Mitochondrial glutamate acts as a messenger in glucose-induced insulin exocytosis

The hormone insulin is stored in secretory granules and released from the pancreatic beta-cells by exocytosis. In the consensus model of glucose-stimulated insulin secretion, ATP is generated by mitochondrial metabolism, promoting closure of ATP-sensitive potassium (KATP) channels, which depolarizes the plasma membrane. Subsequently, opening of voltage-sensitive Ca2+ channels increases the cytosolic Ca2+ concentration ([Ca2+]c) which constitutes the main trigger initiating insulin exocytosis. Nevertheless, the Ca2+ signal alone is not sufficient for sustained secretion. Furthermore, glucose elicits a secretory response under conditions of clamped, elevated [Ca2+]c. A mitochondrial messenger must therefore exist which is distinct from ATP. We have now identified this as glutamate. We show that glucose generates glutamate from beta-cell mitochondria. A membrane-permeant glutamate analogue sensitizes the glucose-evoked secretory response, acting downstream of mitochondrial metabolism. In permeabilized cells, under conditions of fixed [Ca2+]c, added glutamate directly stimulates insulin exocytosis, independently of mitochondrial function. Glutamate uptake by the secretory granules is likely to be involved, as inhibitors of vesicular glutamate transport suppress the glutamate-evoked exocytosis. These results demonstrate that glutamate acts as an intracellular messenger that couples glucose metabolism to insulin secretion.     

Modulation of ATP-sensitive K+ channels in skeletal muscle by intracellular protons

Since their discovery in cardiac muscle, ATP-sensitive K+(KATP) channels have been identified in pancreatic beta-cells, skeletal muscle, smooth muscle and central neurons. The activity of KATP channels is inhibited by the presence of cytosolic ATP. Their wide distribution indicates that they could have important physiological roles that may vary between tissues. In muscle cells the role of K+ channels is to control membrane excitability and the duration of the action potential. In anoxic cardiac ventricular muscle KATP channels are believed to be responsible for shortening the action potential, and it has been proposed that a fall in ATP concentration during metabolic exhaustion increases the activity of KATP channels in skeletal muscle, which may reduce excitability. But the intracellular concentration of ATP in muscle is buffered by creatine phosphate to 5-10 mM, and changes little, even during sustained activity. This concentration is much higher than the intracellular ATP concentration required to half block the KATP-channel current in either cardiac muscle (0.1 mM) or skeletal muscle (0.14 mM), indicating that the open-state probability of KATP channels is normally very low in intact muscle. So it is likely that some additional means of regulating the activity of KATP channels exists, such as the binding of nucleotides other than ATP. Here I present evidence that a decrease in intracellular pH (pHi) markedly reduces the inhibitory effect of ATP on these channels in excised patches from frog skeletal muscle. Because sustained muscular activity can decrease pHi by almost 1 unit in the range at which KATP channels are most sensitive to pHi, it is likely that the activity of these channels in skeletal muscle is regulated by intracellular protons under physiological conditions.     

Neuropeptide modulation of single calcium and potassium channels detected with a new patch clamp configuration

Calcium channel activity is crucial for secretion and synaptic transmission, but it has been difficult to study Ca2+ channel modulation because survival and regulation of some of these channels require cytoplasmic constituents that are lost with the formation of cell-free patches. Here we report a new patch clamp configuration in which activity and regulation of channels are maintained after removal from cells. A pipette containing the pore-forming agent nystatin is sealed onto a cell and withdrawn to form an enclosed vesicle. The resulting perforated vesicle, formed from pituitary tumour cells, contains Ca2+ and K+ channels. Ca2(+)-activated K+ channels in the vesicle are activated by cyclic AMP analogues, and by a neuropeptide (thyrotropin-releasing hormone) that stimulates phosphatidylinositol turnover and inositol trisphosphate-gated Ca2+ release from intracellular organelles. Thus, the perforated vesicle retains signal transduction systems necessary for ion channel modulation. Functional dihydropyridine-sensitive Ca2+ channels (L-type) are maintained in the vesicle, and their gating is inhibited by thyrotropin-releasing hormone. Hence, this new patch clamp configuration has allowed a direct detection of the single-channel basis of transmitter-induced inhibition of L-type Ca2+ channels. The modulation of Ca2(+)-channel gating may be an important mechanism for regulating hormone secretion from pituitary cells.     

Modulation of dihydropyridine-sensitive Ca2+ channels by glucose metabolism in mouse pancreatic beta-cells

Glucose stimulates insulin secretion from the pancreatic beta-cell by increasing the cytosolic calcium concentration. It is believed that this increment results mainly from Ca2+ influx through dihydropyridine-sensitive calcium channels because insulin secretion is abolished by dihydropyridine antagonists and is potentiated by dihydropyridine agonists. Glucose may influence Ca2+ influx through these channels in two ways: either by regulating the beta-cell membrane potential or by biochemical modulation of the channel itself. The former mechanism is well established. Glucose metabolism, by closing ATP-sensitive K+ channels, depolarizes the beta-cell membrane and initiates Ca2+-dependent electrical activity, with higher glucose concentrations further increasing Ca2+ influx by raising the frequency of action potentials. We show here that glucose metabolism also increases calcium influx directly, by modulating the activity of dihydropyridine-sensitive Ca2+ channels.     

Quantification of Ca2+-activated K+ channels under hormonal control in pig pancreas acinar cells

Ca2+- and voltage-activated K+ channels are found in many electrically excitable cells and have an important role in regulating electrical activity. Recently, the large K+ channel has been found in the baso-lateral plasma membranes of salivary gland acinar cells, where it may be important in the regulation of salt transport. Using patch-clamp methods to record single-channel currents from excised fragments of baso-lateral acinar cell membranes in combination with current recordings from isolated single acinar cells and two- and three-cell clusters, we have now for the first time characterized the K+ channels quantitatively. In pig pancreatic acini there are 25-60 K+ channels per cell with a maximal single channel conductance of about 200 pS. We have quantified the relationship between internal ionized Ca2+ concentration [( Ca2+]i) membrane potential and open-state probability (p) of the K+ channel. By comparing curves obtained from excised patches relating membrane potential to p, at different levels of [Ca2+]i, with similar curves obtained from intact cells, [Ca2+]i in resting acinar cells was found to be between 10(-8) and 10(-7) M. In microelectrode experiments acetylcholine (ACh), gastrin-cholecystokinin (CCK) as well as bombesin peptides evoked Ca2+-dependent opening of the K+ conductance pathway, resulting in membrane hyperpolarization. The large K+ channel, which is under strict dual control by internal Ca2+ and voltage, may provide a crucial link between hormone-evoked increase in internal Ca2+ concentration and the resulting NaCl-rich fluid secretion.     

Inositol trisphosphate-dependent periodic activation of a Ca(2+)-activated K+ conductance in glucose-stimulated pancreatic beta-cells.

Glucose-stimulated insulin secretion is associated with the appearance of electrical activity in the pancreatic beta-cell. At intermediate glucose concentrations, beta-cell electrical activity follows a characteristic pattern of slow oscillations in membrane potential on which bursts of action potentials are superimposed. The electrophysiological background of the bursting pattern remains unestablished. Activation of Ca(2+)-activated large-conductance K+ channels (KCa channel) has been implicated in this process but seems unlikely in view of recent evidence demonstrating that the beta-cell electrical activity is unaffected by the specific KCa channel blocker charybdotoxin. Another hypothesis postulates that the bursting arises as a consequence of two components of Ca(2+)-current inactivation. Here we show that activation of a novel Ca(2+)-dependent K+ current in glucose-stimulated beta-cells produces a transient membrane repolarization. This interrupts action potential firing so that action potentials appear in bursts. Spontaneous activity of this current was seen only rarely but could be induced by addition of compounds functionally related to hormones and neurotransmitters present in the intact pancreatic islet. K+ currents of the same type could be evoked by intracellular application of GTP, the effect of which was mediated by mobilization of Ca2+ from inositol 1,4,5-trisphosphate (InsP3)-sensitive intracellular Ca2+ stores. These observations suggest that oscillatory glucose-stimulated electrical activity, which is correlated with pulsatile release of insulin, results from the interaction between the beta-cell and intraislet hormones and neurotransmitters. Our data also provide evidence for a close interplay between ion channels in the plasma membrane and InsP3-induced mobilization of intracellular Ca2+ in an excitable cell.     

Acetylcholine activation of single muscarinic K+ channels in isolated pacemaker cells of the mammalian heart

Acetylcholine (ACh) released on vagal stimulation reduces the heart rate by increasing K+ conductance of pacemaker cells in the sinoatrial (S-A) node. Fluctuation analysis of ACh-activated currents in pacemaker tissue showed this to be due to opening of a separate class of K+ channels gated by muscarinic ACh receptors (m-AChRs). On the other hand, it has been suggested that m-AChRs may simply regulate the current flow through inward rectifying resting K+ channels (gk1). We report here the measurement of ACh-activated single channel K+ currents and of resting K+ channel currents in isolated cells of the atrioventricular (A-V) and S-A node of rabbit heart. The results show that the ACh-dependent K+ conductance increase in nodal cells is mediated by K+ channels which are different in their gating and conductance properties from the inward rectifying resting K+ channels in atrial and ventricular cells. The resting K+ channels in nodal cells are, however, similar to those activated by ACh.     

Detection of K+ and Cl-channels from calf cardiac sarcolemma in planar lipid bilayer membranes

The ionic currents underlying the cardiac action potential are believed to be much more complex than those in nerve. During the cardiac action potential, various membrane channels control the flow of K+, Na+, Ca2+ and Cl- across the sarcolemma of cardiac muscle cells. Thus, it has become increasingly clear that a detailed knowledge of the mechanisms that activate (or inactivate) heart channels is required to understand cardiac excitability. We report here the use of planar lipid bilayer techniques to detect and characterize K+ and Cl- channels in purified heart sarcolemma membrane vesicles. We have identified four different types of channel on the basis of their selectivity, conductance and gating kinetics. We present in some detail the properties of a K+ channel and a Cl- channel. We have tentatively identified the K+ channel with the ix type of current found in Purkinje, myocardial ventricular and atrial fibres. The chloride channel might be related to the transient chloride current found in Purkinje fibres.     

Combined effects of adrenaline and insulin on active electrogenic Na+-K+ transport in rat soleus muscle.

Both beta 2-adrenoreceptor stimulants (such as adrenaline and salbutamol) and insulin can increase active Na+-K+ transport and hyperpolarise skeletal cells. Thus, adrenaline and insulin, which are otherwise antagonistic regulators of several metabolic processes, have one action in common, namely, stimulation of active ion translocation. This is especially interesting as cyclic AMP stimulates Na+-K+ transport, whereas a lowering of the cytoplasmic concentration of cyclic AMP has been proposed as an early signal in the action of insulin. Here we report the results of experiments in which the active Na+-K+ transport and membrane potential (EM) of rat soleus muscles were studied during the action of supramaximal doses of insulin and beta 2-adrenoreceptor stimulants, alone and in combination. We conclude that the stimulant action of insulin on active electrogenic Na+-K+ transport is unlikely to be evoked by a lowering of the intracellular concentration of cyclic AMP.     

Novel mechanism of voltage-dependent gating in L-type calcium channels

Activation of voltage-dependent calcium channels by membrane depolarization triggers a variety of key cellular responses, such as contraction in heart and smooth muscle and exocytotic secretion in endocrine and nerve cells. Modulation of calcium channel gating is believed to be the mechanism by which several neurotransmitters, hormones and therapeutic agents mediate their effects on cell function. Here we describe a novel type of voltage-dependent equilibrium between different gating patterns of dihydropyridine-sensitive (L-type) cardiac Ca2+ channels. Strong depolarizations drive the channel from its normal gating pattern into a mode of gating characterized by long openings and high open probability. The rate constants for conversions between gating modes, estimated from single channel recordings, are much slower than normal channel opening and closing rates, but the equilibrium between modes is almost as steeply voltage-dependent as channel activation and deactivation at more negative potentials. This new mechanism of voltage-dependent gating can explain previous reports of activity-dependent Ca2+ channel potentiation in cardiac and other cells and forms a potent mechanism by which Ca2+ uptake into cells could be regulated.     

Voltage-dependent calcium and potassium channels in retinal glial cells

Glial cells, which outnumber neurones in the central nervous system, have traditionally been considered to be electrically inexcitable and to play only a passive role in the electrical activity of the brain. Recent reports have demonstrated, however, that certain glial cells, when maintained in primary culture, possess voltage-dependent ion channels. It remains to be demonstrated whether these channels are also present in glial cells in vivo. I show here that Müller cells, the principal glial cells of the vertebrate retina, can generate 'Ca2+ spikes' in freshly excised slices of retinal tissue. In addition, voltage-clamp studies of enzymatically dissociated Müller cells demonstrate the presence of four types of voltage-dependent ion channels: a Ca2+ channel, a Ca2+-activated K+ channel, a fast-inactivating (type A) K+ channel and an inward-rectifying K+ channel. Currents generated by these voltage-dependent channels may enhance the ability of Müller cells to regulate extracellular K+ levels in the retina and may be involved in the generation of the electroretinogram.     

Putative receptor for the cytoplasmic inactivation gate in the Shaker K+ channel

Inactivation of ion channels is important in the control of membrane excitability. For example, delayed-rectifier K+ channels, which regulate action potential repolarization, are inactivated only slowly, whereas A-type K+ channels, which affect action potential duration and firing frequency, have both fast and slow inactivation. Fast inactivation of Na+ and K+ channels may result from the blocking of the permeation pathway by a positively charged cytoplasmic gate such as the one encoded by the first 20 amino acids of the Shaker B (ShB) K+ channel. We report here that mutation of five highly conserved residues between the proposed membrane-spanning segments S4 and S5 (also termed H4) of ShB affects the stability of the inactivated state and alters channel conductance. One such mutation stabilizes the inactivated state of ShB as well as the inactivated state induced in the delayed-rectifier type K+ channel drk1 by the cytoplasmic application of the ShB N-terminal peptide. The S4-S5 loop, therefore, probably forms part of a receptor for the inactivation gate and lies near the channel's permeation pathway.     

Functional analysis of an archaebacterial voltage-dependent K+ channel

All living organisms use ion channels to regulate the transport of ions across cellular membranes. Certain ion channels are classed as voltage-dependent because they have a voltage-sensing structure that induces their pores to open in response to changes in the cell membrane voltage. Until recently, the voltage-dependent K+, Ca2+ and Na+ channels were regarded as a unique development of eukaryotic cells, adapted to accomplish specialized electrical signalling, as exemplified in neurons. Here we present the functional characterization of a voltage-dependent K+ (K(V)) channel from a hyperthermophilic archaebacterium from an oceanic thermal vent. This channel possesses all the functional attributes of classical neuronal K(V) channels. The conservation of function reflects structural conservation in the voltage sensor as revealed by specific, high-affinity interactions with tarantula venom toxins, which evolved to inhibit eukaryotic K(V) channels.     

Voltage and Ca2+-activated K+ channel in baso-lateral acinar cell membranes of mammalian salivary glands

Nervous or hormonal stimulation of many exocrine glands evokes release of cellular K+ (ref. 1), as originally demonstrated in mammalian salivary glands2,3, and is associated with a marked increase in membrane conductance1,4,5. We now demonstrate directly, by using the patch-clamp technique6, the existence of a K+ channel with a large conductance localized in the baso-lateral plasma membranes of mouse and rat salivary gland acinar cells. The K+ channel has a conductance of approximately 250 pS in the presence of high K+ solutions on both sides of the membrane. Although mammalian exocrine glands are believed not to possess voltage-activated channels1,7, the probability of opening the salivary gland K+ channel was increased by membrane depolarization. The frequency of channel opening, particularly at higher membrane potentials, was increased markedly by elevating the internal ionized Ca2+ concentration, as previously shown for high-conductance K+ channels from cells of neural origin8-10. The Ca2+ and voltage-activated K+ channel explains the marked cellular K+ release that is characteristically observed when salivary glands are stimulated to secrete.     

Endfeet of retinal glial cells have higher densities of ion channels that mediate K+ buffering

A major function of glial cells in the central nervous system is to buffer the extracellular potassium concentration, [K+]o. A local rise in [K+]o causes potassium ions to enter glial cells, which have membranes that are highly permeable to K+; potassium then leaves the glial cells at other locations where [K+]o has not risen. We report here the first study of the individual ion channels mediating potassium buffering by glial cells. The patch-clamp technique was employed to record single channel currents in Müller cells, the radial glia of the vertebrate retina. Those cells have 94% of their potassium conductance in an endfoot apposed to the vitreous humour, causing K+ released from active retinal neurones to be buffered preferentially to the vitreous. Recordings from patches of endfoot and cell body membrane show that a single type of inward-rectifying K+ channel mediates potassium buffering at both cell locations. The non-uniform density of K+ conductance is due to a non-uniform distribution of one type of K+ channel, rather than to the cell expressing high conductance channels at the endfoot and low conductance channels elsewhere on the cell.     

Ion conduction pore is conserved among potassium channels.

Potassium channels, a group of specialized membrane proteins, enable K+ ions to flow selectively across cell membranes. Transmembrane K+ currents underlie electrical signalling in neurons and other excitable cells. The atomic structure of a bacterial K+ channel pore has been solved by means of X-ray crystallography. To the extent that the prokaryotic pore is representative of other K+ channels, this landmark achievement has profound implications for our general understanding of K+ channels. But serious doubts have been raised concerning whether the prokaryotic K+ channel pore does actually represent those of eukaryotes. Here we have addressed this fundamental issue by substituting the prokaryotic pore into eukaryotic voltage-gated and inward-rectifier K+ channels. The resulting chimaeras retain the respective functional hallmarks of the eukaryotic channels, which indicates that the ion conduction pore is indeed conserved among K+ channels.     

Somatostatin stimulates Ca(2+)-activated K+ channels through protein dephosphorylation.

The neuropeptide somatostatin inhibits secretion from electrically excitable cells in the pituitary, pancreas, gut and brain. In mammalian pituitary tumour cells somatostatin inhibits secretion through two distinct pertussis toxin-sensitive mechanisms. One involves inhibition of adenylyl cyclase, the other an unidentified cyclic AMP-independent mechanism that reduces Ca2+ influx by increasing membrane conductance to potassium. Here we demonstrate that the predominant electrophysiological effect of somatostatin on metabolically intact pituitary tumour cells is a large, sustained increase in the activity of the large-conductance Ca(2+)- and voltage-activated K+ channels (BK). This action of somatostatin does not involve direct effects of Ca2+, cAMP or G proteins on the channels. Our results indicate instead that somatostatin stimulates BK channel activity through protein dephosphorylation.     

Single apamin-blocked Ca-activated K+ channels of small conductance in cultured rat skeletal muscle

Action potentials in many excitable cells are followed by a prolonged afterhyperpolarization that modulates repetitive firing. Although it is established that the afterhyperpolarization is produced by Ca-activated K+ currents, the basis of these currents is not known. The large conductance (250 pS) Ca-activated K+ channel (BK channel) is not a major contributor to the afterhyperpolarization in non-innervated skeletal muscle and some nerve cells, because apamin, a neurotoxic component of bee venom, abolishes the afterhyperpolarization but does not block BK channels, and 5 mM extracellular tetraethylammonium ion (TEA) blocks BK channels but does not reduce the afterhyperpolarization. We now report single-channel currents from small conductance (10-14 pS) Ca-activated K+ channels (SK channels) with the necessary properties to account for the afterhyperpolarization. SK channels are blocked by apamin but not by 5 mM external TEA (TEAo). They are also highly Ca-sensitive at the negative membrane potentials associated with the afterhyperpolarization.     

Mediation of cell volume regulation by Ca2+ influx through stretch-activated channels

Animal cells initially swell in hypotonic media by osmotic water equilibration, but their volume is subsequently regulated by a net loss of KCl and amino acids with concomitant loss of cell water. Mechanisms for regulating cell volume are important in allowing cells to adapt to variations in external tonicity and metabolic load. In red cells the KCl loss is mediated by electroneutral ion transport mechanisms. In contrast, conductive K+ and Cl- transport pathways are activated during regulatory volume decrease in several cell types including epithelia. The activation seems to be mediated by internal Ca2+, but the detailed mechanism is not known. In a leaky epithelium, the choroid plexus epithelium, we have found a cation-selective, Ca2+-permeable channel which opens with membrane stretch. The epithelium also contains a high density of the large (approximately 200 pS) type of Ca2+- voltage-activated K+ channel. Both channels are normally closed. I propose that in hypotonic media, the stretching of the cell membrane produced by the initial swelling causes influx of Ca2+ through the stretch-activated channels, which activates the neighbouring large K+ channels to produce increased K+ outflux with associated loss of cell water.     

Control of ion selectivity in potassium channels by electrostatic and dynamic properties of carbonyl ligands

Potassium channels are essential for maintaining a normal ionic balance across cell membranes. Central to this function is the ability of such channels to support transmembrane ion conduction at nearly diffusion-limited rates while discriminating for K+ over Na+ by more than a thousand-fold. This selectivity arises because the transfer of the K+ ion into the channel pore is energetically favoured, a feature commonly attributed to a structurally precise fit between the K+ ion and carbonyl groups lining the rigid and narrow pore. But proteins are relatively flexible structures that undergo rapid thermal atomic fluctuations larger than the small difference in ionic radius between K+ and Na+. Here we present molecular dynamics simulations for the potassium channel KcsA, which show that the carbonyl groups coordinating the ion in the narrow pore are indeed very dynamic ('liquid-like') and that their intrinsic electrostatic properties control ion selectivity. This finding highlights the importance of the classical concept of field strength. Selectivity for K+ is seen to emerge as a robust feature of a flexible fluctuating pore lined by carbonyl groups.