High external Ca2+ levels trigger membrane potential oscillations in mouse pancreatic beta-cells during blockade of K(ATP) channels.

Glucose depolarizes the pancreatic beta-cell and induces membrane potential oscillations, but the nature of the underlying oscillatory conductance remains unknown. We have now investigated the effects of the Ca2+ ionophore ionomycin and high external Ca2+ concentration ([Ca2+]o) on glucose-induced electrical activity and whole islet intracellular free Ca2+ concentration ([Ca2+]i), under conditions where the K(ATP) channel was blocked (100 microM tolbutamide or 4 microM glibenclamide). Raising [Ca2+]o to 10.2 or 12.8 mM, but not to 5.1 or 7.7 mM, turned continuous electrical activity into bursting activity. High [Ca2+]o (12.8 mM) regenerated a pattern of fast [Ca2+]i oscillations overshooting the levels recorded in tolbutamide. Ionomycin (10 microM) raised the [Ca2+]i and synergized with 5.1 mM Ca2+ to hyperpolarize the beta-cell membrane. The data indicate that a [Ca2+]i-sensitive and sulphonylurea-insensitive oscillatory conductance underlies the beta-cell bursting activity.     

ATP-sensitive inward rectifier and voltage- and calcium-activated K+ channels in cultured pancreatic islet cells

Summary K⁺ channels in cultured rat pancreatic islet cells have been studied using patch-clamp single-channel recording techniques in cell-attached and excised inside-out and outside-out membrane patches. Three different K⁺-selective channels have been found. Two inward rectifier K⁺ channels with slope conductances of about 4 and 17 pS recorded under quasi-physiological cation gradients (Na⁺ outside, K⁺ inside) and maximal conductances recorded in symmetrical K⁺-rich solutions of about 30 and 75 pS, respectively. A voltage- and calcium-activated K^– channel was recorded with a slope conductance of about 90 pS under the same conditions and a maximal conductance recorded in symmetrical K⁺-rich solutions of about 250 pS. Single-channel current recording in the cell-attached conformation revealed a continuous low level of activity in an apparently small number of both the inward rectifier K⁺ channels. But when membrane patches were excised from the intact cell a much larger number of inward rectifier K⁺ channels became transiently activated before showing an irreversible decline. In excised patches opening and closing of both the inward rectifier K⁺ channels were unaffected by voltage, internal Ca²⁺ or externally applied tetraethyl-ammonium (TEA) but the probability of opening of both inward rectifier K⁺ channels was reduced by internally applied 1–5mm adenosine-5-triphosphate (ATP). The large K⁺ channel was not operational in cell-attached membrane patches, but in excised patches it could be activated at negative membrane potentials by 10^–7 to 10^–6 m internal Ca²⁺ and blocked by 5–10mm external TEA.     

Role of voltage-dependent Na+ channels for rhythmic Ca2+ signalling in glucose-stimulated mouse pancreatic beta-cells.

The putative role of voltage-dependent Na+ channels for glucose induction of rhythmic Ca2+ signalling was studied in mouse pancreatic beta-cells with the use of the Ca2+ indicator fura-2. A rise in glucose from 3 to 11 mM resulted in slow oscillations of the cytoplasmic Ca2+ concentration ([Ca2+]i). These oscillations, as well as superimposed transients seen during forskolin-induced elevation of cAMP, remained unaffected in the presence of the Na+ channel blocker tetrodotoxin. During exposure to 1-10 microM veratridine, which facilitates the opening of voltage-dependent Na+ channels, the slow oscillations were replaced by repetitive and pronounced [Ca2+]i transients arising from the basal level. The effects of veratridine were reversed by tetrodotoxin. The veratridine-induced [Ca2+]i transients were critically dependent on the influx of Ca2+ and persisted after thapsigargin inhibition of the endoplasmic reticulum Ca2+-ATPase. Both tolbutamide and ketoisocaproate mimicked the action of glucose in promoting [Ca2+]i transients in the presence of veratridine. It is suggested that activation of voltage-dependent Na+ channels is a useful approach for amplifying Ca2+ signals for insulin release.     

Inhibition of Kv2.1 voltage-dependent K+ channels in pancreatic beta-cells enhances glucose-dependent insulin secretion

Voltage-dependent (Kv) outward K(+) currents repolarize beta-cell action potentials during a glucose stimulus to limit Ca(2+) entry and insulin secretion. Dominant-negative "knockout" of Kv2 family channels enhances glucose-stimulated insulin secretion. Here we show that a putative Kv2.1 antagonist (C-1) stimulates insulin secretion from MIN6 insulinoma cells in a glucose- and dose-dependent manner while blocking voltage-dependent outward K(+) currents. C-1-blocked recombinant Kv2.1-mediated currents more specifically than currents mediated by Kv1, -3, and -4 family channels (Kv1.4, 3.1, 4.2). Additionally, C-1 had little effect on currents recorded from MIN6 cells expressing a dominant-negative Kv2.1 alpha-subunit. The insulinotropic effect of acute Kv2.1 inhibition resulted from enhanced membrane depolarization and augmented intracellular Ca(2+) responses to glucose. Immunohistochemical staining of mouse pancreas sections showed that expression of Kv2.1 correlated highly with insulin-containing beta-cells, consistent with the ability of C-1 to block voltage-dependent outward K(+) currents in isolated mouse beta-cells. Antagonism of Kv2.1 in an ex vivo perfused mouse pancreas model enhanced first- and second-phase insulin secretion, whereas glucagon secretion was unaffected. The present study demonstrates that Kv2.1 is an important component of beta-cell stimulus-secretion coupling, and a compound that enhances, but does not initiate, beta-cell electrical activity by acting on Kv2.1 would be a useful antidiabetic agent.     

Properties of inwardly rectifying K+ channels in ventricular myocytes

Summary The voltage- and time-dependent properties of whole-cell, multi-channel (outside-out), and single channel inwardly-rectifying K⁺ currents were studied using adult and neonatal rat, and embryonic chick ventricular myocytes. Inward rectification of the current-voltage relationship was found in the whole-cell and single channel measurements. The steady-state single channel probability of opening decreased with hyperpolarization from E_K, as did the mean open time, thereby explaining the time-dependent inactivation of the macroscopic current. Myocytes dialysed with a Mg⁺⁺-free K⁺ solution (to remove the property of inward rectification) displayed a quasi-linear current-voltage relationship. The outward K⁺ currents flowing through the modified inward rectifier channels were able to be blocked by the local anesthetic and anti-arrhythmic agent, lidocaine.     

Properties of inwardly rectifying K+ channels in ventricular myocytes

The voltage- and time-dependent properties of whole-cell, multi-channel (outside-out), and single channel inwardly-rectifying K+ currents were studied using adult and neonatal rat, and embryonic chick ventricular myocytes. Inward rectification of the current-voltage relationship was found in the whole-cell and single channel measurements. The steady-state single channel probability of opening decreased with hyperpolarization from EK, as did the mean open time, thereby explaining the time-dependent inactivation of the macroscopic current. Myocytes dialysed with a Mg++-free K+ solution (to remove the property of inward rectification) displayed a quasi-linear current-voltage relationship. The outward K+ currents flowing through the modified inward rectifier channels were able to be blocked by the local anesthetic and anti-arrhythmic agent, lidocaine.     

Inhibition of ATP-regulated K+ channels precedes depolarization-induced increase in cytoplasmic free Ca2+ concentration in pancreatic beta-cells

The effects of glucose, diazoxide, K+, and tolbutamide on the activity of K+ channels, membrane potential, and cytoplasmic free Ca2+ concentration were investigated in beta-cells from the Uppsala colony of obese hyperglycemic mice. With [K+]e = [K+]i = 146 mM, it was demonstrated that the dominating channel at the resting potential is a K+ channel with a single-channel conductance of about 65 picosiemens and a reversal potential of about +70 mV (pipette potential). This channel is characterized by complex kinetics with openings grouped in bursts. The channel was completely inhibited by 20 mM glucose in intact cells or by intracellularly applied Mg-ATP (1 mM). The number of active channels was markedly reduced already by 5 mM glucose. However, the single channel current of the channels remaining active was unaffected, indicating no major depolarization. To evoke a substantial depolarization of the membrane and thereby action potentials, a total block in channel activity was necessary. This could be achieved either by increasing the concentration of glucose to 20 mM or by combining 5 mM glucose with 100 microM tolbutamide. In both cases, the effect was counteracted by the hyperglycemic sulfonamide diazoxide. The effects on single channel activity were paralleled by changes in membrane potential and cytoplasmic free Ca2+ concentration, also when the latter measurements were performed at room temperature. The transient increase in the number of active channels and the resulting hyperpolarization observed after raising the glucose concentration to 20 mM probably reflected a drop in cytoplasmic ATP concentration. It is suggested that ATP works as a key regulator of the beta-cell membrane potential and thereby the opening of voltage-activated Ca2+ channels.     

Contributions of HERG K+ current to repolarization of the human ventricular action potential

Action potential repolarization in the mammalian heart is governed by interactions of a number of time- and voltage-dependent channel-mediated currents, as well as contributions from the Na+/Ca2+ exchanger and the Na+/K+ pump. Recent work has shown that one of the K+ currents (HERG) which contributes to repolarization in mammalian ventricle is a locus at which a number of point mutations can have significant functional consequences. In addition, the remarkable sensitivity of this K+ channel isoform to inhibition by a variety of pharmacological agents and clinical drugs has resulted in HERG being a major focus for Safety Pharmacology requirements. For these reasons we and others have attempted to define the functional role for HERG-mediated K+ currents in repolarization of the action potential in the human ventricle. Here, we describe and evaluate changes in the formulations for two K+ currents, IK1 and HERG (or IK,r), within the framework of ten Tusscher model of the human ventricular action potential. In this computational study, new mathematical formulations for the two nonlinear K+ conductances, IK1 and HERG, have been developed based upon experimental data obtained from electrophysiological studies of excised human ventricular tissue and/or myocytes. The resulting mathematical model provides much improved simulations of the relative sizes and time courses of the K+ currents which modulate repolarization. Our new formulation represents an important first step in defining the mechanism(s) of repolarization of the membrane action potential in the human ventricle. Our overall goal is to understand the genesis of the T-wave of the human electrocardiogram.     

The effect of ATP-sensitive K+ channels on the electrical burst activity and insulin secretion in pancreatic beta-cells.

In recent years, the electrical burst activity of the insulin releasing pancreatic beta-cells has attracted many experimentalists and theoreticians, largely because of its functional importance, but also because of the nonlinear nature of the burst activity. The ATP-sensitive K+ channels are believed to play an important role in electrical activity and insulin release. In this paper, we show by computer simulation how ATP and antidiabetic drugs can lengthen the plateau fraction of bursting and how these chemicals can increase the intracellular Ca2+ level in the pancreatic beta-cell.     

Modulation of K+ conductance by intracellular pH in pancreatic beta-cells

Measurements of the effects of NH3/NH4+ on glucose-induced electrical activity in beta-cells from microdissected mouse islets of Langerhans and on intracellular pH in single collagenase-isolated islets pre-loaded with a fluorescent pH probe were performed and are reported here. Application of NH3/NH4+ (15 mM) in the presence of glucose (11 mM) promptly hyperpolarized the beta-cell membrane, reduced input resistance by 60% and blocked electrical activity. These changes were paralleled by an increase in islet fluorescence indicative of a cytosolic pH increase. Removal of NH4Cl initially stimulated electrical activity, which returned to resting level with a time constant of 51 s. Concomitant with the removal of NH4Cl there was a drop in pHi followed by a slow return to resting level with a time constant of 83 s. The results suggest that the [Ca2+]-dependent K+ channel in the beta-cell membrane is activated by a rise in cytosolic pH.     

Effects of Cl- deficiency on the membrane potential in mouse pancreatic beta-cells

The membrane potential of mouse pancreatic beta-cells was measured with microelectrodes. In the resting cell (3 mM D-glucose), the membrane potential was -63 +/- 3 mV (mean +/- S.E. for four experiments). In the presence of 3 mM D-glucose, total Cl- substitution by isethionate induced a depolarization by 3-4 mV, and readmission of Cl- induced a hyperpolarization by 3-5 mV. At 10 mM glucose, reduction of Cl- to 12 mM by substituting isethionate for Cl- reversibly shifted the repolarization potential by 6-9 mV in the positive direction and stimulated the burst activity during the initial 2-3 min by increasing the fraction of plateau phase. This was followed by a gradual inhibition of electrical activity, including decrease in fraction of plateau phase and slow wave amplitude. Total substitution of Cl- by isethionate or methyl sulphate reversibly shifted the repolarization potential by 3-4 mV in the positive direction and rapidly inhibited the electrical burst pattern without any initial stimulation. Glucose-induced (10 mM) insulin release (15 min) and 45Ca2+ uptake (3 min) were strongly inhibited by reducing the Cl- concentration to 10 mM (isethionate as substitute) and were further inhibited by further reduction of the Cl- concentration. It is suggested that beta-cells are equipped with on electrogenic Cl- flux, which can affect the burst pattern of electrical activity. The inhibitory effects of Cl- substitution may be explained by an influence of Cl- on the voltage-controlled Ca2+ channels.     

ATP-sensitive K+ channels in human isolated pancreatic B-cells

Glucose-stimulated insulin release from rodent pancreatic B-cells is thought to be initiated by the closing of ATP-sensitive K+ channels in the plasma membrane as a consequence of glucose metabolism. We have identified an ATP-sensitive K+ channel in membrane patches excised from human B-cells which is similar to that found in rodent B-cells in conductance, kinetics, ATP sensitivity and its inhibition by sulphonylureas. In man, the ATP-sensitive K+ channel may also have a central role in glucose-stimulated insulin secretion and may be (linked to) the receptor for the hypoglycemic sulphonylureas.     

Calcium-activated K+ channels of mouse beta-cells are controlled by both store and cytoplasmic Ca2+: experimental and theoretical studies

A novel calcium-dependent potassium current (K_slow) that slowly activates in response to a simulated islet burst was identified recently in mouse pancreatic β-cells (Göpel, S.O., T. Kanno, S. Barg, L. Eliasson, J. Galvanovskis, E. Renström, and P. Rorsman. 1999. J. Gen. Physiol. 114:759–769). K_slow activation may help terminate the cyclic bursts of Ca²⁺-dependent action potentials that drive Ca²⁺ influx and insulin secretion in β-cells. Here, we report that when [Ca²⁺]_i handling was disrupted by blocking Ca²⁺ uptake into the ER with two separate agents reported to block the sarco/endoplasmic calcium ATPase (SERCA), thapsigargin (1–5 μM) or insulin (200 nM), K_slow was transiently potentiated and then inhibited. K_slow amplitude could also be inhibited by increasing extracellular glucose concentration from 5 to 10 mM. The biphasic modulation of K_slow by SERCA blockers could not be explained by a minimal mathematical model in which [Ca²⁺]_i is divided between two compartments, the cytosol and the ER, and K_slow activation mirrors changes in cytosolic calcium induced by the burst protocol. However, the experimental findings were reproduced by a model in which K_slow activation is mediated by a localized pool of [Ca²⁺] in a subspace located between the ER and the plasma membrane. In this model, the subspace [Ca²⁺] follows changes in cytosolic [Ca²⁺] but with a gradient that reflects Ca²⁺ efflux from the ER. Slow modulation of this gradient as the ER empties and fills may enhance the role of K_slow and [Ca²⁺] handling in influencing β-cell electrical activity and insulin secretion.     

木黄酮对小鼠胰岛β细胞电压依赖性钙通道表达和电流的影响

目的:研究长期抑制酪氨酸激酶活性对胰岛β细胞中电压依赖性钙通道的影响,探讨酪氨酸激酶在胰岛β细胞中的作用.方法:原代培养小鼠胰岛和胰岛β细胞,经0.1 mmol/L酪氨酸激酶抑制剂木黄酮处理12 h后,运用全细胞电流记录的方法观察电压依赖性钙电流以及动作电位的改变,RT-PCR方法观察电压依赖性钙通道α1亚单位的表达改变.结果:木黄酮处理12 h后,小鼠胰岛β细胞的电压依赖性钙电流明显减小(13.83±1.515pA/pFvs 7.012±1.502 pA/pF,P＜0.01,n=6),动作电位幅度明显减弱(38.50±7.46 mV vs 15.95±4.39 mV,P＜0.01,n=6).木黄酮处理12 h后,小鼠胰岛中电压依赖性钙通道的α1亚单位的表达明显减少,降低为对照组的0.792±0.078(P＜0.01,n=5).结论:木黄酮处理可以抑制小鼠胰岛β细胞中电压依赖性钙通道的表达和电流,提示长期抑制酪氨酸激酶活性在胰岛β细胞功能损害中具有重要作用.     

Alkali pH directly activates ATP-sensitive K+ channels and inhibits insulin secretion in beta-cells

Glucose stimulation of pancreatic beta-cells is reported to lead to sustained alkalization, while extracellular application of weak bases is reported to inhibit electrical activity and decrease insulin secretion. We hypothesize that beta-cell K(ATP) channel activity is modulated by alkaline pH. Using the excised patch-clamp technique, we demonstrate a direct stimulatory action of alkali pH on recombinant SUR1/Kir6.2 channels due to increased open probability. Bath application of alkali pH similarly activates native islet beta-cell K(ATP) channels, leading to an inhibition of action potentials, and hyperpolarization of membrane potential. In situ pancreatic perfusion confirms that these cellular effects of alkali pH are observable at a functional level, resulting in decreases in both phase 1 and phase 2 glucose-stimulated insulin secretion. Our data are the first to report a stimulatory effect of a range of alkali pH on K(ATP) channel activity and link this to downstream effects on islet beta-cell function.     

Secretory phospholipase A2 is released from pancreatic beta-cells and stimulates insulin secretion via inhibition of ATP-dependent K+ channels

The release of sPLA(2) from single mouse pancreatic beta-cells was monitored using a fluorescent substrate of the enzyme incorporated in the outer leaflet of the plasma membrane. Stimulation of beta-cells with agents that increased cytosolic free Ca(2+) concentration ([Ca(2+)](i)) induced a rapid release of sPLA(2) to the extracellular medium. Exogenous sPLA(2) strongly stimulated insulin secretion in mouse pancreatic islets at both basal and elevated glucose concentrations. The stimulation of insulin secretion by sPLA(2) was mediated via inhibition of ATP-dependent K(+) channels and an increase in [Ca(2+)](i). Measurements of cell capacitance in single beta-cells revealed that sPLA(2) did not modify depolarisation-induced exocytosis. Our data suggest that a positive feedback regulation of insulin secretion by co-released sPLA(2) is operational in pancreatic beta-cells and point to this enzyme as an autocrine regulator of insulin secretion.     

Molecular determinants responsible for differential cellular distribution of G protein-gated inwardly rectifying K+ channels

Activation of the heteromeric G protein-gated inwardly rectifying K(+) channel (GIRK) GIRK1 and GIRK4 subunits gives rise to I(KACh), which controls excitability in atrial tissue. Although homomeric GIRK4 channels localize to the plasma membrane and display moderate function, GIRK1 channels fail to localize to the cell surface and do not exhibit significant function as homomers. Using oocytes to express GFP-tagged GIRK1 and GIRK4 and chimeras between these two proteins, we have identified two regions, one in the proximal C terminus and another in the distal N terminus that are critical for their subcellular localization. Replacement of both of these regions in GIRK1 with corresponding regions from GIRK4 was required for efficient expression of GIRK1 on the plasma membrane. Replacement of either region by itself was ineffective. The distal N terminus and proximal C terminus have been previously suggested to play important roles in ER-export and subunit co-assembly respectively in this family of channels. Our data indicate for the first time that both of these regions need to work in concert to mediate efficient targeting of these channels to the plasma membrane.     

Wheel-running exercise alters rat diaphragm action potentials and their regulation by K+ channels.

Endurance exercise modifies regulatory systems that control skeletal muscle Na+ and K+ fluxes, in particular Na+-K+-ATPase-mediated transport of these ions. Na+ and K+ ion channels also play important roles in the regulation of ionic movements, specifically mediating Na+ influx and K+ efflux that occur during contractions resulting from action potential depolarization and repolarization. Whether exercise alters skeletal muscle electrophysiological properties controlled by these ion channels is unclear. The present study tested the hypothesis that endurance exercise modifies diaphragm action potential properties. Exercised rats spent 8 wk with free access to running wheels, and they were compared with sedentary rats living in conventional rodent housing. Diaphragm muscle was subsequently removed under anesthesia and studied in vitro. Resting membrane potential was not affected by endurance exercise. Muscle from exercised rats had a slower rate of action potential repolarization than that of sedentary animals (P = 0.0098), whereas rate of depolarization was similar in the two groups. The K+ channel blocker 3,4-diaminopyridine slowed action potential repolarization and increased action potential area of both exercised and sedentary muscle. However, these effects were significantly smaller in diaphragm from exercised than sedentary rats. These data indicate that voluntary running slows diaphragm action potential repolarization, most likely by modulating K+ channel number or function.     

Hyposmotic challenge inhibits inward rectifying K+ channels in cerebral arterial smooth muscle cells

This study sought to define whether inward rectifying K(+) (K(IR)) channels were modulated by vasoactive stimuli known to depolarize and constrict intact cerebral arteries. Using pressure myography and patch-clamp electrophysiology, initial experiments revealed a Ba(2+)-sensitive K(IR) current in cerebral arterial smooth muscle cells that was active over a physiological range of membrane potentials and whose inhibition led to arterial depolarization and constriction. Real-time PCR, Western blot, and immunohistochemical analyses established the expression of both K(IR)2.1 and K(IR)2.2 in cerebral arterial smooth muscle cells. Vasoconstrictor agonists known to depolarize and constrict rat cerebral arteries, including uridine triphosphate, U46619, and 5-HT, had no discernable effect on whole cell K(IR) activity. Control experiments confirmed that vasoconstrictor agonists could inhibit the voltage-dependent delayed rectifier K(+) (K(DR)) current. In contrast to these observations, a hyposmotic challenge that activates mechanosensitive ion channels elicited a rapid and sustained inhibition of the K(IR) but not the K(DR) current. The hyposmotic-induced inhibition of K(IR) was 1) mimicked by phorbol-12-myristate-13-acetate, a PKC agonist; and 2) inhibited by calphostin C, a PKC inhibitor. These findings suggest that, by modulating PKC, mechanical stimuli can regulate K(IR) activity and consequently the electrical and mechanical state of intact cerebral arteries. We propose that the mechanoregulation of K(IR) channels plays a role in the development of myogenic tone.     

The effect of acetylcholine on Characeae K+ channels at rest and during action potential generation

The role of acetylcholine (ACh) as a signalling molecule in plants was investigated using a model system of Characeae cells. The effect of ACh on conductance of K⁺ channels in Nitella flexilis cells and on the action potential generation in Nitellopsis obtusa cells after H⁺-ATPase inhibition, where repolarization occurs after the opening of outward rectifying K⁺ channels, was investigated. Voltage-clamp method based on only one electrode impalement was used to evaluate the activity of separate potassium ion transport system at rest. We found that ACh at high concentrations (1 mM and 5 mM) activates K⁺ channels as the main membrane transport system at the resting state involved in electrogenesis of Characeaen membrane potential. We observed that ACh caused an increase in duration of AP repolarization of cells in K⁺ state when plasmalemma electrical characteristics are determined by large conductance K⁺ channels irrespective of whether AP were spontaneous or electrically evoked. These results indicate interference of ACh with electrical cellular signalling pathway in plants.