Stimulus-induced currents in isolated taste receptor cells of the larval tiger salamander

Gustatory receptor cells, isolated from the lingual epitheliumof larval tiger salamanders (Ambystoma tigrinum), possess avariety of voltage- and ion-dependent conductances, includinga transient Na⁺ -current (I_Na), a voltage-gated Ca²⁺ -current(I_A). a transient K₊ -current (I_A), a delayed rectifier K⁺ -current(I_K), and a Ca₂₊ -activated K₊ -current (I_K(Ca))- By use ofwhole-cell and excised-patch tight-seal recording techniques,we examined the effects of taste stimuli on the conductancesof taste cells from the tiger salamander. Depolarizing receptorpotentials elicited by NaCl were associated with slow, gradedinward currents which were composed of amiloride-sensitive andtetrodoxin-(TTX)-sensitive components. Potassium chloride producedmaintained inward currents, which usually showed both phasicand tonic components and were only partially blocked by tetraethylammoniumchloride (TEA). Citric and acetic acids elicited slow depolarizationsin taste cells. Under voltage-clamp, acids produced graded inwardcurrents which were composed of two components: one attributableto a transient block of voltage-dependent K₊ -channels and asmaller component which may have resulted from an increasedconductance to cations. Quinine hydrochloride elicited slowdepolarization of taste cells which was associated with a slowlydeveloping maintained inward current under voltage-clamp. Quininesuppressed both voltage-dependent inward and outward currents.In some taste cells, L-arginine elicited small outward currentswhich were attributable to an increase in K₊ conductance. Inother cells, L-arginine produced a decrease in voltage-dependentoutward currents and generated depolarizations associated withinward currents. These results indicate that several independentmechanisms, including amiloride-sensitive Na₊ -channels, andstimulus modulation of voltage-dependent K₊ -channels, are involvedin taste cell responses to chemical stimuli. More than one mechanismis typically present in a single cell. ³Present address: Department of Physiology, Tokyo Medical andDental University, 5-45 Yushima 1-chome, Bunkyo-ku, Tokyo 113,Japan     

Factors controlling the K+ conductance inChara

Summary Previous current/voltage (I/V) investigations of theChara K⁺ state have been extended by increasing the voltage range (up to +200 mV) through blocking the action potential with La³⁺. A region of negative slope was found in theI/V characteristics at positive PD's, similar to that already observed at PD's more negative than the resting level. These decreases in membrane currents at PD's more negative than –150 mV and at PD's close to 0 or positive are thought to arise from the K⁺ channel closure. Both the negative slope regions could be reversibly abolished by 0.1mm K⁺, 20mm Na⁺, more than 10mm Ca²⁺ or 5mm tetraethylammonium (TEA). The K⁺ channels are therefore blocked by TEA, closed by low [K⁺] _o or high [Ca²⁺] _o and are highly selective to K⁺ over Na⁺. With the K⁺ channels closed, the remainingI/V profile was approximately linear over the interval of 400 mV (suggesting a leakage current), but large rectifying currents were observed at PD's more positive than +50 mV. These currents showed a substantial decrease in high [Ca²⁺] _o , sometimes displayed a slight shift to more positive PD's with increasing [K⁺] _o and were unaffected by TEA or changes in [Na⁺] _o . The slope of the linear part of theI/V profile was steeper in low [K⁺] _o than in TEA or high [Na⁺] _o (indicating participation of K⁺, but not Na⁺, in the leak current). Diethylstilbestrol (DES) was employed to inhibit the proton pump, but it was found that the leakage current and later the K⁺ channels were also strongly affected.     

Action of tetraethylammonium on calcium-activated potassium channels in pig pancreatic acinar cells studied by patch-clamp single-channel and whole-cell current recording

Summary The effects of tetraethylammonium ions on currents through high-conductance voltage- and Ca²⁺-activated K⁺ channels have been studied with the help of patch-clamp single-channel and whole-cell current recording on pig pancreatic acinar cells. In excised outside-out membrane patches TEA (1 to 2 mM) added to the bath solution virtually abolishes unitary current activity except at very positive membrane potentials when unitary currents corresponding to a markedly reduced conductance are observed. TEA in a lower concentration (0.2 mM) markedly reduces the open-state probability and causes some reduction of the single-channel conductance. In inside-out membrane patches bath application of TEA in concentrations up to 2 mM has no effect on single-channel currents. At a higher concentration (10 mM) slight reductions in single-channel conductance occur. In whole-cell current recording experiments TEA (1 to 2 mM) added to the bath solution completely suppresses the outward currents associated with depolarizing voltage jumps to membrane potentials of 0 mV and blocks the major part (70 to 90%) of the outward currents even at very positive membrane potentials (30 to 40 mV). In contrast TEA (2 mM) added to the cell interior (pipette solution) has no effect on the outward K⁺ current. Our results demonstrate that TEA in low concentrations (1 to 2 mM) acts specifically on the outside of the plasma membrane to block current through the high-conductance Ca²⁺- and voltage-activated K⁺ channels     

Phe-Met-Arg-Phe-amide Activates a Novel Voltage-dependent K+ Current through a Lipoxygenase Pathway in Molluscan Neurones

The neuropeptide Phe-Met-Arg-Phe-amide (FMRFa) dose dependently (ED₅₀ = 23 nM) activated a K⁺ current in the peptidergic caudodorsal neurones that regulate egg laying in the mollusc Lymnaea stagnalis. Under standard conditions ([K⁺]_o = 1.7 mM), only outward current responses occurred. In high K⁺ salines ([K⁺]_o = 20 or 57 mM), current reversal occurred close to the theoretical reversal potential for K⁺. In both salines, no responses were measured below −120 mV. Between −120 mV and the K⁺ reversal potential, currents were inward with maximal amplitudes at ∼−60 mV. Thus, U-shaped current–voltage relations were obtained, implying that the response is voltage dependent. The conductance depended both on membrane potential and extracellular K⁺ concentration. The voltage sensitivity was characterized by an e-fold change in conductance per ∼14 mV at all [K⁺]_o. Since this result was also obtained in nearly symmetrical K⁺ conditions, it is concluded that channel gating is voltage dependent. In addition, outward rectification occurs in asymmetric K⁺ concentrations. Onset kinetics of the response were slow (rise time ∼650 ms at −40 mV). However, when FMRFa was applied while holding the cell at −120 mV, to prevent activation of the current but allow activation of the signal transduction pathway, a subsequent step to −40 mV revealed a much more rapid current onset. Thus, onset kinetics are largely determined by steps preceding channel activation. With FMRFa applied at −120 mV, the time constant of activation during the subsequent test pulse decreased from ∼36 ms at −60 mV to ∼13 ms at −30 mV, confirming that channel opening is voltage dependent. The current inactivated voltage dependently. The rate and degree of inactivation progressively increased from −120 to −50 mV. The current is blocked by internal tetraethylammonium and by bath- applied 4-aminopyridine, tetraethylammonium, Ba²⁺, and, partially, Cd²⁺ and Cs⁺. The response to FMRFa was affected by intracellular GTPγS. The response was inhibited by blockers of phospholipase A₂ and lipoxygenases, but not by a cyclo-oxygenase blocker. Bath-applied arachidonic acid induced a slow outward current and occluded the response to FMRFa. These results suggest that the FMRFa receptor couples via a G-protein to the lipoxygenase pathway of arachidonic acid metabolism. The biophysical and pharmacological properties of this transmitter operated, but voltage-dependent K⁺ current distinguish it from other receptor-driven K⁺ currents such as the S-current- and G-protein-dependent inward rectifiers.     

Action potentials in primary osteoblasts and in the MG-63 osteoblast-like cell line

Whole-cell patch-clamp analysis revealed a resting membrane potential of −60 mV in primary osteoblasts and in the MG-63 osteoblast-like cells. Depolarization-induced action potentials were characterized by duration of 60 ms, a minimal peak-to-peak distance of 180 ms, a threshold value of −20 mV and a repolarization between the spikes to −45 mV. Expressed channels were characterized by application of voltage pulses between −150 mV and 90 mV in 10 mV steps, from a holding potential of −40 mV. Voltages below −60 mV induced an inward current. Depolarizing voltages above −30 mV evoked two currents: (a) a fast activated and inactivated inward current at voltages between −30 and 30 mV, and (b) a delayed-activated outward current that was induced by voltages above −30 mV. Electrophysiological and pharmacological parameters indicated that hyperpolarization activated strongly rectifying K⁺ (K_ir) channels, whereas depolarization activated tetrodotoxin sensitive voltage gated Na⁺ (Na_v) channels as well as delayed, slowly activated, non-inactivating, and tetraethylammonium sensitive voltage gated K⁺ (K_v) channels. In addition, RT-PCR showed expression of Na_v1.3, Na_v1.4, Na_v1.5, Na_v1.6, Na_v1.7, and K_ir2.1, K_ir2.3, and K_ir2.4 as well as K_v2.1. We conclude that osteoblasts express channels that allow firing of action potentials.     

Ionophore-induced efflux of sodium and potassium ions from sea urchin eggs

The efflux of K⁺ and Na⁺ from sea urchin eggs during Ca²⁺ ionophore A23187-induced parthenogenesis was studied in a K⁺ and Na⁺-free artificial seawater using extracellular ion-specific electrodes. We have probed this model system with monovalent cation-specific ionophores to determine if they affect K⁺ efflux in the unfertilized egg and whether any changes in ionophore sensitivity are observed during egg activation. In 500 mM choline chloride, 10 mM CaCl₂, 50 mM MgCl₂, 10 mM Tris-Cl pH 8.0, A23187 induced a rapid efflux of K⁺ and Na⁺ from the eggs after a short lag time (10–15 seconds). After the burst, the rate of K⁺ efflux remained higher than the pre-activation rate, but was lower than during the burst phase, while the rate of Na⁺ efflux became nearly zero. Monovalent cation-specific ionophores (valinomycin, gramicidin and nigericin) had no effect on K⁺ efflux from the unfertilized eggs in our model system. However, once the egg was activated by A23187, each of the above ionophores caused a prolongation of the burst phase for many minutes. These results show that the unfertilized egg plasma membrane (using our artificial conditions) is not susceptible to the monovalent cation-specific antibiotics and suggest that either the inserted cortical granule membrane or the developing fertilization envelope interacts with these ionophores to cause the change in rate-limiting step for K⁺ efflux observed egg activation.     

Nonselective Suppression of Voltage-gated Currents by Odorants in the Newt Olfactory Receptor Cells

Effects of odorants on voltage-gated ionic channels were investigated in isolated newt olfactory receptor cells by using the whole cell version of the patch–clamp technique. Under voltage clamp, membrane depolarization to voltages between −90 mV and +40 mV from a holding potential (V_h) of −100 mV generated time- and voltage-dependent current responses; a rapidly (< 15 ms) decaying initial inward current and a late outward current. When odorants (1 mM amyl acetate, 1 mM acetophenone, and 1 mM limonene) were applied to the recorded cell, the voltage-gated currents were significantly reduced. The dose-suppression relations of amyl acetate for individual current components (Na⁺ current: I_Na, T-type Ca²⁺ current: I_Ca,T, L-type Ca²⁺ current: I_Ca,L, delayed rectifier K⁺ current: I_Kv and Ca²⁺-activated K⁺ current: I_K(Ca)) could be fitted by the Hill equation. Half-blocking concentrations for each current were 0.11 mM (I_Na), 0.15 mM (I_Ca,T), 0.14 mM (I_Ca,L), 1.7 mM (I_Kv), and 0.17 mM (I_K(Ca)), and Hill coefficient was 1.4 (I_Na), 1.0 (I_Ca,T), 1.1 (I_Ca,L), 1.0 (I_Kv), and 1.1 (I_K(Ca)), suggesting that the inward current is affected more strongly than the outward current. The activation curve of I_Na was not changed significantly by amyl acetate, while the inactivation curve was shifted to negative voltages; half-activation voltages were −53 mV at control, −66 mV at 0.01 mM, and −84 mV at 0.1 mM. These phenomena are similar to the suppressive effects of local anesthetics (lidocaine and benzocaine) on I_Na in various preparations, suggesting that both types of suppression are caused by the same mechanism. The nonselective blockage of ionic channels observed here is consistent with the previous notion that the suppression of the transduction current by odorants is due to the direst blockage of transduction channels.     

Single-Channel Analysis of a Delayed Rectifier K+ Channel in Xenopus Myelinated Nerve

Single-channel properties of a delayed rectifier voltage-gated K⁺ channel (I-type) were investigated in peripheral myelinated axons from Xenopus laevis. Channels activated between −60 and −40 mV with a potential of half-maximal activation, E₅₀, at −47.5 mV. Averaged single-channel currents activated with a time delay at all membrane potentials tested. Time to half-maximal activation decreased from 80 to 1.6 msec between −60 and +40 mV. The channel inactivated monoexponentially with a time constant of 10.9 sec at −40 mV. The time constant of deactivation was 126 msec at −80 mV and 16.9 msec at −110 mV. In symmetrical 105 mm K⁺, the single-channel conductance (γ) was 22 and 13 pS at negative and positive membrane potentials, respectively, at 13–15°C. In Na⁺-rich solution with 2.5 mm extracellular K⁺γ was 7 pS and the reversal potential was negative to −80 mV, indicating a high selectivity for K⁺ over Na⁺. γ depended on extracellular K⁺ concentration (K _D = 19.6 mm) and temperature (Q ₁₀= 1.45). External tetraethylammonium (TEA) reduced the apparent single-channel current amplitude at all potentials tested with a half-maximal inhibiting concentration (IC₅₀) of 0.6 mm. Open probability of the channel, but not single-channel current amplitude was decreased by extracellular dendrotoxin (DTX, IC₅₀= 6.8 nm) and mast cell degranulating peptide (MCDP, IC₅₀= 41.9 nm). In Ringer solution the membrane potential of macroscopic I-channel patches was about −65 mV and depolarized under TEA and DTX. It is concluded that besides their activation during action potentials, I-channels may also stabilize the resting membrane potential. Received: 2 June 1995/Revised: 13 October 1995     

Na+ channels and amiloride-induced noise in the mammalian colon epithelium

(1) The effect of the Na⁺-channel blocker, amiloride, on the short-circuit current carried by Na⁺ was studied with fluctuation analysis, in rabbit descending colon epithelium. (2) In the presence of mucosal amiloride, the power spectrum of the Na⁺-current noise showed a Lorentzian component. When the Na⁺ current was reduced by increasing the blocker concentrations, the Lorentzian plateau decreased and corner frequency increased. Microscopic short-circuit current and current-noise data are evidence for a two-state mechanism of the blocker interaction with the Na⁺ channel. (3) On- and off-rate constants for the blocker-receptor reaction, single-channel currents and Na⁺-channel density were calculated at room temperature and at 37°C. Also, the activation energy for the amiloride-receptor reaction was estimated. The microscopic parameters obtained for the Na⁺ channel in the colon were similar to those found for Na⁺ channels in other tight epithelia.     

Ionic Selectivity and Permeation Properties of Human PIEZO1 Channels

Members of the eukaryotic PIEZO family (the human orthologs are noted hPIEZO1 and hPIEZO2) form cation-selective mechanically-gated channels. We characterized the selectivity of human PIEZO1 (hPIEZO1) for alkali ions: K⁺, Na⁺, Cs⁺ and Li⁺; organic cations: TMA and TEA, and divalents: Ba²⁺, Ca²⁺, Mg²⁺ and Mn²⁺. All monovalent ions permeated the channel. At a membrane potential of -100 mV, Cs⁺, Na⁺ and K⁺ had chord conductances in the range of 35–55 pS with the exception of Li⁺, which had a significantly lower conductance of ~ 23 pS. The divalents decreased the single-channel permeability of K⁺, presumably because the divalents permeated slowly and occupied the open channel for a significant fraction of the time. In cell-attached mode, 90 mM extracellular divalents had a conductance for inward currents carried by the divalents of: 25 pS for Ba²⁺ and 15 pS for Ca²⁺ at -80 mV and 10 pS for Mg²⁺ at -50 mV. The organic cations, TMA and TEA, permeated slowly and attenuated K⁺ currents much like the divalents. As expected, the channel K⁺ conductance increased with K⁺ concentration saturating at ~ 45 pS and the K_D of K⁺ for the channel was 32 mM. Pure divalent ion currents were of lower amplitude than those with alkali ions and the channel opening rate was lower in the presence of divalents than in the presence of monovalents. Exposing cells to the actin disrupting reagent cytochalasin D increased the frequency of openings in cell-attached patches probably by reducing mechanoprotection.     

Effect of Alkali Metal Cations on Slow Inactivation of Cardiac Na+ Channels

Human heart Na⁺ channels were expressed transiently in both mammalian cells and Xenopus oocytes, and Na⁺ currents measured using 150 mM intracellular Na⁺. The kinetics of decaying outward Na⁺ current in response to 1-s depolarizations in the F1485Q mutant depends on the predominant cation in the extracellular solution, suggesting an effect on slow inactivation. The decay rate is lower for the alkali metal cations Li⁺, Na⁺, K⁺, Rb⁺, and Cs⁺ than for the organic cations Tris, tetramethylammonium, N-methylglucamine, and choline. In whole cell recordings, raising [Na⁺]_o from 10 to 150 mM increases the rate of recovery from slow inactivation at −140 mV, decreases the rate of slow inactivation at relatively depolarized voltages, and shifts steady-state slow inactivation in a depolarized direction. Single channel recordings of F1485Q show a decrease in the number of blank (i.e., null) records when [Na⁺]_o is increased. Significant clustering of blank records when depolarizing at a frequency of 0.5 Hz suggests that periods of inactivity represent the sojourn of a channel in a slow-inactivated state. Examination of the single channel kinetics at +60 mV during 90-ms depolarizations shows that neither open time, closed time, nor first latency is significantly affected by [Na⁺]_o. However raising [Na⁺]_o decreases the duration of the last closed interval terminated by the end of the depolarization, leading to an increased number of openings at the depolarized voltage. Analysis of single channel data indicates that at a depolarized voltage a single rate constant for entry into a slow-inactivated state is reduced in high [Na⁺]_o, suggesting that the binding of an alkali metal cation, perhaps in the ion-conducting pore, inhibits the closing of the slow inactivation gate.     

Equilibrium potential for the postsynaptic response in the squid giant synapse

The reversal potential for the EPSP in the squid giant synapse has been studied by means of an intracellular, double oil gap technique. This method allows the electrical isolation of a portion of the axon from the rest of the fiber and generates a quasi-isopotential segment. In order to make the input resistance of this nerve segment as constant as possible, the electroresponsive properties of the nerve membrane were blocked by intracellular injection of tetraethylammonium (TEA) and local extracellular application of tetrodotoxin (TTX). Thus, EPSP''s could be evoked in the isolated segment with a minimal amount of electroresponsive properties. The reversal potential for the EPSP (EEPSP) was measured by recording the synaptic potential or the synaptic current during voltage clamping. The results indicate that EEPSP may vary from +15 to +25 mV, which is more positive than would be expected for a 1:1 conductance change for Na⁺ and K⁺ (approximately -15 mV) and too negative for a pure Na⁺ conductance (⁺40 mV). This latter value (E _Na) was directly determined in the voltage clamp experiments. The results suggest that the synaptic potential is probably produced by a permeability change to Na⁺ to K⁺ in a 4:1 ratio. No change in time-course was observed in the synaptic current at clamp levels of -100 and +90 mV. The implications of a variable ratio for Na⁺-K⁺ permeability in subsynaptic-postsynaptic membranes are discussed.     

Selectivity and permeation of alkali metal ions in K+-channels

Ion conduction in K⁺-channels is usually described in terms of concerted movements of K⁺ progressing in a single file through a narrow pore. Permeation is driven by an incoming ion knocking on those ions already inside the protein. A fine-tuned balance between high-affinity binding and electrostatic repulsive forces between permeant ions is needed to achieve efficient conduction. While K⁺-channels are known to be highly selective for K⁺ over Na⁺, some K⁺ channels conduct Na⁺ in the absence of K⁺. Other ions are known to permeate K⁺-channels with a more moderate preference and unusual conduction features. We describe an extensive computational study on ion conduction in K⁺-channels rendering free energy profiles for the translocation of three different alkali ions and some of their mixtures. The free energy maps for Rb⁺ translocation show at atomic level why experimental Rb⁺ conductance is slightly lower than that of K⁺. In contrast to K⁺ or Rb⁺, external Na⁺ block K⁺ currents, and the sites where Na⁺ transport is hindered are characterized. Translocation of K⁺/Na⁺ mixtures is energetically unfavorable owing to the absence of equally spaced ion-binding sites for Na⁺, excluding Na⁺ from a channel already loaded with K⁺.     

Early after-depolarisations induced by noradrenaline may be initiated by calcium released from sarcoplasmic reticulum

We investigated the effect of 10^–8 M noradrenaline (NA) on [Ca²⁺], and electrical activity of single myocytes of guinea-pig ventricular myocardium loaded with Indo 1-AM. Membrane potential was recorded by means of the patch electrode and patch amplifier set to the current clamp mode. Cells were stimulated at a rate of 30/min by 3 ms pulses of the current injected through the recording electrode. Superfusion of NA resulted in slight shortening of action potentials (APs), increase in rate of rise and amplitude of the respective Ca²⁺ transients, and appearance of secondary Ca²⁺ transients of two kinds: 1. appearing before repolarisation of AP and decay of the preceding Ca²⁺ transient were completed and 2. appearing between the APs. We named them early after-transients (EAT) and delayed after-transients (DAT), respectively. Without any additional intervention EATS caused some prolongation of APs duration and DATs resulted in subthreshold delayed after-depolarisations (DADS). When sarcolemmal K⁺ conductance was decreased by tetraethylammonium (TEA) in the patch electrode or 20 M BaCl₂ in the Tyrode solution, EATs initiated early after depolarizations (EADs) and DATs initiated suprathreshold DADs triggering full-sized APs. Superfusion of 30.0 mM Na⁺ (replaced with LiCl) resulted in reduction of AP duration by -70% and appearance of DATs. Also, the frequent multiple oscillations of Ca ²⁺ concentration were often observed. Neither DATs nor the oscillations had any affect on electrical activity of the cells. Their electrogenicity could not be increased by TEA or 20.0 M Ba²⁺. EATs and DATs and their respective EADs and DADs could not be initiated by NA or low Na⁺ superfusion in the cells pretreated with 2 × 10^–7 M thapsigargin, a selective blocker of Ca²⁺-ATPase of sarcoplasmic reticulum (SR). We conclude that in contrast to the current hypothesis, EADs can be initiated by Ca²⁺ released early in the cardiac cycle from the overloaded SR, and that electrogenicity of both types of Ca²⁺ oscillations critically depends on the sarcolemmal K⁺ conductance.     

The ACh-induced whole-cell currents in sheep parotid secretory cells. Do BK channels really carry the ACh-evoked whole-cell K+ current?

As in other salivary glands, the secretory cells of the sheep parotid have a resting K⁺ conductance that is dominated by BK channels, which are activated by acetylcholine (ACh) and are blocked by tetraethylammonium (TEA). Nevertheless, perfusion studies indicate that TEA does not inhibit ACh-evoked fluid secretion or K⁺ efflux from intact sheep parotid glands. In the present study, we have used whole-cell patch clamp techniques to show that ACh activates K⁺ and Cl^– conductances in sheep parotid secretory cells by increasing intracellular free Ca²⁺, and we have compared the blocker sensitivity of the ACh-evoked whole-cell K⁺ current to the previously reported blocker sensitivity of the BK channels seen in these cells.The ACh-induced whole-cell K⁺ current was not blocked by TEA (10 mmol/l) or verapamil (100 mol/l), both of which block the resting K⁺ conductance and inhibit BK channels in these cells. Quinine (1 mmol/l) and quinidine (1 mmol/l), although only weak blockers of the resting K⁺ conductance, inhibited the ACh-evoked current at 0 mV (K⁺ current), by 68% and 78%, respectively. 4-Aminopyridine (10 mmol/l) partially inhibited the ACh-induced K⁺ current and caused it to fluctuate. It also caused the resting membrane currents to fluctuate, possibly by altering cytosolic free Ca²⁺. Ba²⁺ (100 mol/l), a blocker of the inwardly rectifying K⁺ conductance in sheep parotid cells, had no effect on the ACh-induced K⁺ current.We conclude that the ACh-induced K⁺ conductance in sheep parotid cells is pharmacologically distinct from both the outwardly rectifying (BK) K⁺ conductance and the inwardly rectifying K⁺ conductance seen in unstimulated cells. Given that in vitro perfusion and K⁺ efflux studies on other salivary glands in which BK channels dominate the resting conductance (e.g., the rat mandibular, rat parotid and mouse mandibular glands) have revealed an insensitivity to TEA, suggesting that BK channels do not carry the ACh-evoked K⁺ current, we propose that BK channels do not contribute substantially to the K⁺ current evoked by ACh in the secretory cells of most salivary glands.This project was supported by the Australian Research Council. We thank Dr. N. Sangster, Dr. J. Rothwell and Mr. R. Murphy for giving us access to their sheep.     

Anomalous Effect of Permeant Ion Concentration on Peak Open Probability of Cardiac Na+ Channels

Human heart Na⁺ channels were expressed transiently in both mammalian cells and Xenopus oocytes, and Na⁺ currents measured using 150 mM intracellular Na⁺. Decreasing extracellular permeant ion concentration decreases outward Na⁺ current at positive voltages while increasing the driving force for the current. This anomalous effect of permeant ion concentration, especially obvious in a mutant (F1485Q) in which fast inactivation is partially abolished, is due to an alteration of open probability. The effect is only observed when a highly permeant cation (Na⁺, Li⁺, or hydrazinium) is substituted for a relatively impermeant cation (K⁺, Rb⁺, Cs⁺, N -methylglucamine, Tris, choline, or tetramethylammonium). With high concentrations of extracellular permeant cations, the peak open probability of Na⁺ channels increases with depolarization and then saturates at positive voltages. By contrast, with low concentrations of permeant ions, the open probability reaches a maximum at approximately 0 mV and then decreases with further depolarization. There is little effect of permeant ion concentration on activation kinetics at depolarized voltages. Furthermore, the lowered open probability caused by a brief depolarization to +60 mV recovers within 5 ms upon repolarization to −140 mV, indicative of a gating process with rapid kinetics. Tail currents at reduced temperatures reveal the rapid onset of this gating process during a large depolarization. A large depolarization may drive a permeant cation out of a site within the extracellular mouth of the pore, reducing the efficiency with which the channel opens.     

Novel actions of ryanodine and analogues—Perturbers of potassium channels

The effects of ryanodine, 9,21-didehydroryanodine and 9,21-didehydroryanodol on two types of K⁺ channel (a maxi, Ca²⁺-activated, 170 pS channel (BK channel) and an inward rectifier, stretch-sensitive channel of 35 pS conductance (IK channel) found in the plasma membrane of locust skeletal muscle have been investigated. 10^–9M-10^–5M ryanodine irreversibly induced a dose-dependent reduction of the reversal potential (V_rev) of the currents of both channels, i.e. from 60 mV in the absence of the alkaloid to 15 mV for 10^–5M ryanodine, measured under physiologically normal K⁺ and Na⁺ gradients. In both cases the change in the ionic selectivity was Ca²⁺-independent. 9,21-didehydroryanodine and 9,21-didehyroryanodol also reduced V_rev, but only to 35 mV during application of 10^–5M of these compounds. Additionally, 9,21-didehydroryanodine reversibly diminished the conductances of the two K⁺ channels. To test the hypothesis that ryanoids increase Na⁺ permeability by enlarging the K⁺ channels, the channels were probed with quaternary ammonium ions during ryanoid application. When applied to the cytoplasmic face of inside-out patches exised from locust muscle membrane, TEA blocked the K⁺ channels in a voltage-dependent fashion. The dissociation constant (K_d(0)) for TEA block of the IK channel was reduced from 44 mM to 1 mM by 10^–7 M ryanodine, but the voltage-dependence of the block was unaffected. Qualitatively similar data were obtained for the BK channel. Ryanodine had no effect on the K_d for cytoplasmically-applied TMA. However, the voltage-dependence for TMA block was increased for both K⁺ channels, from 0.47 to 0.8 with 10^–6M ryanodine. The effects of ryanodine on TEA and TMA block support the hypothesis that ryanodine enlarges the K⁺ channels so as to facilitate permeation of partially hydrated Na⁺ ions.     

Persistent Na+ influx drives L-type channel resting Ca2+ entry in rat melanotrophs

Rat melanotrophs express several types of voltage-gated and ligand-gated calcium channels, although mechanisms involved in the maintenance of the resting intracellular Ca²⁺ concentration ([Ca²⁺]_i) remain unknown. We analyzed mechanisms regulating resting [Ca²⁺]_i in dissociated rat melanotrophs by Ca²⁺-imaging and patch-clamp techniques. Treatment with antagonists of L-type, but not N- or P/Q-type voltage-gated Ca²⁺ channels (VGCCs) as well as removal of extracellular Ca²⁺ resulted in a rapid and reversible decrease in [Ca²⁺]_i, indicating constitutive Ca²⁺ influx through L-type VGCCs. Reduction of extracellular Na⁺ concentration (replacement with NMDG⁺) similarly decreased resting [Ca²⁺]_i. When cells were champed at –80 mV, decrease in the extracellular Na⁺ resulted in a positive shift of the holding current. In cell-attached voltage-clamp and whole-cell current-clamp configurations, the reduction of extracellular Na⁺ caused hyperpolarisation. The holding current shifted in negative direction when extracellular K⁺ concentration was increased from 5 mM to 50 mM in the presence of K⁺ channel blockers, Ba²⁺ and TEA, indicating cation nature of persistent conductance. RT-PCR analyses of pars intermedia tissues detected mRNAs of TRPV1, TRPV4, TRPC6, and TRPM3-5. The TRPV channel blocker, ruthenium red, shifted the holding current in positive direction, and significantly decreased the resting [Ca²⁺]_i. These results indicate operation of a constitutive cation conductance sensitive to ruthenium red, which regulates resting membrane potential and [Ca²⁺]_i in rat melanotrophs.     

Sodium and Calcium Inward Currents in Freshly Dissociated Smooth Myocytes of Rat Uterus

Freshly dissociated myocytes from nonpregnant, pregnant, and postpartum rat uteri have been studied with the tight-seal patch-clamp method. The inward current contains both I_Na and I_Ca that are vastly different from those in tissue-cultured material. I_Na is abolished by Na⁺-free medium and by 1 μM tetrodotoxin. It first appears at ∼−40 mV, reaches maximum at 0 mV, and reverses at 84 mV. It activates with a voltage-dependent τ of 0.2 ms at 20 mV, and inactivates as a single exponential with a τ of 0.4 ms. Na⁺ conductance is half activated at −21.5 mV, and half inactivated at −59 mV. I_Na reactivates with a τ of 20 ms. I_Ca is abolished by Ca²⁺-free medium, Co²⁺ (5 mM), or nisoldipine (2 μM), and enhanced in 30 mM Ca²⁺, Ba²⁺, or BAY-K 8644. It first appears at ∼−30 mV and reaches maximum at +10 mV. It activates with a voltage-dependent τ of 1.5 ms at 20 mV, and inactivates in two exponential phases, with τ''s of 33 and 133 ms. Ca²⁺ conductance is half activated at −7.4 mV, and half inactivated at −34 mV. I_Ca reactivates with τ''s of 27 and 374 ms. I_Na and I_Ca are seen in myocytes from nonpregnant estrus uteri and throughout pregnancy, exhibiting complex changes. The ratio of densities of peak I_Na/I_Ca changes from 0.5 in the nonpregnant state to 1.6 at term. The enhanced role of I_Na, with faster kinetics, allows more frequent repetitive spike discharges to facilitate simultaneous excitation of the parturient uterus. In postpartum, both currents decrease markedly, with I_Na vanishing from most myocytes. Estrogen-enhanced genomic influences may account for the emergence of I_Na, and increased densities of I_Na and I_Ca as pregnancy progresses. Other influences may regulate varied channel expression at different stages of pregnancy.