Effects of calcium manipulation and glucose stimulation on a histochemically detectable mobile calcium fraction in isolated rat pancreatic islets

Summary Pancreatic B-cell calcium as histochemically detectable with glyoxal bis (2-hydroxyanil)=GBHA was studied in isolated islets of fed rats. GBHA has previously been shown by us to detect an ionized or readily ionizable Ca-fraction (GBHA-Ca). In the presence of Ca⁺⁺ (2.5 mM), high glucose (15 mM) induced a rapid decrease (30%) of islet GBHA-Ca followed by a rise between 30 and 60 min to levels above the initial value. At low glucose (0 or 2.5 mM) GBHA-Ca showed a slight and gradual decline under these conditions. Omission of Ca⁺⁺ at low glucose rapidly decreased (30%) islet GBHA-Ca. This decrease was markedly inhibited by high glucose, although glucose did not induce insulin secretion under these conditions. Preincubation in the absence of Ca⁺⁺ (15 min) depleted islet GBHA-Ca, but partial restoration occurred during subsequent incubation with Ca⁺⁺ at low glucose. By contrast, high glucose completely restored GBHA-Ca within 5 min, followed by a decline and a subsequent rise. Reintroduction of Ca⁺⁺ also rapidly restored the glucose-induced insulin secretion. These results indicate that islet GBHA-Ca represents a mobile Ca-fraction which is dependent on extracellular Ca⁺⁺ and which responds very rapidly to glucose stimulation. It is suggested that changes of GBHA-Ca in the B-cells may reflect changes in the Ca pool involved in the insulin secretory mechanism.     

Unmasking of arachidonate-induced insulin release by removal of extracellular calcium. Arachidonic acid mobilizes cellular calcium in rat islets of Langerhans

Exogenous arachidonic acid does not stimulate insulin release in Ca++-containing medium, but a potent effect was unmasked by extracellular Ca++ depletion. This secretion met several criteria of exocytotic release. It did not require the oxygenation of arachidonate or its esterification into islet membranes, but was potentiated by the presence of 16.7 mM glucose such that 33 microM arachidonate could reverse the inhibitory effects of extracellular Ca++ removal on glucose-induced insulin secretion. Arachidonic acid alone stimulated a rise in intracellular Ca++ concentrations in dispersed islet cells (measured by the fura-2 technique) equal to that induced by 16.7 mM glucose in normal medium. Arachidonic acid may be a critical coupling signal in normal islets.     

Changes in histochemically detectable calcium and zinc during tolbutamide-induced degranulation and subsequent regranulation of rat pancreatic islets

Secretory granules of pancreatic B-cells contain high concentrations of zinc and calcium. The effect of gradual degranulation (induced by tolbutamide over a period of 3 days) and the subsequent regranulation (over a period of 4 days) on the histochemically detectable zinc (Zn) and calcium (Ca) content of B-cells was investigated. Zn was stained by dithizone, Ca by glyoxal-bis-(2-hydroxyanil), (GBHA), and B-granules by aldehyde fuchsin (AF). The staining intensities were determined cytophotometrically. A decrease of the granulation by 50% causes a comparable decrease of the Zn content. Almost complete degranulations, however, hardly further diminished the Zn content. Regranulation restores the Zn content parallel to the granulation. The presence of 40% of the initial Zn content in degranulated B-cells suggests the existence of a non-granular Zn fraction. The Zn content of B-cells may be partly involved in the storage of insulin as a Zn-insulin complex in the secretory vesicles. A-cells, however, contain even more (+ 30%) Zn than B-cells. Degranulation of B-cells is accompanied by a moderate decrease of the zinc content of the A-cells. The function of Zn in A-cells is completely unknown. Degranulation of B-cells causes the GBHA-Ca content to decrease to a very low level parallel to the AF-positive granulation. During regranulation the GBHA-Ca content restores parallel to the granulation and reaches after complete regranulation a slightly higher level than in untreated control rats. Almost complete disappearance of CBHA-Ca in the B-cells is accompanied by a decrease of the total islet calcium content of 33%. The results indicate that GBHA stains a Ca fraction which is mainly localized to the secretory granules. The stainability of granular Ca by GBHA is probably based on: a) the high Ca concentration in the granules, b) the presence of ionized Ca in the granules, due to the low intragranular pH, and c) on the properties of GBHA, which stains, under conditions used, only ionized (possibly also readily ionizable) Ca.     

Glucose raises cytosolic free calcium in the rat pancreatic islets

Cytosolic free calcium [( Ca2+]i) was measured using fura 2 in the whole pancreatic islets obtained from male Wistar rats by collagenase dispersion. The pattern of change of [Ca2+]i in response to high glucose, potassium (K+) depolarization or the removal of extracellular calcium was compared with the temporal profile of insulin secretion. Twenty-nine mM glucose produced a gradual increase in [Ca2+]i with approximately 1.5 min of latency period. It remained elevated until the end of observation period (25 min) during which period the first phase of insulin secretion ceased and the second phase of secretion gradually increased. Depolarizing concentration of KCl also produced an elevation of [Ca2+]i, without detectable latency period, which lasted at a sustained level for the entire observation period (30 min). KCl caused a rapid increase of insulin secretion followed by a gradually decreasing level of secretion. Elevated [Ca2+]i and insulin secretion in response to high glucose returned to the basal level when external calcium was removed by the addition of EGTA. We conclude that high glucose and K+ depolarization raise [Ca2+]i in the pancreatic islet. However, the elevation of [Ca2+]i and insulin secretion are not always correlated in the later period of stimulation.     

Effects of CCK-8 on the cytoplasmic free calcium concentration in isolated rat islet cells.

The C-terminal octapeptide of cholecystokinin (CCK-8) is known to stimulate insulin secretion. We examined its effects on the cytoplasmic free calcium concentration ([Ca2+]IC) in isolated rat pancreatic islet cells. At 8.3 mM glucose and 1.28 mM Ca2+, CCK-8 (100 nM) rapidly increased [Ca2+]IC to a short-lived peak, whereafter the [Ca2+]IC, within 1.5 minutes, fell to values below baseline. CCK-8 also rapidly increased the [Ca2+]IC at 3.3 mM glucose and in a calcium deficient medium. However, either at low glucose or in the absence of extracellular Ca2+, the post-peak [Ca2+]IC did not fall below baseline levels. The CCKA receptor antagonist, L-364,718 (20 nM), inhibited the effects of CCK-8 on [Ca2+]IC. The results suggest that CCK-8 in islet cells liberates calcium from intracellular stores by activating CCKA receptors.     

Successful cultivation of isolated islets of Langerhans without attachment: relationship between Glucose- and theophylline-induced insulin release and insulin content in rats islets after cultivation.

The effect of various inhibitors of insulin secretion such as mannoheptulose (20 mM), atropine (1 mM), diphenylhydantoin (20 microng/ml), high concentration of Mg++ (5.3 mM) in the presence of 20 mM glucose (control) on insulin content and secretion from collagenase-isolated rat pancreatic islets was studied in vitro by cultivation of islets up to 5 or 9 days in glass Petri dishes without attachment. In a following short-term incubation for 60 min the glucose-induced insulin release without and with theophylline (5 mM) was investigated. Islets cultivated at 5 mM glucose and at 20 mM glucose with the inhibitors mannoheptulose or atropine lost the responsiveness to glucose and theophylline whereas such islets cultivated at 20 mM glucose alone or with diphenylhydantoin (DPH) or 5.3 mg Mg++ showed a stimulation of insulin secretion by glucose and theophylline. Compared, however, with freshly isolated islets all cultivated islets were restricted in their maximal glucose response and this defect was not evoked alone by quantitative changes in islet insulin content. Nevertheless, culture conditions which facilitate a net increase of insulin (content and release) during cultivation influenced also positively the glucose-induced insulin release without and with 5 mM theophylline in the following short-term experiments.     

Glucose-dependent increase in mitochondrial membrane potential, but not cytoplasmic calcium, correlates with insulin secretion in single islet cells

We examined the effects of different physiological concentrations of glucose on cytoplasmic Ca(2+) handling and mitochondrial membrane potential (Deltapsi(m)) and insulin secretion in single mouse islet cells. The threshold for both glucose-induced changes in Ca(2+) and Deltapsi(m) ranged from 6 to 8 mM. Glucose step-jumps resulted in sinusoidal oscillations of cytoplasmic Ca(2+), whereas Deltapsi(m) reached sustained plateaus with oscillations interposed on the top of these plateaus. The amplitude of the Ca(2+) rise (height of the peak) did not vary with glucose concentration, suggesting a "digital" rather than "analog" character of this aspect of the oscillatory Ca(2+) response. The average glucose-dependent elevation of cytoplasmic Ca(2+) concentration during glucose stimulation reached saturation at 8 mM stimulatory glucose, whereas Deltapsi(m) showed a linear glucose dose-response relationship over the range of stimulatory glucose concentrations (4-16 mM). Glucose-dependent increases in insulin secretion correlated well with Deltapsi(m), but not with average Ca(2+) concentration. These data show that an ATP-dependent K(+) channel-independent pathway is operative at the single cell level and suggest mitochondrial metabolism may be a determining factor in explaining graded, glucose concentration-dependent increases in insulin secretion.     

Decreased insulin secretory response of pancreatic islets during culture in the presence of low glucose is associated with diminished 45Ca2+ net uptake, NADPH/NADP+ and GSH/GSSG ratios

In isolated rat pancreatic islets maintained at a physiologic glucose concentration (5.6 mM) the effect of glucose on parameters which are known to be involved in the insulin secretion coupling such as NADPH, reduced glutathione (GSH), 86Rb+ efflux, and 45Ca++ net uptake were investigated. The insulinotropic effect of 16.7 mM glucose was decreased with the period of culturing during the first 14 days being significant after 2 days though in control experiments both protein content and ATP levels per islet were not affected and insulin content was only slightly decreased. Both NADPH and GSH decreased with time of culture. 86Rb+ efflux which is decreased by enhancing the glucose concentration from 3 to 5.6 mM in freshly isolated islets was not affected by culturing whatsoever, even not after 14 days of culture when there was no longer any insulin responsiveness to glucose. The 45Ca++ net uptake was decreased during culturing. The data indicate (1) that the diminished glucose-stimulated release of insulin during culturing is not due to cell loss or simple energy disturbances, (2) that more likely it is the result of a diminished 45Ca++ net uptake as a consequence of the inability of islet cells to maintain proper NADPH and GSH levels, and (3) that potassium (86Rb+) efflux may not be related to changes of NADPH and GSH.     

Effects of lactate on pancreatic islets. Lactate efflux as a possible determinant of islet-cell depolarization by glucose.

The secretion of insulin from perifused rat pancreatic islets was stimulated by raising the glucose concentration from 5.6 to 20 mM or by exposure to tolbutamide. The addition of sodium lactate (40 mM) to islets perifused in the presence of glucose (5.6 mM) resulted in a small, transient, rise in the rate of secretion. The subsequent removal of lactate, but not glucose or tolbutamide, from the perifusate produced a dramatic potentiation of insulin release. The rate of efflux of 45Ca2+ was also increased when islets were exposed to a high concentration of glucose or lactate or to tolbutamide, and again subsequently upon withdrawal of lactate. Efflux of 86Rb+ was modestly inhibited upon addition of lactate and markedly enhanced by the subsequent withdrawal of lactate from islets. The output of [14C]lactate from islets incubated in the presence of [U-14C]glucose increased linearly with increasing concentrations of glucose (1-25 mM). It is proposed that the activation of islets by the addition or withdrawal of lactate is not due to increased oxidative flux, but occurs as a result of the electrogenic passage of lactate ions across the plasma membrane, resulting in islet-cell depolarization, Ca2+ entry and insulin secretion. The production of lactate via the glycolytic pathway, and the subsequent efflux of lactate from the islet cells with concomitant exchange of H+ for Na+, could be a major determinant of depolarization and hence insulin secretion, in response to glucose.     

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

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

Calcium and renin release: inhibition of low sodium-induced renin secretion by high calcium concentration in rat kidney perfusion

The effects of changes in calcium on renin secretion have been studied in the isolated perfused rat kidney. Perfusion with free calcium buffer significantly decreases renin secretion as compared with control experiments (Ca++: 2.5 mM/l). Other calcium concentrations (1.25 mM/l) and 5 mM/l) do not affect basal renin secretion. When the renin release is previously increased by low sodium concentration (Na+: 110 mM/l) however, perfusion with high calcium buffer (Ca++: 5 mM/l) significantly inhibits this stimulation.     

Enhancement of insulin release and islet cell calcium content by an acyl-amino-alkyl benzoic acid derivative, HB 699

HB 699, a hypoglycaemic agent which lacks the structural requirements regarded as essential for the insulin releasing action of the sulfonamide group, was studied in isolated rat islets and compared with tolbutamide. In the presence of 8.3 mM glucose for long exposure (24 h) both substances induced an increase of insulin release without altering the islet insulin content. After preloading of the islets to isotopic equilibrium with 45Ca++ (24 h), HB 699 and tolbutamide induced a significant increase in total exchangeable calcium content parallelled by an increase in insulin release. Both effects could be suppressed by verapamil, a blocker of voltage-sensitive Ca++ channels. These results indicate that HB 699, like tolbutamide, stimulates insulin release by increasing Ca++ uptake by the B cells.     

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.     

Effects of c-MYC activation on glucose stimulus-secretion coupling events in mouse pancreatic islets

Alteration of pancreatic beta-cell survival and Preproinsulin gene expression by prolonged hyperglycemia may result from increased c-MYC expression. However, it is unclear whether c-MYC effects on beta-cell function are compatible with its proposed role in glucotoxicity. We therefore tested the effects of short-term c-MYC activation on key beta-cell stimulus-secretion coupling events in islets isolated from mice expressing a tamoxifen-switchable form of c-MYC in beta-cells (MycER) and their wild-type littermates. Tamoxifen treatment of wild-type islets did not affect their cell survival, Preproinsulin gene expression, and glucose stimulus-secretion coupling. In contrast, tamoxifen-mediated c-MYC activation for 2-3 days triggered cell apoptosis and decreased Preproinsulin gene expression in MycER islets. These effects were accompanied by mitochondrial membrane hyperpolarization at all glucose concentrations, a higher resting intracellular calcium concentration ([Ca(2+)](i)), and lower glucose-induced [Ca(2+)](i) rise and islet insulin content, leading to a strong reduction of glucose-induced insulin secretion. Compared with these effects, 1-wk culture in 30 mmol/l glucose increased the islet sensitivity to glucose stimulation without reducing the maximal glucose effectiveness or the insulin content. In contrast, overnight exposure to a low H(2)O(2) concentration increased the islet resting [Ca(2+)](i) and reduced the amplitude of the maximal glucose response as in tamoxifen-treated MycER islets. In conclusion, c-MYC activation rapidly stimulates apoptosis, reduces Preproinsulin gene expression and insulin content, and triggers functional alterations of beta-cells that are better mimicked by overnight exposure to a low H(2)O(2) concentration than by prolonged culture in high glucose.     

Glucose regulates glucokinase activity in cultured islets from rat pancreas

In this study, we have used isolated pancreatic islets cultured for 7 days in 3 or 30 mM glucose to explore whether glucokinase is induced or activated by high glucose concentrations and has related enzyme activity to glucose-stimulated insulin release. Islets cultured in low glucose medium or low glucose medium plus 350 ng/ml insulin did not respond to high glucose stimulation. Islets cultured in medium containing high glucose concentrations showed a high rate of basal insulin secretion when perifused with 5 mM glucose, and the insulin release was greatly augmented in a biphasic secretion profile when the glucose concentration was raised to 16 mM. Islet glucokinase and hexokinase activities were determined by a sensitive and specific fluorometric method. Glucokinase activity was reduced to approximately 50% in islets cultured in low glucose medium with or without insulin present compared to results with fresh islets. However, islets cultured in 30 mM glucose showed that glucokinase activity was elevated to 236% compared to results with fresh islets. It is concluded that (a) glucose is the physiological regulator of glucokinase in the islet of Langerhans and that (b) the activity of glucokinase plays a crucial role in glucose-induced insulin secretion.     

Accumulation of cadmium in pancreatic beta cells is similar to that of calcium in being stimulated by both glucose and high potassium

The transport of Cd2+ and the effects of this ion on secretory activity and metabolism were investigated in beta cell-rich pancreatic islets isolated from obese-hyperglycemic mice. The endogenous cadmium content was 2.5 mumol/kg dry wt. After 60 min of incubation in a Ca2+-deficient medium containing 2.5 microM Cd2+ the islet cadmium content increased to 0.18 mmol/kg dry wt. This uptake was reduced by approx. 50% in the presence of 1.28 mM Ca2+. The incorporation of Cd2+ was stimulated either by raising the concentration of glucose to 20 mM or K+ to 30.9 mM. Whereas D-600 suppressed the stimulatory effect of glucose by 75%, it completely abolished that obtained with high K+. Only about 40% of the incorporated cadmium was mobilized during 60 min of incubation in a Cd2+-free medium containing 0.5 mM EGTA. It was possible to demonstrate a glucose-induced suppression of Cd2+ efflux into a Ca2+-deficient medium. Concentrations of Cd2+ up to 2.5 microM did not affect glucose oxidation, whereas, there was a progressive inhibition when the Cd2+ concentration was above 10 microM. Basal insulin release was stimulated by 5 microM Cd2+. At a concentration of 160 microM, Cd2+ did not affect basal insulin release but significantly inhibited the secretory response to glucose. It is concluded that the beta cell uptake of Cd2+ is facilitated by the activation of voltage-dependent Ca2+ channels. Apparently, the accumulation of Cd2+ mimics that of Ca2+ also involving a component of intracellular sequestration promoted by glucose.     

A new method for the simultaneous estimation of phosphate efflux and influx during glucose stimulation of isolated pancreatic islets

Isolated rat pancreatic islets were prelabeled with [33Pi] and then incubated with basal (2.8 mM) or stimulatory (16.7 mM) glucose in the presence of [32Pi]. Subsequent changes in islet [33P] and [32P] were utilized as respective indices of net efflux and influx. During the initial eight min, (the period usually spanning the first phase of stimulated insulin secretion) efflux was significantly greater with 16.7 than 2.8 mM glucose whereas the lesser amount of phosphate influx did not differ in the two systems. During the subsequent seven min (a time usually associated with the onset of the second phase of stimulated insulin secretion), efflux was dampened in the presence of 16.7 mM glucose and Pi influx significantly exceeded the 2.8 mM glucose values. Thus, acute stimulation with glucose effects an initial phosphate depletion in pancreatic islets as efflux exceeds influx and repletion occurs thereafter as efflux is attenuated and influx is enhanced. These oscillations in islet phosphate may contribute to the biphasic pattern of glucose-stimulated insulin release.     

Glucose-induced early changes in cytoplasmic calcium of pancreatic beta-cells studied with time-sharing dual-wavelength fluorometry

The cytoplasmic calcium concentration (Ca2+i) was measured in suspensions of fura-2-loaded mouse pancreatic beta-cells by recording the 340:380 nm fluorescence excitation ratio. Exposure to 20 mM glucose resulted in an initial reduction and later increase of Ca2+i irrespective of preincubation in medium containing 0.5 or 1.28 mM Ca2+ and 0 or 3 mM glucose. When elevating the Ca2+ concentration to 5 or 10 mM only 5 min before raising glucose to 20 mM, the sugar-induced reduction of Ca2+i became more pronounced like the subsequent increase. However, when the Ca2+ concentration was increased from 1.28 to 10 mM 2 min after stimulation with glucose, there was a sudden pronounced Ca2+i transient, which was followed by a decrease and a slower secondary rise. After preincubation in 20 mM glucose the glucose-induced initial reduction of Ca2+i was only seen in a Ca2+-deficient medium. Reintroduction of the sugar in the presence of extracellular Ca2+ resulted in an immediate rise of Ca2+i, the rapidity of which depended on the transmembrane Ca2+ gradient. The results emphasize the role of a saturable beta-cell pool of Ca2+ in glucose-induced reduction of Ca2+i and indicate that the first phase of insulin release depends on an influx of extracellular Ca2+.     

Glucagon-like peptide-1 induces a cAMP-dependent increase of [Na+]i associated with insulin secretion in pancreatic beta-cells

Glucagon-like peptide-1 (GLP-1) elevates the intracellular free calcium concentration ([Ca2+]i) and insulin secretion in a Na+-dependent manner. To investigate a possible role of Na ion in the action of GLP-1 on pancreatic islet cells, we measured the glucose-and GLP-1-induced intracellular Na+ concentration ([Na+]i), [Ca2+]i, and insulin secretion in hamster islet cells in various concentrations of Na+. The [Na+]i and [Ca2+]i were monitored in islet cells loaded with sodium-binding benzofuran isophthalate and fura 2, respectively. In the presence of 135 mM Na+ and 8 mM glucose, GLP-1 (10 nM) strongly increased the [Na+]i, [Ca2+]i, and insulin secretion. In the presence of 13.5 mM Na+, both glucose and GLP-1 increased neither the [Na+]i nor the [Ca2+]i. In a Na+-free medium, GLP-1 and glucose did not increase the [Na+]i. SQ-22536, an inhibitor of adenylate cyclase, and H-89, an inhibitor of PKA, incompletely inhibited the response. In the presence of both 8 mM glucose and H-89, 8-pCPT-2'-O-Me-cAMP, a PKA-independent cAMP analog, increased the insulin secretion and the [Na+]i. Therefore, we conclude that GLP-1 increases the cAMP level via activation of adenylate cyclase, which augments the membrane Na+ permeability through PKA-dependent and PKA-independent mechanisms, thereby increasing the [Ca2+]i and promoting insulin secretion from hamster islet cells.     

Long-term treatment with atrial natriuretic peptide inhibits ATP production and insulin secretion in rat pancreatic islets

Atrial natriuretic peptide (ANP) levels correlate with hyperglycemia in diabetes mellitus, but ANP effects on pancreatic islet β-cell insulin secretion are controversial. ANP was investigated for short- and long-term effects on insulin secretion and mechanisms regulating secretion in isolated rat pancreatic islets. A 3-h incubation with ANP did not affect basal or glucose-stimulated islet insulin secretion. However, 7-day culture of islets with 5.5 mM glucose and ANP (1 nM - 1 μM) markedly inhibited subsequent glucose (11 mM)-stimulated insulin secretion; total islet insulin content was not affected. Following ANP removal for 24 h, the islet insulin-secretory response to glucose was restored. The insulin-secretory response to other insulin secretagogues, including α-ketoisocaproic acid, forskolin, potassium chloride, and ionomycin were also markedly inhibited by chronic exposure to ANP. However, the combination of potassium chloride and α-ketoisocaproic acid was sufficient to overcome the inhibitory effects of ANP on insulin secretion. The glucose-stimulated increases in islet ATP levels and the ATP/ADP ratio were completely inhibited in ANP 7-day-treated islets vs. control; removal of ANP for 24 h partially restored the glucose response. ANP did not affect islet glycolysis. ANP significantly increased levels of islet activated hormone-sensitive lipase and the expression of uncoupling protein-2 and peroxisome proliferator-activated receptor-δ and -α. Although islet ANP-binding natriuretic peptide receptor-A levels were reduced to 60% of control after 7-day culture with ANP, the ANP-stimulated cGMP levels remained similar to control islet levels. Thus, long-term exposure to ANP inhibits glucose-stimulated insulin secretion and ATP generation in isolated islets.