Calcium dependency and free calcium concentrations during insulin secretion in a hamster beta cell line.

Using a glucose-responsive beta cell line, we tested the hypothesis that the free cytosolic Ca2+ concentration ([Ca2+]i) is the primary signal that couples a stimulus to insulin secretion, and examined the involvement of the extracellular Ca2+ pool in this process. Glucose or depolarization of the beta cell with 40 mM K+ stimulated a monophasic release of insulin directly proportional to the extracellular Ca2+ concentration. 40 mM K+ increased 45Ca2+ uptake and increased [Ca2+]i, which was measured with quin 2, 4.7-fold, from 56 +/- 3 to 238 +/- 17 nM. With high glucose, 45Ca2+ uptake did not increase, and [Ca2+]i was unchanged or fell slightly. There was a striking correlation between inhibitory effects of verapamil, the Ca2+ channel blocker, on insulin secretion and the rise in [Ca2+]i evoked by K+. Higher concentrations of verapamil were required to inhibit glucose- than K+-stimulated insulin secretion (dose giving half-maximal effect of 1.4 X 10(-4) M vs. 6.0 X 10(-7) M). Incubation in Ca2+-free, 1 mM EGTA buffer for 30 min lowered [Ca2+]i to 14 +/- 2 nM, and inhibited acute insulin release to both secretagogues. If high glucose was present in the Ca2+-free period, reintroduction of 2.5 mM Ca2+ in high glucose restored insulin secretion only to the basal rate. However, if low glucose was present during the Ca2+-free period, high glucose and 2.5 mM Ca2+ triggered a full first-phase insulin response. These data suggest that high glucose generates a non-Ca2+ signal that turns over rapidly and provide direct evidence that K+ triggers insulin release by drawing extracellular Ca2+ into the beta cell through verapamil-sensitive Ca2+ channels. However, an increase [Ca2+]i is not the primary signal that evokes glucose-stimulated insulin release in this beta cell line.     

Cyclic adenosine monophosphate prevents the glucocorticoid-mediated inhibition of insulin gene expression in rodent islet cells.

Dexamethasone negatively regulates insulin gene expression in HIT-15 cells. In vivo, however, an excess of glucocorticoids results in an increase in insulin biosynthesis and peripheral hyperinsulinemia. To resolve this contradiction, we have studied the effects of dexamethasone in primary rat islet cells. We show here that dexamethasone decreases insulin mRNA levels in single islet cells, as in HIT-15 cells, but does not affect these levels in reaggregated islet cells and increases them in intact islets of Langerhans. Because cAMP is an important regulator of insulin gene expression and intracellular cAMP content may be decreased in single beta cells, we investigated whether cAMP could prevent the inhibitory effect of dexamethasone on insulin mRNA levels. In the presence of cAMP analogues, the inhibitory action of dexamethasone was not only prevented, but insulin mRNA increased to levels comparable to those observed when cAMP analogues were used alone. We conclude that the insulin gene is negatively regulated by dexamethasone in single islet cells, but that other factors such as cAMP prevent this effect when the native environment of islet cells is preserved. Our results indicate that insulin gene regulation is influenced by cell to cell contacts within the islet, and that intracellular cAMP levels might be influential in this regulation.     

Pulsatile insulin release from mouse islets occurs in the absence of stimulated entry of Ca2+.

Pancreatic islets are known to respond to a raise of the glucose concentration with Ca2+ -induced 2-3-min pulses of insulin release. The reports of cyclic variations of circulating insulin in the fasting state made it important to explore whether insulin release is also pulsatile in the absence of stimulated entry of Ca2+. Individual pancreatic islets were isolated from a local colony of ob/ob mice and perifused under conditions allowing dual wavelength recordings of the cytoplasmic Ca2+ concentration ([Ca2+]i) with fura-2 and measurements of insulin with ELISA technique. At 3 mM of glucose, [Ca2+]i remained at a stable low level, but insulin was released in pulses with a frequency of 0.41+/-0.02 min-1, determined by Fourier transformation of original and autocorrelated data. Pulses of basal insulin release were also seen when glucose was omitted and 1 microM clonidine or 400 microM diazoxide was added to a glucose-free medium. The results indicate that pulsatile insulin release can be generated in the absence of stimulated entry of Ca2+. A tentative explanation for this phenomenon is inherent fluctuations in the ATP production of the beta cells.     

On the mechanism of impaired insulin secretion in chronic renal failure.

It has been suggested that a sustained rise in resting levels of cytosolic calcium [Ca2+]i of pancreatic islets is responsible for impaired insulin secretion in chronic renal failure (CRF). Evidence for such an event is lacking and the mechanisms through which it may affect insulin secretion are not known. Studies were conducted in normal, CRF, and normocalcemic, parathyroidectomized (PTX) CRF rats to answer these questions. Resting levels of [Ca2+]i of islets from CRF rats were higher (P less than 0.01) than in control of CRF-PTX rats. [3H]2-deoxyglucose uptake and cAMP production by islets were not different in the three groups. Insulin content of, and glucose-induced insulin secretion by islets from CRF rats was lower (P less than 0.01) than in control and CRF-PTX rats. In contrast, glyceraldehyde-induced insulin release by CRF islets was normal. Basal ATP content, both glucose-stimulated ATP content and ATP/ADP ratio, net lactic acid output, Vmax of phosphofructokinase-1, and Ca2+ ATPase of islets from CRF rats were lower (P less than 0.02-less than 0.01) than in normal or CRF-PTX animals. Data show that: (a) Glucose but not glyceraldehyde-induced insulin secretion is impaired in CRF; (b) the impairment in glucose-induced insulin release in CRF is due to a defect in the metabolism of glucose; (c) this latter defect is due to reduced ATP content induced partly by high [Ca2+]i of islets; and (d) the high [Ca2+]i in islets of CRF rats is due to augmented PTH-induced calcium entry into cells and decreased calcium extrusion from the islets secondary to reduced activity of the Ca2+ ATPase.     

The Stimulus-Secretion Coupling of Glucose-Induced Insulin Release. VII. A PROPOSED SITE OF ACTION FOR ADENOSINE-3′,5′-CYCLIC MONOPHOSPHATE

Glucose-induced insulin release is thought to result from the following sequence of events in the beta cell: glucose metabolism leading to the production of a metabolic signal, net calcium uptake by the beta cell in response to the signal, and interaction between calcium and a microtubular-microfilamentous system, leading to emiocytosis of the secretory granules. Dibutyryl-cyclic AMP (db-cAMP) and theophylline are known to potentiate glucose-induced insulin release, their insulinotropic action being most marked at high glucose concentrations. Based on the above mentioned concepts, it was considered in the present experiments that the primary site of action of cAMP in the beta cell could correspond to either a facilitation of glucose metabolism, a modification of calcium distribution, or an interaction with the microtubular-microfilamentous system.The first of these hypotheses appeared unlikely because db-cAMP and theophylline, in sharp contrast with other agents known to affect glucose metabolism in the beta cell, did not modify glucose-induced calcium uptake by isolated islets incubated at high glucose concentrations. The last hypothesis also appeared unlikely since theophylline did not interfere with the deleterious effect of colchicine on the microtubular system, and since vincristine or colchicine did not differentially affect the respective insulinotropic action of glucose and theophylline. An effect of cAMP upon calcium distribution in the beta cell was suggested by the following findings. Whereas glucose and leucine were unable to promote insulin release in the absence of extracellular calcium, the addition of db-cAMP or theophylline to the calcium-depleted media partially restored theinsulinotropic action of glucose and leucine. Moreover, theophylline caused a dramatic increase in (45)Ca efflux from perifused islets, even in the absence of glucose. It is concluded that the insulinotropic action of cAMP could be due to a glucose-independent translocation of calcium within the beta cell, from an organelle-bound pool to a cytoplasmic pool of ionized calcium readily available for transport across the cell membrane.     

Virus-induced alterations in insulin release in hamster islets of Langerhans.

After the inoculation of Golden Syrian hamsters with the TC-83 vaccine strain of Venezuelan encephalitis (VE) virus, a sustained diminution in glucose-stimulated insulin release and glucose intolerance of shorter duration develops. To understand better the mechanism of this defect in insulin release, we examined insulin secretion in response to several test agents in isolated perifused islets from control and 24-d post-VE virus-infected hamsters. 50 islets were used in all perifusion experiments, and data were expressed as total insulin released as well as peak response for each test agent during a 30-min perifusion period from control and VE-infected islets. After perifusion with 20 mM glucose, a 45% diminution of insulin release was noted in VE-infected islets in comparison with control islets, which in turn was similar to in vivo findings. However, following 1-mM tolbutamide stimulation, insulin release was similar in control and VE-infected islets. In separate studies, 1 mM tolbutamide, 10 mM theophilline, 1 mM dibutyryl cyclic (c)AMP, and 1 mM 8-bromo-cAMP resulted in statistically similar insulin-release curves in control and VE-infected islets. Additional experiments assessing [5-3H]glucose use in control and infected islets after 20 min of perifusion with 20 mM glucose revealed virtually identical values (239 +/- 30-control; and 222 +/- 27-VE-infected islets). Morphological and morphometric evaluation of VE-infected islets (21 d following virus inoculation) showed no changes in islet volume density, beta cell density, and beta cell granulation. Thus, VE virus induces a defect in glucose-stimulated insulin release from hamster beta cells that can be corrected by cAMP analogues and does not alter islet glucose use.     

Virus-induced alterations in cyclic adenosine monophosphate generation in hamster islets of Langerhans.

Inoculation of golden Syrian hamsters with Venezuelan encephalitis (VE) virus results in a sustained diminution in glucose-stimulated insulin release that is correctable by cyclic (c) AMP analogs and phosphodiesterase inhibitors. This suggested the importance of directly measuring cAMP content in VE-infected and control islets in response to insulin secretagogues. The basal cAMP content of VE-infected islets (0.14 +/- 0.02 pmol/micrograms islet DNA) was approximately half that of control islets (0.27 +/- 0.02 pmol/micrograms islet DNA) (P less than 0.05). In the presence of 10 microM glucagon (and 3 mM glucose), the rate of cAMP generation in VE-infected islets was only half that of control islets. With 10 mM alpha-ketoisocaproic acid, the rates of cAMP generation were indistinguishable between control and experimental groups. In response to 20 mM glucose and 3-isobutyl-1-methylxanthine (IBMX) (a phosphodiesterase inhibitor), cAMP generation in VE-infected islets was 81% (NS) of the control rate. When a more specific phosphodiesterase inhibitor, RO 20-1724, was used with 20 mM glucose, cAMP generation in the infected islets was only 44% (P less than 0.001) of the control value. Insulin secretion over the perifusion period paralleled the cAMP levels. In the presence of 10 mM alpha-ketoisocaproic acid, there was no difference in insulin secretion between VE-infected and control islets, while there was a statistically significant (P less than 0.05) difference with 10 microM glucagon or 20 mM glucose (in 1 mM RO 20-1724). These data point to a defect in the cAMP generation system of VE-infected islets, although additional factors involved in insulin secretion may also be impaired by the virus.     

Alterations in regulation of energy homeostasis in cyclic nucleotide phosphodiesterase 3B-null mice

Cyclic nucleotide phosphodiesterase 3B (PDE3B) has been suggested to be critical for mediating insulin/IGF-1 inhibition of cAMP signaling in adipocytes, liver, and pancreatic beta cells. In Pde3b-KO adipocytes we found decreased adipocyte size, unchanged insulin-stimulated phosphorylation of protein kinase B and activation of glucose uptake, enhanced catecholamine-stimulated lipolysis and insulin-stimulated lipogenesis, and blocked insulin inhibition of catecholamine-stimulated lipolysis. Glucose, alone or in combination with glucagon-like peptide-1, increased insulin secretion more in isolated pancreatic KO islets, although islet size and morphology and immunoreactive insulin and glucagon levels were unchanged. The beta(3)-adrenergic agonist CL 316,243 (CL) increased lipolysis and serum insulin more in KO mice, but blood glucose reduction was less in CL-treated KO mice. Insulin resistance was observed in KO mice, with liver an important site of alterations in insulin-sensitive glucose production. In KO mice, liver triglyceride and cAMP contents were increased, and the liver content and phosphorylation states of several insulin signaling, gluconeogenic, and inflammation- and stress-related components were altered. Thus, PDE3B may be important in regulating certain cAMP signaling pathways, including lipolysis, insulin-induced antilipolysis, and cAMP-mediated insulin secretion. Altered expression and/or regulation of PDE3B may contribute to metabolic dysregulation, including systemic insulin resistance.     

Glucose activates the carboxyl methylation of gamma subunits of trimeric GTP-binding proteins in pancreatic beta cells. Modulation in vivo by calcium, GTP, and pertussis toxin.

The gamma subunits of trimeric G-proteins (gamma1, gamma2, gamma5, and gamma7 isoforms) were found to be methylated at their carboxyl termini in normal rat islets, human islets and pure beta [HIT-T15] cells. Of these, GTPgammaS significantly stimulated the carboxyl methylation selectively of gamma2 and gamma5 isoforms. Exposure of intact HIT cells to either of two receptor-independent agonists--a stimulatory concentration of glucose or a depolarizing concentration of K+--resulted in a rapid (within 30 s) and sustained (at least up to 60 min) stimulation of gamma subunit carboxyl methylation. Mastoparan, which directly activates G-proteins (and insulin secretion from beta cells), also stimulated the carboxyl methylation of gamma subunits in intact HIT cells. Stimulatory effects of glucose or K+ were not demonstrable after removal of extracellular Ca2+ or depletion of intracellular GTP, implying regulatory roles for calcium fluxes and GTP; however, the methyl transferase itself was not directly activated by either. The stimulatory effects of mastoparan were resistant to removal of extracellular Ca2+, implying a mechanism of action that is different from glucose or K+ but also suggesting that dissociation of the alphabetagamma trimer is conducive to gamma subunit carboxyl methylation. Indeed, pertussis toxin also markedly attenuated the stimulatory effects of glucose, K+ or mastoparan without altering the rise in intracellular calcium induced by glucose or K+. Glucose-induced carboxyl methylation of gamma2 and gamma5 isoforms was vitiated by coprovision of any of three structurally different cyclooxygenase inhibitors. Conversely, exogenous PGE2, which activates Gi and Go in HIT cells and which thereby would dissociate alpha from beta(gamma), stimulated the carboxyl methylation of gamma2 and gamma5 isoforms and reversed the inhibition of glucose-stimulated carboxyl methylation of gamma subunits elicited by cyclooxygenase inhibitors. These data indicate that gamma subunits of trimeric G-proteins undergo a glucose- and calcium-regulated methylation-demethylation cycle in insulin-secreting cells, findings that may imply an important role in beta cell function. Furthermore, this is the first example of the regulation of the posttranslational modification of G-protein gamma subunits via nonreceptor-mediated activation mechanisms, which are apparently dependent on calcium influx and the consequent activation of phospholipases releasing arachidonic acid.     

Effect of dexamethasone on insulin binding, glucose transport, and glucose oxidation of isolated rat adipocytes.

We have studied the in vitro effects of dexamethasone on isolated rat adipocytes at concentrations of dexamethasone therapeutically achieved in man. Glucose oxidation, glucose transport, and insulin binding were assessed. In dexamethasone-treated cells, glucose oxidation was decreased by 30-40% both in the absence of insulin (basal state) and at low insulin levels (less than 25 mu/ML). At maximally effective insulin levels (over 100 muU/ml) no differences existed between control and treated cells. If glucose transport were the rate-limiting step for glucose oxidation in the basal state and at low (submaximal) insulin levels, but not at maximally effective insulin concentrations, then these data could be explained by postulating that dexamethasone has a direct affect on glucose transport and does not affect intracellular oxidative pathways. We tested this hypothesis by directly assessing glucose transport in dexamethasone-treated cells. Glucose transport was assessed by measuring the uptake of [14C]2-deoxy glucose. These studies demonstrated a 30-40% decrease in 2-deoxy glucose uptake by treated cells both in the basal state and at all insulin concentrations. Thus, a direct glucocorticoid effect on the glucose transport system seems to account for the decreased ability of dexamethasone-treated cells to oxidize glucose. Since dexamethasone treatment leads to decreased insulin binding to adipocytes in vivo, we examined the possibility that the in vitro decreases in insulin-mediated glucose transport could be due to decreased insulin receptors. Insulin binding to control and treated adipocytes was measured, and no differences were found. Therefore, in cntrast to previously reported in vivo studies, adipocytes treated in vitro with dexamethasone retain a normal ability to bind insulin. Thus, these studies suggest that all of the in vitro effects of dexamethasone on glucose oxidation are due to direct inhibition of the glucose transport system.     

CaV2.3 calcium channels control second-phase insulin release

Concerted activation of different voltage-gated Ca( (2+) ) channel isoforms may determine the kinetics of insulin release from pancreatic islets. Here we have elucidated the role of R-type Ca(V)2.3 channels in that process. A 20% reduction in glucose-evoked insulin secretion was observed in Ca(V)2.3-knockout (Ca(V)2.3(-/-)) islets, close to the 17% inhibition by the R-type blocker SNX482 but much less than the 77% inhibition produced by the L-type Ca(2+) channel antagonist isradipine. Dynamic insulin-release measurements revealed that genetic or pharmacological Ca(V)2.3 ablation strongly suppressed second-phase secretion, whereas first-phase secretion was unaffected, a result also observed in vivo. Suppression of the second phase coincided with an 18% reduction in oscillatory Ca(2+) signaling and a 25% reduction in granule recruitment after completion of the initial exocytotic burst in single Ca(V)2.3(-/-) beta cells. Ca(V)2.3 ablation also impaired glucose-mediated suppression of glucagon secretion in isolated islets (27% versus 58% in WT), an effect associated with coexpression of insulin and glucagon in a fraction of the islet cells in the Ca(V)2.3(-/-) mouse. We propose a specific role for Ca(V)2.3 Ca(2+) channels in second-phase insulin release, that of mediating the Ca(2+) entry needed for replenishment of the releasable pool of granules as well as islet cell differentiation.     

Autoantibodies against CD38 (ADP-ribosyl cyclase/cyclic ADP-ribose hydrolase) that impair glucose-induced insulin secretion in noninsulin- dependent diabetes patients.

Cyclic ADP-ribose (cADPR) has been shown to be a mediator for intracellular Ca2+ mobilization for insulin secretion by glucose in pancreatic beta cells, and CD38 shows both ADP-ribosyl cyclase to synthesize cADPR from NAD+ and cADPR hydrolase to hydrolyze cADPR to ADP-ribose. We show here that 13.8% of Japanese non-insulin-dependent diabetes (NIDDM) patients examined have autoantibodies against CD38 and that the sera containing anti-CD38 autoantibodies inhibit the ADP-ribosyl cyclase activity of CD38 (P </= 0.05). Insulin secretion from pancreatic islets by glucose is significantly inhibited by the addition of the NIDDM sera with anti-CD38 antibodies (P </= 0.04-0.0001), and the inhibition of insulin secretion is abolished by the addition of recombinant CD38 (P </= 0.02). The increase of cADPR levels in pancreatic islets by glucose was also inhibited by the addition of the sera (P </= 0.05). These results strongly suggest that the presence of anti-CD38 autoantibodies in NIDDM patients can be one of the major causes of impaired glucose-induced insulin secretion in NIDDM.     

Effects of tacrine on insulin secretion and 86Rb+ and 45Ca++ efflux from rat pancreatic islets.

Tacrine (1,2,3,4-tetrahydro-9-aminoacridine), a drug that has attained interest because of its ability to alleviate symptoms in Alzheimer's type of dementia, was found to stimulate insulin secretion from isolated rat pancreatic islets. The insulinotropic effect of the drug was observed at 8.3 mM but not at 3.3 mM glucose and was dependent on extracellular Ca++. From perifused 86Rb(+)-prelabeled islets, tacrine inhibited the fractional efflux of 86Rb+ at 3.3 mM glucose, but stimulated 86Rb+ efflux at 8.3 mM glucose. These effects persisted in the absence of extracellular Ca++. Tacrine also stimulated 45Ca++ efflux from perifused 45Ca(++)-prelabeled islets at 8.3 mM but had no effect on 45Ca++ efflux at 3.3 mM glucose or in the absence of extracellular Ca++. It is concluded that tacrine potentiates glucose-stimulated insulin secretion by a mechanism that is dependent on extracellular Ca++ and involves an increased Ca++ influx. The increased Ca++ influx is either secondary to a decreased K+ permeability induced by an inhibition of ATP-dependent K+ channels and/or due to a direct effect of tacrine on glucose-activated Ca++ channels.     

Somatostatin- and Epinephrine-Induced Modifications of 45Ca++ Fluxes and Insulin Release in Rat Pancreatic Islets Maintained in Tissue Culture

The effects of somatostatin and epinephrine have been studied with regard to glucose-induced insulin release and (45)Ca(++) uptake by rat pancreatic islets after 2 days in tissue culture and with regard to (45)Ca(++) efflux from islets loaded with the radio-isotope during the 2 days of culture. (45)Ca(++) uptake, measured simultaneously with insulin release, was linear with time for 5 min. (45)Ca(++) efflux and insulin release were also measured simultaneously from perifused islets.Glucose (16.7 mM) markedly stimulated insulin release and (45)Ca(++) uptake. Somatostatin inhibited the stimulation of insulin release by glucose in a concentration-related manner (1-1,000 ng/ml) but was without effect on the glucose-induced stimulation of (45)Ca(++) uptake. Similarly, under perifusion conditions, both phases of insulin release were inhibited by somatostatin while no effect was observed on the pattern of (45)Ca(++) efflux after glucose.Epinephrine, in contrast to somatostatin, caused a concentration-dependent inhibition of the stimulation of both insulin release and (45)Ca(++) uptake by glucose. Both phases of insulin release were inhibited by epinephrine and marked inhibition could be observed with no change in the characteristic glucose-evoked pattern of (45)Ca(++) efflux (e.g., with 10 nM epinephrine). The inhibitory effect of epinephrine on (45)Ca(++) uptake and insulin release appeared to be mediated via an alpha-adrenergic mechanism, since is was abolished in the presence of phentolamine.Somatostatin inhibits insulin release without any detectable effect upon the handling of calcium by the islets. In contrast, inhibition of insulin release by epinephrine is accompanied by a partial inhibition of glucose-induced Ca(++) uptake.     

Increased islet apoptosis in Pdx1+/- mice

Mice with 50% Pdx1, a homeobox gene critical for pancreatic development, had worsening glucose tolerance with age and reduced insulin release in response to glucose, KCl, and arginine from the perfused pancreas. Surprisingly, insulin secretion in perifusion or static incubation experiments in response to glucose and other secretagogues was similar in islets isolated from Pdx1(+/-) mice compared with Pdx1(+/+) littermate controls. Glucose sensing and islet Ca(2+) responses were also normal. Depolarization-evoked exocytosis and Ca(2+) currents in single Pdx1(+/-) cells were not different from controls, arguing against a ubiquitous beta cell stimulus-secretion coupling defect. However, isolated Pdx1(+/-) islets and dispersed beta cells were significantly more susceptible to apoptosis at basal glucose concentrations than Pdx1(+/+) islets. Bcl(XL) and Bcl-2 expression were reduced in Pdx1(+/-) islets. In vivo, increased apoptosis was associated with abnormal islet architecture, positive TUNEL, active caspase-3, and lymphocyte infiltration. Although similar in young mice, both beta cell mass and islet number failed to increase with age and were approximately 50% less than controls by one year. These results suggest that an increase in apoptosis, with abnormal regulation of islet number and beta cell mass, represents a key mechanism whereby partial PDX1 deficiency leads to an organ-level defect in insulin secretion and diabetes.     

Dependency of cyclic AMP-induced insulin release on intra- and extracellular calcium in rat islets of Langerhans.

Calcium and cyclic AMP are important in the stimulation of insulin release. The phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (IBMX) raises islet cAMP levels and causes insulin release at nonstimulatory glucose concentrations. In isolated rat pancreatic islets maintained for 2 d in tissue culture, the effects of IBMX on insulin release and 45Ca++ fluxes were compared with those of glucose. During perifusion at 1 mM Ca++, 16.7 mM glucose elicited a biphasic insulin release, whereas 1 mM IBMX in the presence of 2.8 mM glucose caused a monophasic release. Decreasing extracellular Ca++ a monophasic release. Decreasing extracellular Ca++ to 0.1 mM during stimulation reduced the glucose effect by 80% but did not alter IBMX-induced release. Both glucose and IBMX stimulated 45Ca++ uptake (5 min). 45Ca++ efflux from islets loaded to isotopic equilibrium (46 h) was increased by both substances. IBMX stimulation of insulin release, of 45Ca++ uptake, and of efflux were not inhibited by blockade of Ca++ uptake with verapamil, whereas glucose-induced changes are known to be inhibited. Because IBMX-induced insulin release remained unaltered at 0.1 mM calcium, it appears that cAMP-stimulated insulin release is controlled by intracellular calcium. This is supported by perifusion experiments at 0 Ca++ when IBMX stimulated net Ca++ efflux. In addition, glucose-stimulated insulin release was potentiated by IBMX. These results suggest that cAMP induced insulin release is mediated by increases in cytosolic Ca++ and that cAMP causes dislocation of Ca++ from intracellular stores.     

Junctional communication of pancreatic beta cells contributes to the control of insulin secretion and glucose tolerance

Proper insulin secretion requires the coordinated functioning of the numerous beta cells that form pancreatic islets. This coordination depends on a network of communication mechanisms whereby beta cells interact with extracellular signals and adjacent cells via connexin channels. To assess whether connexin-dependent communication plays a role in vivo, we have developed transgenic mice in which connexin 32 (Cx32), one of the vertebrate connexins found in the pancreas, is expressed in beta cells. We show that the altered beta-cell coupling that results from this expression causes reduced insulin secretion in response to physiologically relevant concentrations of glucose and abnormal tolerance to the sugar. These alterations were observed in spite of normal numbers of islets, increased insulin content, and preserved secretory response to glucose by individual beta cells. Moreover, glucose-stimulated islets showed improved electrical synchronization of these cells and increased cytosolic levels of Ca(2+). The results show that connexins contribute to the control of beta cells in vivo and that their excess is detrimental for insulin secretion.     

Role of Ca2+ in secretagogue-stimulated breakdown of phosphatidylinositol in rat pancreatic islets.

Breakdown of phosphatidylinositol (PI) has been shown to be increased during Ca2+-mediated stimulation of cellular responses in many systems and has been proposed to be involved in stimulus-secretion coupling. The effects on PI breakdown of insulin secretagogues that alter cellular Ca2+ or cyclic (c)AMP levels were investigated in perifused rat islets of Langerhans. Isolated islets were labeled with myo-[2-3H(N)]inositol and the efflux of 3H-labeled metabolites was monitored. Glucose (16.7 mM) greatly increased 3H release in a manner that paralleled the second phase of the insulin secretory response; by 60 min, the amount of [3H]PI in the islet decreased by 50%. Removal of Ca2+ from the perifusate or blockade of Ca2+ entry through the voltage-dependent channels by D600 (20 microM) abolished the glucose-induced increase in 3H efflux. Depolarization with 47 mM K+, which increases Ca2+ entry, stimulated protracted 3H and insulin release. Glucose-stimulated output of 3H was not prevented by epinephrine (1 microM) even though the insulin response was abolished. In contrast, 3H output was not affected by isobutylmethylxanthine (1 mM), known to raise cellular levels of cAMP, although insulin release was stimulated. These findings indicate that PI breakdown is not related to the exocytotic process since stimulation of insulin release and PI breakdown could be uncoupled, and that it is not associated with cAMP-mediated regulation of insulin release. PI breakdown in islets differs from the immediate, transient phenomenon reported in other systems in both its timing and requirement for Ca2+. It appears to result from the entry of Ca2+ and not to be the mechanism by which glucose initiates Ca2+ influx.     

Mechanisms by which glucose can control insulin release independently from its action on adenosine triphosphate-sensitive K+ channels in mouse B cells.

Glucose stimulation of insulin release involves closure of ATP-sensitive K+ channels (K(+)-ATP channels), depolarization, and Ca2+ influx in B cells. However, by using diazoxide to open K(+)-ATP channels, and 30 mM K to depolarize the membrane, we could demonstrate that another mechanism exists, by which glucose can control insulin release independently from changes in K(+)-ATP channel activity and in membrane potential (Gembal et al. 1992. J. Clin. Invest. 89:1288-1295). A similar approach was followed here to investigate, with mouse islets, the nature of this newly identified mechanism. The membrane potential-independent increase in insulin release produced by glucose required metabolism of the sugar and was mimicked by other metabolized secretagogues. It also required elevated levels of cytoplasmic Cai2+, but was not due to further changes in Cai2+. It could not be ascribed to acceleration of phosphoinositide metabolism, or to activation of protein kinases A or C. Thus, glucose did not increase inositol phosphate levels and hardly affected cAMP levels. Moreover, increasing inositol phosphates by vasopressin or cAMP by forskolin, and activating protein kinase C by phorbol esters did not mimic the action of glucose on release, and down-regulation of protein kinase C did not prevent these effects. On the other hand, it correlated with an increase in the ATP/ADP ratio in islet cells. We suggest that the membrane potential-independent control of insulin release exerted by glucose involves changes in the energy state of B cells.