The electrogenic sodium-potassium pump of mouse pancreatic B-cells

NKCC transport mediates the insulinotropic effects of taurine and other small neutral amino acids

AIMS

Despite its high concentration in pancreatic islets of Langerhans and broad range of antihyperglycemic effects, the route facilitating the import of dietary taurine into pancreatic β-cell and mechanisms underlying its insulinotropic activity are unclear. We therefore studied the impact of taurine on beta-cell function, alongside that of other small neutral amino acids, L-alanine and L-proline.

MAIN METHODS

Pharmacological profiling of insulin secretion was conducted using clonal BRIN BD11 β-cells, the impact of taurine on the metabolic fate of glucose carbons was assessed using NMR and the findings were verified by real-time imaging of Ca²⁺ dynamics in the cytosol of primary mouse and human islet beta-cells.

KEY FINDINGS

In our hands, taurine, alanine and proline induced secretory responses that were dependent on the plasma membrane depolarisation, import of Ca²⁺, homeostasis of K⁺ and Na⁺ as well as on cell glycolytic and oxidative metabolism. Taurine shifted the balance between the oxidation and anaplerosis towards the latter, in BRIN BD11 beta-cells. Furthermore, the amino acid signalling was significantly attenuated by inhibition of Na⁺-K⁺-Cl^- symporter (NKCC).

SIGNIFICANCE

These data suggest that taurine, like L-alanine and L-proline, acutely induces glucose-dependent insulin-secretory responses by modulating electrogenic Na⁺ transport, with potential role of intracellular K⁺ and Cl^- in the signal transduction. The acute action delineated would be consistent with antidiabetic potential of dietary taurine supplementation.

Gi/o protein-coupled receptor inhibition of beta-cell electrical excitability and insulin secretion depends on Na+/K+ ATPase activation

Gi/o-coupled somatostatin or α2-adrenergic receptor activation stimulated β-cell NKA activity, resulting in islet Ca2+ fluctuations. Furthermore, intra-islet paracrine activation of β-cell Gi/o-GPCRs and NKAs by δ-cell somatostatin secretion slowed Ca2+ oscillations, which decreased insulin secretion. β-cell membrane potential hyperpolarization resulting from Gi/o-GPCR activation was dependent on NKA phosphorylation by Src tyrosine kinases. Whereas, β-cell NKA function was inhibited by cAMP-dependent PKA activity. These data reveal that NKA-mediated β-cell membrane potential hyperpolarization is the primary and conserved mechanism for Gi/o-GPCR control of electrical excitability, Ca2+ handling, and insulin secretion.

Somatostatin secretion by Na+-dependent Ca2+-induced Ca2+ release in pancreatic delta-cells

Pancreatic islets are complex micro-organs consisting of at least three different cell types: glucagon-secreting α-, insulin-producing β- and somatostatin-releasing δ-cells¹. Somatostatin is a powerful paracrine inhibitor of insulin and glucagon secretion². In diabetes, increased somatostatinergic signalling leads to defective counter-regulatory glucagon secretion³. This increases the risk of severe hypoglycaemia, a dangerous complication of insulin therapy⁴. The regulation of somatostatin secretion involves both intrinsic and paracrine mechanisms⁵ but their relative contributions and whether they interact remains unclear. Here we show that dapagliflozin-sensitive glucose- and insulin-dependent sodium uptake stimulates somatostatin secretion by elevating the cytoplasmic Na⁺ concentration ([Na⁺]_i) and promoting intracellular Ca²⁺-induced Ca²⁺ release (CICR). This mechanism also becomes activated when [Na⁺]_i is elevated following the inhibition of the plasmalemmal Na⁺-K⁺ pump by reductions of the extracellular K⁺ concentration emulating those produced by exogenous insulin in vivo ⁶. Islets from some donors with type-2 diabetes hypersecrete somatostatin, leading to suppression of glucagon secretion that can be alleviated by a somatostatin receptor antagonist. Our data highlight the role of Na⁺ as an intracellular second messenger, illustrate the significance of the intraislet paracrine network and provide a mechanistic framework for pharmacological correction of the hormone secretion defects associated with diabetes that selectively target the δ-cells.

Pancreatic β-Cell Electrical Activity and Insulin Secretion: Of Mice and Men

The pancreatic β-cell plays a key role in glucose homeostasis by secreting insulin, the only hormone capable of lowering the blood glucose concentration. Impaired insulin secretion results in the chronic hyperglycemia that characterizes type 2 diabetes (T2DM), which currently afflicts >450 million people worldwide. The healthy β-cell acts as a glucose sensor matching its output to the circulating glucose concentration. It does so via metabolically induced changes in electrical activity, which culminate in an increase in the cytoplasmic Ca2+ concentration and initiation of Ca2+-dependent exocytosis of insulin-containing secretory granules. Here, we review recent advances in our understanding of the β-cell transcriptome, electrical activity, and insulin exocytosis. We highlight salient differences between mouse and human β-cells, provide models of how the different ion channels contribute to their electrical activity and insulin secretion, and conclude by discussing how these processes become perturbed in T2DM.

Shortcomings of current models of glucose-induced insulin secretion

Glucose-induced insulin secretion by pancreatic beta-cells is generally schematized by a 'consensus model' that involves the following sequence of events: acceleration of glucose metabolism, closure of ATP-sensitive potassium channels (K(ATP) channels) in the plasma membrane, depolarization, influx of Ca(2+) through voltage-dependent calcium channels and a rise in cytosolic-free Ca(2+) concentration that induces exocytosis of insulin-containing granules. This model adequately depicts the essential triggering pathway but is incomplete. In this article, we first make a case for a model of dual regulation in which a metabolic amplifying pathway is also activated by glucose and augments the secretory response to the triggering Ca(2+) signal under physiological conditions. We next discuss experimental evidence, largely but not exclusively obtained from beta-cells lacking K(ATP) channels, which indicates that these channels are not the only possible transducers of glucose effects on the triggering Ca(2+)signal. We finally address the identity of the widely neglected background inward current (Cl(-) efflux vs. Na(+) or Ca(2+) influx through voltage-independent channels) that is necessary to cause beta-cell depolarization when glucose closes K(ATP) channels. More attention should be paid to the possibility that some components of this background current are influenced by glucose metabolism and have their place in a model of glucose-induced insulin secretion.

Glucose controls cytosolic Ca2+ and insulin secretion in mouse islets lacking adenosine triphosphate-sensitive K+ channels owing to a knockout of the pore-forming subunit Kir6.2

Glucose-induced insulin secretion is classically attributed to the cooperation of an ATP-sensitive potassium (K ATP) channel-dependent Ca2+ influx with a subsequent increase of the cytosolic free Ca2+ concentration ([Ca2+]c) (triggering pathway) and a K ATP channel-independent augmentation of secretion without further increase of [Ca2+]c (amplifying pathway). Here, we characterized the effects of glucose in beta-cells lacking K ATP channels because of a knockout (KO) of the pore-forming subunit Kir6.2. Islets from 1-yr and 2-wk-old Kir6.2KO mice were used freshly after isolation and after 18 h culture to measure glucose effects on [Ca2+]c and insulin secretion. Kir6.2KO islets were insensitive to diazoxide and tolbutamide. In fresh adult Kir6.2KO islets, basal [Ca2+]c and insulin secretion were marginally elevated, and high glucose increased [Ca2+]c only transiently, so that the secretory response was minimal (10% of controls) despite a functioning amplifying pathway (evidenced in 30 mm KCl). Culture in 10 mm glucose increased basal secretion and considerably improved glucose-induced insulin secretion (200% of controls), unexpectedly because of an increase in [Ca2+]c with modulation of [Ca2+]c oscillations. Similar results were obtained in 2-wk-old Kir6.2KO islets. Under selected conditions, high glucose evoked biphasic increases in [Ca2+]c and insulin secretion, by inducing K ATP channel-independent depolarization and Ca2+ influx via voltage-dependent Ca2+ channels. In conclusion, Kir6.2KO beta-cells down-regulate insulin secretion by maintaining low [Ca2+]c, but culture reveals a glucose-responsive phenotype mainly by increasing [Ca2+]c. The results support models implicating a K ATP channel-independent amplifying pathway in glucose-induced insulin secretion, and show that K ATP channels are not the only possible transducers of metabolic effects on the triggering Ca2+ signal.

Activation of the Na+/K+-ATPase by insulin and glucose as a putative negative feedback mechanism in pancreatic beta-cells

Pancreatic beta-cells of sulfonylurea receptor type 1 knock-out (SUR1(-/-)) mice exhibit an oscillating membrane potential (V (m)) demonstrating that hyper-polarisation occurs despite the lack of K(ATP) channels. We hypothesize that glucose activates the Na(+)/K(+)-ATPase thus increasing a hyper-polarising current. Elevating glucose in SUR1(-/-) beta-cells resulted in a transient fall in V (m) and [Ca(2+)](c) independent of sarcoplasmic and endoplasmic reticulum Ca(2+)-activated ATPase (SERCA) activation. This was not affected by K(+) channel blockade but inhibited by ATP depletion and by ouabain. Increasing glucose also reduced [Na(+)](c), an effect reversed by ouabain. Exogenously applied insulin decreased [Na(+)](c) and hyper-polarised V (m). Inhibiting insulin signalling in SUR1(-/-) beta-cells blunted the glucose-induced decrease of [Ca(2+)](c). Tolbutamide (1 mmol/l) disclosed the SERCA-independent effect of glucose on [Ca(2+)](c) in wild-type beta-cells. The data show that in SUR1(-/-) beta-cells, glucose activates the Na(+)/K(+)-ATPase presumably by increasing [ATP](c). Insulin can also stimulate the pump and potentiate the effect of glucose. Pathways involving the pump may thus serve as potential drug targets in certain metabolic disorders.

Glucose stimulates Ca2+ influx and insulin secretion in 2-week-old beta-cells lacking ATP-sensitive K+ channels

In adult beta-cells glucose-induced insulin secretion involves two mechanisms (a) a K(ATP) channel-dependent Ca(2+) influx and rise of cytosolic [Ca(2+)](c) and (b) a K(ATP) channel-independent amplification of secretion without further increase of [Ca(2+)](c). Mice lacking the high affinity sulfonylurea receptor (Sur1KO), and thus K(ATP) channels, have been developed as a model of congenital hyperinsulinism. Here, we compared [Ca(2+)](c) and insulin secretion in overnight cultured islets from 2-week-old normal and Sur1KO mice. Control islets proved functionally mature: the magnitude and biphasic kinetics of [Ca(2+)](c) and insulin secretion changes induced by glucose, and operation of the amplifying pathway, were similar to adult islets. Sur1KO islets perifused with 1 mm glucose showed elevation of both basal [Ca(2+)](c) and insulin secretion. Stimulation with 15 mm glucose produced a transient drop of [Ca(2+)](c) followed by an overshoot and a sustained elevation, accompanied by a monophasic, 6-fold increase in insulin secretion. Glucose also increased insulin secretion when [Ca(2+)](c) was clamped by KCl. When Sur1KO islets were cultured in 5 instead of 10 mm glucose, [Ca(2+)](c) and insulin secretion were unexpectedly low in 1 mm glucose and increased following a biphasic time course upon stimulation by 15 mm glucose. This K(ATP) channel-independent first phase [Ca(2+)](c) rise was attributed to a Na(+)-, Cl(-)-, and Na(+)-pump-independent depolarization of beta-cells, leading to Ca(2+) influx through voltage-dependent calcium channels. Glucose indeed depolarized Sur1KO islets under these conditions. It is suggested that unidentified potassium channels are sensitive to glucose and subserve the acute and long-term metabolic control of [Ca(2+)](c) in beta-cells without functional K(ATP) channels.

Glucose triggers protein kinase A-dependent insulin secretion in mouse pancreatic islets through activation of the K+ATP channel-dependent pathway

OBJECTIVE

To assess the significance of protein kinase A (PKA) in glucose triggering of ATP-sensitive K(+) (K(+)(ATP)) channel-dependent insulin secretion and in glucose amplification of K(+)(ATP) channel-independent insulin secretion.

METHODS

Insulin release from cultured perifused mouse pancreatic islets was determined by radioimmunoassay.

RESULTS

In islets cultured at 5.5 mmol/l glucose, and then perifused in physiological Krebs-Ringer medium, the PKA inhibitors, H89 (10 micromol/l) and PKI 6-22 amide (30 micromol/l) did not inhibit glucose (16.7 mmol/l)-induced insulin secretion, but inhibited stimulation by the adenylyl cyclase activator, forskolin (10 micromol/l). In the presence of 60 mmol/l K(+) and 250 micromol/l diazoxide, which stimulates maximum Ca(2+) influx independently of K(+)(ATP) channels, H89 (10 micromol/l) inhibited Ca(2+)-evoked insulin secretion, but failed to prevent glucose amplification of K(+)(ATP) channel-independent insulin secretion. In the presence of 1 mmol/l ouabain and 250 micromol/l diazoxide, which cause modest Ca(2+) influx, glucose amplification of K(+)(ATP) channel-independent insulin secretion was observed without concomitant Ca(2+) stimulation of PKA activity. In islets cultured at 16.7 mmol/l glucose, glucose (16.7 mmol/l)-induced insulin secretion in physiological Krebs-Ringer medium was augmented and now inhibited by H89 (10 micromol/l), implicating that culture at 16.7 mmol/l glucose may increase Ca(2+)-sensitive adenylyl cyclase activity and hence PKA activity. In accordance, Ca(2+)-evoked insulin secretion at 60 mmol/l K(+) and 250 micromol/l diazoxide was improved, whereas glucose amplification of K(+)(ATP) channel-independent insulin secretion was unaffected.

CONCLUSIONS

Glucose may activate PKA through triggering of the K(+)(ATP) channel-dependent pathway. Glucose amplification of K(+)(ATP) channel-independent insulin secretion, on the other hand, occurs by PKA-independent mechanisms.

G protein-independent activation of an inward Na(+) current by muscarinic receptors in mouse pancreatic beta-cells

Depolarization of pancreatic beta-cells is critical for stimulation of insulin secretion by acetylcholine but remains unexplained. Using voltage-clamped beta-cells, we identified a small inward current produced by acetylcholine, which was suppressed by atropine or external Na(+) omission, but was not mimicked by nicotine, and was insensitive to nicotinic antagonists, tetrodotoxin, 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DiDS), thapsigargin pretreatment, and external Ca(2+) and K(+) removal. This suggests that muscarinic receptor stimulation activates voltage-insensitive Na(+) channels distinct from store-operated channels. No outward Na(+) current was produced by acetylcholine when the electrochemical Na(+) gradient was reversed, indicating that the channels are inward rectifiers. No outward K(+) current occurred either, and the reversal potential of the current activated by acetylcholine in the presence of Na(+) and K(+) was close to that expected for a Na(+)-selective membrane, suggesting that the channels opened by acetylcholine are specific for Na(+). Overnight pretreatment with pertussis toxin or the addition of guanosine 5'-O-(3-thiotriphosphate) (GTP-gamma-S) or guanosine-5'-O-(2-thiodiphosphate) (GDP-beta-S) instead of GTP to the pipette solution did not alter this current, excluding involvement of G proteins. Injection of a current of a similar amplitude to that induced by acetylcholine elicited electrical activity in beta-cells perifused with a subthreshold glucose concentration. These results demonstrate that muscarinic receptor activation in pancreatic beta-cells triggers, by a G protein-independent mechanism, a selective Na(+) current that explains the plasma membrane depolarization.

Ouabain suppresses glucose-induced mitochondrial ATP production and insulin release by generating reactive oxygen species in pancreatic islets

We examined the effects of reduced Na(+)/K(+)-ATPase activity on mitochondrial ATP production and insulin release from rat islets. Ouabain, an inhibitor of Na(+)/K(+)-ATPase, augmented 16.7 mmol/l glucose-induced insulin release in the early period but suppressed it after a delay of 20-30 min. Unexpectedly, the ATP content in an islet decreases in the presence of 16.7 mmol/l glucose when Na(+)/K(+)-ATPase activity is diminished by ouabain, despite the reduced consumption of ATP by the enzyme. Ouabain also suppressed the increment of ATP content produced by glucose even in Ca(2+)-depleted or Na(+)-depleted conditions. That mitochondrial membrane hyperpolarization and O(2) consumption in islets exposed to 16.7 mmol/l glucose were suppressed by ouabain indicates that the glycoside inhibits mitochondrial respiration but does not produce uncoupling. Ouabain induced mitochondrial reactive oxygen species (ROS) production that was blocked by myxothiazol, an inhibitor of site III of the mitochondrial respiratory chain. An antioxidant, alpha-tocopherol, also blocked ouabain-induced ROS production as well as the suppressive effect of ouabain on ATP production and insulin release. However, ouabain did not directly affect the mitochondrial ATP production originating from succinate and ADP. These results indicate that ouabain suppresses mitochondrial ATP production by generating ROS via transduction, independently of the intracellular cationic alternation that may account in part for the suppressive effect on insulin secretion.

Modulation of islet ATP content by inhibition or stimulation of the Na(+)/K(+) pump

High (30 mM) K(+), known to cause beta-cell membrane depolarisation, significantly decreased the islet total ATP content, supporting the view that beta-cell membrane depolarisation can activate the ATP-consuming Na(+)/K(+) pump. Ouabain (1 mM) did not change the islet ATP content after 5-15 min of incubation in the absence or presence of 3 mM glucose but reduced it after 30 min, and in the presence of 20 mM glucose, the reduction by ouabain occurred already after 15 min. Incubation of islets with ouabain for 60 min decreased the islet ATP content in the presence of 3, 10 or 20 mM glucose or 30 mM K(+). Also, the islet glucose oxidation rate was decreased by ouabain. When K(+) deficiency was used to inhibit the Na(+)/K(+) pump, no change in ATP content was observed irrespective of glucose concentration, although K(+) deficiency caused a slight inhibition of the glucose oxidation rate. Diazoxide reduced the islet glucose oxidation rate and increased the islet ATP content in the presence of 20 mM glucose. There may exist a feedback mechanism decreasing the flow of glucose metabolism in response to reduced ATP consumption by the Na(+)/K(+) pump.

Relationships between the Na(+)/K(+) pump and ATP and ADP content in mouse pancreatic islets: effects of meglitinide and glibenclamide

We have previously demonstrated that both D-glucose and glibenclamide stimulate the Na(+)/K(+) pump and suggested that this may be part of the membrane repolarization process, following the primary depolarization by these agents. The aim of this study was to investigate whether the non-sulphonylurea meglitinide (HB 699) exerts similar effects as glibenclamide or glucose on the islet Na(+)/K(+) pump and if effects of meglitinide or glibenclamide on this pump activity is paralleled by changes in islet ATP content and/or ATP/ADP ratio. The acyl-amino-alkyl benzoic acid derivative, meglitinide, stimulated the islet ouabain-sensitive portion of (86)Rb(+) influx (Na(+)/K(+) pump) by 53%, while the ouabain-resistant portion was inhibited by 70%. The stimulatory effect was not additive to that caused by D-glucose, suggesting that both agents may activate the Na(+)/K(+) pump via the same mechanism. Glibenclamide (10 microM) decreased the islet ATP and ADP content as well as the ATP/ADP ratio at 0 mM glucose. These effects were no longer observed at 10 mM glucose. Meglitinide (10 or 50 microM) lowered the islet ATP and ADP content at 0 mM glucose without affecting the ATP/ADP ratio. At 10 mM glucose, however, 10 microM of the drug reduced the islet ATP content but not the ATP/ADP ratio, while 50 microM of the drug, besides lowering the ATP content, also reduced the ATP/ADP ratio. Diazoxide (0.5 mM) increased the islet ATP content in the absence of glucose, an effect not seen in the presence of 10 mM glucose. The rate of glucose oxidation at 1, 10 or 20 mM of the sugar was not affected by glibenclamide (0.1 - 10 microM) and at 10 or 20 mM of the sugar not affected by meglitinide (1 - 100 microM). These results suggest that glibenclamide and meglitinide lower the islet ATP level by indirectly activating the beta-cell Na(+)/K(+) pump, which is a major consumer of ATP in the islets, while diazoxide increases the ATP level due to inhibition of the pump.

Metabolic and K(ATP) channel-independent actions of keto acid initiators of insulin secretion

Insulin-releasing effects of 2-ketobutyric acid (KB), 2-ketoisocaproic acid (KIC), 2-keto-3-methylvaleric acid (KMV), and 3-phenylpyruvic acid (PP) were examined by using clonal beta cells. Whereas KIC, KMV, and PP dose-dependently initiated insulin secretion and potentiated the effects of 4.2-16.7 mM glucose, equimolar KB was without effect. Transport inhibition by using 10 mM valine, isoleucine, 2-cyano-3 hydroxycinnamate or 2-cyano-4 hydroxycinnamate, or metabolic inhibition by 15 mM mannoheptulose, 5 mM sodium azide, 5 mM sodium cyanide, or removal of HCO3 reduced the secretory effects of KIC, KMV, and PP. Whereas K+ depletion reduced keto acid-induced insulin output, depolarizing concentrations of L-leucine and L-arginine potentiated the keto acid-induced effects. Under depolarizing conditions (25 mM KCI and 16.7 mM glucose), 10 mM KIC, KMV, or PP induced insulin secretion, suggesting K(ATP) channel-independent actions. Furthermore, the K(ATP) channel opener diazoxide reduced, but did not abolish, the keto acid-induced effects. However, voltage-dependent Ca2+ channel blockade with verapamil or removal of extracellular Ca2+ abolished keto acid-induced insulin release. Collectively, these results indicate that KIC, KMV, and PP initiate insulin secretion at least partially independently of K(ATP) channel activity, through both mitochondrial metabolism and regulation of Ca2+ influx.

Glucose decreases Na+,K+-ATPase activity in pancreatic beta-cells. An effect mediated via Ca2+-independent phospholipase A2 and protein kinase C-dependent phosphorylation of the alpha-subunit

In the pancreatic beta-cell, glucose-induced membrane depolarization promotes opening of voltage-gated L-type Ca2+ channels, an increase in cytoplasmic free Ca2+ concentration ([Ca2+]i), and exocytosis of insulin. Inhibition of Na+,K+-ATPase activity by ouabain leads to beta-cell membrane depolarization and Ca2+ influx. Because glucose-induced beta-cell membrane depolarization cannot be attributed solely to closure of ATP-regulated K+ channels, we investigated whether glucose regulates other transport proteins, such as the Na+,K+-ATPase. Glucose inhibited Na+,K+-ATPase activity in single pancreatic islets and intact beta-cells. This effect was reversible and required glucose metabolism. The inhibitory action of glucose was blocked by pretreatment of the islets with a selective inhibitor of a Ca2+-independent phospholipase A2. Arachidonic acid, the hydrolytic product of this phospholipase A2, also inhibited Na+, K+-ATPase activity. This effect, like that of glucose, was blocked by nordihydroguaiaretic acid, a selective inhibitor of the lipooxygenase metabolic pathway, but not by inhibitors of the cyclooxygenase or cytochrome P450-monooxygenase pathways. The lipooxygenase product 12(S)-HETE (12-S-hydroxyeicosatetranoic acid) inhibited Na+,K+-ATPase activity, and this effect, as well as that of glucose, was blocked by bisindolylmaleimide, a specific protein kinase C inhibitor. Moreover, glucose increased the state of alpha-subunit phosphorylation by a protein kinase C-dependent process. These results demonstrate that glucose inhibits Na+, K+-ATPase activity in beta-cells by activating a distinct intracellular signaling network. Inhibition of Na+,K+-ATPase activity may thus be part of the mechanisms whereby glucose promotes membrane depolarization, an increase in [Ca2+]i, and thereby insulin secretion in the pancreatic beta-cell.

Na+ cotransport by metabolizable and nonmetabolizable amino acids stimulates a glucose-regulated insulin-secretory response

The involvement of Na+ in insulin-secretory responses to metabolizable and nonmetabolizable amino acids known to be cotransported with Na+, were examined using islet-derived BRIN-BD11 cells. At stimulatory (16.7 mM) glucose, 10 mM of l-alanine, alpha-aminoisobutyric acid (AIB) or l-proline stimulated 1.3- to 10. 4-fold (p < 0.01) insulin-secretory responses. In each case, these effects were significantly greater than those observed at nonstimulatory (1.1 mM) glucose (p < 0.01). While, tetrodotoxin blockade of voltage-dependent Na+ channels exerted no significant effect on insulin release, Na/K pump blockade with ouabain significantly promoted the amino acid-induced effects (p < 0.05). Replacement of extracellular Na+ with equimolar N-methyl-d-glucamine+ and omission of extracellular K+ or Ca2+ were all effective in removing the actions of each amino acid, confirming the critical role of ionic fluxes in the secretory responses to these amino acids. Collectively these results demonstrate that metabolizable and nonmetabolizable amino acids can induce glucose-dependent insulin-secretory responses by modulating electrogenic Na+ transport.

A minimum of fuel is necessary for tolbutamide to mimic the effects of glucose on electrical activity in pancreatic beta-cells

Glucose stimulation of pancreatic beta-cells triggers electrical activity (slow waves of membrane potential with superimposed spikes) that is best monitored with intracellular microelectrodes. Closure of ATP-sensitive K+ channels underlies the depolarization to the threshold potential and participates in the increase in electrical activity produced by suprathreshold (>7 mM) concentrations of glucose, but it is still unclear whether this is the sole mechanism of control. This was investigated by testing whether blockade of ATP-sensitive K+ channels by low concentrations of tolbutamide is able to mimic the effects of glucose on mouse beta-cell electrical activity even in the absence of the sugar. The response to tolbutamide was influenced by the duration of the perifusion with the low glucose medium. Tolbutamide (25 microM) caused a rapid and sustained depolarization with continuous activity after 6 min of perifusion of the islet with 3 mM glucose, and a progressive depolarization with slow waves of the membrane potential after 20 min. In the absence of glucose, the beta-cell response to tolbutamide was a transient phase of depolarization with rare slow waves (6 min) or a silent, small, but sustained, depolarization (20 min). Readministration of 3 mM glucose was sufficient to restore slow waves, whereas an increase in the glucose concentration to 5 and 7 mM was followed by a lengthening of the slow waves and a shortening of the intervals. In contrast, induction of slow waves by tolbutamide proved very difficult in the absence of glucose, because the beta-cell membrane tended to depolarize from a silent level to the plateau level, at which electrical activity is continuous. Azide, a mitochondrial poison, abrogated the electrical activity induced by tolbutamide in the absence of glucose, which demonstrates the influence of the metabolism of endogenous fuels on the response to the sulfonylurea. The partial repolarization that azide also produced was reversed by increasing the concentration of tolbutamide, but reappearance of the spikes required the addition of glucose. It is concluded that inhibition of ATP-sensitive K+ channels is not the only mechanism by which glucose controls electrical activity in beta-cells.

A possible role of the ATP-sensitive potassium ion channel in determining the duration of spike-bursts in mouse pancreatic beta-cells

The pancreatic beta-cell displays an electrical activity consisting of spike bursts and silent phases at glucose concentrations of about 10 mM. The mechanism of initial depolarization induced by glucose is well defined. However, the mechanism inducing the silent phase has not been fully elucidated. In the present study, the possibility of involvement of ATP-sensitive K+ channels in repolarization was examined using the patch-clamp technique in the cell-attached recording configuration. Ouabain (0.1 mM), an inhibitor of Na+/K+-ATPase, caused a complete suppression of ATP-sensitive K+ channel activity followed by typical biphasic current deflections, which were due to action potentials. The channel activity was also inhibited by removal of K+ from a perifusion solution. Furthermore, the activity of ATP-sensitive K+ channels was markedly inhibited either by replacement of external NaCl with LiCl or by addition of amiloride (0.2 mM), a blocker of Na+/H+ antiport. Addition of L-type Ca2+ channel blockers such as Nifedipine for Mn2+ induced the complete suppression of K+ channel activity. These findings strongly suggest that a fall in ATP consumption results in sustained depolarization, and that the repolarizations interposed between spike-bursts under normal ionic conditions are due to the periodical fall of ATP concentration brought about by periodical acceleration of ATP consumption at Na+/K+-pumps. It is concluded that the elevation of intracellular Na+ concentration as a consequence of accelerated Na+/Ca2+-countertransport during the period of spike-burst enhances ATP consumption, leading to a fall in ATP concentration which is responsible for termination of spike-burst and initiation of repolarization.

Sulfonylurea binding to a low-affinity site inhibits the Na/K-ATPase and the KATP channel in insulin-secreting cells

We have used hamster insulinoma tumor (HIT) cells, an insulin-secreting tumor cell line, to investigate modulation of the Na/K-ATPase and of the ATP-sensitive K channel (K(ATP)) by the sulfonylurea glyburide. Membrane proteins from cells cultured in RPMI with 11 mM glucose have at least two glyburide receptor populations, as evidenced by high and low binding affinity constants, (K(d) = 0.96 and 91 nM, respectively). In these cells K(ATP) channel activity was blocked by low glyburide concentrations, IC(50) = 5.4 nM. At 12.5 nM glyburide the inhibition developed slowly, tau = 380 s, and caused reduction of channel activity by 75 percent. At higher concentrations, however, inhibition occurred at a fast rate, tau = 42 s at 100 nM, and was almost complete. Na/K-ATPase activity measured enzymatically and electrophysiologically was also suppressed by glyburide, but higher concentrations were needed, IC(50) = 20-40 nM. Inhibition occurred rapidly, tau = 30 s at 50 nM, when maximum, activity was reduced by 40 percent. By contrast, cells cultured in RPMI supplemented with 25 mM glucose exhibit a single receptor population binding glyburide with low affinity, K(d)= 68 nM. In these cells inhibition of the Na/K-ATPase by the sulfonylurea was similar to that observed in cells cultured in 11 mM glucose, but K(ATP) channel inhibition was markedly altered. Inhibition occurred only at high concentrations of glyburide and at a fast rate; maximum inhibition was observed at 100 nM. Based on these data, we propose that glyburide binding to the high affinity site affects primarily K(ATP) channel activity, while interaction with the low affinity site inhibits both Na/K-ATPase and K(ATP) channel activities. The latter observation suggests possible functional interactions between the Na/K-ATPase and the K(ATP) channel.

Glucose promotes turnover of Na+ in pancreatic beta-cells

Ouabain-induced changes of the free cytoplasmic Na+ concentration ([Na+]i) were monitored in aggregates of cells prepared from beta-cell-rich pancreatic mouse islets and the results were compared with the total islet content of sodium. The steady-state [Na+]i was lower in 20 mM glucose (11 mM) than in 3 mM glucose (14 mM). In the presence of 3 mM glucose the addition of 1 mM ouabain resulted in a rise in [Na+]i with an initial rate of 1.5 mM/min. However, the increase of total sodium corresponded to 2.8 mM/min, suggesting that rapid binding and/or sequestration of Na+ are prominent features for pancreatic beta-cells. Elevation of the glucose concentration to 20 mM increased the rate of ouabain-dependent rise of [Na+]i. The effect of glucose was mimicked by 1 mM tolbutamide or 100 microM carbachol and was counteracted by 100 nM of the alpha 2-adrenergic agonist clonidine. Glucose also accelerated the lowering of [Na+]i after withdrawal of ouabain. In promoting not only the entry but also the extrusion of Na+, glucose actually enhances the turnover of the ion in pancreatic beta-cells.

The diabetogenic agent alloxan increases K+ permeability by a mechanism involving activation of ATP-sensitive K(+)-channels in mouse pancreatic beta-cells

The effects of the diabetogenic agent, alloxan, on membrane potential, input resistance and electrical activity of normal mouse pancreatic beta-cells were studied. Tetraethylammonium (TEA), quinine and Glyburide were used to block K(+)-channels and to elucidate the mechanisms underlying alloxan's effects on beta-cell membrane potential. Exposure of the islet to alloxan (75-100 microM) in the presence of glucose (11 mM), produced a rapid (15 sec), transient inhibition of electrical activity, often accompanied by hyperpolarization of the membrane, and this was followed by recovery of the burst pattern. This early effect of alloxan was followed after approximately 15 min by a complete inhibition of electrical activity and hyperpolarization. The inhibition accompanied by hyperpolarization was associated with a decrease in input resistance, indicating increased K(+)-conductance. Both the transient and delayed effects of alloxan were blocked by glucose (33 mM), quinine and glyburide but not by other conditions which induce continuous electrical activity such as elevated external [K+] (10 mM), ouabain, K+ removal, or TEA (20 mM). The transient inhibition induced by alloxan may be due to a direct competition with glucose transport/metabolism since it did not occur when alpha-keto isocaproic acid (KIC) was used to induce electrical activity. The delayed inhibition may reflect indirect effects of accumulation of this agent or its metabolites within the cell. Since both effects of alloxan are blocked by glyburide they appear to involve activation of the ATP-sensitive K(+)-channel (K-ATP).

Sulfonylureas mimic glucose in stimulating the uptake of Na+ in pancreatic islets exposed to ouabain

The increase of sodium in response to ouabain inhibition of the Na+/K+ pump was measured in beta-cell-rich pancreatic islets from ob/ob mice using integrating flame photometry. D-Glucose promoted the uptake of sodium when added at a concentration of 6 mM or above. The hypoglycemic sulfonylurea compound, tolbutamide, mimicked the action of D-glucose in stimulating the sodium uptake at concentrations of 10 microM or above. There was no stimulation beyond that obtained with 20 mM glucose during exposure to 100 microM tolbutamide. Other test substances also affected sodium uptake in a way reflecting known effects on insulin release. Accordingly, the sodium uptake was stimulated with glibenclamide, glipizide, HB 699 (4-[2-(5-chloro-2-methoxybenzamido)ethyl]benzoic acid) and high K+. Sulphonamides (sulfamethazole, sulfadiazine and sulfadoxine) had practically no effect when added at a concentration of 1 mM. Sodium uptake in response to glucose and tolbutamide was antagonized by 400 microM diazoxide or 4 microM tetrodotoxin. It is concluded that both glucose and hypoglycemic sulfonylureas stimulate Na+ entry into the pancreatic beta-cells, a process presumably involving depolarization.

Two sites of glucose control of insulin release with distinct dependence on the energy state in pancreatic B-cells

The energy state of pancreatic B-cells may influence insulin release at several steps of stimulus-secretion coupling. By closing ATP-sensitive K+ channels (K(+)-ATP channels), a rise in the ATP/ADP ratio may regulate the membrane potential, and hence Ca2+ influx. It may also modulate the effectiveness of Ca2+ on its intracellular targets. To assess the existence of these two roles and determine their relative importance for insulin release, we tested the effects of azide, a mitochondrial poison, on mouse B-cell function under various conditions. During stimulation by glucose alone, when K(+)-ATP channels are controlled by cellular metabolism, azide caused parallel, concentration-dependent (0.5-5 mM), membrane repolarization, decrease in cytosolic Ca2+ concentration [Ca2+]i and inhibition of insulin release. When K(+)-ATP channels were closed pharmacologically (by tolbutamide in high glucose), azide did not repolarize the membrane or decrease [Ca2+]i, and was much less effective in inhibiting insulin release. A similar resistance to azide was observed when K(+)-ATP channels were opened by diazoxide, and high K+ was used to depolarize the membrane and raise [Ca2+]i. In contrast, azide similarly decreased ATP levels and increased ADP levels, thereby lowering the ATP/ADP ratio under all conditions. In conclusion, lowering the ATP/ADP ratio in B-cells can inhibit insulin release even when [Ca2+]i remains high. However, this distal step is much more resistant to a decrease in the energy state of B-cells than is the control of membrane potential by K(+)-ATP channels. Generation of the signal triggering insulin release, high [Ca2+]i, through metabolic control of membrane potential requires a higher global ATP/ADP ratio than does activation of the secretory process itself.

Tolbutamide-sensitivity of the adenosine 5'-triphosphate-dependent K+ channel in mouse pancreatic B-cells

The patch-clamp technique was used to examine the tolbutamide-sensitivity of the adenosine 5'-triphosphate (ATP)-dependent K+ channel in mouse pancreatic B-cells. When studied at 37 degrees C in cell-attached membrane patches, this channel had a single-channel conductance of 88 pS and was half-maximally inhibited by 2.2 mumol/l tolbutamide in the presence of 3 mmol/l D-glucose and 10 mumol/l nifedipine. The tolbutamide-induced decrease in the amplitude of the single-channel currents indicated that the membrane potential was sufficiently depolarized for initiation of insulin release by 30 but not by 10 mumol/l of tolbutamide. Using 300 mumol/l diazoxide to open the ATP-dependent K+ channels already closed by 3 mmol/l D-glucose alone, it was demonstrated that initiation of insulin release requires closure of more than 98% of all ATP-dependent K+ channels. In excised inside-out membrane patches, the K+ channel-blocking potency of tolbutamide was maximally enhanced by 0.3 mmol/l adenosine 5'-diphosphate (ADP) at the cytoplasmic side. This ADP effect required the presence of Mg2+. Inhibition of K+ channel activity by ATP, ADP (Mg2(+)-free) or their non-hydrolyzable analogues adenylyl-imidodiphosphate (AMP-PNP) and alpha, beta methylene adenosine 5'-diphosphate (AMP-CP) was not accompanied by enhancement of tolbutamide-sensitivity. The results suggest that cytosolic MgADP controls tolbutamide-sensitivity by interaction with a receptor site not identical with the site mediating channel closure and that this control plays a role in the intact B-cell.

Effect of extracellular sodium removal upon 86Rb outflow from pancreatic islet cells

The present study was undertaken to characterize the effect of extracellular Na+ removal on 86Rb outflow from perifused rat pancreatic islets. Complete Na+ omission inhibited 86Rb outflow whether the islets were perifused in the presence or in the absence of extracellular Ca2+. Ouabain (1 mM) did not reduce the inhibitory effect of Na+ deprivation, whilst diphenylhydantoin (72.9 microM) mimicked the Na+-removal-induced fall in 86Rb outflow. Glucose (16.7 mM) lost its capacity to inhibit 86Rb outflow when the perifusate was deprived of extracellular Na+. These results indicate that Na+ omission reproduces the inhibitory effect of glucose on 86Rb outflow. The reduction in 86Rb outflow recorded after Na+ deprivation could be mediated by an intracellular acidification and/or a decrease in the intracellular Na+ activity. It is tempting to speculate that the capacity of glucose to reduce the B-cell Na+ content may participate in the process by which the sugar decreases K+ permeability.

Glucose modulation of spike activity independently from changes in slow waves of membrane potential in mouse B-cells

In mouse B-cells glucose induces a typical electrical activity consisting of slow waves of the membrane potential with spikes superimposed on the plateau. As the concentration of glucose is raised the number of spikes per minute increases. However, this increase could simply be due to the concomitant lengthening of the slow waves. We thus investigated whether glucose can influence spike activity when no slow waves occur. Persistent depolarization to the plateau potential was achieved at 3 mM glucose by tolbutamide or at 10 mM glucose by low Ca2+, by arginine or by ouabain. Under all these conditions, raising the concentration of glucose increased the spike frequency without changing the plateau potential. Similar effects were produced by tolbutamide which does not affect B-cell metabolism but directly blocks K+-ATP channels. The spike frequency could also be increased by arginine, which, however, consistently depolarized the membrane. In conclusion, spike activity in B-cells can be influenced by glucose independently from changes in slow wave duration. This indicates that some K+-ATP channels, a target for both glucose and tolbutamide, are still open when the membrane is depolarized at the plateau, or that these two agents share another yet unidentified target involved in spike generation.

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.

Basic mechanisms for transmembrane ion fluxes. A review

The principles for transport of ions across cell membranes are briefly reviewed and some cell physiological applications of ion flux are discussed, including the regulation of electrical activity, intracellular pH and cell volume.

Cytosolic ratios of free [NADPH]/[NADP+] and [NADH]/[NAD+] in mouse pancreatic islets, and nutrient-induced insulin secretion

When the extracellular concentration of glucose was raised from 3 mM to 7 mM (the concentration interval in which beta-cell depolarization and the major decrease in K+ permeability occur), the cytosolic free [NADPH]/[NADP+] ratio in mouse pancreatic islets increased by 29.5%. When glucose was increased to 20 mM, a 117% increase was observed. Glucose had no effect on the cytosolic free [NADH]/[NAD+] ratio. Neither the cytosolic free [NADPH]/[NADP+] ratio nor the corresponding [NADH]/[NAD+] ratio was affected when the islets were incubated with 20 mM-fructose or with 3 mM-glucose + 20 mM-fructose, although the last-mentioned condition stimulated insulin release. The insulin secretagogue leucine (10 mM) stimulated insulin secretion, but lowered the cytosolic free [NADPH]/[NADP+] ratio; 10 mM-leucine + 10 mM-glutamine stimulated insulin release and significantly enhanced both the [NADPH]/[NADP+] ratio and the [NADH]/[NAD+] ratio. It is concluded that the cytosolic free [NADPH]/[NADP+] ratio may be involved in coupling beta-cell glucose metabolism to beta-cell depolarization and ensuing insulin secretion, but it may not be the sole or major coupling factor in nutrient-induced stimulation of insulin secretion.

Cyclic adenosine monophosphate differently affects the response of mouse pancreatic beta-cells to various amino acids

1. The membrane potential of mouse beta-cells was measured in parallel with 86Rb+ efflux and insulin release from mouse islets during stimulation by three types of amino acids and modulation of their effects by glucose and cyclic adenosine monophosphate (cyclic AMP) (forskolin being used to activate the adenylate cyclase). 2. In the absence of glucose, alanine and arginine accelerated 86Rb+ efflux, whereas leucine decreased it. They all depolarized the beta-cell membrane and slightly increased insulin release. Forskolin had little effect on 86Rb+ efflux, consistently potentiated insulin release but induced electrical activity only in the presence of leucine. 3. The effects of the three amino acids on 86Rb+ efflux and beta-cell membrane potential were not qualitatively altered by a non-stimulatory concentration of glucose (3 mM). However, the release of insulin induced by leucine alone or with forskolin was markedly amplified, in contrast to that of alanine or arginine, which was inhibited. 4. In the presence of a threshold concentration of glucose (7 mM), the three amino acids accelerated 86Rb+ efflux and depolarized the beta-cell membrane. With alanine and arginine, spike activity was transiently observed and coincided with a short-lived increase in insulin release. With leucine, slow waves with superimposed bursts of spikes occurred and were accompanied by a sustained release of insulin. Forskolin alone also triggered slow waves and bursts of spikes, and increased insulin release. Both effects were larger in the presence of arginine, but not in the presence of alanine. Forskolin considerably increased the electrical and secretory effects of leucine. 5. A higher concentration of glucose (10 mM) induced slow waves with bursts of spikes in all cells and stimulated insulin release. Alanine, arginine and leucine increased 86Rb+ efflux, electrical activity and insulin release. However, the changes produced by the three amino acids displayed different time course, amplitude and characteristics. Forskolin potentiated insulin release and electrical activity induced by glucose alone. These effects were not augmented by alanine, but markedly amplified by arginine or leucine. 6. Several conclusions can be drawn from this study. The three types of amino acids depolarize the beta-cell membrane by different mechanisms and produce distinct patterns of electrical activity. Slow waves with bursts of spikes occur only if a decrease in K+ permeability contributes to the depolarization.(ABSTRACT TRUNCATED AT 400 WORDS)

Glucose reduces both Rb+ influx and efflux in pancreatic islet cells

Microdissected, beta-cell-rich pancreatic islets from ob/ob mice were used in studies of 86Rb+ transport. D-Glucose (20 mM) induced a biphasic reduction in 86Rb+ efflux. The reduction stabilized within 10 min at 34% of the efflux rate at zero glucose. The initial 86Rb+ uptake (5 min) was dose-dependently reduced by ouabain with maximum inhibition at 1 mM. D-Glucose (20 mM) did not affect the ouabain-sensitive 86Rb+ influx but markedly reduced (48%) the ouabain-resistant isotope influx. The results suggest that D-glucose does not affect the Na+/K+ pump in pancreatic beta-cells and that the glucose-sensitive K+-transporting modalities (K+ channels) in the beta-cells can mediate both inward and outward K+ flux.

Contribution of electrogenic sodium-potassium ATPase to resting membrane potential of cultured rat skeletal myotubes

The contribution of electrogenic Na+ -K+ ATPase to resting membrane potential (Em) of mature and developing rat skeletal myotubes in culture was determined by examining effects of inhibition of this enzyme on Em. Ouabain, a specific Na+-K+ ATPase inhibitor, caused resting Em to decrease within 30 s by 5-8 mV and reach a minimum value of about -60 mV after 5 min. The decrease in Em was not accompanied by a decrease in input resistance for up to 15 min after application. Resting Em was found to be dependent on the temperature of the recording medium with maximum values of Em ranging from -85 to -90 mV at a temperature of 35-37 degrees C and minimum values about -60 mV at 10-15 degrees C. Ouabain (1 mM), added to cultures at low temperature (10-15 degrees C) did not further decrease Em but did prevent the increase in Em that occurs with increasing temperature up to 37 degrees C. Resting Em of cultured myotubes was reduced to about -60 mV by reducing the supply of ATP either with 2,4 dinitrophenol (DNP), which inhibits oxidative phosphorylation or with fluorodinitrobenzene (FDNB), which inhibits creatine phosphokinase. Neither of these compounds, when added to cultures in the presence of ouabain, reduced resting Em to a value lower than that obtained with ouabain alone.(ABSTRACT TRUNCATED AT 250 WORDS)

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+.

The dihydropyridine derivative, Bay K 8644, enhances insulin secretion by isolated pancreatic islets

The effects of the dihydropyridine derivative Bay K 8644 upon insulin secretion by perifused isolated mouse pancreatic islets were examined. At a non-stimulatory glucose concentration (5 mmol/l) Bay K 8644 (1 mumol/l) did not stimulate insulin release. However, the same drug concentration enhanced the insulin secretory responses to an intermediate (15 mmol/l) or high (30 mmol/l) glucose concentration by 80 or 90%, respectively. Bay K 8644 was half maximally effective at 0.1 mumol/l and maximally effective at 1 mumol/l. The results are compatible with the view that voltage-dependent calcium channels are essential for stimulus-secretion coupling in pancreatic B-cells.

Cavitation in the mouse preimplantation embryo: Na/K-ATPase and the origin of nascent blastocoele fluid

This study tested the proposition that Na/K-ATPase activity could be involved in the morphogenetic aspects of mouse blastocyst formation by facilitating the localization of certain organelles to apposed borders, the production of nascent blastocoele fluid, and cavitation. It was assumed that such Na/K-ATPase activity would be sensitive to varying concentrations of external K (Ko)--which would alter plasma membrane potentials--and to ouabain--which would directly alter Na/K-ATPase function. Morulae were cultured for 40 hr in varying concentrations of Ko and/or ouabain and were observed for their ability to form blastocoeles (cavitate) and to localize mitochondria to apposed cell borders. Cavitation was accelerated when Ko was decreased from the control value of 6.0 to 0.6 mM and was delayed when Ko was increased to 25 mM. With Ko at 6.0 mM, 10(-5) M ouabain accelerated cavitation while 10(-4) M ouabain delayed cavitation and reduced the total number of embryos that cavitated by the end of the 40-hr culture period. With Ko at 0.6 mM, 10(-5) M ouabain now delayed cavitation while 10(-4) M ouabain almost completely inhibited it. When Ko was increased to 25 mM, 10(-5) M ouabain again accelerated cavitation while 10(-4) M ouabain delayed-rather than inhibited--cavitation. Morphometric analyses at the electron microscopic level showed changes in the distances of mitochondria from apposed cell borders with conditions that accelerated or delayed cavitation and these changes differed for inside and outside cells of the morula. These observations are consistent with the proposition that Na/K-ATPase activity could be involved in the localization of organelles to apposed cell borders, the production of nascent blastocoele fluid, and in cavitation during mouse blastocyst development.

Effects of theophylline and dibutyryl cyclic adenosine monophosphate on the membrane potential of mouse pancreatic beta-cells

The effects of theophylline and dibutyryl cyclic AMP on the membrane potential of mouse beta-cells were studied with micro-electrodes. They were compared to their effects on insulin release by perifused mouse islets. In 3 mM-glucose, theophylline (10 mM) depolarized the beta-cell membrane and stimulated insulin release, but did not induce electrical activity. Dibutyryl cyclic AMP (1 mM) was without effect. In 7 mM-glucose, theophylline (0.5-2 mM) and dibutyryl cyclic AMP (1 mM) slightly depolarized the beta-cell membrane, induced electrical activity in otherwise silent cells and increased insulin release. A higher concentration of theophylline (10 mM) hyperpolarized the beta-cell membrane, did not induce electrical activity, but also stimulated insulin release. In 10 mM-glucose, the membrane potential of beta-cells exhibited repetitive slow waves with bursts of spikes on the plateau. Under steady state, these slow waves were differently affected by low or high concentrations of theophylline. At 0.5-2 mM, theophylline shortened the intervals, lengthened the slow waves and slightly increased their frequency. On the other hand, 10 mM-theophylline markedly decreased the duration of both intervals and slow waves, and increased their frequency. The effects of 1 mM-dibutyryl cyclic AMP were similar to those of 2 mM-theophylline. With 2-10 mM-theophylline, two other effects were also observed: a transient hyperpolarization with suppression of electrical activity immediately after addition of the methylxanthine and an increase in electrical activity upon its withdrawal. Theophylline and dibutyryl cyclic AMP markedly potentiated insulin release induced by 10 mM-glucose. The magnitude of these changes did not correlate well with the importance of the changes in electrical activity. However, with 2-10 mM-theophylline the increase in release was also preceded by an initial transient inhibition, whereas withdrawal of the methylxanthine was accompanied by a further increase. When Ca influx was inhibited by D600, the slow waves were suppressed, the membrane was depolarized to the plateau level and only few spikes were present. Although theophylline markedly increased insulin release under these conditions, it did not affect the membrane potential. Several conclusions can be drawn from this study. Insulin release and electrical activity in beta-cells can be dissociated when intracellular Ca is used to trigger exocytosis. High concentrations of theophylline produce effects unrelated to cyclic AMP.(ABSTRACT TRUNCATED AT 400 WORDS)

Forskolin suppresses the slow cyclic variations of glucose-induced electrical activity in pancreatic B cells

The membrane potential of mouse pancreatic B cells was recorded with microelectrodes. In certain cells, both the slow waves of depolarization and the intervals of repolarization triggered by glucose (10 or 15 mM) displayed regular oscillations in their duration, though the concentration of the sugar remained constant. When forskolin (0.2 microM), an activator of adenylate cyclase, was added to the medium, the electrical activity rapidly became very regular, with slow waves and intervals of constant duration. This effect was unrelated to the overall increase in activity also brought about by forskolin. The oscillations resumed in 75% of the cells after withdrawal of the drug. Under similar conditions, forskolin rapidly and reversibly raised the cAMP concentration in the islets. The data suggest that cAMP is an important modulator of the electrical activity triggered by glucose in insulin-secreting cells.

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.

Na+--K+ pump activity and the glucose-stimulated Ca2+-sensitive K+ permeability in the pancreatic B-cell

A rise in the extracellular concentration of glucose from an intermediate to a high value changes the burst pattern of electrical activity of the pancreatic B-cell into a continuous firing, and yet activates the B-cell Ca2+-sensitive K+ permeability. The hypothesis that glucose exerts such effects by inhibiting the Na+, K+-ATPase was investigated. Ouabain (1 mM) mimicked the effect of 16.7 mM glucose in stimulating 86Rb, 45Ca outflow and insulin release from perifused rat pancreatic islets first exposed to 8.3 mM glucose. The stimulation by ouabain of 86Rb outflow was reduced in the absence of extracellular Ca2+ and almost completely abolished in the presence of quinine, and inhibitor of the Ca2+-sensitive K+ permeability. In the presence of ouabain, a rise in the glucose concentration from 8.3 to 16.7 mM failed to stimulate 86Rb outflow. However, the rise in the glucose concentration failed to inhibit 86Rb influx in islet cells, while ouabain dramatically reduced 86Rb influx whether in the presence of 8.3 or 16.7 mM glucose. These findings do not suggest that inhibition of the B-cell Na+, K+-ATPase represents the mechanism by which glucose in high concentration stimulates 86Rb outflow and induces continuous electrical activity in the B-cell.