Insulin release and metabolism of calcium, adenine and adenosine 3',5'-cyclic monophosphate.

In order to assess further the mechanisms involved in insulin release, we prelabeled rat pancreatic islets of Langerhans by incubating either 45Ca or [2-3H]adenine. When prelabeled islets were perfused with a glucose-free medium (the experiment with 45Ca) and a medium containing 2.8 mM glucose (the experiment with [2-3H]adenine) respectively, a constant rate of efflux of the radioactivity was established by 30 min in each case. D-Glucose at 16.7 mM concentration elicited a rapid efflux of 45Ca and [2-3H]adenine derivatives ([3H]Ad) within 4 to 6 min after commencing the step-wise stimulation by glucose, concomitantly with insulin release. However, L-glucose and D-galactose littel stimulated both 45Ca and [3H]Ad release. Lanthanum chloride caused a burst peak of 45Ca release in the absence of glucose. A rapid efflux of 45Ca was caused by beta-D-glucose and D-glyceraldehyde to much lesser extent than by alpha-D-glucose. The slowly rising concentration of glucose at 0.1 mM/min of gradient level failed to elicit any rapid efflux of 45Ca or [3H]Ad, although insulin release occurred in accordance with an increase in glucose concentration. Even when the gradient of glucose concentration was raised to 0.7 mM/min, glucose failed to stimulate an efflux of [3H]Ad but the subsequent stimulation by 16.7 mM glucose caused a rapid efflux of [3H]Ad concomitantly with the release of insulin. No rapid efflux of 45Ca was observed under a slow-rise glucose stimulation until the gradient level of the glucose concentration was raised to 6.7 mM. Analysis of distribution of the radioactive adenine derivatives after incubation showed that the adenosine fraction had the highest radioactivity in the medium followed by the ATP, adenine and cAMP fraction in that order, and the ATP fraction had the highest radioactivity in the islet. The ratio of radioactivity in the cAMP fraction in the medium to the total count was the highest among all. On the basis of these results, it was suggested that the discharge of [3H]Ad and 45Ca might occur with the alteration of the membrane permeability induced by a rapid change of the glucose concentration, and that their discharge might perhaps link to the glucoreceptor mechanism directly controlling insulin release.     

Significance of Ca2+, Rb+ fluxes, of cAMP and cGMP for the CCK8-modulated insulin release

In rat pancreatic islets the effects of cholecystokinin-8 (CCK8) on glucose-mediated insulin release, 45Ca2+ net uptake, 45Ca2+ efflux, 86Rb+ efflux, cAMP- and cGMP levels were studied. In the presence of a substimulatory glucose concentration (3 mM) CCK8 concentrations of up to 1 microM had no effect on insulin release, but CCK8 at 10 nM potentiated the stimulatory effect of glucose (11.1 mM). 10 nM CCK8 enhanced glucose-stimulated 45Ca2+ net uptake but was ineffective at substimulatory glucose levels. CCK8 had no effect on cAMP and cGMP levels in the presence of 11.1 mM glucose, CCK8 increased 86Rb+ (a measure of K+) in the presence of both 3 and 11.1 mM glucose. This effect was abolished when Ca2+ was omitted from the perifusion medium. CCK8 did not alter glucose (11.1 mM)-stimulated 45Ca2+ efflux rate. These data indicate that (1) CCK8 potentiates glucose-stimulated insulin secretion possibly via an effect on Ca2+ uptake, 2) by affecting Ca2+ uptake, CCK8 enhances K+ efflux, and 3) CCK8 does not mediate its effect via cAMP or cGMP. With respect to 86Rb+ efflux the mechanism of CCK8 action appears to be different from that of glucose. When the mechanism of CCK action on islets is compared with that on exocrine pancreas (data from others) there are similarities (importance of Ca2+ uptake and non-importance of cAMP and cGMP).     

Calcium and pancreatic beta-cell function. The mechanism of insulin secretion studied with the aid of lanthanum.

La3+ was used to study the involvement of Ca2+ in insulin secretion in beta-cell-rich pancreatic islets micro-dissected from non-inbred ob/ob mice. Ultrastructural studies revealed that the localization of La3+ was entirely restricted to the exterior of the cells. Consistent with a membrane action, exposure to La3+ failed to affect glucose oxidation and either the sucrose space or the general ultrastructure of the islets. In contrast, La3+ had marked effects on insulin release and 45Ca fluxes. Exposure to La3+ resulted in pronounced inhibition of insulin release irrespective of the presence or absence of Ca2+, 3-isobutyl-1-methylxanthine or glucose. Perifusion experiments revealed that the inhibitory action was prompt, sustained and readily reversible. Removal of La3+ was associated with a subsequent prolonged stimulatory phase of insulin release even in medium deficient in Ca2+. This action could not be attributed to an increase in cyclic AMP, but was potentiated by 3-isobutyl-1-methylxanthine and abolished by L-adrenaline. La3+ displaced 45Ca from superficially located binding sites and inhibited the uptake and efflux of 45Ca. The stimulatory and inhibitory actions of glucose on 45Ca efflux were also abolished in the presence of 2 mM-La3+ Removal of La3+ was associated with the preferential mobilization of 45Ca incorporated in response to glucose. The results indicate that binding of La3+ to superficial sites in the plasma membrane leads to inhibition of insulin release by suppression of transmembrane Ca2+ fluxes. It is suggested that accumulation of Ca2+ in the cytoplasm accounts for the stimulation of insulin release seen after removal of La3+ from inhibitory binding sites in the beta-cell plasma membrane.     

Calcium and pancreatic beta-cell function. 4. Evidence that glucose and phosphate stimulate calcium-45 incorporation into different intracellular pools.

beta-Cell-rich pancreatic islets were microdissected from ob/ob-mice and used for studies of 45Ca uptake and washout. Irrespective of whether the experiments were performed at 21 or 37 degrees C both glucose and phosphate stimulated the net uptake of lanthanum-nondisplaceable 45Ca. The stimulatory effect of phosphate was additive to that produced by glucose. 45Ca incorporated in response to phosphate differed from that taken up in the presence of 20 mM glucose in being easily washed out although it was not affected by the glucose concentration of the washing medium. The efflux of 45Ca was reduced after introducing phosphate into a medium used to perifuse islets which had accumulated 45Ca in response to 20 mM glucose. This suggests that the outward calcium transport can be influenced also by intracellular trapping of the cation. The glucose-stimulated insulin release was inhibited by phosphate; an effect reversed by the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine. It is concluded that a common effect of glucose and phosphate is to trap calcium in the pancreatic beta-cells but that there are fundamental differences between their effects on intracellular distribution of calcium and on insulin release.     

Glucose-, calcium- and concentration-dependence of acetylcholine stimulation of insulin release and ionic fluxes in mouse islets.

Mouse islets were used to define the glucose-dependence and extracellular Ca2+ requirement of muscarinic stimulation of pancreatic beta-cells. In the presence of a stimulatory concentration of glucose (10 mM) and of Ca2+, acetylcholine (0.1-100 microM) accelerated 3H efflux from islets preloaded with myo-[3H]inositol. It also stimulated 45Ca2+ influx and efflux, 86Rb+ efflux and insulin release. In the absence of Ca2+, only 10-100 microM-acetylcholine mobilized enough intracellular Ca2+ to trigger an early but brief peak of insulin release. At a non-stimulatory concentration of glucose (3 mM), 1 microM- and 100 microM-acetylcholine increased 45Ca2+ and 86Rb+ efflux in the presence and absence of extracellular Ca2+. However, only 100 microM-acetylcholine marginally increased 45Ca2+ influx and caused a small, delayed, stimulation of insulin release, which was abolished by omission of Ca2+. At a maximally effective concentration of glucose (30 mM), 1 microM- and 100 microM-acetylcholine increased 45Ca2+ influx and efflux only slightly, but markedly amplified insulin release. Again, only 100 microM-acetylcholine mobilized enough Ca2+ to trigger a peak of insulin release in the absence of Ca2+. The results thus show that only high concentrations of acetylcholine (greater than or equal to 10 microM) can induce release at low glucose or in a Ca2+-free medium. beta-Cells exhibit their highest sensitivity to acetylcholine in the presence of Ca2+ and stimulatory glucose. Under these physiological conditions, the large amplification of insulin release appears to be the result of combined effects of the neurotransmitter on Ca2+ influx, on intracellular Ca2+ stores and on the efficiency with which Ca2+ activates the releasing machinery.     

The effects of cesium chloride on insulin release, ionic fluxes and membrane potential in pancreatic B-cells

Cs+ decreases K+ permeability in nerve and muscle cells. Its effects on the pancreatic B-cell function were studied with mouse islets. In the presence of 3 mM glucose, Cs+ substitution for K+ steadily inhibited 86Rb+ efflux and hyperpolarized the B-cell membrane. Addition of Cs+ to a K+-medium also inhibited 86Rb+ efflux, but depolarized the B-cell membrane. None of these changes altered insulin release. Substitution of Cs+ for K+ in a medium containing 10 mM glucose caused a Ca2+-dependent stimulation of insulin release and 45Ca2+ efflux, produced an initial fall and a secondary rise in 86Rb+ efflux and augmented the electrical activity in B-cells. Reintroduction of K+ to the medium was followed by a marked and transient inhibition of insulin release, that was blocked by ouabain and accompanied by an inhibition of 45Ca2+ and 86Rb+ efflux and by a hyperpolarization of the B-cell membrane. Addition of Cs+ to a K+ medium containing 10 mM glucose stimulated insulin release, 45Ca2+ efflux and 86Rb+ efflux. It also increased the electrical activity in B-cells. In the absence of Ca2+, however, Cs+ addition decreased the rate of 86Rb+ efflux. The effects of Cs+ on the B-cell function may be explained by its ability to decrease K+ permeability of the plasma membrane, by its inability to activate the sodium pump, and by a third unidentified effect likely brought about by the accumulation of intracellular Cs+.     

Calcium and pancreatic β-cell function: 4. Evidence that glucose and phosphate stimulate calcium-45 incorporation into different intracellular pools

β-Cell-rich pancreatic islets were microdissected from ob/ob-mice and used for studies of ⁴⁵Ca uptake and washout. Irrespective of whether the experiments were performed at 21 or 37°C both glucose and phosphate stimulated the net uptake of lanthanum-nondisplaceable ⁴⁵Ca. The stimulatory effect of phosphate was additive to that produced by glucose. ⁴⁵Ca incorporated in response to phosphate differed from that taken up in the presence of 20 mM glucose in being easily washed out although it was not affected by the glucose concentration of the washing medium. The efflux of ⁴⁵Ca was reduced after introducing phosphate into a medium used to perifuse islets which had accumulated ⁴⁵Ca in response to 20 mM glucose. This suggests that the outward calcium transport can be influenced also by intracellular trapping of the cation. The glucose-stimulated insulin release was inhibited by phosphate; an effect reversed by the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine. It is concluded that a common effect of glucose and phosphate is to trap calcium in the pancreatic β-cells but that there are fundamental differences between their effects on intracellular distribution of calcium and on insulin release.     

Studies on the interaction of staphylococcal delta-haemolysin with isolated islets of Langerhans.

delta-Haemolysin, a small surface-active polypeptide purified from the culture media of Staphylococcus aureus, was observed to stimulate the release of insulin from isolated rat islets of Langerhans. This effect was dose-dependent and saturable, with the half-maximal response elicited by a delta-haemolysin concentration of 10 micrograms/ml. Stimulation of insulin release by delta-haemolysin (10 micrograms/ml) was not dependent on the presence of glucose in the incubation medium, but was augmented by increasing concentrations of the sugar. The release of insulin in response to delta-haemolysin could be inhibited by depletion of extracellular Ca2+ or by adrenaline (epinephrine) (10 microM) and was readily reversible when delta-haemolysin was removed from the medium. In addition, the response was potentiated by incubation with the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (0.2 mM). These observations suggest that delta-haemolysin induced a true activation of the beta-cell secretory mechanism. Stimulation of islets of Langerhans with delta-haemolysin was found to be associated with a modest increase in intracellular cyclic AMP levels, although the adenylate cyclase activity of islet homogenates was not increased by delta-haemolysin. delta-Haemolysin was observed to induce a dose-dependent net accumulation of 45Ca2+ by islet cells and to stimulate the efflux of 45Ca2+ from preloaded islets. The efflux of 45Ca2+ was modest in size and short-lived, but dramatically increased in medium depleted fo 40Ca2+. Incubation in the presence of verapamil augmented delta-haemolysin-induced 45Ca2+ efflux and insulin secretion. delta-Haemolysin was found to be a potent 45Ca2+-translocating ionophore in an artificial system. This response was dose-dependent and could be augmented by verapamil. In addition, phosphatidylcholine (25 micrograms/ml) was found to inhibit both delta-haemolysin induced 45Ca2+ translocation and insulin release in a precisely parallel manner. These studies suggest that the ability of delta-haemolysin to stimulate insulin release may be due, in part, to the facilitation of Ca2+ entry into the beta-cells of islets of Langerhans, mediated directly by an ionophoretic mechanism.     

Effects of monensin on metabolism of isolated rat islets of Langerhans.

Monensin, a univalent ionophore, is a carboxylic acid produced by Streptomyces cinnamonensis. It will complex various alkali-metal ions, but most readily binds Na+. Because of interest in the possible role of Na+ in the regulation of insulin secretion, we examined its effects on several aspects of the metabolism of isolated rat islets of Langerhans. The ionophore inhibited glucose-stimulated insulin release in a concentration-dependent manner, completely inhibiting secretion evoked by 20 mM-glucose at concentrations as low as 0.1 microM in static incubations. In perifusion experiments, both phases of insulin release were equally affected. Monensin (0.1 microM) had no significant effect on glucose oxidation as measured by the generation of 14CO2 from [14C]glucose. Monensin increased the rate of 22Na+ efflux from preloaded islets and net 22Na+ uptake over 30 min, in the absence of changes in islet volume or extracellular space. The ionophore increased the Rb+/K+ permeability of islet cells, as shown by its inhibition of 86Rb+ retention and stimulation of 86Rb+ efflux. At 0.1 microM, monensin abolished glucose-stimulated 45Ca2+ uptake by islets during 5 min incubations, and stimulated 45Ca2+ efflux from preloaded islets perifused with Ca2+-free medium, even in the complete absence of extracellular Na+. Studies of the uptake of 14C-labelled 5,5-dimethyloxazolidine-2,4-dione showed that 0.1 microM-monensin increased net intracellular pH from 7.05 to 7.13. 7 Monensin has widespread, complex, effects on the secretory responses and ion handling by the B cells, which are difficult to interpret in terms solely of actions as a Na+ ionophore.     

Glucose inhibits 45Ca efflux from pancreatic beta-cells also in the absence of Na+-Ca2+ countertransport

During perifusion with medium deprived of Ca2+, addition of glucose or omission of Na+ resulted in prompt and quantitatively similar inhibitions of 45Ca efflux from beta-cell rich pancreatic islets microdissected from ob/ob mice. Glucose had no additional inhibitory effect when Na+ was isoosmotically replaced by sucrose or choline+. When K+ was used as a substitute for Na+, the inhibitory effect of Na+ removal on 45Ca efflux became additive to that of glucose. The observation that glucose can be equally effective in inhibiting 45Ca efflux in the presence or absence of Na+ is difficult to reconcile with the postulate that the Na+-Ca2+ countertransport mechanism is a primary site of action for glucose.     

Manganese accumulation in pancreatic beta-cells and its stimulation by glucose.

Electrothermal atomic-absorption spectroscopy was employed for measuring manganese in beta-cell-rich pancreatic islets microdissected from ob/ob mice. The islet content of endogenous manganese was 80 mumol/kg dry wt., which is about half as much as found in the exocrine pancreas. The initial uptake was characterized by two components, with approximate Km values of 35 microM and 3.7 microM respectively. After 60 min of incubation with 0.25 mM-Mn2+, the intracellular concentration of manganese corresponded to an almost 25-fold accumulation compared with that of the extracellular medium. When exposed to 20 mM-D-glucose, the islets retained more manganese, owing to suppression of its mobilization. The glucose inhibition of efflux was prompt and reversible, as indicated from direct recordings of manganese in a perifusion medium. D-Glucose was an equally potent inhibitor of efflux in the presence of 15 microM- and 1.28 mM-Ca2+. The inhibitory action disappeared when metabolism was suppressed by adding 0.1 mM-N-ethylmaleimide or by lowering the temperature from 37 degrees C to 2 degrees C. At a concentration of 0.25 mM, Mn2+ abolished the insulin-releasing action of D-glucose, exerting only moderate suppression of its metabolism. The addition of Mn2+ resulted in inhibition of basal insulin release in the presence of 1.28 mM-Ca2+, but not in a Ca2+-deficient medium. The studies indicate that the previously observed phenomenon of glucose inhibition of 45Ca efflux has a counterpart in the suppression of manganese mobilization from the pancreatic islets. With the demonstration of a pronounced glucose inhibition of manganese efflux, it is evident that Mn2+ may represent a useful tool for exploring the mechanism of glucose-induced retention of calcium in the pancreatic beta-cells.     

Effects of acute sodium omission on insulin release, ionic flux and membrane potential in mouse pancreatic B-cells

The effects of acute omission of extracellular Na+ on pancreatic B-cell function were studied in mouse islets, using choline and lithium salts as impermeant and permeant substitutes, respectively. In the absence of glucose, choline substitution for Na+ hyperpolarized the B-cell membrane, inhibited 86Rb+ and 45Ca2+ efflux, but did not affect insulin release. In contrast, Li+ substitution for Na+ depolarized the B-cell membrane and caused a Ca2+-independent, transient acceleration of 45Ca2+ efflux and insulin release. Na+ replacement by choline in the presence of 10 mM glucose and 2.5 mM Ca2+ again rapidly hyperpolarized the B-cell membrane. This hyperpolarization was then followed by a phase of depolarization with continuous spike activity, before long slow waves of the membrane potential resumed. Under these conditions, 86Rb+ efflux first decreased before accelerating, concomitantly with marked and parallel increases in 45Ca2+ efflux and insulin release. In the absence of Ca2+, 45Ca2+ and 86Rb+ efflux were inhibited and insulin release was unaffected by choline substitution for Na+. Na+ replacement by Li+ in the presence of 10 mM glucose rapidly depolarized the B-cell membrane, caused an intense continuous spike activity, and accelerated 45Ca2+ efflux, 86Rb+ efflux and insulin release. In the absence of extracellular Ca2+, Li+ still caused a rapid but transient increase in 45Ca2+ and 86Rb+ efflux and in insulin release. Although not indispensable for insulin release, Na+ plays an important regulatory role in stimulus-secretion coupling by modulating, among others, membrane potential and ionic fluxes in B-cells.     

Effects of trifluoperazine and pimozide on stimulus–secretion coupling in pancreatic B-cells. Suggestion for a role of calmodulin?

The possible involvement of calmodulin in insulin release was evaluated by studying the effects on intact islets of trifluoperazine and pimozide, two antipsychotic agents known to bind strongly to calmodulin in cell-free systems. Trifluoperazine (10-100mum) produced a dose- and time-dependent inhibition of the two phases of glucose-stimulated insulin release. The effect was not reversible by simple washing of the drug, but could be prevented by cytochalasin B or theophylline. Trifluoperazine also inhibited the release induced by glyceraldehyde, oxoisocaproate, tolbutamide or barium, but not that stimulated by 10mm-theophylline or 1mm-3-isobutyl-1-methylxanthine. Pimozide (0.5-10mum) also produced a dose-dependent inhibition of insulin release triggered by glucose, leucine or barium, but did not affect the release induced by methylxanthines. Glucose utilization by islet cells was not modified by trifluoperazine (25mum), which slightly increased cyclic AMP concentration in islets incubated without glucose. The drug did not prevent the increase in cyclic AMP concentration observed after 10min of glucose stimulation, but suppressed it after 60min. Basal or glucose-stimulated Ca(2+) influx (5min) was unaffected by 25mum-trifluoperazine, whereas Ca(2+)net uptake (60min) was inhibited by 20%. Glucose-stimulated Ca(2+) uptake was almost unaffected by pimozide. In a Ca(2+)-free medium, trifluoperazine decreased Ca(2+) efflux from the islets and did not prevent the further decrease by glucose; in the presence of Ca(2+), the drug again decreased Ca(2+) efflux and inhibited the stimulation normally produced by glucose. In the absence of glucose, trifluoperazine lowered the rate of Rb(+) efflux from the islets, decreased Rb(+) influx (10min), but did not affect Rb(+) net uptake (60min). It did not interfere with the ability of glucose to decrease Rb(+) efflux rate further and to increase Rb(+) net uptake. The results show thus that trifluoperazine does not alter the initial key events of the stimulus-secretion coupling. Its inhibition of insulin release suggests a role of calmodulin at late stages of the secretory process.     

Mathematical modeling of stimulus-secretion coupling in the pancreatic beta-cell. III. Glucose-induced inhibition of calcium efflux.

The inhibitory effect of glucose upon 45Ca efflux from prelabeled pancreatic islets was simulated in a mathematical model for Ca2+-cyclic AMP interaction in the process of glucose-induced insulin release. At variance with a previous interpretation, it was postulated that glucose inhibits 45Ca efflux by facilitating the uptake of the cation by the vacuolar system. The latter facilitation did not hinder glucose from provoking a rapid accumulation of cytosolic Ca2+ and, hence, insulin release. The postulated facilitation was also suitable in simulating the effect of glucose upon 45Ca efflux, uptake, and intracellular distribution in the pancreatic islets.     

Distinct mechanisms for two amplification systems of insulin release.

The mechanisms whereby activation of the cyclic AMP-dependent protein kinase A or the Ca2+-phospholipid-dependent protein kinase C amplifies insulin release were studied with mouse islets. Forskolin and the phorbol ester 12-O-tetradecanoylphorbol 13-acetate (TPA) were used to stimulate adenylate cyclase and protein kinase C respectively. The sulphonylurea tolbutamide was used to initiate insulin release in the presence of 3 mM-glucose. Tolbutamide alone inhibited 86Rb+ efflux, depolarized beta-cell membrane, triggered electrical activity, accelerated 45Ca2+ influx and efflux and stimulated insulin release. Forskolin alone only slightly inhibited 86Rb+ efflux, but markedly increased the effects of tolbutamide on electrical activity, 45Ca2+ influx and efflux, and insulin release. In the absence of Ca2+, only the inhibition of 86Rb+ efflux persisted. TPA (100 nM) alone slightly accelerated 45Ca2+ efflux and insulin release without affecting 45Ca2+ influx or beta-cell membrane potential. It increased the effects of tolbutamide on 45Ca2+ efflux and insulin release without changing 86Rb+ efflux, 45Ca2+ influx or electrical activity. Omission of extracellular Ca2+ suppressed all effects due to the combination of TPA and tolbutamide, but not those of TPA alone. Though ineffective alone, 10 nM-TPA amplified the releasing action of tolbutamide without affecting its ionic and electrical effects. In conclusion, the two amplification systems of insulin release involve at least partially distinct mechanisms. The cyclic AMP but not the protein kinase C system initiating signal (Ca2+ influx) triggered by the primary secretagogue.     

Distinct effects of various amino acids on 45Ca2+ fluxes in rat pancreatic islets.

The effects of three types of amino acids on 45Ca2+ fluxes in rat pancreatic islets have been compared. Alanine, a non-insulinotropic neutral amino acid, transported with Na+, increased 45Ca2+ efflux in the presence or in the absence of extracellular Ca2+, but not in the absence of Na+. Its effects in Na+-solutions were practically abolished by 7 mM-glucose. Alanine slightly stimulated 45Ca2+ influx (5 min uptake) only when Na+ was present. Two insulinotropic cationic amino acids (arginine and lysine) triggered similar changes in 45Ca2+ efflux. They accelerated the efflux in the presence of Ca2+ and inhibited the efflux in a Ca2+-free medium, whether glucose was present or not. In an Na+-free Ca2+-medium, arginine and lysine markedly accelerated 45Ca2+ efflux, but this effect was suppressed by 7 mM-glucose. Arginine stimulated 45Ca2+ influx irrespective of the presence or absence of glucose and Na+. Leucine, a neutral insulinotropic amino acid well metabolized by islet cells, inhibited 45Ca2+ efflux from the islets in a Ca2+-free medium; this effect was potentiated by glutamine. In the presence of Ca2+ and Na+, leucine was ineffective alone, but triggered a marked increase in 45Ca2+ efflux when combined with glutamine. In an Na+-free Ca2+-medium, leucine accelerated 45Ca2+ efflux to the same extent with or without glutamine. Leucine also stimulated 45Ca2+ influx in the presence or in the absence of Na+, but its effects were potentiated by glutamine only in the presence of Na+. The results show that amino acids of various types cause distinct changes in 45Ca2+ fluxes in pancreatic islets. Certain of these changes involve an Na+-mediated mobilization of cellular Ca2+ from sequestering sites where glucose appears to exert an opposite effect.     

Activation of insulin-secreting cells by pyruvate and halogenated derivatives.

Addition of pyruvate to rat islets perifused in the presence of 5 mM-glucose elicited an immediate pronounced biphasic stimulation of insulin secretion. At lower concentrations of glucose (2.5 mM), only the initial, transient, phase of secretion was observed. Pyruvate inhibited 45Ca2+ efflux from islets at 2.5 mM-glucose and stimulated efflux at 5 mM-glucose. Pyruvate also decreased the rate of efflux of 86Rb+ from perifused islets. A marked stimulation of insulin secretion and 45Ca2+ efflux rate was observed in response to 3-fluoropyruvate and 3-bromopyruvate, compounds which inhibited oxidative metabolism of [14C]glucose and [14C]pyruvate in islets. The stimulatory effects of 3-fluoro- and 3-bromo-pyruvate were associated with enhanced 86Rb+ efflux. Withdrawal of pyruvate or halogenated analogues from the perfusate resulted in a secondary stimulation of insulin release, 45Ca2+ efflux and, to some extent, 86Rb+ efflux rates. Pyruvate, 3-fluoropyruvate and 3-bromopyruvate were all effective in promoting intracellular acidification and a rise in cytosolic Ca2+ concentration, as judged from fluorescence measurements in HIT-T15 cells loaded with 2',7'-biscarboxyethyl-5'(6')-carboxyfluorescein and Quin 2 respectively. It is proposed that oxidative metabolism of pyruvate is not a prerequisite for its stimulatory actions on pancreatic beta-cells. An alternative mechanism of activation by pyruvate and its halogenated derivatives is proposed, based on the possible electrogenic flux of these anions across the cell membrane.     

Dibutyryl cyclic AMP triggers Ca2+ influx and Ca2+-dependent electrical activity in pancreatic B cells

In the presence of 7 mM glucose, dibutyryl cyclic AMP induced electrical activity in otherwise silent mouse pancreatic B cells. This activity was blocked by cobalt or D600, two inhibitors of Ca2+ influx. Under similar conditions, dibutyryl cyclic AMP stimulated 45Ca2+ influx (5-min uptake) in islet cells; this effect was abolished by cobalt and partially inhibited by D600. The nucleotide also accelerated 86Rb+ efflux from preloaded islets, did not modify glucose utilization and markedly increased insulin release. Its effects on release were inhibited by cobalt, but not by D600. These results show that insulin release can occur without electrical activity in B cells and suggest that cyclic AMP not only mobilizes intracellular Ca, but also facilitates Ca2+ influx in insulin secreting cells.     

Cadmium-induced insulin release does not involve changes in intracellular handling of calcium

A possible interaction between Cd2+ and Ca2+ as a component in Cd2+-induced insulin release was investigated in beta cells isolated from obese hyperglycemic mice. The glucose stimulated Cd2+ uptake was dependent on the concentration of sugar. This uptake was sigmoidal with a Km for glucose of about 5 mM and was suppressed by both 50 microM of the voltage-activated Ca2+ channel blocker D-600 and 12 mM Mg2+. In the presence of 8 mM glucose 5 microM Cd2+ evoked a prompt and sustained stimulatory response, corresponding to about 3-fold of the insulin release obtained in the absence of the ion. Whereas 5 microM Cd2+ was without effect on the glucose-stimulated 45Ca efflux in the presence of extracellular Ca2+, 40 microM inhibited it. At a concentration of 5 microM, Cd2+ had no effect on the resting membrane potential or the depolarization evoked by either glucose or K+. In the absence of extracellular Ca2+ there was only a modest stimulation of 45Ca efflux by 5 microM Cd2+. Studies of the ambient free Ca2+ concentration maintained by permeabilized cells also indicate that 5 microM Cd2+ do not mobilize intracellularly bound Ca2+ to any great extent. On the contrary, at this concentration, Cd2+ even suppressed inositol 1,4,5-trisphosphate (IP3)-induced Ca2+ release. The present study suggests that Cd2+ stimulates insulin release by a direct mechanism which does not involve an increase in cytoplasmic free Ca2+ concentration.     

Studies on the role of inositol trisphosphate in the regulation of insulin secretion from isolated rat islets of Langerhans.

Glucose (20 mM) and carbachol (1 mM) produced a rapid increase in [3H]inositol trisphosphate (InsP3) formation in isolated rat islets of Langerhans prelabelled with myo-[3H]inositol. The magnitude of the increase in InsP3 formation was similar when either agent was used alone and was additive when they were used together. In islets prelabelled with 45Ca2+ and treated with carbachol (1 mM), the rise in InsP3 correlated with a rapid, transient, release of 45Ca2+ from the cells, consistent with mobilization of 45Ca2+ from an intracellular pool. Under these conditions, however, insulin secretion was not increased. In contrast, islets prelabelled with 45Ca2+ and exposed to 20mM-glucose exhibited a delayed and decreased 45Ca2+ efflux, but released 7-8-fold more insulin than did those exposed to carbachol. Depletion of extracellular Ca2+ failed to modify the increase in InsP3 elicited by either glucose or carbachol, whereas it selectively inhibited the efflux of 45Ca2+ induced by glucose in preloaded islets. Under these conditions, however, glucose was still able to induce a small stimulation of the first phase of insulin secretion. These results demonstrate that polyphosphoinositide metabolism, Ca2+ mobilization and insulin release can all be dissociated in islet cells, and suggest that glucose and carbachol regulate these parameters by different mechanisms.