Voltage-gated ion conductances corresponding to regenerative positive and negative spikes in the dinoflagellateNoctiluca miliaris

Depolarization-activated and hyperpolarization-activated ion conductances in the membrane of a marine dinoflagellateNoctiluca miliaris were examined under voltage-clamp conditions.Noctiluca exhibited a transient inward current in response to a step depolarization from a holding potential level of –80 mV to a potential level more positive than –50 mV. The I–V relationship for the current exhibited typical N-shaped characteristics similar to those of most excitable membranes. The current was inactivated by a membrane depolarization. The reversal potential of the current shifted in hyperpolarizing direction when the external Na⁺ concentration was lowered. The transient inward current is assumed to be responsible for the Na⁺-dependent positive spike in non-clamped specimens ofNoctiluca.Noctiluca exhibited a transient outward current in response to a step hyperpolarization from a holding potential level of –20 mV to a potential level more negative than –30 mV. The I–V relationship for the current was a typical N-shape as if it was turned 180° around its origin. The outward current showed a two-step exponential time-decay. The outward current was inactivated by a membrane hyperpolarization. The reversal potential shifted in the depolarizing direction when the external Cl^– concentration was lowered. The transient outward current is responsible for the Cl^–-dependent negative spike in non-clamped specimens ofNoctiluca.Abbreviations ASW artificial seawater - TRP tentacle regulating potentials - TTX tetrodotoxin     

Correlation between membrane potential responses and tentacle movement in the dinoflagellate Noctiluca miliaris

Membrane potential responses and tentacle movement of the marine dinoflagellate Noctiluca miliaris were recorded simultaneously and their time relationships were examined. The food-gathering tentacle of Noctiluca exhibited slow extension-flexion movements in association with the spontaneously recurring membrane potential responses termed the tentacle regulating potentials (TRPs). The flexion of the tentacle began during the slow depolarization of the TRPs. The rate of the flexion increased after the hyperpolarizing (negative) spike following the slow depolarization. The tentacle then extended slowly during the hyperpolarized level of the TRPs. A TRPs-associated flexion did not occur when the external Ca(2+) ions were removed. On the contrary, the tentacle showed conspicuous flexion (coiling) when the external Ca(2+) concentration was raised. In association with the stimulus-evoked action potential, which triggers bioluminescent flash (flash-triggering action potential; FTP), the tentacle coiled quickly. The FTP-associated coiling took place even in the Ca(2+)-deprived condition. The coupling mechanisms of the TRPs-associated and FTP-associated tentacle movements were compared, and their biological significance was discussed.     

Anions permeate and gate GCAC1, a voltage-dependent guard cell anion channel

GCAC1 is a strongly voltage-dependent anion channel in the guard-cell plasma membrane of Vicia faba . In patch–clamp experiments, we have investigated the permeation and gating properties of GCAC1 with respect to its anion dependence in the whole-cell and excised-patch configuration. The relative permeability followed the order SCN^– > NO₃^– > Br^– > Cl^–, while the single-channel conductances in symmetrical anionic solutions exhibited a nearly inverse sequence. The Cl^– dependence of inward currents (Cl^– release) is characterized by a maximum single-channel conductance of 89 pS half-saturating at 87 mM cytoplasmic chloride. In addition to this substrate saturation, anion release was also dependent on the external Cl^– activity ( K _m = 16 mM). In the presence of SCN^– and Cl^–, the single-channel conductance exhibited an anomalous mole-fraction dependence, identifying GCAC1 as a multi-ion single-file pore. Using anions with increasing ionic size, a minimum pore diameter of 0.5 nm was assumed from their relative permeabilities. In line with an anion-selective channel, a tenfold increase in the extracellular anion activity shifted the reversal potential by –59.8 mV. Simultaneously, the half-activation potential shifted negatively by about 23 mV. A further analysis of the anion dependence revealed that extracellular rather than cytosolic anions affect the gating process of GCAC1. From anion substitution experiments, we conclude that anion concentration and species determines both permeation and gating of the plant anion channel GCAC1.     

Mechanism of Cl- sensitivity in internal ion receptors of the leech; an inward current gated off by Cl- in the nephridial nerve cells

Summary The nephridial nerve cells of the leech, Hirudo medicinalis, 34 sensory cells, each associated with one nephridium, are sensitive to changes in extracellular Cl^- concentration, an important factor in ion homeostasis. Using single-electrode current- and voltage clamp and ion substitution techniques, the specificity and mechanism of Cl^- sensitivity of the nephridial nerve cell was studied in isolated preparations. Increase of the normally low external Cl^- concentration leads to immediate and sustained hyperpolarization, decrease of the frequency of bursts and decrease of membrane conductance. The response is halogen specific: Cl^- can be replaced by Br^–, but not by organic mono- or divalent anions or inorganic divalent anions.At physiological Cl^- concentrations (36mM extra-cellular Cl^-), the nephridial nerve cell has a high resting conductance for Cl^- and the membrane potential is governed by Cl^-. In high extracellular Cl^- concentrations (110–130 mM), membrane conductance is low, most likely due to the gating off of Cl^- channels. Under these conditions, membrane potential is dominated by the K⁺ distribution and the nephridial nerve cell hyperpolarizes towards E_K.Abbreviations NNC nephridial nerve cell - V _m membrane potential - E _Cl(k) equilibrium potential for Cl (K) - IV-curve current-voltage relationship     

Membrane potentials and ion permeabilities in flexor cells of the laminar pulvini of Phaseolus coccineus L.

The internal potential of flexor cells in slices of the laminar pulvini of Phaseolus coccineus has been recorded by standard microelectrode techniques in 100 eq m^-3 external salt solutions of various ionic compositions. The measured values are between-15 and-60 mV depending on the external medium. Treating the results with the Goldman equation yields the following relative permeabilities: K⁺, 1.00; Na⁺, 0.24; Cl^-, 0.19; NO ₃ ^- , 1.6. The membrane potential was only slightly sensitive to external pH and Ca²⁺. Metabolic inhibitors (azide, cyanide and salicylhydroxamic acid, carbonyl cyanid m-chlorphenyl hydrazone) caused only slight depolarizations (ca. 4 mV), which differed from the ion-induced changes by their slow time courses. The results are consistent with the hypothesis that the relatively impermeable Cl^- is actively transported and osmotically efficient, whereas the well-permeable K⁺ passively follows Cl^- to maintain electroneutrality and is osmotically of only minor significance.Abbreviations SHAM salicylhydroxamic acid - CCCP carbonyl cyanid m-chlorphenyl hydrazone     

Modification of voltage-sensitive inactivation of Na+ current by external Ca2+ in the marine dinoflagellateNoctiluca miliaris

Effects of the external Ca²⁺ concentration on the depolarization-induced transient inward Na⁺ current responsible for the Na⁺ spike in the dinoflagellate Noctiluca miliaris were examined. The peak value and the duration of the Na⁺ current increased when lowering the external Ca²⁺ concentration. The threshold potential level for activation and the reversal potential level of the current were not affected by the external Ca²⁺ concentration. The inactivation took place even in a solution containing EGTA with very low (<10^–9 M) Ca²⁺ concentration. Voltage dependency of the inactivation was scarcely affected by the external Ca²⁺ concentration. It is concluded that inactivation of Na⁺ channels responsible for the current is dependent on membrane depolarization and that the external Ca²⁺ modulates the inactivation kinetics. Appearance of a Na⁺ spike in a solution with reduced Ca²⁺ concentration is caused by a lowered rate of inactivation of the Na⁺ channels.     

Ion Permeabilities in Mouse Sperm Reveal an External Trigger for SLO3-Dependent Hyperpolarization

Unlike most cells of the body which function in an ionic environment controlled within narrow limits, spermatozoa must function in a less controlled external environment. In order to better understand how sperm control their membrane potential in different ionic conditions, we measured mouse sperm membrane potentials under a variety of conditions and at different external K⁺ concentrations, both before and after capacitation. Experiments were undertaken using both wild-type, and mutant mouse sperm from the knock-out strain of the sperm-specific, pH-sensitive, SLO3 K⁺ channel. Membrane voltage data were fit to the Goldman-Hodgkin-Katz equation. Our study revealed a significant membrane permeability to both K⁺ and Cl⁻ before capacitation, as well as Na⁺. The permeability to both K⁺ and Cl⁻ has the effect of preventing large changes in membrane potential when the extracellular concentration of either ion is changed. Such a mechanism may protect against undesired shifts in membrane potential in changing ionic environments. We found that a significant portion of resting membrane potassium permeability in wild-type sperm was contributed by SLO3 K⁺ channels. We also found that further activation of SLO3 channels was the essential mechanism producing membrane hyperpolarization under two separate conditions, 1) elevation of external pH prior to capacitation and 2) capacitating conditions. Both conditions produced a significant membrane hyperpolarization in wild-type which was absent in SLO3 mutant sperm. Hyperpolarization in both conditions may result from activation of SLO3 channels by raising intracellular pH; however, demonstrating that SLO3-dependent hyperpolarization is achieved by an alkaline environment alone shows that SLO3 channel activation might occur independently of other events associated with capacitation. For example sperm may undergo stages of membrane hyperpolarization when reaching alkaline regions of the female genital tract. Significantly, other events associated with sperm capacitation, occur in SLO3 mutant sperm and thus proceed independently of hyperpolarization.     

The Initiation of Spike Potential in Barnacle Muscle Fibers under Low Intracellular Ca++

Electrical properties of the muscle fiber membrane were studied in the barnacle, Balanus nubilus Darw. by using intracellular electrode techniques. A depolarization of the membrane does not usually produce an all-or-none spike potential in the normal muscle fiber even though a mechanical response is elicited. The intracellular injection of Ca⁺⁺-binding agents (K₂SO₄ and K salt of EDTA solution, K₃ citrate solution, etc.) renders the fiber capable of initiating all-or-none spikes. The overshoot of such a spike potential increases with increasing external Ca concentration, the increment for a tenfold increase in Ca concentration being about 29 mv. The threshold membrane potential for the spike and also for the K conductance increase shifts to more positive membrane potentials with increasing [Ca⁺⁺]_out. The removal of Na ions from the external medium does not change the configuration of the spike potential. In the absence of Ca⁺⁺ in the external medium, the spike potential is restored by Ba⁺⁺ and Sr⁺⁺ but not by Mg⁺⁺. The overshoot of the spike potential increases with increasing [Ba⁺⁺]_out or [Sr⁺⁺]_out. The Ca influx through the membrane of the fiber treated with K₂SO₄ and EDTA was examined with Ca⁴⁵. The influx was 14 pmol per sec. per cm² for the resting membrane and 35 to 85 pmol per cm² for one spike. From these results it is concluded that the spike potential of the barnacle muscle fiber results from the permeability increase of the membrane to Ca⁺⁺ (Ba⁺⁺ or Sr⁺⁺).     

A channel that allows inwardly directed fluxes of anions in protoplasts derived from wheat roots

An anion channel that only allows outward current flow (anion influx) has been identified in protoplasts derived from wheat (Triticum aestivum L., Triticum turgidum L.) roots. The anion outward rectifier (anion OR) measured by patch-clamp of whole cells activated very quickly, usually reaching a steady-state level in less than 100 ms and was easily distinguished from the cation outward rectifier (cation OR) which activated more slowly during membrane depolarisation. The anion OR is permeable to NO ₃ ^– and Cl^–, moderately permeable to I^–, and relatively impermeable to H₂PO₄/^– and ClO₄/^–. An anomalous mole-fraction effect between ClO_4/ ^– and Cl^– was observed on the outward current, indicating that the channel is a multi-ion pore. The anion OR is gated by both voltage and external anion concentration such that it activates near to the equilibrium potential for the permeant anion. It activated at more negative membrane potentials when NO ₃ ^– was substituted for Cl^– in the external medium, indicating that the channel may function to allow NO ₃ ^– influx under luxuriant external NO ₃ ^– concentrations. For most experiments, K⁺ and Cl^– were the main cation and anion in solution, and under these conditions it appeared likely that the anion OR functioned in membrane-potential regulation by facilitating a Cl^– influx at membrane potentials more positive than the chloride reversal potential (E_Cl). If E_Cl was more negative than the K⁺ reversal potential (E_K) then the anion OR dominated but both the anion and cation ORs occurred together when the membrane potential difference (V_m) was positive of both E_Cl and E_K. The cation OR was inhibited by increasing external Cl^– concentrations, but the anion OR was not affected by external K⁺ or Na⁺ concentration. The anion-transport inhibitors, zinc and phenylglyoxal were ineffective in blocking the anion OR. 4,4-Di-isothiocyanostilbene-2, 2-disulfonic acid (DIDS) irreversibly blocked about 34% of the current when applied extracellularly at a concentration of 25 M, and about 69% at a concentration of 200 M. However, DIDS (200 M) also occasionally acted as an irreversible blocker of the cation OR. Perchlorate blocked irreversibly 75% of the current at an external concentration of 10 mM and did not block the cation OR. Whole-cell currents also indicated that the anion OR was insensitive to external pH (pH=5–7) and calcium concentration ([Ca²⁺]=0.1–10 mM). Increasing intracellular calcium concentration significantly increased the occurrence of the fast outward current in whole cells (P < 0.005, X² test). With approximately 10 nM calcium inside the cell the anion outward current was observed in 64% (n = 45) of cells and with 50 nM calcium inside the cell the anion current was observed in 88% (n = 69) of cells. Single-anion OR channels observed in outside-out patches had a conductance in 300 mM KCl (external) of about 4 pS. When voltage pulses were applied to outside-out patches the average currents were similar to those observed in whole cells. The significance of the anion OR as a likely route for Cl uptake in high salinities is discussed.Abbreviations Bath solution bathing the extracellular face of the membrane - DIDS (4,4-diisothiocyanostilbene-2,2-disulfonic acid) - E_x reversal potential for ion x - OR outward rectifier - Pip solution inside the pipette - TEACl (tetraethyl-ammonium chloride) - V_m membrane potential difference We thank the Australian Research Council for financial support, G.P. Findlay and A. Garrill for helpful discussions, and K. Morris and D. Mackenzie for expert technical assistance. M.S. was supported by an Australian Postgraduate Research Award.     

Modeling Plasmalemma Ion Transport of the Aquatic Plant Egeria densa

Fresh-water plants generate extraordinarily high electric potential differences at the plasma membrane. For a deeper understanding of the underlying transport processes a mathematical model of the electrogenic plasmalemma ion transport was developed based on experimental data mainly obtained from Egeria densa. The model uses a general nonlinear network approach and assumes coupling of the transporters via membrane potential. A proton pump, an outward-rectifying K⁺ channel, an inward-rectifying K⁺ channel, a Cl⁻ channel and a (2H-Cl)⁺ symporter are considered to be elements of the system. The model takes into consideration the effects of light, external pH and ionic content of the bath medium on ion transport. As a result it does not only satisfactorily describe the membrane potential as a function of these external physiological factors but also succeeds in simulating the effects of specific inhibitors as well as I-V-curves obtained with the patch-clamp technique in the whole cell mode. The quality of the model was checked by stability and sensitivity analyses. Received: 18 March 1996/Revised: 17 July 1996     

Dynamic modeling for flow-activated chloride-selective membrane current in vascular endothelial cells

In this paper, a dynamic model is proposed to quantify the relationship between fluid flow and Cl⁻-selective membrane current in vascular endothelial cells (VECs). It is assumed that the external shear stress would first induce channel deformation in VECs. This deformation could activate the Cl⁻ channels on the membrane, thus allowing Cl⁻ transport across the membrane. A modified Hodgkin–Huxley model is embedded into our dynamic system to describe the electrophysiological properties of the membrane, such as the Cl⁻-selective membrane current (I), voltage (V) and conductance. Three flow patterns, i. e., steady flow, oscillatory flow, and pulsatile flow, are applied in our simulation studies. When the extracellular Cl⁻ concentration is constant, the I-V characteristics predicted by our dynamic model shows strong consistency with the experimental observations. It is also interesting to note that the Cl⁻ currents under different flow patterns show some differences, indicating that VECs distinguish among and respond differently to different types of flows. When the extracellular Cl⁻ concentration keeps constant or varies slowly with time (i.e. oscillates at 0.02 Hz), the convection and diffusion of Cl⁻ in extracellular space can be ignored and the Cl⁻ current is well captured by the modified Hodgkin–Huxley model alone. However, when the extracellular Cl⁻ varies fast (i.e., oscillates at 0.2 Hz), the convection and diffusion effect should be considered because the Cl⁻ current dynamics is different from the case where the convection-diffusion effect is simply ignored. The proposed dynamic model along with the simulation results could not only provide more insights into the flow-regulated electrophysiological behavior of the cell membrane but also help to reveal new findings in the electrophysiological experimental investigations of VECs in response to dynamic flow and biochemical stimuli.     

Regulation of ion concentration by Drosophila hydei Na+, K+, Ca2+, and Cl-

The ionic composition of the haemolymph of osmotically unencumbered larvae of Drosophila hydei shows a pattern that is typical (Bone, 1944) for highly developed phytophagous insect larvae: 36 mval/l. Cl^?; 56 mval/l. Na⁺; 31 mval/l. K⁺; approximately 18 mval/l. Ca²⁺ at an osmolality of 299 mOsmol/l.The larvae are able to maintain their most favourable ionic concentrations in the haemolymph after experimental osmotic stress in hypertonic as well as in hypotonic media. The reactions are most distinct with an increase or decrease of Cl^? concentration of the external medium. Characteristic regulating processes begin, and the Cl^? concentration of the haemolymph adjusts to the ‘standard’ again. The principal lapse shows the functional representation of an intensely suppressed oscillation. There seems to be a two-point regulation which requires the existence of a Cl^? ion depot and the existence of Cl^?-sensitive receptors.     

Interactions between growth, Cl− and Na+ uptake, and water relations of plants in saline environments. I. Slightly vacuolated cells

Abstract. Slightly vacuolated cells, i.e. microalgae and meristematic cells of vascular plants, maintain low Cl^? and Na⁺ concentrations even when exposed to a highly saline environment. The factors regulating the internal ion concentration are the relative rate of volume expansion, the membrane permeability to ions, the electrical potential, and the active ion fluxes. For ion species which are not actively transported, a formula is developed which relates the internal concentration to the rate of expansion of cell volume, the permeability of membranes to that ion, and the electrical potential. For example, when the external concentration of Cl^? is high, and Cl^? influx is probably mainly passive, the formula predicts that rapid growth keeps the internal Cl^? concentration lower than that in a non-growing cell with the same electrical potential; this effect is substantial if the plasmalemma has a low permeability to Cl^?. For ion species which are actively transported, the rate of pumping must be considered. For instance Na⁺ concentrations are kept low mainly by an efficient Na⁺ extrusion pump which works against the electric field across the membrane. The requirement for Na⁺ extrusion is related to the external Na⁺ concentration, the rate of expansion of cell volume, the membrane permeability, and the electrical potential. It is possible that microalgae have a more positive electrical potential than many other plant cells; if so, requirements for high rates of active Na⁺ extrusion will be lower. The required rates of Na⁺ extrusion are lower during rapid growth, provided that the permeability of the plasmalemma to Na⁺ is low. The energy required for the regulation of Cl^? and Na⁺ concentrations is low, especially in rapidly expanding cells where Na⁺ extrusion requires only 1–2% of the energy normally produced in respiration. The exclusion of these ions, however, must be accompanied by the synthesis of enough organic compounds to provide adequate osmotic solutes for the increases in volume accompanying growth. This process reduces the substrates available for respiration and synthesis of cell constituents, but the reduction is not prohibitively large—even for cells growing in 750 mol m^?3 NaCl, the carbohydrate accumulated as osmotic solute is only 10% of that consumed in respiration.     

Calcium dependence of acetylcholine induced conductance changes.

The influence of external calcium variation (0.7–28 mM) on acetylcholine (ACh) induced conductance changes was examined under voltage clamp conditions in snail neurons in which ACh elicitis hyperpolarizing responses and in which the main current-carrying ion species is Cl^?. Raising external calcium to 28 mM as well as lowering external calcium to 1.75 mM decreased the ACh-induced condutance change without altering the reversal potential for ACh-induced currents. Lowering external calcium to 0.7 mM increased the ACh-induced conductance change and shifted the reversal potential to less negative values. The results at 28 mM calcium can be best explained on the assumption that excess calcium interferes with the interaction between ACh and the receptor. The results at 1.75 mM calcium can be satisfactorily explained in terms of the concept that fixed membrane charges play a role in regulating Cl^? permeation through transmitter sensitive membranes. Evidence was also obtained that in snail neurons receptor inactivation increases when external calcium is reduced.     

Cold‐ and menthol‐evoked membrane potential changes in the moss Physcomitrella patens: influence of ion channel inhibitors and phytohormones

Microelectrode measurements carried out on leaf cells from Physcomitrella patens revealed that a sudden temperature drop and application of menthol evoked two types of different‐shaped membrane potential changes. Cold stimulation evoked spike‐type responses. Menthol depolarized the cell membrane with different rates. When it reached above 1 mV s^?1, the full response was recorded. Characteristic for the full responses was also a few‐minute plateau of the membrane potential recorded after depolarization. The influence of inhibitors of calcium channels (5 mM Gd³⁺), potassium channels (5 mM Ba²⁺), chloride channels (200 μM Zn²⁺, 50 μM niflumic acid) and proton pumps (10 μM DES), an activator of calcium release from intracellular stores (Sr²⁺), calcium chelation (by 400 μM EGTA) and phytohormones (50 μM auxin, 50 μM abscisic acid (ABA), 500 μM salicylic acid) on cold‐ and menthol‐evoked responses was tested. Both responses are different in respect to the ion mechanism: cold‐evoked depolarizations were influenced by Ba²⁺ and DES; in turn, menthol‐evoked potential changes were most effectively blocked by Zn²⁺. Moreover, the effectiveness of menthol in generation of full responses was reduced after administration of auxin or ABA, i.e. phytohormones known for their participation in responses to cold and regulation of proton pumps. The effects of DES indicated that one of the main conditions for generation of menthol‐evoked responses is inhibition of the proton pump activity. Our results indicate that perception of cold and menthol by plants proceeds in different ways due to the differences in ionic mechanism and hormone dependence of cold‐ and menthol‐evoked responses.     

Ca2+-dependent Cl− efflux in tonoplast-free cells ofNitellopsis obtusa

Summary In order to demonstrate the presence of a Ca²⁺-activated Cl^–-channel in theNitellopsis plasmalemma, tonoplast-free cells were prepared and their intracellular Ca²⁺ concentration was modified by internal perfusion. An increase in the Ca²⁺ concentration caused a large Cl^– efflux with a concomitant depolarization of the membrane potential. These changes were for the most part reversible. The critical Ca²⁺ concentration was about 4.0 m. Neither the Cl^– efflux nor the membrane depolarization showed a time-dependent inactivation. A Cl^–-channel blocker, A-9-C (9-anthracenecarboxylic acid) reduced both the Cl^– efflux and the magnitude of the membrane potential depolarization. A small increase in the intracellular Ca²⁺ concentration, which is caused by membrane excitation of tonoplast-free cells is not sufficient to activate this Ca²⁺-dependent Cl^–-channel.     

Resting potential of rat cerebellar granule cells during early maturation in vitro

The survival of rat cerebellar granule cells maintained in vitro is enhanced by a KCl-enriched medium. This effect is classically interpreted as resulting from a higher cytosolic calcium concentration. This implies the presence of voltage-dependent Ca²⁺ channels and a membrane potential that can respond to changes in external K⁺. Since previous studies cast a doubt on these two conditions, we reinvestigated the resting membrane potential and Ca²⁺ influxes in rat cerebellar granule neurones during the first week in vitro using a fluorescence imaging approach. Membrane potential was assessed with the fluorescent dye bis-oxonol, and intracellular free calcium with Fura-2. Resting potential was shown to progressively decrease from −40 mV at the first day in vitro to −60 mV at day 7. At all times in culture, as early as day 0, cells were depolarized when external KCl concentration was increased from 5 to 30 mM. This depolarization resulted in an increased cytosolic calcium concentration due to Ca²⁺ influx through L-type and N-type voltage-activated Ca²⁺ channels, functional at day 0. Gross estimations of the permeabilities of Na⁺ and Cl⁻ were obtained at various times in culture by measuring the changes in resting potential brought about by a reduction of their external concentration. A progressive increase of the relative permeability to K⁺ ions seems to underlie the evolution of the resting potential with time. © 1997 John Wiley & Sons, Inc. J Neurobiol 32: 11–21, 1997.     

Mechanism of Cl− transport at the plasma membrane ofChara corallina: II. Transinhibition and the determination of H+/Cl− binding order from a reaction kinetic model

Summary Internal Cl^– and low internal pH are strong inhibitors of Cl^– influx at the plasma membrane ofChara. The present investigation seeks to understand the mechanism by which this is achieved. Since both Cl^– and H⁺ are transported by the same system, one possible mechanism is simply through a change in the electrochemical gradients of these ions. However, it is found that transport is more sensitive to theinternal concentrations of the two ions than to their respective gradients. It is demonstrated that Cl^– influx, which shows Michaelis-Menten kinetics with respect to external concentration, is affected only in itsV _max by internal Cl^– and pH; the apparentK _m of the transport system for external Cl^– is unchanged. In addition, it is found that there is an apparent interaction between internal Cl^– and pH in their effects on Cl^– influx, both in intact cells and those that have been perfused internally. A kinetic model is proposed which can account quantitatively for all these observations simply through the effects of substrate concentration on the apparent rate constants of a recycling carrier. The model predicts (i) strictly ordered binding of Cl^– and H⁺ to the carrier at both internal and external surfaces, with Cl^– first on and first off (ii) movement of charge through the membrane on the loaded, rather than the unloaded, carrier. The present model is expected to account for similar kinetic observations from a variety of other cotransport systems.     

A heterogeneous electrophysiological profile of bone marrow-derived mast cells

Electrophysiological properties of mouse bone marrow-derived mast cells (BMMC) were studied under the whole-cell clamp configuration. About one third of the cells were quiescent, but others expressed either inward or outward currents. Inwardly rectifying (IR) currents were predominant in 14% of the cells, and outwardly rectifying (OR) currents in 24%. The rest (22%) of the cells exhibited both inward and outward currents. The IR currents were eliminated by 1 mm Ba²⁺, and were partially inhibited by 100 μm quinidine. The reversal potential was dependent on extracellular K⁺, thereby indicating that K⁺ mediated the IR currents. The negative conductance region was seen at potentials positive to E _K. The OR currents did not apparently depend on the extracellular K⁺ concentration, but were reduced by lowering the extracellular Cl^? concentration. The OR currents were partially blocked by 1 mm Ba²⁺, and were further blocked by a Cl^? channel blocker, 4,4′-diisothiocyano-2, 2′-stilbenedisulfonate (DIDS). In addition, the reversal potential of the OR currents was positively shifted by decreasing the ratio of external and internal Cl^? concentrations, suggesting that Cl^? was a major ion carrier. In cells exhibiting IR currents, the membrane potential varied among cells and tended to depolarize by elevating the external K⁺ concentration. In cells with OR currents, the resting potential was hyperpolarized in association with an increase in conductance. These results suggest that BMMC have a heterogeneous electrophysiological profile that may underlie a variety of ion channels expressed in different phenotypes of mast cells. Activities of both the inwardly rectifying K⁺ channel and the outwardly rectifying Cl^? channel seem to contribute to the regulation of the membrane potential.     

Characterization of the Stretch-activated Chloride Channel in Isolated Human Atrial Myocytes

Macroscopic and unitary currents through stretch-activated Cl⁻ channels were examined in isolated human atrial myocytes using whole-cell, excised outside-out and inside-out configurations of the patch-clamp technique. When K⁺ and Ca²⁺ conductances were blocked and the intracellular Ca²⁺ concentration ([Ca²⁺] _i ) was reduced, application of positive pressure via the pipette activated membrane currents under whole-cell voltage-clamp conditions. The reversal potential of the current shifted by 60 mV per 10-fold change in the external Cl⁻ concentration, indicating that the current was Cl⁻ selective. The current was inhibited by bath application of 4,4′-diisothiocyanatostilbene-2,2′-disulfonic acid (DIDS) and 9-anthracenecarboxylic acid (9-AC). β-Adrenergic stimulation failed to activate a Cl⁻ current. In single channel recordings from outside-out patches, positive pressure in the pipette activated the unitary current with half-maximal activation of 14.7 mm Hg at +40 mV. The current-voltage relationship of single channel activity obtained in inside-out patches was linear in symmetrical Cl⁻ solution with the averaged slope conductance of 8.6 ± 0.7 pS (mean ±sd, n= 10). The reversal potential shift of the channel by changing Cl⁻ concentration was consistent with a Cl⁻ selective channel. The open time distribution was best described by a single exponential function with mean open lifetime of 80.4 ± 9.6 msec (n= 9), while at least two exponentials were required to fit the closed time distributions with a time constant for the fast component of 11.5 ± 2.2 msec (n= 9) and that for the slow component of 170.2 ± 21.8 msec (n= 9). Major changes in the single channel activity in response to pressure were caused by changes in the interburst interval. Single channel activity was inhibited by DIDS and 9-AC in a manner similar to whole-cell configuration. These results suggest that membrane stretch induced by applying pressure via the pipette activated a Cl⁻ current in human atrial myocytes. The current was sensitive to Cl⁻ channel blockers and exhibited membrane voltage-independent bursting opening without sensitive to β-adrenergic stimulation. Received: 21 October 1996/Revised: 17 December 1997