid of precursors for endogenous prostaglandin synthesis secreted insulin and glucagon in response to common secretagogues. On the basis of our data, it is concluded that endogenous prostaglandins are probably not obligatory for normal secretory functions of islets of Langerhans.     

Correlation between Ca(2+)-ATPase activity of rat islet cells and insulin secretion.

Using medium with a low ionic strength, a low concentration of Ca2+ and Mg2+ and devoid of K+, we have measured Ca(2+)-ATPase activity in the homogenates of rat islets preincubated for 3 min with several hormones in the presence of 3.3 mmol glucose/l. Insulin secretion was also measured in islets incubated for 5 min under identical experimental conditions. Islets preincubated with glucose (3.3 mmol/l) and glucagon (1.4 mumol/l) plus theophylline (10 mmol/l), ACTH (0.11 nmol/l), bovine GH (0.46 mumol/l), prolactin (0.2 mumol/l) or tri-iodothyronine (1.0 nmol/l) have significantly lower Ca(2+)-ATPase activity than those preincubated with only 3.3 mmol glucose/l. All these hormones increased the release of insulin significantly. Dexamethasone (0.1 mumol/l) and somatostatin (1.2 mumol/l) enhanced the Ca(2+)-ATPase activity while adrenaline (10 mumol/l) did not produce any significant effect on the activity of the enzyme. These hormones decreased the release of insulin significantly. These results demonstrated that islet Ca(2+)-ATPase activity was modulated by the hormones tested. Their inhibitory or enhancing effect seemed to be related to their effect on insulin secretion; i.e. those which stimulated the secretion of insulin inhibited the activity of the enzyme and vice versa. Hence, their effect on insulin secretion may be due, in part, to their effect on enzyme activity and consequently on the concentration of cytosolic Ca2+. These results reinforce the assumption that Ca(2+)-ATPase activity participates in the physiological regulation of insulin secretion, being one of the cellular targets for several agents which affect this process.     

Failure to adequately adapt reduced insulin sensitivity with increased insulin secretion in women with impaired glucose tolerance

Summary To study the islet adaptation to reduced insulin sensitivity in normal and glucose intolerant post-menopausal women, we performed a euglycaemic, hyperinsulinaemic clamp in 108 randomly selected women, aged 58–59 years. Of the 20 women with the lowest insulin sensitivity, 11 had impaired glucose tolerance (IGT) whereas 9 had normal glucose tolerance (NGT). These women together with 15 women with medium insulin sensitivity and 16 women with high insulin sensitivity and NGT were further examined with arginine stimulation at three glucose levels (fasting, 14 and >25 mmol/l). In NGT, the acute insulin response (AIR) to 5 g i. v. arginine at all three glucose levels and the slope_AIR, i. e. the glucose potentiation of insulin secretion, were markedly increased in the women with the lowest insulin sensitivity and NGT compared to those with medium or high insulin sensitivity. In contrast, in low insulin sensitivity, AIR was significantly lower in IGT than in NGT (at glucose 14 mmol/l p=0.015, and at >25 mmol/l p=0.048). The potentiation of AIR induced by low insulin sensitivity in women with NGT was reduced by 74% (AIR at 14 mmol/l glucose) and 57% (AIR at >25 mmol/l glucose), respectively, in women with IGT. Also the slope_AIR was lower in IGT than in NGT (p=0.025); the increase in slope_AIR due to low insulin sensitivity was abolished in IGT. In contrast, glucagon secretion was not different between women with IGT as opposed to NGT. We conclude that as long as there is an adequate beta-cell adaptation to low insulin sensitivity with increased insulin secretory capacity and glucose potentiation of insulin secretion, NGT persists.Abbreviations NIDDM Non-insulin-dependent diabetes mellitus - AIR acute insulin response - AGR acute glucagon response     

Contribution of neural intrapancreatic non-cholinergic non-adrenergic mechanisms to glucose-induced insulin release in the isolated rat pancreas

Summary In the isolated rat pancreas the effect of intrapancreatic non-adrenergic non-cholinergic nerves was examined upon insulin, glucagon and somatostatin release during perturbations of perfusate glucose. Elevation of glucose from 1.6 to 8.3 mmol/l increased insulin and somatostatin secretion and inhibited glucagon release. The first phase of insulin secretion was significantly reduced by the neurotoxin tetrodotoxin to 55% of the controls (p<0.05). The somatostatin response was attenuated by tetrodotoxin while the change of glucagon remained unaffected. In contrast the combined adrenergic and cholinergic blockade with atropine, phentolamine and propranolol (10^–5mol/l) did not modify the insulin, glucagon and somatostatin response. When glucose was changed from 8.3 to 1.6 mmol/l, the reduction of insulin and somatostatin release was not modified by tetrodotoxin, but stimulation of glucagon was significantly attenuated by 60–70% (p<0.03), which was similar to the effect of combined adrenergic and cholinergic blockade. Subsequently, the effect of neural blockade was examined during more physiological perturbations of perfusate glucose levels. When glucose was changed from 3.9 to 7.2 mmol/l, tetrodotoxin also attenuated first phase insulin response by 40% while cholinergic and adrenergic blockade had no effect. The nitric oxide synthase inhibitor N^G-Nitro-l-arginine-methylester (l-NAME) did not alter the glucose-induced insulin response indicating that nitric oxide is not involved in this mechanism. It is concluded that neural non-adrenergic noncholinergic mechanisms contribute to the first, but not second phase of glucose-induced insulin release. Non-adrenergic non-cholinergic effects do not participate in regulation of glucagon and somatostatin secretion under the conditions employed. The non-adrenergic non-cholinergic effect is most likely of peptidergic nature and remains to be examined in greater detail.     

糖毒性对TC1-6细胞胰升糖素分泌的影响

目的 探讨长期糖毒性对胰岛α细胞胰升糖素分泌的影响及其与α细胞胰岛素抵抗的关系.方法 TC1-6细胞(α细胞株)分别培养于含低浓度(5.5 mmoL/L)、中浓度(11.1 mmol/L)和高浓度(25 mmoL/L)葡萄糖的培养基中1～5天,检测胰升糖素分泌及其mRNA表达;加入不同浓度胰岛素6 h后,观察对培养5天的TC1-6细胞胰升糖素分泌的影响并以Western印迹检测高糖对TC1-6细胞Akt磷酸化的影响.结果 (1)与低糖培养相比,中、高浓度葡萄糖培养1天和3天的TC1-6细胞胰升糖素分泌无明显改变,而高糖培养5天时TC1-6细胞的胰升糖素分泌明显增高[(136.80±10.94 vs 78.62±4.72)ng/106细胞,P<0.05];另外,培养5天时胰升糖素mRNA的表达较1天时明显升高(P<0.05);(2)10-7mol/L胰岛素抑制低糖组TC1-6细胞胰升糖素的分泌[(21.59±1.30 vs 55.12±3.86)ng/106细胞],但仅能轻微抑制高糖组胰升糖素的分泌[(106.58±8.53 vs 117.18±10.55)ng/106细胞];当胰岛素增至10-5mol/L时,高糖组胰升糖素的分泌也受到抑制[(46.55±3.72 vs 118.61±10.68)ng/106细胞];(3)加入10-5mol/L胰岛素2h后,两组TC1-6细胞磷酸化Akt水平分别升高180%和70%,但高糖组明显低于低糖组,给予磷脂酰肌醇3激酶抑制剂后两组TC1-6细胞磷酸化Akt水平在低糖组抑制率明显高于高糖组.结论 高糖可增加TC1-6细胞胰升糖素的分泌,其可能的机制与TC1-6细胞胰岛素抵抗有关.     

Not all insulin secretagogues sensitize pancreatic islets to recombinant human interleukin 1 beta.

The purpose of this study was to test the influence of different insulin secretagogues on interleukin 1 beta mediated injury to isolated rat pancreatic islets. Islets were exposed to interleukin 1 beta for 6 days. During exposure, beta-cells were stimulated with glucose (11 mmol/l vs 3.3 mmol/l) or with non-nutrients as tolbutamide (250 mumols/l), iso-butyl 1-methyl-xanthine (50 mumols/l), or glucagon (10 mg/l). At 3.3 mmol/l of glucose, 60,000 U/l of interleukin 1 beta caused an inhibition of medium insulin accumulation to 62 +/- 5% of control from 48 h to 6 days of exposure, whereas islet DNA content was unaffected. At 11 mmol/l of glucose, interleukin 1 beta dose-dependently decreased medium insulin accumulation (e.g. 60,000 U/l of interleukin 1 beta, 12 +/- 3% of control) and islet content of DNA (60,000 U/l of interleukin 1 beta, 60 +/- 8% of control). During beta-cell stimulation with tolbutamide, interleukin 1 beta caused inhibition of insulin accumulation to 36 +/- 9% of control. In contrast, on islets stimulated with iso-butyl 1-methyl-xanthine or glucagon, the effects of interleukin 1 beta were equivalent to those on non-stimulated islets. These differences were paralleled by differences in the interleukin 1 beta effect on islet morphology. In conclusion, high beta-cell activity (as measured by islet insulin release) may increase islet susceptibility to interleukin 1 beta, however, depending upon the intracellular pathway through which insulin secretion is activated.     

Glucagon,insulin and somatostatin secretion in response to sympathetic neural activation in streptozotocin-induced diabetic rats. A study with the isolated perfused rat pancreas in vitro

Summary Changes in glucagon, insulin and somatostatin secretion induced by electrical splanchnic nerve stimulation were examined in rats treated with streptozotocin as neonates and as adults. In order to study the direct neural effects we used the isolated perfused rat pancreas with intact left splanchnic nerve in vitro. In normal rats splanchnic nerve stimulation causes significant decreases in insulin (30–40%) and somatostatin (30–50%) secretion at both 16.7 mmol/l and 1 mmol/l glucose concentrations. In the neonatal streptozotocin-diabetic rats splanchnic nerve stimulation at 16.7 mmol/l glucose decreased insulin secretion (14%) further than in the control rats (30%), however, somatostatin secretion did not decrease to the same extent. Similar results were also observed at the low (1 mmol/l) glucose concentration. On the other hand, percent decreases of insulin and somatostatin secretion induced by splanchnic nerve stimulation in the streptozotocin-diabetic rats were similar to the values observed in the normal control rats. The glucagon secretion in response to splanchnic nerve stimulation at 16.7 mmol/l glucose from pancreatic Alpha cells in both types of induced diabetes is exaggerated, and the degree of exaggeration seems to parallel the severity of the hyperglycaemia. However, the splanchnic nerve stimulation-induced glucagon secretion at 1 mmol/l glucose was impaired in the streptozotocin-diabetic rats, but not in the neonatal streptozotocin-diabetic rats. These data suggest that the sensitivity of diabetic Alpha and Delta cells to sympathetic neural activation are blunted, whereas the sensitivity of Beta cells is enhanced in the diabetic animal model.     

IMPAIRMENT OF INSULIN SECRETION DURING EXPERIMENTAL POTASSIUM DEPLETION IS NOT CORRECTED BY THE PROSTAGLANDIN SYNTHESIS INHIBITOR, INDOMETHACIN

The effect of potassium depletion on glucose tolerance, plasma insulin and plasma glucagon was studied in six normal young female subjects. Negative potassium balance was induced by a diet low in potassium, together with frusemide (40 mg/day), for 3 days. Studies were performed during a period of potassium depletion and were repeated during potassium depletion in five subjects taking indomethacin (150 mg/day), an inhibitor of prostaglandin biosynthesis. Mean plasma potassium concentration was reduced from 4·2 ± 0·1 mmol/l to 3·3 ± 0·1 mmol/l, and was 3·2 ± 0·1 mmol/l during administration of indomethacin. Potassium depletion had no significant effect on the levels of plasma glucose, either fasting or following a 100 g oral glucose load, although the peak rise in plasma glucose after oral glucose was delayed (from 30 to 60 min). There was a decrease in the fasting plasma insulin concentration from 10·0 ± 1·3 mu/l to 6·7 ± 0·6 mu/l and a significant suppression of the early (30 min) insulin response to oral glucose from 126·0 ± 23·5 mu/l to 74·0 ± 19·2 mu/l. The insulin: glucose ratio during the first 60 min following oral glucose was significantly decreased from 43·7 ± 7·3 mu insulin/mmol glucose to 30·6 ± 7·3 mu insulin/mmol glucose. Furthermore, the suppression of plasma glucagon secretion that normally follows oral glucose was not observed. Administration of indomethacin during potassium depletion had no significant effect on plasma glucose, insulin or glucagon concentrations. These data indicate that short-term potassium depletion in normal young females impairs the early insulin response to oral glucose but does not significantly alter overall glucose tolerance. Failure of an indomethacin effect suggests that the defect in insulin secretion may not be mediated by an increased synthesis of prostaglandins.