Glucose or insulin, but not zinc ions, inhibit glucagon secretion from mouse pancreatic alpha-cells

The mechanisms by which hypoglycemia stimulates glucagon release are still poorly understood. In particular, the relative importance of direct metabolic coupling versus paracrine regulation by beta-cell secretory products is unresolved. Here, we compare the responses to glucose of 1) alpha-cells within the intact mouse islet, 2) dissociated alpha-cells, and 3) clonal alphaTC1-9 cells. Free cytosolic concentrations of ATP ([ATP](c)) or Ca(2+) ([Ca(2+)](c)) were imaged using alpha-cell-targeted firefly luciferase or a green fluorescent protein-based Ca(2+) probe ("pericam"), respectively. Consistent with a direct effect of glucose on alpha-cell oxidative metabolism, an increase in glucose concentration (from 0 or 3 mmol/l to 20 mmol/l) increased [ATP](c) by 7-9% in alpha-cells within the intact islet and by approximately 4% in alphaTC1-9 cells. Moreover, glucose also dose-dependently decreased the frequency of [Ca(2+)](c) oscillations in both dissociated alpha-cells and alphaTC1-9 cells. Although the effects of glucose were mimicked by exogenous insulin, they were preserved when insulin signaling was blocked with wortmannin. Addition of ZnCl(2) slightly increased the frequency of [Ca(2+)](c) oscillations but failed to affect glucagon release from either islets or alphaTC1-9 cells under most conditions. We conclude that glucose and insulin, but not Zn(2+) ions, independently suppress glucagon secretion in the mouse.     

Pancreastatin inhibits insulin secretion and stimulates glucagon secretion in mice

Recently a new peptide, pancreastatin, was isolated from porcine pancreatic extracts. It contains 49 amino acids and shows a structural similarity to chromogranin A, which occurs in secretory granules of the endocrine pancreas. Furthermore, pancreastatin has been found to inhibit glucose-induced insulin secretion in the perfused rat pancreas. However, its effects under in vivo conditions have never been studied. We have therefore investigated the effects of this peptide on insulin and glucagon secretion in vivo in the mouse. We found that an intravenous injection of pancreastatin (4.0 nmol/kg) lowered basal plasma insulin concentration at 6 min from 55 +/- 8 microU/ml in control mice to 21 +/- 7 microU/ml (P less than .01). The peptide also inhibited the plasma insulin response to both glucose (P less than .01) and the cholinergic agonist carbachol (P less than .001). Furthermore, 2 min after injection of pancreastatin, plasma glucagon concentration had increased to 301 +/- 19 pg/ml compared to 190 +/- 12 pg/ml in control mice (P less than .001). The peptide did not, however, affect the carbachol-induced plasma glucagon response. In addition, pancreastatin induced a transient hyperglycemia. Combined adrenergic blockade by means of a pretreatment of phentolamine and propranolol did not prevent pancreastatin from exerting its effects on plasma insulin levels, whereas the increase in plasma glucagon levels was abolished. Thus, in the mouse, the newly discovered intrapancreatic peptide pancreastatin 1) lowers baseline plasma insulin levels, 2) inhibits glucose- and cholinergically induced insulin secretion, 3) stimulates baseline glucagon secretion, and 4) induces hyperglycemia.     

Insulin augmentation of glucose-stimulated insulin secretion is impaired in insulin-resistant humans

Type 2 diabetes (T2D) is characterized by insulin resistance and pancreatic β-cell dysfunction, the latter possibly caused by a defect in insulin signaling in β-cells. We hypothesized that insulin's effect to potentiate glucose-stimulated insulin secretion (GSIS) would be diminished in insulin-resistant persons. To evaluate the effect of insulin to modulate GSIS in insulin-resistant compared with insulin-sensitive subjects, 10 participants with impaired glucose tolerance (IGT), 11 with T2D, and 8 healthy control subjects were studied on two occasions. The insulin secretory response was assessed by the administration of dextrose for 80 min following a 4-h clamp with either saline infusion (sham) or an isoglycemic-hyperinsulinemic clamp using B28-Asp-insulin (which can be distinguished immunologically from endogenous insulin) that raised insulin concentrations to high physiologic concentrations. Pre-exposure to insulin augmented GSIS in healthy persons. This effect was attenuated in insulin-resistant cohorts, both those with IGT and those with T2D. Insulin potentiates glucose-stimulated insulin secretion in insulin-resistant subjects to a lesser degree than in normal subjects. This is consistent with an effect of insulin to regulate β-cell function in humans in vivo with therapeutic implications.     

Genistein acutely stimulates insulin secretion in pancreatic beta-cells through a cAMP-dependent protein kinase pathway

Although genistein, a soy isoflavone, has beneficial effects on various tissues, it is unclear whether it plays a role in physiological insulin secretion. Here, we present evidence that genistein increases rapid glucose-stimulated insulin secretion (GSIS) in both insulin-secreting cell lines (INS-1 and MIN6) and mouse pancreatic islets. Genistein elicited a significant effect at a concentration as low as 10 nmol/l with a maximal effect at 5 micromol/l. The effect of genistein on GSIS was not dependent on estrogen receptor and also not related to an inhibition of protein tyrosine kinase (PTK). Consistent with its effect on GSIS, genistein increases intracellular cAMP and activates protein kinase A (PKA) in both cell lines and the islets by a mechanism that does not involve estrogen receptor or PTK. The induced cAMP by genistein, at physiological concentrations, may result primarily from enhanced adenylate cyclase activity. Pharmacological or molecular intervention of PKA activation indicated that the insulinotropic effect of genistein is primarily mediated through PKA. These findings demonstrated that genistein directly acts on pancreatic beta-cells, leading to activation of the cAMP/PKA signaling cascade to exert an insulinotropic effect, thereby providing a novel role of soy isoflavones in the regulation of insulin secretion.     

Beta-endorphin-induced inhibition and stimulation of insulin secretion in normal humans is glucose dependent

This study evaluated the effect of human beta-endorphin on pancreatic hormone levels and their responses to nutrient challenges in normal subjects. Infusion of 0.5 mg/h beta-endorphin caused a significant rise in plasma glucose concentrations preceded by a significant increase in peripheral glucagon levels. No changes occurred in the plasma concentrations of insulin and C-peptide. Acute insulin and C-peptide responses to intravenous pulses of different glucose amounts (0.33 g/kg and 5 g) and arginine (3 g) were significantly reduced by beta-endorphin infusion (P less than .01). This effect was associated with a significant reduction of the glucose disappearance rates, suggesting that the inhibition of insulin was of biological relevance. beta-Endorphin also inhibited glucose suppression of glucagon levels and augmented the glucagon response to arginine. To verify whether the modification of prestimulus glucose level could be important in these hormonal responses to beta-endorphin, basal plasma glucose concentrations were raised by a primed (0.5 g/kg) continuous (20 mg kg-1.min-1) glucose infusion. After stabilization of plasma glucose levels (350 +/- 34 mg/dl, t = 120 min), beta-endorphin infusion caused an immediate and marked increase in plasma insulin level (peak response 61 +/- 9 microU/ml, P less than .01), which remained elevated even after the discontinuation of opioid infusion. Moreover, the acute insulin response to a glucose pulse (0.33 g/kg i.v.) given during beta-endorphin infusion during hyperglycemia was significantly higher than the response obtained during euglycemia (171 +/- 32 vs. 41 +/- 7 microU/ml, P less than .01).(ABSTRACT TRUNCATED AT 250 WORDS)     

Ultradian oscillations of insulin secretion in humans

Ultradian rhythmicity appears to be characteristic of several endocrine systems. As described for other hormones, insulin release is a multioscillatory process with rapid pulses of about 10 min and slower ultradian oscillations (50--120 min). The mechanisms underlying the ultradian circhoral oscillations of insulin secretion rate (ISR), which arise in part from a rhythmic amplification of the rapid pulses, are not fully understood. In humans, included in the same period range is the alternation of rapid eye movement (REM) and non-REM (NREM) sleep cycles and the associated opposite oscillations in sympathovagal balance. During sleep, the glucose and ISR oscillations were amplified by about 150%, but the REM-NREM sleep cycles did not entrain the glucose and ISR ultradian oscillations. Also, the latter were not related to either the ultradian oscillations in sympathoagal balance, as inferred from spectral analysis of cardiac R-R intervals, or the plasma fluctuations of glucagon-like peptide-1 (GLP-1), an incretin hormone known to potentiate glucose-stimulated insulin. Other rhythmic physiological processes are currently being examined in relation to ultradian insulin release.     

Endogenous gut-derived bacterial endotoxin tonically primes pancreatic secretion of insulin in normal rats

This laboratory has proposed that endogenous gut-derived bacterial endotoxin primes the pancreatic secretion of insulin in normal rats. Endogenous lipopolysaccharide (LPS) is continually absorbed from the gut into intestinal capillaries, and low-grade portal venous endotoxemia is the status quo. Under physiologic conditions, Kupffer cells of the liver totally phagocytize and degrade endotoxin from the portal circulation. Evidence from this and other laboratories indicates that administration of exogenous LPS to humans and rats enhances pancreatic secretion of both insulin and glucagon. Conversely, findings of the present study demonstrate that restriction of endogenous LPS in fasted rats depresses the basal and arginine-stimulated concentrations of plasma insulin. Techniques used to restrict gut-derived LPS availability included chronic daily gavage with neomycin and cefazolin for gut sterilization and with cholestyramine or lactulose to reduce endotoxin within the gut. In addition, induction of endotoxin tolerance was produced by progressively higher doses of LPS intraperitoneally (i.p.), and polymyxin B was administered subcutaneously (s.c.) daily to neutralize the lipid A portion of circulating LPS. Finally, isolator-reared, defined flora rats, which were gram-negative-bacteria-deficient, and, therefore, LPS-deficient, were compared with conventional counterparts. Basal plasma insulin but not glucagon levels were consistently and significantly reduced in endogenous LPS-restricted animals. Glucose-stimulated plasma insulin was decreased only after parenteral treatment by tolerance induction and polymyxin B administration. Both plasma insulin and glucagon were depressed in response to arginine challenge in most LPS-restricted rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of glucosamine infusion on insulin secretion and insulin action in humans

Glucose toxicity (i.e., glucose-induced reduction in insulin secretion and action) may be mediated by an increased flux through the hexosamine-phosphate pathway. Glucosamine (GlcN) is widely used to accelerate the hexosamine pathway flux, independently of glucose. We tested the hypothesis that GlcN can affect insulin secretion and/or action in humans. In 10 healthy subjects, we sequentially performed an intravenous glucose (plus [2-3H]glucose) tolerance test (IVGTT) and a euglycemic insulin clamp during either a saline infusion or a low (1.6 micromol x min(-1) x kg(-1)) or high (5 micromol x min(-1) x kg(-1) [n = 5]) GlcN infusion. Beta-cell secretion, insulin (SI*-IVGTT), and glucose (SG*) action on glucose utilization during the IVGTT were measured according to minimal models of insulin secretion and action. Infusion of GlcN did not affect readily releasable insulin levels, glucose-stimulated insulin secretion (GSIS), or the time constant of secretion, but it increased both the glucose threshold of GSIS (delta approximately 0.5-0.8 mmol/l, P < 0.03-0.01) and plasma fasting glucose levels (delta approximately 0.3-0.5 mmol/l, P < 0.05-0.02). GlcN did not change glucose utilization or intracellular metabolism (glucose oxidation and glucose storage were measured by indirect calorimetry) during the clamp. However, high levels of GlcN caused a decrease in SI*-IVGTT (delta approximately 30%, P < 0.02) and in SG* (delta approximately 40%, P < 0.05). Thus, in humans, acute GlcN infusion recapitulates some metabolic features of human diabetes. It remains to be determined whether acceleration of the hexosamine pathway can cause insulin resistance at euglycemia in humans.     

Phosphate depletion impairs insulin secretion by pancreatic islets.

Phosphate depletion (PD) is associated with resistance to the peripheral action of insulin and with glucose intolerance. However, data on the effect of PD on insulin secretion are not consistent, and were derived indirectly by measurements of blood levels of insulin during intravenous glucose tolerance test (IVGTT) or with hyperglycemic clamp technique. Direct evidence for an effect of PD on insulin secretion by pancreatic islets is not available, and the potential mechanisms through which PD may affect insulin secretion are not known. We performed IVGTT, examined in vitro insulin secretion by pancreatic islets, and evaluated various factors involved in insulin secretion in PD and pair weighed (PW) rats. PD animals had fasting hyperglycemia and normal plasma insulin levels, and displayed abnormal IVGTT as compared to PW rats. Both initial and late phases of D-glucose-induced insulin secretion from islets were markedly and significantly (P less than 0.01) lower than from islets of PW rats. In contrast, D-glyceraldehyde-induced insulin release in PD rats was similar to that of PW rats. [H3]2-deoxyglucose uptake by islets and their cyclic AMP content after exposure to D-glucose, D-glyceraldehyde or forskolin were not different among the two groups of animals. Insulin content in PD islets was modestly but significantly (P less than 0.01) higher than PW islets. In PD islets, ATP content and the ATP/ADP ratio at basal state and after incubation with 16.7 mM D-glucose were significantly (P less than 0.01) lower and resting cytosolic calcium was significantly (P less than 0.01) higher than in PW islets.(ABSTRACT TRUNCATED AT 250 WORDS)     

Abnormalities of pancreatic somatostatin secretion corrected by in vivo insulin treatment of streptozotocin-diabetic rats

In islets removed from untreated streptozotocin-diabetic rats, the somatostatin-containing cells were unresponsive to changes in glucose concentration, while they did respond to raised cyclic AMP levels. By contrast, in vivo insulin treatment restored the glucose sensitivity of the somatostatin secreting cells. In addition, in vivo insulin treatment resulted in a lowering of the high basal somatostatin secretion rate found in islets from untreated diabetic rats. These changes were made without any alteration of islet insulin content or enhancement of the in vitro insulin secretion. These results indicate that there is not a basic defect in the glucoreceptor of the somatostatin cell in diabetes.     

Acute edematous pancreatitis impairs pancreatic secretion in rats.

There are few observations of in vivo pancreatic secretory changes that accompany acute pancreatitis. We hypothesized that acute pancreatitis impairs pancreatic exocrine function. We developed a conscious-rat experimental preparation with gastric, duodenal, bile, and pancreatic fistulas. We studied cholecystokinin-stimulated pancreatic secretion in conscious rats before and after inducing acute pancreatitis with supramaximal administration of caerulein--5 micrograms/kg/hr intravenously for 6 hours. Marked hyperamylasemia developed in all rats immediately after administration of caerulein. Basal and cholecystokinin-stimulated pancreatic juice flow and protein (enzyme) secretion decreased significantly 24 hours after acute pancreatitis was induced even though plasma amylase returned to basal levels. We conclude that acute pancreatitis markedly impairs pancreatic secretion.     

Comparative modulations of insulin secretion, pancreatic insulin content, and proinsulin mRNA in rats. Effects of 50% pancreatectomy and dexamethasone administration

These studies compared measurements of in vivo insulin secretion, insulin stores, and insulin synthesis. Rats were studied at 24 wk of age, either 1 or 20 wk after a sham operation (Sham) or 50% pancreatectomy (Px), reducing beta-cell number. By 20 wk after surgery, an adaptation to pancreatectomy was apparent from results of serial glucose tolerance tests, done in a preliminary protocol. Some of the rats also received dexamethasone (ShamDex and PxDex, respectively), imposing insulin resistance. Insulin secretion was assessed with the acute insulin response to arginine under basal (AIRbas) and maximum glucose-potentiated (AIRmax) states. Pancreatic insulin was measured, and insulin synthesis was estimated by measurement of proinsulin mRNA. At 1 wk after surgery, there was no difference among Sham and Px rats in AIRbas, but in the Px rats, expected reductions of AIRmax, pancreatic insulin, and proinsulin mRNA were found. ShamDex rats had a markedly augmented AIRbas and increased AIRmax and proinsulin mRNA. However, pancreatic insulin was reduced both in ShamDex and PxDex rats. At 20 wk after surgery, the predicted adaptation to Px was substantiated by AIRmax and proinsulin mRNA in Px rats not different from those in Sham rats, but pancreatic insulin in the Px rats remained low. AIRbas and proinsulin mRNA were augmented in ShamDex and PxDex rats, but pancreatic insulin was again reduced, and in PxDex rats, low AIRmax and fed hyperglycemia were seen. Linear correlations of AIRbas and AIRmax with proinsulin mRNA were observed over a roughly fourfold range of secretion and synthesis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Morphologic and functional changes in sympathetic nerve relationships with pancreatic alpha-cells after destruction of beta-cells in rats

Insulin-dependent diabetes mellitus (IDDM) in humans is accompanied by an attenuation of the response of glucagon to hypoglycemia. To identify an animal model of IDDM with alpha-cell unresponsiveness to glucopenia in which to pursue morphologic and in vitro functional investigation of the lesion, pancreases isolated from rats with IDDM induced by streptozocin (STZ) or occurring spontaneously in BB/W rats were perfused with buffer containing 150, 25, and 150 mg/dl of glucose. In both forms of IDDM the normal glucagon rise during glucopenia was markedly impaired, suggesting an abnormality comparable to that of human IDDM. Studies of the insular sympathetic apparatus were conducted in these rat models. Electron-microscopic examination of peri-insular nerve endings disclosed no discernible abnormality in either form of rat IDDM. However, morphometric analysis of contacts between [3H]norepinephrine-labeled sympathetic nerve terminals and alpha-cells in pancreases from STZ-induced diabetic (STZ-D) rats revealed a 65-70% reduction in direct contacts. An 80% reduction in the number of nerve endings (not labeled) in direct contact with alpha-cells was also noted in the BB/W diabetic rats. Norepinephrine reuptake, studied only in the STZ-D group, was not impaired. The availability of local endogenous norepinephrine to alpha-cells and their sensitivity to exogenous norepinephrine was determined by perfusing 2, 5, or 10 micrograms/ml of tyramine, a releaser of endogenous norepinephrine, and norepinephrine at a concentration that in pancreases from nondiabetic rats gave a quantitatively similar glucagon response.(ABSTRACT TRUNCATED AT 250 WORDS)     

Vesicular inhibitory amino acid transporter is present in glucagon-containing secretory granules in alphaTC6 cells,mouse clonal alpha-cells,and alpha-cells of islets of Langerhans

Islets of Langerhans contain gamma-aminobutyrate (GABA) and may use it as an intercellular transmitter. In beta-cells, GABA is stored in synaptic-like microvesicles and secreted through Ca(2+)-dependent exocytosis. Vesicular inhibitory amino acid transporter (VIAAT), which is responsible for the storage of GABA and glycine in neuronal synaptic vesicles, is believed to be responsible for the storage and secretion of GABA in beta-cells. However, a recent study by Chessler et al. indicated that VIAAT is expressed in the mantle region of islets. In the present study, we investigated the precise localization of VIAAT in rat islets of Langerhans and clonal islet cells and found that it is present in alpha-cells, a minor population of F-cells and alphaTC6 cells, and clonal alpha-cells but not in beta-cells, delta-cells, or MIN6 m9-cells (clonal beta-cells). Combined biochemical, immunohistochemical, and electronmicroscopical evidence indicated that VIAAT is specifically localized with glucagon-containing secretory granules in alpha-cells. ATP-dependent uptake of radiolabeled GABA, which is energetically coupled with a vacuolar proton pump, was detected in digitonin-permeabilized alphaTC6 cells as well as in MIN6 m9 cells. These results demonstrate that functional neuronal VIAAT is present in glucagon-containing secretory granules in alpha-cells and suggest that the ATP-dependent GABA transporter in beta-cells is at least immunologically distinct from VIAAT. Because glucagon-containing secretory granules also contain vesicular glutamate transporter and store L-glutamate, as demonstrated by Hayashi et al., the present results suggest more complex features of the GABAergic phenotype of islets than previously supposed.     

Glucose homeostasis and insulin secretion during isoflurane anesthesia in humans

The effect of isoflurane-air anesthesia on glucose tolerance in humans was investigated using two successive intravenous glucose tolerance tests (IVGTT). After a first IVGTT while awake, patients received a second IVGTT either while awake (group I), during anesthesia with isoflurane-air and pancuronium without surgical stimulation (group II), or during the same anesthetic technique but combined with surgery (group III). Isoflurane seemed to induce glucose intolerance (glucose disappearance rate K10-60 min = 1.628 +/- 0.462% min-1 [control] versus 1.086 +/- 0.920% min-1 [anesthesia], P less than 0.05) partly due to a decreased glucose induced insulin response. Growth hormone and norepinephrine levels were also increased during anesthesia. Epinephrine levels were lowered by isoflurane anesthesia. Although glucose intolerance was marked during surgery (K10-60 min = 0.892 +/- 0.286% min-1), the glucose-induced insulin response remained similar to that observed in patients in group II, while growth hormone, cortisol, epinephrine, and norepinephrine concentrations increased significantly. These known stress factors thus seemed to enhance glucose intolerance through a diminished response to insulin action and/or an enhanced hepatic glucose output, rather than by further impairing pancreatic insulin secretion.     

Ghrelin infusion in humans induces acute insulin resistance and lipolysis independent of growth hormone signaling

OBJECTIVE—Ghrelin is a gut-derived peptide and an endogenous ligand for the growth hormone (GH) secretagogue receptor. Exogenous ghrelin stimulates the release of GH (potently) and adrenocorticotropic hormone (ACTH) (moderately). Ghrelin is also orexigenic, but its impact on substrate metabolism is controversial. We aimed to study direct effects of ghrelin on substrate metabolism and insulin sensitivity in human subjects.RESEARCH DESIGN AND METHODS—Six healthy men underwent ghrelin (5 pmol · kg⁻¹ · min⁻¹) and saline infusions in a double-blind, cross-over study to study GH signaling proteins in muscle. To circumvent effects of endogenous GH and ACTH, we performed a similar study in eight hypopituitary adults but replaced with GH and hydrocortisone. The methods included a hyperinsulinemic-euglycemic clamp, muscle biopsies, microdialysis, and indirect calorimetry.RESULTS—In healthy subjects, ghrelin-induced GH secretion translated into acute GH receptor signaling in muscle. In the absence of GH and cortisol secretion, ghrelin acutely decreased peripheral, but not hepatic, insulin sensitivity together with stimulation of lipolysis. These effects occurred without detectable suppression of AMP-activated protein kinase phosphorylation (an alleged second messenger for ghrelin) in skeletal muscle.CONCLUSIONS—Ghrelin infusion acutely induces lipolysis and insulin resistance independently of GH and cortisol. We hypothesize that the metabolic effects of ghrelin provide a means to partition glucose to glucose-dependent tissues during conditions of energy shortage.Ghrelin, an endogenous ligand for the growth hormone (GH) secretagogue receptor (GHS-R), stimulates GH and adrenocorticotropic hormone (ACTH) secretion (1) in addition to having orexigenic and gastrokinetic effects (2,3). The observation that GHS-R is located in peripheral tissues suggests that ghrelin may exert direct effects (4). The effects of ghrelin on substrate in humans are uncertain, but insulin resistance and stimulation of lipolysis have been reported (5–7). However, it remains difficult to segregate direct effects from effects related to GH and cortisol, and we have recently demonstrated that somatostatin infusion fails to sufficiently suppress ghrelin-induced GH and cortisol secretion (8). Hormonally replaced hypopituitary patients constitute a means for studying putative GH- and cortisol-independent effects of ghrelin in human subjects in vivo.We aimed to study potential direct effects of ghrelin on substrate metabolism and insulin sensitivity in the postabsorptive state. In one experiment in healthy adults, we assessed whether ghrelin-induced GH release translated into GH signaling in skeletal muscle, in the event of which the importance of abrogating indirect effects of ghrelin is obvious. Second, we studied the effects of ghrelin exposure on whole-body and regional substrate metabolism in the basal and insulin-stimulated state in hypopituitary patients on stable replacement with GH and hydrocortisone.     

Pulsatile insulin secretion dictates systemic insulin delivery by regulating hepatic insulin extraction in humans

In health, insulin is secreted in discrete pulses into the portal vein, and the regulation of the rate of insulin secretion is accomplished by modulation of insulin pulse mass. Several lines of evidence suggest that the pattern of insulin delivery by the pancreas determines hepatic insulin clearance. In previous large animal studies, the amplitude of insulin pulses was related to the extent of insulin clearance. In humans (and in large animals), the amplitude of insulin oscillations is approximately 100-fold higher in the portal vein than in the systemic circulation, despite only a fivefold dilution, implying preferential hepatic extraction of insulin pulses. In the present study, by direct hepatic vein sampling in healthy humans, we sought to establish the extent of first-pass hepatic insulin extraction and to determine whether the pattern of insulin secretion (insulin pulse mass and amplitude) dictates the hepatic insulin clearance and thereby delivery of insulin to extrahepatic insulin-responsive tissues. Five nondiabetic subjects (two men and three women, mean age 32 years [range 25-39], BMI 24.9 kg/m(2) [21.2-27.1]) participated. Insulin and C-peptide delivery from the splanchnic bed was measured in basal overnight-fasted state and during a glucose infusion of 2 mg . kg(-1) . min(-1) by simultaneous sampling from the hepatic vein and an arterialized vein along with direct estimation of splanchnic blood flow. Fractional insulin extraction was calculated from the difference between the C-peptide and insulin delivery rates from the liver. The time patterns of insulin concentrations and hepatic insulin clearance were analyzed by deconvolution and Cluster analysis, respectively. Cross-correlation analysis was used to relate C-peptide secretion and insulin clearance. Glucose infusion increased peripheral glucose concentrations from 5.4 +/- 0.1 to 6.4 +/- 0.4 mmol/l (P < 0.05). Likewise, insulin and C-peptide concentrations increased during glucose infusion (P < 0.05). Hepatic insulin clearance increased with glucose infusion (1.06 +/- 0.18 vs. 2.55 +/- 0.38 pmol . kg(-1) . min(-1); P < 0.01), but fractional hepatic insulin clearance was stable (78.2 +/- 4.4 vs. 84 0. +/- 3.9%, respectively; P = 0.18). Insulin secretory-burst mass rose during glucose infusion (P < 0.05), whereas the interburst interval remained unchanged (4.4 +/- 0.2 vs. 4.5 +/- 0.3 min; P = 0.36). Cluster analysis identified an oscillatory pattern in insulin clearance, with peaks occurring approximately every 5 min. Cross-correlation analysis between prehepatic C-peptide secretion and hepatic insulin clearance demonstrated a significant positive association without detectable (<1 min) time lag. Insulin secretory-burst mass strongly predicted insulin clearance (r = 0.81, P = 0.0043). In conclusion, in humans, approximately 80% of insulin is extracted during the first liver passage. The liver rapidly responds to fluctuations in insulin secretion, preferentially extracting insulin delivered in pulses. The mass (and therefore amplitude) of insulin pulses traversing the liver is the predominant determinant of hepatic insulin clearance. Therefore, through this means, the pulse mass of insulin release dictates both hepatic (directly) as well as extra-hepatic (indirectly) insulin delivery. These findings emphasize the dual role of the liver and pancreas and their relationship mediated through magnitude of insulin pulse mass in regulating the quantity and pattern of systemic insulin delivery.     

Multiple sites of purinergic control of insulin secretion in mouse pancreatic beta-cells.

In mouse pancreatic beta-cells, extracellular ATP (0.1 mmol/l) effectively reduced glucose-induced insulin secretion. This inhibitory action resulted from a direct interference with the secretory machinery, and ATP suppressed depolarization-induced exocytosis by 60% as revealed by high-resolution capacitance measurements. Suppression of Ca2+-dependent exocytosis was mediated via binding to P2Y1 purinoceptors but was not associated with inhibition of the voltage-dependent Ca2+ currents or adenylate cyclase activity. Inhibition of exocytosis by ATP resulted from G-protein-dependent activation of the serine/threonine protein phosphatase calcineurin and was abolished by cyclosporin A and deltamethrin. In contrast to the direct inhibitory action on exocytosis, ATP reduced the whole-cell ATP-sensitive K+ (K(ATP)) current by 30% (via activation of cytosolic phospholipase A2), leading to membrane depolarization and stimulation of electrical activity. The stimulatory effect of ATP also involved mobilization of Ca2+ from thapsigargin-sensitive intracellular stores. We propose that the inhibitory action of ATP, by interacting with the secretory machinery at a level downstream to an elevation in [Ca2+]i, is important for autocrine regulation of insulin secretion in mouse beta-cells.