Dual effects of intracellular magnesium on muscarinic potassium channel current in single guinea-pig atrial cells

The Impact of Chronic Magnesium Deficiency on Excitable Tissues-Translational Aspects

Neuromuscular excitability is a vital body function, and Mg2+ is an essential regulatory cation for the function of excitable membranes. Loss of Mg2+ homeostasis disturbs fluxes of other cations across cell membranes, leading to pathophysiological electrogenesis, which can eventually cause vital threat to the patient. Chronic subclinical Mg2+ deficiency is an increasingly prevalent condition in the general population. It is associated with an elevated risk of cardiovascular, respiratory and neurological conditions and an increased mortality. Magnesium favours bronchodilation (by antagonizing Ca2+ channels on airway smooth muscle and inhibiting the release of endogenous bronchoconstrictors). Magnesium exerts antihypertensive effects by reducing peripheral vascular resistance (increasing endothelial NO and PgI2 release and inhibiting Ca2+ influx into vascular smooth muscle). Magnesium deficiency disturbs heart impulse generation and propagation by prolonging cell depolarization (due to Na+/K+ pump and Kir channel dysfunction) and dysregulating cardiac gap junctions, causing arrhythmias, while prolonged diastolic Ca2+ release (through leaky RyRs) disturbs cardiac excitation-contraction coupling, compromising diastolic relaxation and systolic contraction. In the brain, Mg2+ regulates the function of ion channels and neurotransmitters (blocks voltage-gated Ca2+ channel-mediated transmitter release, antagonizes NMDARs, activates GABAARs, suppresses nAChR ion current and modulates gap junction channels) and blocks ACh release at neuromuscular junctions. Magnesium exerts multiple therapeutic neuroactive effects (antiepileptic, antimigraine, analgesic, neuroprotective, antidepressant, anxiolytic, etc.). This review focuses on the effects of Mg2+ on excitable tissues in health and disease. As a natural membrane stabilizer, Mg2+ opposes the development of many conditions of hyperexcitability. Its beneficial recompensation and supplementation help treat hyperexcitability and should therefore be considered wherever needed.

Gender Differences With Ibutilide Effectiveness and Safety in Cardioversion of Atrial Fibrillation

INTRODUCTION

Few studies have examined the use of ibutilide in noncardiac surgical populations. Our study considered the effectiveness and safety of ibutilide in cardioversion of atrial fibrillation (AF) in medical and surgical intensive care patients.

METHODS

A retrospective chart review was performed for patients with a confirmed diagnosis of AF who were hemodynamically stable and received ibutilide after the initial diagnosis. Patients were administered 1 mg of ibutilide fumarate intravenous for 10 min with a second dose administered if AF persisted after 30 min. Patients were pretreated with intravenous magnesium sulfate if their blood magnesium level was <2 mg/dL.

RESULTS

Fifty seven total female patients and 99 male patients received ibutilide. Females had an 88% conversion rate to normal sinus rhythm (NSR) compared to 68% in males (P = 0.008). A 70% successful return to NSR was observed in patients from all groups pretreated with magnesium sulfate (P = 0.045). One year after discharge, 74% of the patients stayed in the NSR.

CONCLUSIONS

Within our population, pretreatment with magnesium sulfate followed by ibutilide was associated with increased conversion to NSR. Additionally, we noted that females had a higher conversion rate to NSR compared to males, regardless of whether they were pretreated with magnesium sulfate.

Ion Channels as Reporters of Membrane Receptor Function: Automated Analysis in Xenopus Oocytes

G-protein-coupled receptors (GPCR) are the most widely used system of communication used by cells. They sense external signals and translate them into intracellular signals. The information is carried mechanically across the cell membrane, without perturbing its integrity. Agonist binding on the extracellular side causes a change in receptor conformation which propagates to the intracellular side and causes release of activated G-proteins, the first messengers of a variety of signaling cascades.Permitting access to powerful electrophysiological techniques, ion channels can be employed to monitor precisely the most proximal steps of GPCR signaling, receptor conformational changes, and G-protein release. The former is achieved by physical attachment of a potassium channel to the GPCR to create an Ion-Channel Coupled Receptor (ICCR). The latter is based on the use of G-protein-regulated potassium channels (GIRK). We describe here how these two systems may be used in the Xenopus oocyte heterologous system with a robotic system for increased throughput.

Transglutaminase 2: a multi-functional protein in multiple subcellular compartments

Transglutaminase 2 (TG2) is a multifunctional protein that can function as a transglutaminase, G protein, kinase, protein disulfide isomerase, and as an adaptor protein. These multiple biochemical activities of TG2 account for, at least in part, its involvement in a wide variety of cellular processes encompassing differentiation, cell death, inflammation, cell migration, and wound healing. The individual biochemical activities of TG2 are regulated by several cellular factors, including calcium, nucleotides, and redox potential, which vary depending on its subcellular location. Thus, the microenvironments of the subcellular compartments to which TG2 localizes, such as the cytosol, plasma membrane, nucleus, mitochondria, or extracellular space, are important determinants to switch on or off various TG2 biochemical activities. Furthermore, TG2 interacts with a distinct subset of proteins and/or substrates depending on its subcellular location. In this review, the biological functions and molecular interactions of TG2 will be discussed in the context of the unique environments of the subcellular compartments to which TG2 localizes.

New insight into the functioning of nitric oxide-receptive guanylyl cyclase: physiological and pharmacological implications

The cellular counterpart of the "soluble" guanylyl cyclase found in tissue homogenates over 30 years ago is now recognized as the physiological receptor for nitric oxide (NO). The ligand-binding site is a prosthetic haem group that, when occupied by NO, induces a conformational change in the protein that propagates to the catalytic site, triggering conversion of GTP into cGMP. This review focuses on recent research that takes this basic information forward to the beginnings of a quantitative depiction of NO signal transduction, analogous to that achieved for other major transmitters. At its foundation is an explicit enzyme-linked receptor mechanism for NO-activated guanylyl cyclase that replicates all its main properties. In cells, NO signal transduction is subject to additional, activity-dependent modifications, notably through receptor desensitization and changes in the activity of cGMP-hydrolyzing phosphodiesterases. The measurement of these parameters under varying conditions in rat platelets has made it possible to formulate a cellular model of NO-cGMP signaling. The model helps explain cellular responses to NO and their modification by therapeutic agents acting on the guanylyl cyclase or phosphodiesterase limbs of the pathway.

Mechanisms of activity-dependent plasticity in cellular nitric oxide-cGMP signaling

Cellular responsiveness to nitric oxide (NO) is shaped by past history of NO exposure. The mechanisms behind this plasticity were explored using rat platelets in vitro, specifically to determine the relative contributions made by desensitization of NO receptors, which couple to cGMP formation, and by phosphodiesterase-5 (PDE5), which is activated by cGMP and also hydrolyzes it. Repeated delivery of brief NO pulses (50 nm peak) at 1-min intervals resulted in a progressive loss of the associated cGMP responses, which was the combined consequence of receptor desensitization and PDE5 activation, with the former dominating. Delivery of pulses of differing amplitude showed that NO stimulated and desensitized receptors with similar potency (EC₅₀ = 10–20 nm). PDE5 activation was highly sensitive to NO, with a single pulse peaking at 2 nm being sufficient to evoke a 50% loss of response to a subsequent near-maximal NO pulse. However, the activated state of the PDE subsided quickly after removal of NO, the half-time for recovery being 25 s. In contrast, receptor desensitization reverted much more slowly, the half-time being 16 min. Accordingly, with long (20-min) exposures, NO concentrations as low as 600 pm provoked significant desensitization. The results indicate that PDE5 activation and receptor desensitization subserve distinct short term and longer term roles as mediators of plasticity in NO-cGMP signaling. A kinetic model explicitly describing the complex interplay between NO concentration, cGMP synthesis, PDE5 activation, and the resulting cGMP accumulation successfully simulated the present and previous data.

An enzyme-linked receptor mechanism for nitric oxide-activated guanylyl cyclase

Nitric oxide (NO) exerts physiological effects by activating specialized receptors that are coupled to guanylyl cyclase activity, resulting in cGMP synthesis from GTP. Despite its widespread importance as a signal transduction pathway, the way it operates is still understood only in descriptive terms. The present work aimed to elucidate a formal mechanism for NO receptor activation and its modulation by GTP, ATP, and allosteric agents, such as YC-1 and BAY 41-2272. The model comprised a module in which NO, the nucleotides, and allosteric agents bind and the protein undergoes a conformational change, dovetailing with a catalytic module where GTP is converted to cGMP and pyrophosphate. Experiments on NO-activated guanylyl cyclase purified from bovine lung allowed values for all of the binding and isomerization constants to be derived. The catalytic module was a modified version of one describing the kinetics of adenylyl cyclase. The resulting enzyme-linked receptor mechanism faithfully reproduces all of the main functional properties of NO-activated guanylyl cyclase reported to date and provides a thermodynamically sound interpretation of those properties. With appropriate modification, it also replicates activation by carbon monoxide and the remarkable enhancement of that activity brought about by the allosteric agents. In addition, the mechanism enhances understanding of the behavior of the receptor in a cellular setting.

Regulation of cation channels in cardiac and smooth muscle cells by intracellular magnesium

Magnesium regulates various ion channels in many tissues, including those of the cardiovascular system. General mechanisms by which intracellular Mg(2+) (Mg(i)(2+)) regulates channels are presented. These involve either a direct interaction with the channel, or an indirect modification of channel function via other proteins, such as enzymes or G proteins, or via membrane surface charges and phospholipids. To provide an insight into the role of Mg(i)(2+) in the cardiovascular system, effects of Mg(i)(2+) on major channels in cardiac and smooth muscle cells and the underlying mechanisms are then reviewed. Although Mg(i)(2+) concentrations are known to be stable, conditions under which they may change exist, such as following stimulation of beta-adrenergic receptors and of insulin receptors, or during pathophysiological conditions such as ischemia, heart failure or hypertension. Modifications of cardiovascular electrical or mechanical function, possibly resulting in arrhythmias or hypertension, may result from such changes of Mg(i)(2+) and their effects on cation channels.

Cardiovascular actions of magnesium

Intracellular magnesium is an important modulator of calcium and potassium channels in cardiac myocytes. Hypomagnesemia is common in hospitalized patients and may contribute significantly to cardiac morbidity and mortality, particularly in states associated with myocardial ischemia. Therefore, it is important to maintain the plasma magnesium concentration within the normal range in asymptomatic patients and in patients with cardiac disease as prophylaxis against the occurrence of significant arrhythmias.

Permeation properties of inward-rectifier potassium channels and their molecular determinants

The structural domains contributing to ion permeation and selectivity in K channels were examined in inward-rectifier K(+) channels ROMK2 (Kir1.1b), IRK1 (Kir2.1), and their chimeras using heterologous expression in Xenopus oocytes. Patch-clamp recordings of single channels were obtained in the cell-attached mode with different permeant cations in the pipette. For inward K(+) conduction, replacing the extracellular loop of ROMK2 with that of IRK1 increased single-channel conductance by 25 pS (from 39 to 63 pS), whereas replacing the COOH terminus of ROMK2 with that of IRK1 decreased conductance by 16 pS (from 39 to 22 pS). These effects were additive and independent of the origin of the NH(2) terminus or transmembrane domains, suggesting that the two domains form two resistors in series. The larger conductance of the extracellular loop of IRK1 was attributable to a single amino acid difference (Thr versus Val) at the 3P position, three residues in front of the GYG motif. Permeability sequences for the conducted ions were similar for the two channels: Tl(+) > K(+) > Rb(+) > NH(4)(+). The ion selectivity sequence for ROMK2 based on conductance ratios was NH(4)(+) (1.6) > K(+) (1) > Tl(+) (0.5) > Rb(+) (0.4). For IRK1, the sequence was K(+) (1) > Tl(+) (0.8) > NH(4)(+) (0.6) >> Rb(+) (0.1). The difference in the NH(4)(+)/ K(+) conductance (1.6) and permeability (0.09) ratios can be explained if NH(4)(+) binds with lower affinity than K(+) to sites within the pore. The relatively low conductances of NH(4)(+) and Rb(+) through IRK1 were again attributable to the 3P position within the P region. Site-directed mutagenesis showed that the IRK1 selectivity pattern required either Thr or Ser at this position. In contrast, the COOH-terminal domain conferred the relatively high Tl(+) conductance in IRK1. We propose that the P-region and the COOH terminus contribute independently to the conductance and selectivity properties of the pore.

Elevation of intracellular calcium induced by the intrapipette perfusion technique modifies membrane ion currents in the chick cochlear hair cell

The concentration of intracellular calcium ion ([Ca2+]i) was altered in the same hair cell dissociated from a chick cochlea by the intrapipette perfusion technique. At a membrane potential of -40 mV, the elevation of [Ca2+]i generated outward-going currents within 60 sec when the intrapipette solution was based on KCl. In controls, at membrane potentials more positive than -50 mV, outward K+ currents were observed and at large positive potentials, the outward K+ current decreased, showing an N-shaped I-V relationship. This outward K+ current was increased by elevation of [Ca2+]i and was partially suppressed by a TEA-containing extracellular solution. We suggest that the Ca2+ increased by the intrapipette perfusion technique operates directly inside the cell membrane and activates Ca(2+)-activated K+ currents.

[Clinico-electrophysiologic effects of magnesium, especially in supraventricular tachycardia]

Clinical electrophysiological effects of magnesium (Mg2+) are known for more than 60 years. Mg2+ is a cation to be found ubiquitously in the human body and is involved in more than 300 different enzymatic reactions. However, so far this ion has not been established as a standard therapeutic tool for the treatment of supraventricular tachyarrhythmia. This may be explained by the inconsistent efficacy of Mg2+, partly in relationship to a given plasma Mg(2+)-concentration, partly caused by the uncertainty regarding the dosage and injection rate or the unawareness of the clinical effects of the cation. Mg2+ influences myocardial metabolism by its effects on contractility and electrical activity. Both effects are closely linked. About 12% of cardiac Mg2+ is found in the mitochondria and 2 to 3% in the myofibrils. A large portion is incorporated in adenosin mono-, di- and triphosphate. Mg2+ affects intracellular calcium by inhibiting the influx of calcium into the myocyte through sarcolemmal channels, by modulation of cyclic AMP and by competing with calcium for binding to a single high affinity site on actin. Mg2+ has been linked to a naturally occurring calcium channel blocker. Furthermore Mg2+ blocks the outward current through some potassium channels resulting in an inward rectification of these channels. This suggests that internal magnesium functions as a potassium channel-blocking agent. Early afterdepolarizations are oscillations in the membrane potential and lead to triggered activity and therefore are the electrophysiological substrate of "torsade de pointes" type of ventricular flutter. Mg2+ is able to inhibit both early afterdepolarizations and tachyarrhythmias. Additionally Mg2+ interferes with the sodium-potassium-ATPase system by stabilizing the transmembrane gradient of both cations. Mg2+ deficiency alters this balance and leads to increased neuromuscular excitability. Digitalis is able to block the sodium-potassium-ATPase system, which can be cancelled by Mg2+. Thus the first clinical reports of the therapeutic use of Mg2+ refer to digitalis-induced atrial arrhythmia and ventricular ectopy which could be converted to sinus-rhythm or suppressed by the intravenous application of Mg2+ in 1935. Some years later, the first successful termination of paroxysmal supraventricular and ventricular tachycardia following application of 1.5 to 3 g of Mg2+ was published. But only in the late eighties, systematic studies of the electrophysiological effects of Mg2+ were performed and clinical use was first tested in random fashion in the nineties. Summarizing studies in older patients with different heart diseases and young healthy volunteers the most pronounced and clinically important effect seems to be related to the modulation of the AV node function. The prolongation of the PR interval by 7 to 12% without changing significantly heart rate, QRS duration and QT duration, can be considered a consistent and reproducible effect of Mg2+. In electrophysiological studies a prolongation of the AH interval by 8 to 18%, of the Wenckebach cycle length by up to 20% and of the refractory period of the AV node by 6 to 20% is usually observed, but no change of the retrograde conduction, or the HV interval can be found. Furthermore sinus node recovery time increases by 10% and sinuatrial conduction time by up to 25%. There is no significant effect on intraventricular conduction and atrial and ventricular refractory period. Additionally no significant effect on the anterograde and retrograde refractory period of accessory pathways could be measured; however in some cases (up to 40%) an anterograde block in the accessory pathway may be observed after intravenous Mg(2+)-injection. For the treatment of paroxysmal atrioventricular tachycardia like AV-nodal reentrant tachycardia or orthodromic atrioventricular reentrant tachycardia in WPW syndrome, Mg2+ has been applied in a limited number of recent prospective but uncontrolled studies. Recently, an

Different sulfonylurea and ATP sensitivity characterizes the juvenile and the adult form of KATP channel complex of rat skeletal muscle

We have described here the changes of the biophysical and pharmacological properties of the sarcolemmal ATP-sensitive K+ channels (KATP) of rat skeletal muscle fibres, occurring from an early postnatal period (5 days) to adulthood (210 days). The age-dependent changes of the mean current of the KATP channel (channel activity) and the effects of the blockers, ATP and glybenclamide, were examined by using the patch-clamp technique. Measurements of the single channel conductance, open probability and channel density were also performed. Excision of cell-attached patches into an ATP-free solution dramatically increased the KATP channel activity; however, the intensity of this activity was age dependent. The relative activity was low at 5-6 days of postnatal life, increased to a plateau at 12-13 days, then declined toward adult values after 37 days. Two distinct types of the KATP channel complex could be distinguished. The early developmental period (5-6 days) was dominated by a KATP channel having a conductance of 66 pS, a high open probability of 0.602, and an IC50 for ATP and glybenclamide of 123.1 microM and 3.97 microM, respectively. This type of channel disappeared with maturation of the muscle to be replaced by the adult form of the KATP channel. The later developmental period (from 56 days) was dominated by a KATP channel having a 71 pS conductance, but a low open probability of 0.222. This adult channel was also 3.2 and 73.5 times more sensitive to ATP and glybenclamide, respectively. We have also observed that the sensitivity of the KATP channel to ATP and glybenclamide develops differently. Indeed, the greater increase in the sensitivity of the channel to ATP was observed between 5 and 12 days of age. Conversely, the greater enhancement of the sensitivity of the channel to glybenclamide occurred between 12 and 37 days. A further increase of this parameter was also observed between 37 and 56 days of age. The differential age-dependent acquisition of the sensitivity of KATP channels to ATP and glybenclamide poses the hypothesis that in rat skeletal muscle the ATP regulatory site and sulfonylurea site are located on different subunits of the KATP channel complex. The intense KATP channel activity recorded between 12 and 37 days of postnatal life sustains the high resting macroscopic K+ conductance characteristic of the early postnatal development.

Modulation of Ca2+-activated K+ channels by Mg2+ and ATP in frog oxyntic cells

Ca2+-activated K+ channels in the basolateral plasma membrane of bullfrog oxynticopeptic cells are intimately involved in the regulation of acid secretion. Patch-clamp techniques were applied to study the regulating mechanism of these channels. In the excised inside-out configuration, intracellular Mg2+ decreased channel activity in a dose-dependent manner. In the absence of Mg2+, administration of adenosine 5'-trisphosphate (ATP) to the cytoplasmic side also inhibited channel activity. On the other hand, in the presence of Mg2+, addition of ATP markedly increased channel activity. At a fixed concentration of free Mg2+, the Mg-ATP complex caused channel activation and shifted the dose response relationship between channel activity and the intracellular Ca2+ concentration to the left. A nonhydrolysable ATP analogue, adenosine 5'-[beta,gamma-imido]triphosphate (AMP-PNP) adenylyl [beta,gamma-methylene]diphosphate (AMP-PCP), could not substitute for ATP in channel activation, but a hydrolysable ATP analogue, adenosine 5'-O-(3-thiotriphosphate) (ATP[gammaS]) could do so. Furthermore, application of alkaline phosphatase to the cytoplasmic side inhibited channel activity. These results demonstrate that Ca2+-activated K+ channels are regulated by Mg2+ and ATP, and suggest that a phosphorylation reaction may be involved in the regulation mechanism of these channels.

Measurement of tissue transglutaminase activity in a permeabilized cell system: its regulation by Ca2+ and nucleotides

Electropermeabilized human endothelial cells (ECV-304) were used to study the regulation of tissue transglutaminase (tTGase) activity in the intracellular environment. An ELSA (enzyme-linked sorbent assay) plate assay was developed for intracellular tTGase activity, using the incorporation of a biotinylated primary amine, 5-{[(N-biotinoylamino)hexanoyl]amino}pentylamine(biotin-x-cadaveri ne; BTC), into endogenous protein substrates of tTGase. This incorporation process was inhibited by competitive inhibitors of tTGase, cystamine and monodansylcadaverine, in a dose-dependent manner. Over a 30 min period tTGase and its protein substrates did not leak out of the cell, and no incorporation of BTC occurred in unpermeabilized cells, indicating the reaction to be intracellular. In the presence of 10 nM or 10 muM CA2+, when nucleotides ATP and GTP were added at concentrations mimicking cytosolic levels, tTGase activity was decreased virtually to zero. Only at 100 muM Ca2+, when nucleotides were low or absent was tTGase activity observed. Under these conditions a variety of proteins was labelled by the enzyme, with the major labelling found in a protein of molecular mass around 51 kDa when analysed by SDS/PAGE/Western blotting.

Effects of divalent cations on muscarinic receptor cationic current in smooth muscle from guinea-pig small intestine

1. Effects of Mg2+ and Ca2+ on muscarinic receptor cationic current (Icat) in guinea-pig ileal smooth muscle cells have been studied using patch-clamp techniques (whole-cell recording). Icat was activated either by externally applied carbachol or, to bypass receptors, by intracellular GTP-gamma-S. 2. Independently of the main permeant cation the current-voltage (I-V) relation for Icat was U-shaped between the reversal potential (usually 0 mV) and very negative potentials such as -120 mV where current could be virtually lost. Adding Ca2+ to Ca(2+)- and Mg(2+)-free external solution reduced inward current and made it less U-shaped whereas adding Mg2+ reduced inward current and shifted more positively the potential at which maximum inward current occurred. 3. Activation of the conductance underlying Icat could be described by the Boltzmann relation which was shifted positively by adding Ca2+ or Mg2+. Extracellular Ca2+ also distorted the relation by increasing the slope factor; maximal conductance was reduced in all cases. Icat relaxation at negative potentials was accelerated by increasing Mg2+ and slowed down by Ca2+. 4. These data suggest the presence of fixed negative surface charges on or near the muscarinic receptor cationic channel, which allow its modulation through alteration of surface potential. Additional more direct ion binding to and blocking of the channel cannot be ruled out. Some additional effects of Ca2+ (if compared with Mg2+) could be explained on the assumption that the Ca(2+)-binding activation site known to be present on the internal side of the channel can be accessible to Ca2+ entering through the open channel during muscarinic receptor stimulation, as Ca2+ ions contribute to a limited extent to Icat. 5. We conclude that voltage-dependent gating of muscarinic receptor cationic channels is an intrinsic channel property and that Ca2+ and Mg2+ have strong modulatory effects.

Spermine gates inward-rectifying muscarinic but not ATP-sensitive K+ channels in rabbit atrial myocytes. Intracellular substance-mediated mechanism of inward rectification

The effect of spermine, a low molecular mass aliphatic amine with positive charges, on the strongly inwardly rectifying muscarinic K+ (KACh) channel was examined in rabbit atrial myocytes. In inside-out patch membranes, the single channel current-voltage relationship of KACh channels activated by guanosine 5'-3-O-(thio)triphosphate became linear in the absence of intracellular Mg2+. The open probability (Po) of the channels did not show significant voltage dependence under these conditions. Spermine specifically reduced Po of outwardly flowing KACh channel currents without affecting the unitary current amplitude at depolarized potentials, but had no effect on inward KACh currents under hyperpolarization. This voltage dependence of Po of KACh channels in the presence of spermine resembled that normally observed in the whole cell or open cell-attached configurations. Spermine (300 nM to 3 microM) also restored the relaxation of KACh currents which had been lost in the inside-out configuration. The effect of spermine was concentration-dependent with IC50 of approximately 10 nM at +40 mV. The order of potency of polyamines in reducing Po at +40 mV was spermine > or = spermidine > putrescine > ornithine; arginine had no significant effect. Intracellular Mg2+ antagonized the effect of spermine. Neither the single channel conductance nor Po of the ATP-sensitive K+ channel, a weak inward rectifier, was affected by spermine. Because submillimolar concentrations of spermine and spermidine are available in the cytosol of most cells, these substances may be the unidentified intracellular gating factors for strong inward rectifiers such as KACh and IK1 channels.

Towards the elucidation of the structural-functional relationship of inward rectifying K+ channel family

With recent cDNA cloning of members of the inward rectifying K+ channel family, it was revealed that they have only 2 putative transmembrane regions with no voltage-sensor element. Based on the deduced primary structure, possible schematic models to explain their characteristic features are proposed in this article. The features are (1) blocking by intracellular Mg2+, (2) intrinsic gating, (3) the triple barrel structure of the inward rectifier K+ channel and (4) the activation by the direct interaction with G-protein subunits of the muscarinic K+ channel. The recent findings of the mutagenesis study of voltage-gated K+ channels, which provide a clue for the structural-functional study of the inward rectifying K+ channels, are also looked at.

Intracellular Ca2+ inactivates an outwardly rectifying K+ current in human adenomatous parathyroid cells

We have used whole-cell patch-clamp techniques to study the conductances in the plasma membranes of human parathyroid cells. With a KCl-rich pipette solution containing Ca2+ buffered to a concentration of 0.1 mumol/l, the zero current potential was -71.1 +/- 0.5 mV (n = 19) and the whole-cell current/voltage (I/V) relation had an inwardly rectifying and an outwardly rectifying component. The inwardly rectifying current activated instantaneously on hyperpolarization of the plasma membrane to potentials more negative than -80 mV, and a semi-logarithmic plot of the reversal potential of the inward current (estimated by extrapolation from the range in which it was linear) as a function of extracellular K+ concentration ([K+]o) revealed a linear relation with a slope of 64 mV per decade change in [K+]o, which is not significantly different from the Nernstian slope, demonstrating that the current was carried by K+ ions. The conductance exhibited a square root dependence on [K+]o as has been observed for inward rectifiers in other tissues. The current was blocked by the presence of Ba2+ (1 mmol/l) or Cs+ (1.5 mmol/l) in the bath. The outwardly rectifying current was activated by depolarization of the membrane potential to potentials more positive than -20 mV. It was inhibited by replacement of pipette K+ with Cs+, indicating that it also was a K+ current: it was partially (42%) blocked when tetraethylammonium (TEA+, 10 mmol/l) was added to the bath.(ABSTRACT TRUNCATED AT 250 WORDS)

Voltage-dependent block by internal Ca2+ ions of inwardly rectifying K+ channels in guinea-pig ventricular cells

1. The block of the inwardly rectifying K+ channel by intracellular Ca2+ was studied in guinea-pig ventricular cells. 2. Single-channel currents through the inwardly rectifying K+ channel were recorded in the inside-out configuration at 150 mM external and internal K+. Internal Ca2+, at a concentration of 0.4-10 microM, induced subconductance levels with one-third and two-thirds of the unitary amplitude in the outward currents without affecting the inward currents. 3. Occupancy at each sublevel was estimated from the amplitude histogram which showed four equally spaced peaks in the presence of internal Ca2+. At different degrees of blockade, the distribution of the current levels showed a reasonable agreement with the binomial theorem. 4. The outward mean open-channel currents were measured at different Ca2+ concentrations and voltages. The current-voltage relation rectified inwardly in the presence of internal Ca2+ in a concentration-dependent manner. 5. The outward mean open-channel currents were normalized to unitary amplitudes in the absence of Ca2+. The normalized current-Ca2+ concentration curve was fitted by saturation kinetics with a Hill coefficient of 1 at each voltage. The voltage dependence of the dissociation constants gives the value for the fractional electrical distance of the Ca2+ binding site of 0.7. 6. The dwell times in each substrate were distributed exponentially. On the assumption that the inwardly rectifying K+ channel of cardiac cells is composed of three identical conducting subunits and each subunit is blocked by Ca2+ independently, the blocking (mu) and unblocking (lambda) rates were calculated. The value of mu increased with higher Ca2+ concentrations or larger depolarizations, while lambda was independent of Ca2+ and decreased with larger depolarization. 7. It is thus concluded that internal Ca2+ produces a voltage-dependent block of the channel to cause inward rectification although the blocking effect is less potent than that of Mg2+. The substate behaviour seen with internal Ca2+ supports the triple-barrelled structure of the cardiac inwardly rectifying K+ channel.

Potassium channels in growth cones of leech Retzius cells

1. Potassium-selective channels were analysed in growth cones of cultured leech Retzius cells. 2. In the cell-attached mode and at physiological bath and pipette solution little channel activity was observed at resting membrane potential. The channel open probability (p(o)) increased with cell depolarization, and the slope conductance of the single K+ channel current was about 60 pS. 3. With symmetrical high KCl solution on both sides of the excised membrane patch three K(+)-selective channels could be discriminated. Two channels exhibited a linear current-voltage relation of about 18 pS and 106 pS, respectively. 4. The most frequently observed K+ channel showed a non-linear current-voltage relation and p(o) increased with increasing free cytoplasmic Ca2+ and during cell hyperpolarization.

Primary structure and functional expression of a rat G-protein-coupled muscarinic potassium channel

Parasympathetic nerve stimulation causes slowing of the heart rate by activation of muscarinic receptors and the subsequent opening of muscarinic K+ channels in the sinoatrial node and atrium. This inwardly rectifying K+ channel is coupled directly with G protein. Based on sequence homology with cloned inwardly rectifying K+ channels, ROMK1 (ref. 11) and IRK1 (ref. 12), we have isolated a complementary DNA for a G-protein-coupled inwardly rectifying K+ channel (GIRK1) from rat heart. The GIRK1 channel probably corresponds to the muscarinic K+ channel because (1) its functional properties resemble those of the atrial muscarinic K+ channel and (2) its messenger RNA is much more abundant in the atrium than in the ventricle. In addition, GIRK1 mRNA is expressed not only in the heart but also in the brain.

Muscarinic receptors--characterization, coupling and function

At least five muscarinic receptor genes have been cloned and expressed. Muscarinic receptors act via activation of G proteins: m1, m3 and m5 muscarinic receptors couple to stimulate phospholipase C, while m2 and m4 muscarinic receptors inhibit adenylyl cyclase. This review describes the localization, pharmacology and function of the five muscarinic receptor subtypes. The actions of muscarinic receptors on the heart, smooth muscle, glands and on neurons (both presynaptic and postsynaptic) in the autonomic nervous system and the central nervous system are analyzed in terms of subtypes, biochemical mechanisms and effects on ion channels, including K+ channels and Ca2+ channels.

Primary structure and functional expression of a mouse inward rectifier potassium channel

A complementary DNA encoding an inward rectifier K+ channel (IRK1) was isolated from a mouse macrophage cell line by expression cloning. This channel conducts inward K+ current below the K+ equilibrium potential but passes little outward K+ current. The IRK1 channel contains only two putative transmembrane segments per subunit and corresponds to the inner core structure of voltage-gated K+ channels. The IRK1 channel and an ATP-regulated K+ channel show extensive sequence similarity and constitute a new superfamily.

Acetylcholine-mediated K+ channel activity in guinea-pig atrial cells is supported by nucleoside diphosphate kinase

We studied the role of nucleoside diphosphate kinase (NDPK) in acetylcholine-mediated muscarinic K+ channel activation in inside-out patches of guinea-pig atrial cells. NDPK-catalysed activation of the muscarinic K+ channels by adenosine triphosphate-Mg2+ (ATP-Mg2+) is not prevented by occupation of the muscarinic receptor [by acetylcholine (ACh) or atropine], nor by uncoupling of the receptor from the G protein by pertussis-toxin-catalysed adenosine diphosphate (ADP)-ribosylation of GK. In the presence of ACh, addition of 0.1 mM guanosine triphosphate (GTP) after activation of the channels by 4 mM ATP alone resulted in a moderate increase of channel activity (in contrast to block in the absence of ACh): NDPK-mediated direct transphosphorylation is uncoupled by the G nucleotide but agonist-induced guanosine diphosphate (GDP)-to-GTP exchange takes over activation of the channels. Moreover, ACh-dependent channel stimulation was possible in inside-out patches while ATP and GDP were present in the bathing solution (in contrast to the complete absence of channel activation in the absence of ACh). This indicates that NDPK synthesizes sufficient GTP to support channel activation by exchange. Hence, it is postulated that the main functional role of NDPK under physiological conditions is to provide a local supply of GTP (using GDP and ATP) in the immediate vicinity of the G protein, thereby maintaining a high local GTP/GDP ratio and ensuring adequate receptor-mediated regulation of muscarinic K+ channel activity.

Effects of internal and external Na+ ions on inwardly rectifying K+ channels in guinea-pig ventricular cells

1. The effects of internal and external Na+ ions on the inwardly rectifying K+ channel were studied in guinea-pig ventricular cells. 2. Single-channel currents through the inwardly rectifying K+ channel were recorded in the open cell-attached or inside-out configuration at 150 mM internal K+ and either 150 or 25 mM external K+. Internal Na+, at a concentration of 5-40 mM, reduced the unitary amplitude of the outward current. No increase in open-channel current noise was detected with the filter cut-off frequency of 3 kHz. Substate behaviour seen with internal Mg2+ at a micromolar level was not observed. The inward currents were little affected by internal Na+. 3. The unitary current-voltage relation rectified inwardly in the presence of internal Na+ in a concentration-dependent manner. 4. Outward unitary currents were normalized to those measured in the absence of Na+. The normalized current-voltage relation was shifted in the negative direction by 20-25 mV by decreasing external K+ from 150 to 25 mM, indicating that the blocking effect increases with low external K+ when compared at a fixed voltage. 5. The normalized current-Na+ concentration curve was fitted by a one-to-one binding curve at each voltage. In a semi-logarithmic plot of dissociation constant versus membrane potential, data points for 150 and 25 mM external K+ were fitted by straight lines with nearly the same slope. The dissociation constant at 0 mV is 154 mM in 150 mM external K+ and 89 mM in 25 mM external K+. The voltage dependence of dissociation constants gives a value for the effective valency of the Na+ ion of around 0.5. 6. To study effects of external Na+, single-channel currents were recorded with pipette solutions containing 125 mM Na+, 125 mM choline or 125 mM N-methyl-D-glucamine (NMDG) in addition to 25 mM K+. Current amplitude was smaller with choline than with Na+ or NMDG. The reduction in current amplitude with choline was more evident in the inward current, resulting in a stronger outward rectification of the current-voltage relation. This finding and prolonged mean open time (see Summary point 7) was interpreted by assuming that choline is an open-channel blocker. 7. The lifetimes of the openings in the inward currents were distributed according to a single exponential. The mean open time with Na+ was similar to that with NMDG, which decreased with hyperpolarization. The mean open time with choline was much longer and less voltage dependent.(ABSTRACT TRUNCATED AT 400 WORDS)

Interaction of dynamin with microtubules: its structure and GTPase activity investigated by using highly purified dynamin

We purified a large amount of dynamin with high enzymatical activity from rat brain tissue by a new procedure. Dynamin 0.48 mg was obtained from 20 g of rat brain. The purity of dynamin was almost 98%. Dynamin plays a role of GTPase rather than ATPase. In the absence of microtubules, Michaelis constant (Km) and maximum velocity (Vmax) for dynamin GTPase were 370 microM and 0.25 min-1, respectively, and in their presence, both were significantly accelerated up to 25 microM and 5.5 min-1. On the other hand, the ATPase activity was very low in the absence of microtubules, and even in their presence, Km and Vmax for dynamin ATPase were 0.2 mM and 0.91 min-1. Despite slow GTPase turnover rate in the absence of microtubules, binding of GTP and its nonhydrolizing analogues was very fast, indicating that GTP binding step is not rate limiting. Dynamin did not cause a one-directional consistent microtubule sliding movement just like kinesin or dynein in the presence of 2 mM ATP or 2 mM GTP. We observed the molecular structure of dynamin with low-angle rotary shadowing technique and revealed that the dynamin molecule is globular in shape. Gel filtration assay revealed that these globules were the oligomers of 100-kDa dynamin polypeptide. Dynamin bound to microtubules with a 1:1 approximately 1.2 molar ratio in the absence of GTP. Quick-freeze deep-etch electron microscopy of the dynamin-microtubule complex showed that dynamin decorates the surface of microtubules helically, like a screw bolt, very orderly and tightly with 11.4 +/- 0.9 (SD)nm period. Contrary to the previous report, microtubules make bundles by the attachment of the dynamin helixes around each adjacent microtubule, and no cross-bridge formation was observed.

Examination of subconductance levels arising from a single ion channel

Single-channel records often show frequent currents at a main conductance level and occasional currents at subconductance levels. In some instances, the conductances occur at regular levels that are multiples of a minimum conductance. It is well-appreciated that multiple conductance levels may arise either from the co-operative gating of more than one pore or from changes that occur in a single pore. In this paper, we used theoretical models of ion permeation to examine subconductances arising in a single-pore channel. In particular, the work focuses on the following question: how can an ion channel that provides only one aqueous pore through the membrane produce regular subconductances and a main conductance that all have the same selectivity and the same ion binding affinity? The three types of ion permeation models used in this study showed that a single-pore channel can have subconductances because of long-lived conformational states, because of alterations in rapid fluctuations between conformational states, or because of slight alterations in the electrostatic properties in the channel's entrance vestibules. Regular subconductances with the same selectivity and binding affinity can arise in a single pore even if the energy profile changes do not meet the constant peak offset condition. The results show that the appearance of regular subconductance levels in a single-channel recording is not sufficient evidence to conclude that identical pores have co-operative gating, as would arise in a channel that is a multi-pore complex.

Single cardiac outwardly rectifying K+ channels modulated by protein kinase A and a G-protein

Elementary K+ currents were recorded at 19 degrees C in cell-attached and in inside-out patches excised from neonatal rat heart myocytes. An outwardly rectifying K+ channel which prevented Na+ ions from permeating could be detected in about 10% of the patches attaining (at 5 mmol/l external K+ and between -20 mV and +20 mV) a unitary conductance of 66 +/- 3.9 pS. K+(outw.-rect.) channels have one open and at least two closed states. Open probability and tau open rose steeply on shifting the membrane potential in the positive direction, thereby tending to saturate. Open probability (at -7 mV) was as low as 3 +/- 1% but increased several-fold on exposing the cytoplasmic surface to Mg-ATP (100 mumol/l) without a concomitant change of tau open. No channel activation occurred in response to ATP in the absence of cytoplasmic Mg++. The cytoplasmic administration of the catalytic subunit of protein kinase A (120-150 mu/ml) or GTP-gamma-S (100 mumol/l) caused a similar channel activation. GDP-beta-S (100 mumol/l) was also tested and found to be ineffective in this respect. This suggests that cardiac K+(outw.-rect.) channels are metabolically modulated by both cAMP-dependent phosphorylation and a G-protein.

K+ and Cl- currents in freshly isolated rat osteoclasts

Membrane electrical properties of freshly isolated rat osteoclasts were studied using patch-clamp recording methods. Characterization of the passive membrane properties indicated that the osteoclast cell membrane behaved as an isopotential surface. The specific membrane capacitance was 1.2 +/- 0.3 microF/cm2 (mean +/- SD), with no difference between cells plated on glass and those adhering to a permeable collagen substrate. The current/voltage (I/V) relationship of all cells showed inward rectification and I/V curves shifted 51 mV positive per tenfold increase of [K+]out, indicating an inwardly rectifying K+ conductance. The voltage dependence of the K+ chord conductance (gK) also shifted positive along the voltage axis, and the maximum conductance increased, with elevation of [K+]out. gK for cells bathed in 4.7 mM [K+]out increased e-fold per 12 mV hyperpolarization, and half-maximal activation was at -89 mV. Approximately 18% (50 pS/pF) of the maximum gK was active at -70 mV. Inward single-channel currents were recorded in cell-attached patches at hyperpolarizing potentials. With symmetrical K+, channel conductance was 25 +/- 3 pS and reversal was close to the K+ equilibrium potential, consistent with this K+ channel underlying the whole-cell K+ currents. With both conventional whole-cell and perforated-patch recording, no voltage-activated Ca2+ current was detected. In approximately 30% of osteoclasts studied, an outwardly rectifying current was observed, which was reversibly blocked by 4,4'-diisothiocyanostilbene-2,2'-disulphonic acid (DIDS) and 4-acetamido-4'-isothiocyanostilbene-2,2'-disulphonic acid (SITS). This DIDS- and SITS-sensitive current reversed direction at the chloride equilibrium potential. We conclude that an inwardly rectifying K+ current is present in all rat osteoclasts and that some osteoclasts also exhibit an outwardly rectifying Cl- current. Both these membrane conductances may play an important physiological role by dissipating the potential that arises from the electrogenic transport of H+ across the ruffled membrane of the osteoclast.

Clinical correlates of the molecular and cellular actions of magnesium on the cardiovascular system

Magnesium is a ubiquitous element that participates in metabolic processes essential for life. Magnesium acts as a metallic cofactor in more than 300 enzymatic reactions; notably it is essential for all reactions requiring ATP. Magnesium also functions as a transmembrane and intracellular modulator of other ions. Altered magnesium homeostasis, particularly a deficiency, can cause alterations in metabolic functions that result in clinically recognizable events. Recognition of magnesium deficiency is problematic, since there is no test that will reliably and consistently detect this condition. A high index of suspicion for magnesium deficiency is necessary and treatment should be given when indicated. This article reviews the molecular and cellular actions of magnesium and correlates these basic scientific findings with clinically recognized cardiovascular events in humans. In addition, management guidelines are delineated.

Effects of Mg2+ on basal and beta-adrenergic-stimulated delayed rectifier potassium current in frog atrial myocytes

1. The effects of internal Mg2+ ions on the delayed rectifier potassium current (IK) of bull-frog atrial myocytes were studied using the whole-cell configuration of the patch-clamp technique with a perfusable patch electrode. 2. Initial variations in IK amplitude were dependent on [Mg2+]i. With [Mg2+] greater than 1 mM, the amplitude of IK usually decreased after initiating the whole-cell recording configuration (run-down); with [Mg2+]i less than 1 mM, IK usually increased (run-up). Mg2+ blocked IK with an apparent half-maximal effect of 0.6 mM [Mg2+]i. 3. The basal free [Mg2+]i, indicated by the amplitude of IK before run-up or run-down, was estimated from the relationship between [Mg2+]i and IK to be 0.8 mM. 4. The amplitude of both the activation curve and the instantaneous voltage-current relationship was decreased by increasing [Mg2+]i. Under these conditions, the voltage dependence of IK was not affected. 5. The rate of activation of the current at +40 mV was slowed by increasing [Mg2+]i with little effect on the rate of deactivation at -50 mV. This is in contrast to the effects of isoprenaline, which speeded activation and slowed deactivation. 6. Isoprenaline increased IK on average by about 2.5 pA/pF, whether IK had previously run down or not, and regardless of [Mg2+]i. The reversibility of isoprenaline was partially inhibited at [Mg2+]i less than 1 mM. 7. It is concluded that Mg2+ affects IK via several mechanisms that might include a Mg(2+)-dependent phosphatase.

Effects of external and internal K+ ions on magnesium block of inwardly rectifying K+ channels in guinea-pig heart cells

1. Block of the inwardly rectifying K+ channel by intracellular Mg2+ was studied in guinea-pig ventricular cells at varying external or internal K+ concentrations. Sucrose or glucose was mainly used as a substitute for K+. 2. The current-voltage (I-V) relation for the single channel, in the absence of internal Mg2+, was almost linear in 30 mM-external K+ and 150 mM-internal K+ (30 mM [K+]o) and in 45 mM-internal K+ and 150 mM-external K+ (45 mM [K+]i) as well as in 150 mM-external and internal K+ (the control condition). The channel conductance was 31.7 +/- 1.7 pS (mean +/- S.D., n = 36) in the control, 23.1 +/- 1.2 pS (n = 8) in 30 mM [K+]o and 29.7 +/- 1.3 pS (n = 16) in 45 mM [K+]i, respectively. 3. Mg2+ on the cytoplasmic side blocked the outward currents without affecting the inward currents. Outward mean open-channel currents were measured at different Mg2+ concentrations (0-100 microM) and voltages. The current-voltage relation rectified inwardly in the presence of internal Mg2+ in a voltage- and concentration-dependent manner. 4. Outward mean open-channel currents were normalized to that measured in the absence of Mg2+. The normalized current-voltage relation in 45 mM [K+]i was almost superimposable on that obtained in the control at the same Mg2+ concentration, while that in 30 mM [K+]o was shifted in the negative direction by some 30 mV. 5. The normalized current-Mg2+ concentration curve was fitted by a one-to-one binding curve at each K+ condition and voltage. In a semilogarithmic plot of dissociation constant versus membrane potential, data points for 45 mM [K+]i were located on the same line as the control, whereas data points for 30 mM [K+]o were shifted in the negative direction by about 30 mV. The dissociation constant at 0 mV is 37 microM in the control and 45 mM [K+]i and 8.8 microM in 30 mM [K+]o. The voltage dependence of dissociation constants gives a value for the fractional electrical distance of the Mg2+ binding site of 0.57. 6. Subconductance levels with one-third and two-thirds of the unitary amplitude were seen with low internal Mg2+ at 45 mM [K+]i or 30 mM [K+]o as well as in the control condition. Blocking and unblocking rates were calculated on the assumption that the channel is composed of three identical conducting units and each unit is blocked by Mg2+ independently.(ABSTRACT TRUNCATED AT 400 WORDS)

Selective modulation of the ATP-sensitive K+ channel by nicorandil in guinea-pig cardiac cell membrane

Effects of a vasodilator, nicorandil (2-nicotinamidoethyl nitrate) on four kinds for cardiac K+ channels were investigated in guinea pig ventricular and atrial cells using inside-out patch recording combined with "oil-gate" concentration jump method. Nicorandil of 300 mumols/l failed to affect the inward-rectifier K+ channel and the Na(+)-activated K+ channel. The open probability of the muscarinic K+ channel, when activated by the application of GTP, was not changed by the drug. Nicorandil selectively increased the open probability of the ATP-sensitive K+ channel that was partly suppressed by intracellular ATP. The median effective concentration (EC50) of nicorandil was 74 mumols/l and Hill coefficient was 1.32 in the concentration-open probability relationship. The closing rate of the K+ channel by ATP was markedly delayed by the drug, whereas the open rate on removal of ATP was scarcely affected. Nicorandil had only little effect on this channel after run-down. It was concluded that nicorandil selectively activates the ATP-sensitive K+ channel mainly by modulating the ATP-dependent gate.

A magnesium current in Paramecium

Recent reappraisals of the role of ionized magnesium in cell function suggest that many cells maintain intracellular free Mg2+ at low concentrations (0.1 to 0.7 mM) and that external agents can influence cell function via changes in intracellular Mg2+ concentration. Depolarization and hyperpolarization of voltage-clamped Paramecium elicited a Mg2(+)-specific current, IMg. Both Co2+ and Mn2+ were able to substitute for Mg2+ as charge carriers, but the resultant currents were reduced compared with Mg2+ currents. Intracellular free Mg2+ concentrations were estimated from the reversal potential of IMg to be about 0.39 mM. The IMg was inhibited when external Ca2+ was removed or a Ca2+ chelator was injected, suggesting that its activation was Ca2(+)-dependent.

A pharmacological study of the responses induced by muscarinic agonists on the isolated superior cervical ganglion of the guinea-pig

We have studied the muscarinic agonist induced responses on the guinea-pig superior cervical ganglion in vitro, as recorded from the internal carotid nerve using a grease-gap. The principal response was a depolarization, but a small hyperpolarizing response could be revealed under certain conditions. We determined the pA2 of a number of muscarinic antagonists against the muscarine induced depolarization. Four selective antagonists and atropine appeared to act competitively. The rank order of their pA2s was 4-DAMP (8.5), atropine (8.4), pirenzepine (8.0), methoctramine (7.2) and AF-DX 116 (6.3). In addition to muscarine, we assessed the potency and relative maximum response of nine other muscarinic compounds to depolarize this preparation: carbachol, 5-methylfurmethide, oxotremorine, oxotremorine-M, pilocarpine, RS 86, AF102B and two novel compounds L-670548 and L-679512. L-670548 was the most potent and AF102B was the least potent agonist tested. Only AF102B evoked a maximum depolarization that was significantly smaller than muscarine. A hyperpolarizing response to carbachol (1 microM) could be recorded when the superfusing medium contained 0.3 microM pirenzepine and only 0.1 mM CaCl2 (cf. usual 2.5 mM). This response was relatively small compared to that evoked on the superior cervical ganglion of the rat. It was blocked by the cardioselective antagonists methoctramine (0.1-0.3 microM) and AF-DX 116 (0.3-1.0 microM). Of the 10 agonists tested, only carbachol, oxotremorine and oxotremorine-M reproducibly evoked a hyperpolarizing response. It was concluded that muscarinic agonists can induce a depolarization of the guinea-pig superior cervical ganglion mediated by M1 receptors. The activation of cardiac-like M2 receptors resulted in a hyperpolarizing response that was relatively small.

Intracellular Mg2+ modulates the A-current and its blockage by catechol in isolated Lymnaea neurons

The effects of intracellular Mg2+ (2-8 mM) upon the transient outward current (the A-current) under normal conditions and under catechol-induced blockage were studied in molluscan neurons by using the voltage-clamp and intracellular dialysis techniques. Identified giant Lymnaea stagnalis L. neurons were investigated at room temperature (20-22 degrees C). When applied intracellularly, Mg2+ caused both time- and dose-dependent shifts of the voltage dependence of the steady-state activation and inactivation of the A-current to more negative membrane potentials. Upon external application, catechol suppressed (5-6 mM) or eliminated (9-10 mM) the A-currents, slowed down the current decay and shifted the activation and inactivation curves to more positive membrane voltages. Intracellular Mg2+ decreased the blocking ability of extracellularly applied catechol, whereas catechol antagonized the Mg2(+)-induced negative shift of the steady-state activation and inactivation curves of the A-currents.

Voltage-dependent block by intracellular Mg2+ of N-methyl-D-aspartate-activated channels

The N-methyl-D-aspartate (NMDA)-activated channel, which is known to be blocked by extracellular Mg ions, is shown also to be blocked by intracellular Mg ions. The block by intracellular Mg can be explained by assuming that Mg ions from the intracellular side enter the membrane electrical field before binding to the blocking site. The dissociation constant of the binding site for intracellular Mg is 8 mM at 0 mV, which is close to the value previously calculated for the extracellular Mg blocking site. The unbinding rates of intracellular and extracellular Mg are different, and their effects are additive, suggesting that the corresponding binding sites are distinct. Both blocks occur at physiological concentrations of Mg, making the NMDA-activated channel a bidirectional rectifier.

Three different potassium channels in human atrium. Contribution to the basal potassium conductance

We applied the cell-attached and inside-out patch-clamp technique under symmetrical isotonic potassium conditions on single human (and guinea pig) atrial cells. The human cells were isolated by a modified method to that described earlier. Our aim was twofold: 1) to study the single-channel characteristics of potassium channels in human atrial single cells, present under basal conditions (iK1 and iK(ATP] or when stimulated with 10(-5) M acetylcholine; and 2) to calculate the contribution of these three channel types to the total basal potassium conductance in human atrial cells, and to compare the results with data on guinea pig atrial cells under the same conditions. We found that in human cells 58% of the patches (n = 42/74) contained acetylcholine-sensitive potassium channels: their conductance was 42 +/- 1.2 pS and mean open time (tau o) was 1.7 +/- 0.5 msec. They showed sporadic openings in the absence of agonist, and activation by acetylcholine was G-protein dependent. In 16% of the patches (n = 7/44), adenosine (10(-4) M) activated the same channels, but the activity was lower than when stimulated by acetylcholine. In 18% of the patches (n = 9/51), an iK1 channel was present (conductance, 27 pS; tau o, 8.7 msec), whereas in the cell-attached mode, ATP-dependent channels were never seen. However, they were present in half of the inside-out patches on washout of ATPi (conductance, 73 pS; tau o, 1.4 msec). The basal potassium conductance (i.e., in the absence of any exogenous hormone or neurotransmitter) was mainly due to iK1 channels in both human and guinea pig cells, a finding that is in contrast with previous reports. However, the potassium current that is induced by acetylcholine is much higher in guinea pig than in human isolated cells; a fraction of it would suffice to fully determine the resting potassium conductance in guinea pig atrial cells, whereas it can play only a modulatory role in human cells. This difference could be important in species-specific autonomic modulation and antiarrhythmic drug action.

The Mg2+ block and intrinsic gating underlying inward rectification of the K+ current in guinea-pig cardiac myocytes

1. The blockade by Mg2+ and intrinsic gating of the channel, which underlie the rectification of the inward rectifier K+ current, was investigated using the oil-gap voltage clamp method in isolated guinea-pig ventricular cells. 2. The inward rectifier K+ current was isolated by subtracting trans-gap currents recorded at an extracellular K+ concentration ([K+]o) of 0 mM from those obtained at 14 mM [K+]o in the presence of a given concentration of intracellular Mg2+ ([Mg2+]i). The reversal potential (V0) of the difference current was near the equilibrium potential for K+ (EK). 3. On repolarization across EK, the inward rectifier K+ current showed a rapid exponential increase. The time constant decreased with increasing hyperpolarization, but it was independent of both [Mg2+]i and the preceding depolarization. 4. When the pre-pulse potential was made progressively positive between V0-20 and V0 + 30 mV, the amplitude of the time-dependent component became larger and the preceding current jump decreased at any [Mg2+]i. With pre-pulses more positive than V0 + 40 mV, the time-dependent component started from almost the zero current level at 2 microM [Mg2+]i. At higher [Mg2+]i (350, 500 and 3000 microM), however, the time-dependent component became smaller as the pre-pulse potential was made more positive than V0 + 40 mV. 5. When the membrane was depolarized from a potential of full activation at 2 microM [Mg2+]i, the initial jump in the outward current was ohmic and was followed by an exponential decay. The time-dependent component of the inward current, recorded on repolarization after increasing durations of the preceding depolarization, developed as the outward current decayed. The time constants of both processes were in good agreement. 6. At 500 microM [Mg2+]i, the outward current on depolarization was instantaneously rectified. The time-dependent component recorded on repolarization developed with prolongation of the pre-pulse with a time course slower than at 2 microM [Mg2+]i. The envelope time course became slower as the potential of the depolarization became more positive. 7. Lowering the temperature from 23 to 15 degrees C slowed the time-dependent current with an apparent Q10 of about 3.5 at V0. 8. Based on the experimental data, kinetic parameters were estimated for a model of Mg2+ block, which well simulated the inward-going rectification of the K+ current. 9. It is concluded that the instantaneous inward rectification on depolarization is due to the Mg2+ block at physiological [Mg2+]i.(ABSTRACT TRUNCATED AT 400 WORDS)