The effect of the tetraethylammonium ion on the delayed currents of frog skeletal muscle

Neuromuscular transmission of pectoral fin muscles of the goldfish Carassius auratus

The electrical properties and neuromuscular transmission of white and red fibers of pectoral fin muscles of the goldfish Carassius auratus were studied using an intracellular recording technique. The pectoral fin muscles consist mainly of white and red fibers. Almost all of white fibers elicited action potentials with overshoot by direct stimulation, but graded responses appeared in the red fibers. However, overshooting action potentials were often recorded from the red fibers in saline containing 20 microM tetraethylammonium (TEA) chloride. In response to single nerve stimulations, excitatory (EJPs) and inhibitory junction potentials (IJPs) were obtained from both white and red fibers in common. Both EJPs and IJPs were blocked completely or partially by d-tubocurarine, a nicotinic acetylcholine (ACh) receptor antagonist. Nicotine, a nicotinic ACh receptor agonist, and oxotremorine, a muscarinic ACh receptor agonist, depolarized both fiber types. The results suggest that white and red fibers receive double innervation from excitatory and inhibitory nerves, and have nicotinic and muscarinic ACh receptors. In the resting muscle, miniature excitatory junction potentials were generated spontaneously in both white and red fibers. Occasionally, miniature inhibitory junction potentials were recorded from the red fibers. The results indicate that the release of both excitatory and inhibitory transmitters is quantal in nature.

Tonotopic map of potassium currents in chick auditory hair cells using an intact basilar papilla

The avian basilar papilla is tonotopically organized such that hair cells along the sensory epithelium respond best to acoustic stimulation at differing frequencies. This specificity arises due to the mechanics of the cochlea itself and intrinsic electrical properties of the hair cells. Tall hair cells show membrane voltage oscillations in response to step current injection that may allow cells to act as electrical resonators, boosting the response at the resonant frequency. These oscillations and the underlying currents have been studied in enzymatically isolated cells. This study uses a whole chick (Gallus domesticus) basilar papilla preparation where the entire epithelium and its afferent connections are intact. With this preparation, a map of changes in potassium currents of tall hair cells was produced. All cells recorded from expressed two K+ currents, a calcium-activated K+ current, I(K(Ca)), and a voltage-activated K+ current, I(K). Also, apical cells expressed an inward rectifier K+ current, I(IR). The amplitude of total outward current increases in a gradient along the tonotopic axis. Pharmacological blockers were used to separate the outward K+ currents. These experiments showed that both currents individually increase in magnitude along a gradient from apex to base. Finally, measurements of oscillation frequency in response to current steps suggest a discontinuous change in the electrical resonances at about 33% from the apex. This study demonstrates a new preparation to study the electrical properties of hair cells in more detail along the tonotopic axis of the chick basilar papilla.

Inotrophic effects of the K(+) channel blocker TEA on dystrophic (mdx and dy/dy) mouse diaphragm

K(+) channels regulate diaphragm resting membrane potential and action potential duration, and hence force. Certain blockers of these channels, e.g. tetraethylammonium (TEA), increase twitch force of normal diaphragm. To further address whether these agents may be useful in the treatment of diaphragm weakness, studies examined the effects of TEA on force of overtly diseased muscle. Diaphragm from two mouse models of muscular dystrophy (mdx and dy/dy) was studied in vitro. Diaphragm from both models was significantly weaker than diaphragm from control animals. TEA (10 mM) increased twitch force of both mdx diaphragm (P<0.005) and dy/dy diaphragm (P<0.0005), as well as force of diaphragm from non-diseased animals. The percent force increase of mdx diaphragm was at least as great as that of non-diseased muscle (15.3 vs 9.2%, P=0.14), and the percent force increase of dy/dy diaphragm was significantly greater than that of non-diseased muscle (22.7 vs 10.2%, P<0.02). Absolute force increases normalized for cross-sectional area were comparable for healthy and diseased diaphragm, however. These findings indicate that TEA increases force of both dystrophin-deficient and merosin-deficient dystrophic mouse diaphragm muscle.

Transient outward K+ channels in vesicles derived from frog skeletal muscle plasma membranes

Whole-cell voltage-clamp experiments were performed in vesicles derived from frog skeletal muscle plasma membranes. Capacitance measurements showed that these vesicles lack invaginations. In solutions containing K+, transient outward currents with reversal potentials close to EK were recorded with a maximum potassium conductance of 0.3 mS/cm2. These currents inactivated in a voltage-dependent manner with a time constant of decay that reached a limiting value of 26 ms at large depolarizations. The steady-state inactivation reached half-maximum values at -66 mV. Transient currents were completely blocked with 5 mM 4-aminopyridine. Single-channel recordings made in inside-out excised patches from the vesicles had ensemble averages with characteristics similar to those of the macroscopic currents, although with significantly faster inactivation time constants. The single-channel chord conductance was 21 pS when the pipette and bath solutions contained 2.5 mM and 120 mM KCl, respectively. It is concluded that these vesicles contain potassium channels that are very similar to A channels found in neurons and other cells.

Convertible modes of inactivation of potassium channels in Xenopus myocytes differentiating in vitro

1. Voltage-dependent inactivating single-channel potassium currents were recorded in cell-attached and inside-out patches from embryonic Xenopus myocytes differentiating in culture. 2. Channels with rapid inactivation (time constants < 25 ms) and with slow inactivation (time constants > 80 ms) recorded after one day in vitro appear to belong to two functionally different classes. Rapidly and slowly inactivating channels show steady-state inactivation with potentials of half-inactivation of -74 +/- 7 and -44 +/- 9 mV. They exhibit voltage-dependent activation, with times to half-maximal activation of 0.79 +/- 0.09 and 1.17 +/- 0.22 ms when stepped from -120 to +40 mV. Rapidly inactivating channels also have a lower open probability than slowly inactivating ones. The channels have similar conductances of 23 +/- 6 and 17 +/- 4 pS and extrapolated reversal potentials close to the potassium equilibrium potential. 3. In cell-attached patches, inactivation behaviours of channels with rapid or slow inactivation do not change during recording. After patch excision, rapidly inactivating channels usually switch to a slow inactivation mode. Slowly inactivating channels derived from rapidly inactivating channels after patch excision retain their conductance and extrapolated reversal potential, but are not distinguishable from native slowly inactivating channels with respect to steady-state inactivation, activation and inactivation times, as well as open probabilities. 4. The change in inactivation behaviour of rapidly inactivating channels after patch excision is reversed by application of reduced dithiothreitol (DTT). In contrast, channels with slow inactivation in the cell-attached mode do not change in to rapidly inactivating channels after application of DTT in the excised configuration, suggesting that these channels belong to a structurally different class. 5. Frequent observation of superposing channel openings indicates clustering of inactivating potassium channels in the myocyte membrane, since many patches lack channel activity. Clustering does not depend on the presence of differentiating neurones. 6. Channels with rapid inactivation increase 6-fold in density during the first day in culture in the presence of neurones; channel density decreases in their absence. Channels with slow inactivation increase 2-fold in density in the presence or absence of differentiating neurones during this period. 7. Channels with rapid or slow inactivation in cell-attached membrane belong to functionally distinct classes that are developmentally regulated differently. Reversible changes from rapid to slow inactivation mode after patch excision suggest that the channels may be structurally related.

Characteristics of multiple voltage-activated K+ currents in acutely dissociated chick ciliary ganglion neurones

1. The properties of voltage-activated K+ currents were examined using whole-cell recording techniques in acutely isolated chick ciliary ganglion neurones. 2. Application of depolarizing voltage pulses from a holding potential of -60 mV evoked sustained outward currents that inactivated with time constants of hundreds of milliseconds (IDR). Bath application of 10 mM tetraethylammonium (TEA) caused a 70-90% reduction of IDR. Application of depolarizing voltage steps from a holding potential of -120 mV revealed a second class of TEA-resistant outward currents. These currents activated quickly but inactivated completely within tens of milliseconds (IA). IA activated at more negative command potentials than IDR. However, IDR exhibited a steeper voltage dependence of activation than IA. 3. The midpoint of the steady-state inactivation curve of IA was between -95 and -110 mV. By contrast the midpoint of the steady-state inactivation curve of IDR was between -80 and -90 mV. It was not possible to produce a complete inactivation of IDR using prepulses of up to 2 s duration. 4. The time course of IA inactivation could only be fitted with double-exponential curves with time constants of 5-18 ms and 30-60 ms at membrane potentials positive to -30 mV. The inactivation of IA was slower at more positive membrane potentials because of a greater contribution of the long time constant. The individual time constants were not markedly voltage dependent. 5. Bath application of 5 mM 4-aminopyridine (4-AP) caused a 70-100% block of IA whereas 1 mM 4-AP was ineffective. Bath application of 560 nM alpha-dendrotoxin (DTX) produced a 50-70% reduction of IA, but application of 280 nM DTX had no effect on IA. 6. Application of 1 mM 4-AP produced a reversible 55-80% block of IDR measured at the end of a 500 ms depolarizing pulse. The 4-AP-sensitive components of IDR activated rapidly and exhibited a gradual inactivation with continued depolarization. The 4-AP-resistant components of IDR activated much more slowly and showed very little tendency to inactivate. Significant blockade of IDR was produced by 10 microM 4-AP. 7. The decay of IDR tail currents could only be fitted with double exponential curves with time constants of 3-6 and 40-60 ms, respectively. The fast and slow components of the tail currents behaved independently with respect to the duration of the depolarizing voltage step. 8. Application of 1 mM 4-AP eliminated the fast, but not the slow component of IDR tail currents.(ABSTRACT TRUNCATED AT 400 WORDS)

Conductances contributing to the action potential of Sternopygus electrocytes

In Sternopygus macrurus, electrocyte action potential duration determines the electric organ discharge pulse duration. Since the electric organ discharge is a sexually-dimorphic behavior under the control of steroid hormones, and because electrocyte action potential durations can range from 3-14 ms, the electrocytes provide a unique opportunity to study how sex steroids regulate membrane excitability. In this study, the voltage-sensitive ionic currents of electrocytes were identified under current- and voltage-clamp as a prelude to further studies on their regulation by sex steroid hormones. Bath application of TTX completely abolished the spike and eliminated an inward current under voltage clamp, indicating that the action potential is due primarily to a sodium current. Calcium-free saline had no effect on spike waveform or voltage-clamp currents, indicating that neither calcium nor calcium-dependent currents contribute to the action potential. Application of potassium channel blocking agents, such as tetraethylammonium and cesium ions, caused changes in the spike which, together with voltage-clamp results, indicate the presence of two potassium currents: an inward rectifier and a classical delayed rectifier. In addition, these cells have a large, presumably voltage-insensitive, chloride current. Differences in one or more of these currents could be responsible for the range of action potential durations found in these cells and for the steroid-mediated changes in spike duration.

Activation of a slow outward current by the calcium released during contraction of cultured rat skeletal muscle cells

A slow outward current, activated during depolarization, which induced contraction in whole-cell patch-clamped rat skeletal muscle cells in primary culture [10], was extensively characterized in the present study. This current, Io, was simultaneously recorded with the contraction as a slow outward current during the test pulse, and a slow outward bell-shaped tail after repolarization. Io never appeared below the threshold potential for contraction, and the tail amplitude displayed a similar evolution with peak contraction amplitude as a function of membrane potential. This feature is consistent with the fact that Io was suppressed when contraction was blocked by 5 microM nifedipine [10], and it suggests that Io was dependent on calcium released during contraction. This was confirmed by the fact that the presence of 10 mM EGTA in the patch pipette prevented the development of both contraction and Io, and that Io could be activated during caffeine-induced contractures without applying depolarizations. Io could be carried by K+ or Cs+ ions, but not by Na+. The pharmacology of Io was different from that of Ca(2+)-dependent BK and SK channels, since it was resistant to tetraethylammonium (135 mM), charybdotoxin (25 nM) and apamin (50 nM). Io was also insensitive to 4-aminopyridine (1 mM) but blocked by 5 mM Ba2+ without change to contraction. It was concluded that rat cultured myoballs exhibit a Cs+ permeation through an atypical K+ channel type, which is activated by the calcium released during contraction.

Developmental sequence of expression of voltage-dependent currents in embryonic Xenopus laevis myocytes

Although the development of several of the voltage-dependent currents in embryonic amphibian myocytes has been described, the overall muscle electrical development, particularly the relative times of expression of different voltage-dependent currents, has not been addressed in a single study under one set of conditions. We have found that, in mesoderm isolated and cultured from neurula stage embryos, myocytes are identifiable before they express voltage-gated currents. These ionic currents are absent from all Xenopus mesodermal cells during the late gastrula/early neurula stages of embryonic development. At about the time of first somite segregation an inward rectifier K+ current is expressed in some myocytes, followed within 2 hr by a delayed rectifier K+ current. The density of both currents increases fourfold over the next 24 hr in culture. A Na+ current is not expressed in large numbers of myocytes until late in this culture period, at about the time that a slow Ca2+ current appears. Under our culture conditions the myocytes have a very low chloride conductance. A fast inactivating component to the outward K+ current is expressed in all myocytes by 24 hr in culture. In some experiments we dissociated embryos at later times and made recordings when all previously isolated myocytes expressed currents. In the late dissociations, most myocytes did not express currents, but developed them after a short period in culture. Because we have evidence that in vivo development is more closely approximated by the early dissociations, these results suggest that dissociation causes some degree of dedifferentiation.

Developmental changes in delayed rectifier K+ currents in the muscular- and neural-type blastomere of ascidian embryos

1. Developmental changes in the amplitude, kinetic properties, tetraethyl-ammonium (TEA) sensitivity, and ion selectivity of the delayed rectifier K+ currents were investigated in differentiating muscular-type (M) and neural-type (N) blastomeres isolated from the early cleavage-arrested ascidian embryos, using conventional two-microelectrode voltage clamp techniques. 2. No voltage-sensitive outward K+ currents were found in either type of blastomere during the first 35 h of development at 9 degrees C. Thereafter the delayed rectifier K+ current became apparent. The peak amplitude of the K+ current in the M-blastomere increased abruptly from 50 to 60 h and tended to plateau after 60 h, while in the N-blastomere it continued to increase after initial emergence at around 35 h. 3. The threshold potential level of the K+ current in the M-blastomere was initially about -10 mV in a standard external solution (1 mM-K+ solution), but shifted towards the hyperpolarized direction until it reached a steady level at 45 h after fertilization. At the fully differentiated stages, the threshold was around -32 mV and -26 mV in the M- and N-blastomeres, respectively. 4. Throughout development, the reversal potential of the tail current changed with the external K+ concentration in both M- and N-blastomeres as expected for a K(+)-electrode. There was no significant difference in the selectivity ratios for the K+ channel between the two types of blastomeres. The relative selectivities were K+ (1.000): Rb+ (0.774): NH4+ (0.122): Na+ (0.074) and K+ (1.000): Rb+ (0.724): NH4+ (0.155): Na+ (0.074) in the M- and N-blastomeres, respectively. 5. Modified Scatchard plots of TEA-sensitivity data indicated a one-to-one reaction between TEA and the K+ channel. These plots revealed the presence of TEA-resistant K+ channels in addition to TEA-sensitive K+ channels in the M-blastomere, but revealed only TEA-sensitive K+ channels in the N-blastomere. The dissociation constant (Ki) values of these three types of K+ channel did not change during development. In the M-blastomere, the Ki of the TEA-sensitive K+ channel was 1.29 +/- 0.05 mM (mean +/- S.E.M., n = 31) and that of the TEA-resistant K+ channel was 1.4 +/- 0.1 M (mean +/- S.E.M., n = 31) at a test potential of 45 mV. The Ki value of the neural-type K+ current was 1.38 +/- 0.03 mM (mean +/- S.E.M., n = 20) at 45 mV.(ABSTRACT TRUNCATED AT 400 WORDS)

ATP-dependent potassium channels of muscle cells: their properties, regulation, and possible functions

ATP-dependent potassium channels are present at high density in the membranes of heart, skeletal, and smooth muscle and have a low Popen at physiological [ATP]i. The unitary conductance is 15-20 pS at physiological [K+]o, and the channels are highly selective for K+. Certain sulfonylureas are specific blockers, and some K channel openers may also act through these channels. KATP channels are probably regulated through the binding of ATP, which may in turn be regulated through changes in the ADP/ATP ratio or in pHi. There is some evidence for control through G-proteins. The channels have complex kinetics, with multiple open and close states. The main effect of ATP is to increase occupancy of long-lived close states. The channels may have a role in the control of excitability and probably act as a route for K+ loss from muscle during activity. In arterial smooth muscle they may act as targets for vasodilators.

Potassium currents in hair cells isolated from the cochlea of the chick

1. Potassium currents were characterized in tall hair cells of the chick's cochlea. Outward potassium currents were found to flow through two distinct classes of channels. 2. Individual hair cells were isolated from 200 microns long segments of the apical half of the chick's cochlea. Whole-cell voltage-clamp and current-clamp recordings were made from these cells. 3. Voltage responses to injected current ranged from high-frequency (100-250 Hz) oscillations in some cells, to slowly repetitive Ca2+ action potentials or slow oscillations (5-20 Hz) in others. 4. Ionic currents recorded in voltage clamp also varied in different hair cells. Cells with high-frequency voltage oscillations had rapidly activating Ca2(+)-dependent outward K+ current, IK(Ca). Cells that generated action potentials had slow delayed rectifier outward K+ current, IK, and inward rectifier current, IIR. All hair cells had inward Ca2+ current. 5. IK(Ca) activated positive to -45 mV. Tail currents reversed at the K+ equilibrium potential. This current was eliminated in Ca2(+)-free solutions, or when exposed to 10 mM-TEA. This outward current was fully activated within 1-3 ms at 0 mV. The whole-cell current was noisy and ensemble variance analysis suggested a single-channel conductance of 63 pS near 0 mV. 6. IK activated positive to -50 mV. Tail currents reversed at the K+ equilibrium potential. This current was not eliminated in Ca2(+)-free solutions, and was relatively resistant to external TEA. IK activated slowly, reaching peak values in 10-20 ms at 0 mV. This current showed little variance and the average single-channel conductance based on macroscopic noise near 0 mV was 8 pS. 7. External tetraethylammonium (TEA) or Ca2(+)-free saline eliminated the high-frequency voltage oscillations seen in many basal cells. In contrast TEA had little effect on slow action potentials (or low-frequency oscillations) seen in cells with IK. 8. IK(Ca) was prominent in hair cells originating 1.0-2.0 mm from the cochlear apex. IK and IIR dominated the membrane conductance of tall hair cells originating within 0.5 mm of the cochlear apex. 9. The frequency of voltage oscillation in apical cells was temperature-dependent, nearly doubling for each 10 degrees C rise in temperature. 10. IIR activated at membrane potentials negative to -75 mV. The average time constant of activation at -100 mV was 2 ms. Tail currents reversed at the K+ equilibrium potential and did not depend on the external Na+ concentration. IIR was blocked by 5 mM-Cs+ or 100 microM-Ba2+ in the external saline.

Potassium channel activity in sarcolemmal vesicles formed from skeletal muscle fibres of normal and dystrophic mice

Sarcolemmal vesicles were produced from adult mouse extensor digitorum longus muscle (EDL) by treating swollen muscle fibres with collagenase. Vesicles formed from dystrophic (C57BL/6J dy/dy) and phenotypically normal animals were patch clamped and the single channel activity was recorded. Three types of K+ channel were observed in excised patches taken from normal and dystrophic muscle. A large conductance (300 pS) Ca2(+)-dependent K+ channel (KCa) was the most frequently observed of the K+ channels in both types of muscle preparation. In a number of patches taken from dystrophic muscle the open probability-voltage relationship for the KCa channel was markedly different from that in normal muscle, suggesting a possible reduction in Ca2+ sensitivity. An ATP-sensitive K+ channel (90 pS) was common to both normal and dystrophic muscle vesicles and was present in a large number of patches. An inwardly rectifying K+ channel (40 pS) was also observed in both types of sarcolemmal vesicles. The properties of all three K+ channels types were broadly consistent with other observations of skeletal muscle K+ channels, though all had higher conductances than had previously been noted in other species.

Optical evidence for a chloride conductance in the T-system of frog skeletal muscle

T-system action potentials were recorded optically from intact frog skeletal muscle fibers stained with the non-penetrating potentiometric dye NK-2367. The effect of chloride removal on the falling phase of the radially propagating tubular action potential was studied to determine whether a chloride conductance located in the T-system membranes contributes to tubular repolarization during activity. Our results show that, in chloride-free Ringer, repolarization of the tubular action potential is significantly slowed. Moreover, the late phase of tubular repolarization is characterized by a large after-potential, which is highly temperature-dependent and appears as a secondary peak above 10 degrees C. The optical data were compared with predicted T-system action potentials generated from a radial cable equivalent circuit model of the T-system, in which the effects of a distributed tubular leak conductance were tested. Results of this analysis are consistent with the proposal that some of the outward repolarization current during the T-system action potential is drawn across a chloride conductance located in the T-system membranes.

The depressing effect of tetracaine and ryanodine on the slow outward current correlated with that of contraction in voltage-clamped frog muscle fibres

The effects of tetracaine (10-50 microM) and ryanodine (0.1-10 microM) were tested on the slow outward K+ current (Iso) and the mechanical tension of isolated frog muscle fibres in a voltage-clamp device (double mannitol-gap) connected to a mechanoelectric transducer. In the concentration range tested, both drugs induced a simultaneous inhibition of tension and current. In all cases the effect on tension was twice that on current. The tetracaine-induced current and tension blocks were fully reversible and dose-dependent. In contrast the ryanodine effects on current and tension were not reversible and did not exhibit a dose dependence except for the delay before the onset of the response, which was shortened when the concentration was raised. Linear regression analysis of the time-dependent and dose-dependent effects of both drugs indicated a strong correlation between the decreases in tension and current. It is concluded that the slow outward current is partly under the control of the Ca2+ release from sarcoplasmic reticulum during contraction.

State-dependent inactivation of K+ currents in rat type II alveolar epithelial cells

Inactivation of K+ channels responsible for delayed rectification in rat type II alveolar epithelial cells was studied in Ringer, 160 mM K-Ringer, and 20 mM Ca-Ringer. Inactivation is slower and less complete when the extracellular K+ concentration is increased from 4.5 to 160 mM. Inactivation is faster and more complete when the extracellular Ca2+ concentration is increased from 2 to 20 mM. Several observations suggest that inactivation is state-dependent. In each of these solutions depolarization to potentials near threshold results in slow and partial inactivation, whereas depolarization to potentials at which the K+ conductance, gK, is fully activated results in maximal inactivation, suggesting that open channels inactivate more readily than closed channels. The time constant of current inactivation during depolarizing pulses is clearly voltage-dependent only at potentials where activation is incomplete, a result consistent with coupling of inactivation to activation. Additional evidence for state-dependent inactivation includes cumulative inactivation and nonmonotonic from inactivation. A model like that proposed by C.M. Armstrong (1969. J. Gen. Physiol. 54: 553-575) for K+ channel block by internal quaternary ammonium ions accounts for most of these properties. The fundamental assumptions are: (a) inactivation is strictly coupled to activation (channels must open before inactivating, and recovery from inactivation requires passage through the open state); (b) the rate of inactivation is voltage-independent. Experimental data support this coupled model over models in which inactivation of closed channels is more rapid than that of open channels (e.g., Aldrich, R.W. 1981. Biophys. J. 36:519-532). No inactivation results from repeated depolarizing pulses that are too brief to open K+ channels. Inactivation is proportional to the total time that channels are open during both a depolarizing pulse and the tail current upon repolarization; repolarizing to more negative potentials at which the tail current decays faster results in less inactivation. Implications of the coupled model are discussed, as well as additional states needed to explain some details of inactivation kinetics.

Chloride action potentials and currents in embryonic skeletal muscle of the chick

Chloride-dependent action potentials were elicited from embryonic skeletal muscle fibers of the chick during the last week of in ovo development. The duration of the action potentials was extremely long (greater than 8 sec). The action potentials were reversibly blocked by the stilbene derivative, SITS, a specific blocker of chloride permeability. Using patch clamp pipettes, in which the intracellular chloride concentration was controlled and with other types of ion channels blocked, the membrane potential at the peak of the action potential closely coincided with the chloride equilibrium potential calculated from the Nernst equation. These data indicate that activation of a chloride-selective conductance underlies the long duration action potential. The occurrence of the chloride-dependent action potential was found to increase during embryonic development. The percentage of fibers that displayed the action potential increased from approximately 20% at embryonic day 13 to approximately 70% at hatching. Chloride-dependent action potentials were not found in adult fibers. The voltage and time-dependent currents underlying the action potential were recorded under voltage clamp using the whole-cell version of the patch pipette technique. The reversal potential of the currents was found to shift with the chloride concentration gradient in a manner predicted by the Nernst equation, and the currents were blocked by SITS. These data indicate that chloride ions were the charge carriers. The conductance was activated by depolarization and exhibited very slow activation and deactivation kinetics.

Voltage- and time-dependent chloride currents in chick skeletal muscle cells grown in tissue culture

Membrane chloride currents in chick skeletal muscle cells grown in tissue culture were studied by use of the whole cell variation of the patch electrode voltage clamp technique. Small diameter myoballs were obtained by adding colchicine to the growth media. To isolate the currents through the chloride channels, the currents through the sodium, calcium and potassium channels were minimized. With symmetrical chloride concentrations bathing the membrane, inward currents were activated by depolarizations above -45 mV. Above 0 mV, the currents became outward. The reversal potential for the currents shifted with the chloride concentration gradient in a manner consistent with the Nernst relation, indicating that the currents were predominantly carried by chloride ions. The instantaneous current-voltage relation obtained from tail current data was linear. The relationship between conductance and membrane potential was sigmoid. The conductance activated above -45 mV, increased steeply between -45 and -10 mV and saturated above +20 mV. Over the range of potentials where the conductance was just beginning to activate, the conductance increased e-fold for a 7 mV depolarization. The currents activated with an exponential time course and did not decline during step depolarizations. Tail currents declined slowly as the sum of two exponential components. The currents were reversibly suppressed by 100 microM SITS and were irreversibly suppressed by 10 microM DIDS.

Characterization of three types of potassium current in cultured neurones of rat supraoptic nucleus area

1. Whole-cell, voltage-clamp recordings were obtained from neurones of the supraoptic area of neonatal rats in dissociated cell culture. Recordings were made from neurones having the same morphology as those which were vasopressin or oxytocin immunoreactive. 2. Three types of voltage-activated K+ current were identified on the basis of their kinetics, voltage sensitivities, Ca2+ dependence and pharmacology. The currents corresponded to the delayed rectifier current (IK), the A-current (IA), and the Ca2+-dependent current (IK(Ca] described in other neurones. 3. IK had a threshold of -40 mV, a sigmoidal time course of activation, and was sustained during voltage steps lasting less than 300 ms. The underlying conductance was voltage dependent reaching a maximum at +30 mV (mean maximum conductance 4.09 nS). The activation time constant was also voltage dependent declining exponentially from 4.5 ms at -30 mV to 1.8 ms at +50 mV. 4. IA was transient, and was activated from holding potentials negative to -70 mV; the maximum conductance (mean 5.9 nS) underlying the current was obtained at +10 mV. The activation and inactivation time constants were voltage dependent: the activation time constant declined exponentially between -40 mV (2.2 ms) and +40 mV (0.65 ms). 5. IK and IA were attenuated by the K+ channel blockers tetraethylammonium (TEA) and 4-aminopyridine (4-AP). TEA blocked the conductance underlying IK but appeared to alter the kinetics of IA. In contrast, 4-AP blocked the conductance underlying IA and, to a lesser extent, IK. 6. IK and IA were activated independently of external Ca2+ and the voltage activation of Ca2+ channels since these currents were recorded in the presence of Co2+, a Ca2+ channel blocker. 7. IK(Ca) was recorded only when Ca2+ (2 mM) was present in the external medium. From a holding potential of -30 mV, IK(Ca) had a threshold of -20 mV, was maximal at about +20 mV and declined at more positive potentials. This current was sustained during voltage steps lasting 100 ms and was abolished by addition of Co2+ (2 mM) to the medium. 8. The possible roles of the three K+ currents in regulating the characteristic firing behaviour of supraoptic neurones previously recorded in vivo and in vitro are discussed.

Macromolecular sites for specific neurotoxins and drugs on chemosensitive synapses and electrical excitation in biological membranes

The present review deals with the molecular mechanisms and elementary phenomena underlying the activation of the voltage- and chemo-sensitive membrane macromolecules: sodium- and potassium-ion channels and nicotinic ACh receptors and their associated ion channel. To achieve an understanding of their various kinetics and conformational states, a number of novel alkaloids, BTX, HTXs, gephyrotoxins, and certain psychotomimetic drugs such as phencyclidine, and many other pharmacologically active agents have been used. Biochemical assays and various electrophysiological techniques have been used in a number of biological preparations--e.g., Torpedo membranes, brain synaptosomes, amphibian and mammalian neuromuscular preparations--to describe the action of such agents. The availability of BTX and scorpion toxins together with aconitine and veratridine as activators and TTX and STX as antagonists of the voltage-sensitive sodium channels, made possible the identification and the physiological and pharmacological characterization of these channels. These studies provided the basis for understanding the mechanisms underlying electrical excitability and culminated, more recently, in the purification and reconstitution of sodium channels from rat brain and in the successful cloning of these channels with the elucidation of their primary structure. We now know that the sodium channel has a molecular mass of 316,000 daltons, consists of five subunits, and has multiple sites for various ligands. In contrast to sodium channels, various classes of potassium channels (inward and outward rectifier potassium channels and Ca(2+)-activated potassium channels) have been described. Unlike the sodium channels, there are no known specific activators for potassium channels. However, a number of potassium channel blockers such as 4-aminopyridine, HTX, histamine, and norepinephrine have been identified which complement the varying types of potassium channels in different neurons. One class of potassium channel blockers with profound medical and social implications comprises PCP and its analogues. The blockade of the potassium-induced 86Rb+ efflux from brain cells, the resulting prolongation of muscle and nerve action potentials, and the increase in transmitter release observed with PCP and some analogues are all highly suggestive of a role for the potassium channel in the behavioral effects of these drugs and its potential involvement in schizophrenia. A number of toxic principles of both plant and animal origin played a significant role in the development of our knowledge about the nAChR.(ABSTRACT TRUNCATED AT 400 WORDS)

The action of external tetraethylammonium ions on unitary delayed rectifier potassium channels of frog skeletal muscle

1. We have used single-channel recording to investigate the block by extracellular tetraethylammonium ions (TEA+) of delayed rectifier potassium channels of frog skeletal sarcolemma. 2. TEA+ blocks by reducing the apparent amplitude of unitary currents, without detectable increase in open-level current variance. 3. The block by TEA+ appeared to be 1:1, the fractional current being halved at 5.8 mM and -3 mV. The dissociation constant for the block was voltage dependent, increasing e-fold for a 138 mV depolarization. 4. Activation of delayed rectifier potassium currents is not altered by TEA+. 5. Open times, which in the presence of TEA+ represents bursts of open and blocked events, are not increased by TEA+, indicating that blocked channels are able to close normally.

Chloride-thiocyanate interactions in frog muscle anion-conducting channels at pH 5

Bi-ionic membrane potential measurements and three-microelectrode voltage clamp experiments have been performed on surface fibres of Xenopus laevis sartorius muscle at various mole fractions of SCN- in Cl- in the perfusate, at pH 5. Potassium was replaced in the test solutions by rubidium and/or tetraethylammonium and when the mole fraction of anions was changed the measured membrane potential changed to a new constant (i.e. time-independent) value. Over a mole fraction range of 0.05-0.95 the permeability ratio of thiocyanate to chloride was independent of [SCN-]. When the bathing solution was completely changed from control to one containing thiocyanate the change in membrane potential indicated that the permeability ratio, PSCN/PCl is close to 5.9. Inward voltage clamp currents (chloride efflux) were suppressed in the presence of thiocyanate, the degree of suppression increasing with [SCN-]. Outward currents (anion influx) were not substantially altered, suggesting that it is only the voltage-dependent anion current that is sensitive to SCN-. The results are interpreted as indicating that there is a binding site in the anion-conducting channel, accessible to the extracellular space, that must be occupied by an anion in order for the channel to be "open". But that for ion traverse to be complete, the ion at the binding site must be exchanged. If the site is occupied by thiocyanate, the more strongly bound ion, the thiocyanate blocks the channel. The bi-ionic permeability ratio is thought to reflect the ratio of the binding constants for the anions at that site.

Intrinsic optical and passive electrical properties of cut frog twitch fibers

This article describes a new apparatus for making simultaneous optical measurements on single muscle fibers at three different wavelengths and two planes of linear polarization. There are two modes of operation: mode 1 measures the individual absorbances of light linearly polarized along and perpendicular to the fiber axis, and mode 2 measures retardation (or birefringence) and the average of the two absorbance components. Although some intact frog twitch fibers were studied, most experiments used cut fibers (Hille, B., and D. T. Campbell. 1976. Journal of General Physiology. 67:265-293) mounted in a double-Vaseline-gap chamber (Kovacs, L., E. Rios, and M. F. Schneider. 1983. Journal of Physiology. 343:161-196). The end-pool segments were usually exposed for 2 min to 0.01% saponin. This procedure, used in subsequent experiments to make the external membranes in the end pools permeable to Ca indicators (Maylie, J., M. Irving, N. L. Sizto, G. Boyarsky, and W. K. Chandler. 1987. Journal of General Physiology. 89:145-176; Maylie, J., M. Irving, N. L. Sizto, and W. K. Chandler. 1987. Journal of General Physiology. 89:41-143), was routinely employed so that all our cut fiber results would be comparable. A simple method, which does not require microelectrodes, allowed continual estimation of a fiber's membrane (rm) and internal longitudinal (ri) resistances as well as the external resistance (re) under the Vaseline seals. The values of rm and ri obtained from cut fibers with this method agree reasonably well with values obtained from intact fibers using microelectrode techniques. Optical measurements were made on resting and action potential-stimulated fibers. The intrinsic fiber absorbance, defined operationally as log10 of the ratio of incident light to transmitted light intensity, was similar in intact and cut preparations, as were the changes that accompanied stimulation. On the other hand, the resting birefringence and the peak of the active change in cut fibers were, respectively, only 0.8 and 0.7 times the corresponding values in intact fibers. Both the amplitude and the half-width of the active retardation signal increased considerably during the time course of cut fiber experiments; a twofold increase in 2 h was not unusual. Such changes are probably due to a progressive alteration in the internal state of the cut fibers.

Bay K 8644 enhances slow inward and outward currents in voltage-clamped frog skeletal muscle fibres

In isolated frog skeletal muscle fibre slow inward calcium current and slow outward potassium current were recorded by means of a double mannitol-gap device. Bay K 8644, the so-called Ca-channel activator, shifted the activation threshold of the slow inward calcium current (recorded in Cl-free, Ca-rich solution), towards negative potential by 15 mV. It increased the peak current amplitude in a dose-dependent manner (from 10(-11) to 10(-7) M; EC50 approximately equal to 10(-9) M). Apamin, the bee venom toxin which is known to specifically block a class of calcium-dependent potassium channels, failed to block the slow inward calcium current and slowed down its declining phase. This effect exhibited a potential dependence: the more the membrane was depolarized, the more the current decay was slowed down. Bay K 8644 (10(-7) M) transiently decreased the slow outward potassium current, which then progressively increased to stabilize at 135% of the control value. This effect seemed to be more pronounced at potentials above the reversal potential for inward ICa. The results suggest that the increase of the slow outward current is due to a direct action of Bay K 8644 on the slow K channel, rather than an indirect action via potentiation of slow inward calcium current. Moreover, results obtained with apamin indicated that the slow outward potassium current is unlikely to flow through Ca-channels.

Properties of potassium and sodium channels in frog internode

1. Voltage-clamp experiments were performed on single frog internodes after acute demyelination with lysolecithin. The action of lysolecithin was stopped by washing out the lysolecithin with normal Ringer solution containing bovine albumin when the first delayed current was observed. After washing, the temperature was lowered from 25 to 15 degrees C. These procedures greatly prolonged the survival of the demyelinated internode up to 1 h. 2. External tetraethylammonium chloride (TEA+, 110 mM) reduced the K+ current in the internode only to 11% of the control value. 110 mM-TEA+ increased the time constant tau n of K+ activation by a factor of two in the node and by a factor of four in the internode. 120 mM-CsCl at the cut ends of the fibre also reduced the delayed outward current recorded at 60 mV in the internode to 11% of the control value, hardly changing the time constant tau n. 3. After a depolarization, the K+ tail current decayed in two phases, suggesting that the K+ conductance of the internodal membrane may be composed of at least two components, a slow one (gKs) and a fast one (gKf). As in the node, the fast K+ conductance of the internode can be further decomposed into two components (gKf1 and gKf2) with different activation potential ranges. The fast phase of the tail current was blocked by external application of 1 mM-4-aminopyridine (4-AP). The slow phase was almost unaltered by 1 mM-4-AP. The extrapolated slow tail current was 33% of the total tail current in the internode and 15% at the node, i.e. the proportion of slow K+ channels is larger in the internode than in the node. 4. Tetrodotoxin (TTX)-sensitive transient inward currents could be measured in the demyelinated internode, provided the large K+ currents were blocked by internal Cs+. The time course, TTX sensitivity, reversal potential and steady-state inactivation of the transient early inward current indicate that this current is caused mainly by Na+ passing through Na+ channels. 5. The density of K+ and Na+ channels in the demyelinated internode is estimated from the size of the K+ and Na+ current, respectively, and the capacity of the demyelinated segment. The K+ channel density of the internode seems to be about 20 times smaller than in the node, whereas the Na+ channel density in the internode appears to be about 500 times smaller than in the node.

Ionic channels: II. Voltage- and agonist-gated and agonist-modified channel properties and structure

This article reviews the different forms of ionic channels: voltage-gated, agonist-gated, and agonist- and second messenger-modified channels. The recent advances in our knowledge of the amino acid sequence of the sodium channel and the nicotinic acetylcholine receptor and the relationship of the primary structure to the channels' quarternary structure and function are discussed.

Ionic channels: I. The biophysical basis for ion passage and channel gating

This article reviews the biophysics of ion passage through membrane pores, as well as the physical factors that control the ion selectivity, gating, and conductance of an ionic channel. Different voltage clamp techniques are discussed in detail. The biophysical properties of sodium channels are reviewed.

Tetraethylammonium blockade of calcium-activated potassium channels in clonal anterior pituitary cells

The effects of extracellular and intracellular tetraethylammonium (TEA) ions on single Ca2+-activated K+ channels were studied in excised membrane patches from the anterior pituitary clone AtT-20/D16-16 with the patch-clamp technique. The presence of TEA on either surface of the membrane resulted in a decrease in the single-channel current. Dissociation constants at zero voltage for the TEA-receptor complex were calculated to be 52.2 mM and 0.08 mM for external and internal TEA, respectively. The high sensitivity of AtT-20/D16-16 cells to internal TEA is of considerable interest, since in other preparations, the greater TEA sensitivity for Ca2+-activated K+ channels has thus far been found to occur on the external membrane surface. Hill plot analysis of the dose-response data yielded a slope of 0.92, indicating a one-to-one stoichiometry for TEA-receptor binding. The blockade by TEA showed little voltage or current sensitivity over the membrane potential range studied, and could be fully reversed by washout in drug-free solution. The results suggest the presence of TEA receptors on both the external and internal membrane surfaces but with different binding affinities. Occupancy of either site by TEA leads to an apparent decrease in the single-channel conductance of Ca2+-activated K+ channels.

The apamin-sensitive potassium current in frog skeletal muscle: its dependence on the extracellular calcium and sensitivity to calcium channel blockers

Slow outward potassium currents were recorded in isolated frog skeletal muscle fibres using the double mannitol-gap voltage-clamp technique. Detubulated fibres failed to generate a slow outward current, and apamin had no effect on the remaining current. The maximum blocking effect of organic and inorganic Ca2+-channel blockers on the slow outward channels of intact fibres was larger than that of apamin. Apamin failed to induce an additional block when applied after Ca2+-channel blockers. In a low-Ca2+ solution (OCa, EGTA 1 mM) the slow outward current was slightly increased and the blocking effect of apamin was enhanced. A Ca2+-rich solution (Ca2+ X 10) increased the slow outward current and the blocking effect of apamin was drastically reduced. It is concluded that the apamin-sensitive current which is a component of the slow outward K+ current is located in the tubular membrane. Its activation seems barely dependent on the Ca2+ influx via the slow inward Ca2+ current. Apamin-receptor binding appears to be dependent on the extracellular Ca2+ concentration. Blockade of slow outward current by Ca2+-channel blockers is likely to be the result of a direct action on the slow K+ permeability rather than a consequence of Ca2+ channel inhibition.

Mobility of voltage-dependent ion channels and lectin receptors in the sarcolemma of frog skeletal muscle

The mobility of lectin receptors and of two types of ion channels was studied in skeletal muscles of the frog Rana temporaria. Lectin receptors were labeled with fluorescent derivatives of succinyl-concanavalin A (Con A) or wheat germ agglutinin (WGA), and their mobility was measured by fluorescence recovery after photobleaching. Of the receptors for WGA, approximately 53% were free to diffuse in the plane of the membrane, with an average diffusion coefficient as found in other preparations (D = 6.4 X 10(-11) cm2/s). Con A receptors were not measurably mobile. The mobility of voltage-dependent Na and K (delayed rectifier) channels was investigated with the loose-patch clamp method, coupled with through-the-pipette photodestruction of channels by ultraviolet (UV) light. Na channels were not measurably mobile (D less than or equal to 10(-12) cm2/s). With K channels, photodestruction was followed by a small but consistent recovery of K current, which suggested that some K channels diffused in the plane of the membrane. Our results with K currents are best fit if 25% of the K channels diffuse with D = 5 X 10(-11) cm2/s, with the remainder being immobile. For both Na and K channels, photodestruction by UV was most effective at a wavelength of approximately 289 nm. At this wavelength, the energy density required for an e-fold reduction in the number of functional channels was 0.40 J/cm2 for Na channels and 0.94 J/cm2 for K channels. Irradiation at this wavelength and dose did not measurably diminish the mobility of WGA receptors; hence, the immobility of Na and most K channels is not due to UV irradiation. It is concluded that mobile and immobile membrane proteins coexist in the sarcolemma of frog skeletal muscle, and that voltage-dependent Na and K channels are singled out for immobilization.

The voltage-dependent blocking effect of phalloidin on the delayed potassium current of voltage-clamped frog skeletal muscle fibres

The effects of phalloidin (10(-14)-10(-6) M) were tested on voltage-clamped isolated frog muscle fibres. The toxin reversibly blocked the potassium current similarly in both detubulated and intact fibres. Neither the reversal potential nor the activation curve of the current were affected by the toxin (10(-8) M). The inactivation curve was shifted toward negative values at holding potentials more than +20 mV from the reference potential. This shift enhanced the potential-dependent facilitation of the current block observed between -40 and +40 mV from the reference holding potential (the higher the depolarization, the greater the blocking effect, which reached 100% at +40 mV). Contrary to what was seen with the current, hyperpolarization did not relieve the mechanical block. The effect of phalloidin did not seem to be frequency-dependent.

Biochemical separation of delayed rectifier currents in frog short skeletal muscle fibres

Frog short (1-1.5 mm) skeletal muscle fibres in sucrose hypertonic Ringer at 5 degrees C were voltage clamped employing a two-electrode technique. Decreasing pH from 7.0 to 5.0 dramatically increased the rate of turn on of the slow delayed rectifier (GK,s) current, so that it became similar to the rapidly activated form. The accelerating effects of decreased pH upon slow current kinetics had a pKa of 5.8. Decreased pH also appeared to shift the voltage dependence of fast and GK,s gating to more positive potentials. In addition, a decrease in pH from 7.0 to 5.0 shifted the reversal potential of GK,s by over 11 mV in the positive direction. GK,s was selectively and irreversibly abolished by applying 1 mM-diethylpyrocarbonate (DEP), a histidine reagent. This effect occurred even after GK,s had been accelerated by low pH. DEP had no effect upon fast delayed rectifier current except for a small positive shift in voltage dependence. Application of 1 or 2 mM-N-ethylmaleimide, a sulphydryl reagent, depressed the fast delayed rectifier while sparing the GK,s currents. However, the muscle fibres also developed markedly increased leakage currents.

Ionic conductances in frog short skeletal muscle fibres with slow delayed rectifier currents

Short (0.8-1.6 mm) lumbricalis fibres of Rana pipiens were voltage clamped by a two-micro-electrode technique at 5 degrees C in sucrose hypertonic Ringer solution (SHR). Terminated linear cable analysis suggests that if the current electrode is placed near the centre of the fibre length and the voltage-sensing electrode is placed 0.19 times the fibre length from the current electrode, the fibre can be adequately voltage clamped and the conductance may be simply calculated as I/V for fibre length constants from 1.0 to 0.15 mm. In SHR solution lumbricalis fibres have action potentials with peak amplitudes of only +2 to 7 mV and a slow, gradual repolarization, distinct from the action potentials observed in sartorius muscle. In 60 mM-Na+ SHR the inward Na current could be adequately controlled over the fibre length, providing an estimated Na conductance (GNa) of 8.9 mS/cm2. The magnitude of GNa and GK (delayed rectifier) in lumbricalis fibres was approximately 20% of that reported for sartorius and semitendinosus, although the resting conductances were similar. Fibres demonstrated delayed rectifier currents with complex patterns of activation suggesting two components of conductance (fast, GK,f and slow, GK,s) which were combined together in varied amounts: (a) GK,f activated rapidly to a maximum within 80 ms at 0 mV as previously described (Adrian, Chandler & Hodgkin, 1970a); (b) GK,s activated gradually with depolarizations below -50 mV and achieving peak currents at about 400 ms at 0 mV. In about 10% of lumbricalis fibres studied, GK,s occurred in isolation with a peak magnitude of 1.4 +/- 0.4 mS/cm2 (+/- S.D.). GK,s activation kinetics and tail currents are described by a squared two-state (l2) Hodgkin-Huxley model and have a Q10 of 2.8. These currents inactivated with a time constant of 5-7 s at 0 mV. Isolated GK,s with identical kinetics was also observed in certain sartorius fibres studied with the three-electrode voltage clamp. The fractional amount of GK,s in the combined delayed rectifier (GK,s + GK,f) currents could be estimated from analysis of the late activation phase with depolarization. Combined delayed currents were described by summing GK,f currents using a n4 model with GK,s currents defined by the l2 model.

Slow calcium and potassium currents in frog skeletal muscle: their relationship and pharmacologic properties

Slow Ca and K currents across frog skeletal muscle membrane were recorded with the Vaseline gap voltage clamp in order to investigate block by divalent cations and various organic compounds. Cd2+, Ni2+, Co2+, Mn2+, Mg2+ all block Ca currents, as do barbiturates, D-600 and nifedipine. Local anesthetics also block Ca currents, with the impermeant quaternary lidocaine derivative, OX-314, being more than an order of magnitude less potent than its permeant parent compound. Surprisingly, all agents that blocked Ca currents also blocked the slow K currents. To explain this pharmacologic parallel, one could suggest that K current is activated by Ca2+ appearing in the myoplasm due to the combination of Ca current and release from internal stores. While possibly correct for intact fibres, this hypothesis appears not to apply in our case where the myoplasm contained the Ca chelator EGTA at high concentration. Instead, K currents seem to be activated by a decrease in external [Ca2+]. In the transverse tubules, Ca current is known to cause [Ca2+] to decline to submicromolar concentrations, and evidence is presented that K currents are activated by Ca depletion from a restricted extracellular space. It is suggested that K currents flow through Ca channels that have become capable of passing monovalent cations after the tubules have become depleted of Ca2+.

Properties of single potassium channels in vesicles formed from the sarcolemma of frog skeletal muscle

The patch-clamp method was used to study unitary delayed rectifier K+ channels in large vesicles formed from the membrane of frog skeletal muscle. Channels were activated by depolarizing pulses. Single-channel conductance was about 15 pS in physiological [K+]o and was doubled by raising [K+]o to 120 mM. TEA+ caused an apparent reduction in single-channel current, which we attribute to a rapid block. When depolarizations were repeated at brief intervals, records with and without channel openings were ordered non-randomly, providing evidence for a slow process which was probably inactivation. In multichannel patches the relation between variance and mean current, binomial analysis, and the distribution of times for single and double openings were all consistent with channels behaving independently. Open times were distributed exponentially. Mean open time, tau o, increased with depolarization so that 1/tau o was an exponential function of voltage. First latency histograms peaked at times later than zero and could not be fitted by a scheme having only two closed states. Channel openings occurred in bursts and closed time histograms could be fitted by the sum of three exponentials. Our results imply a scheme with at least three closed states, an open and an inactivated state.

Changes in the ionic currents sensitivity to inhibitors in twitch rat skeletal muscles following denervation

Under voltage clamp conditions, using the double mannitol gap technique, ionic currents developed by fast (e.d.l.) and slow (soleus) twitch muscle fibers of the rat were analysed at different times following denervation and the results compared with those obtained in normal cells. In slow fibers, denervation caused the appearance of a new population of TTX-resistant Na+ channels (dissociation constant K2 = 2,800 nM) compared with the normal TTX-sensitive Na+ channels (K1 = 9 nM). This new population of Na channels appeared in 5 days and contributed about 32% of the total Na conductance. Denervated fast fibres developed a slow component in the delayed outward current which was found to be typical of slow innervated muscles. This component appeared 5 to 20 days after nerve section. These changes are associated with modifications of potassium channels' sensitivity for specific inhibitors (TEA and 4-AP). After denervation, the delayed outward current in the two types of muscles becomes resistant to 4-AP whereas TEA, which blocks the total delayed outward current in innervated fibers (dissociation constant of 21.4 mM) becomes more effective in blocking the fast component (dissociation constant of 0.61 mM) and less effective in blocking the slow component in denervated cells. The analysis of the characteristics of the TEA sensitive and TEA insensitive components of the outward current leads to the proposal that these components were related to the fast and to the slow components previously described in fast and slow twitch mammalian skeletal muscles.

Effects of phalloidin on electrical and mechanical activity of frog muscle fibres

The effects of phalloidin (10(-15) to 10(-5) M) on isolated muscle fibres of the frog were investigated under current or voltage clamp conditions in a double mannitol gap device coupled to a mechanoelectric transducer which allowed the estimation of isometric tension. The toxin significantly increased the action potential duration and the amplitude of the associated contraction. Under voltage-clamp conditions, for a concentration range of 10(-14) to 10(-8) M, phalloidin reversibly decreased (up to 42.7% +/- 3.1) the fast outward potassium current responsible for the delayed rectification. For concentrations from 10(-8) to 10(-5) M, the toxin irreversibly reduced (up to 43.3% +/- 2.9) the amplitude of the contractile response. It is concluded that, in skeletal muscle fibre of frog, phalloidin acts at two different levels, one which may be located at the outer face of the surface membrane while the other may be located deeper within the cell.

Ionic currents and charge movements in organ-cultured rat skeletal muscle

The middle of the fibre voltage-clamp technique was used to measure ionic currents and non-linear charge movements in intact, organ-cultured (in vitro denervated) mammalian fast-twitch (rat extensor digitorum longus) muscle fibres. Muscle fibres organ cultured for 4 days can be used as electrophysiological and morphological models for muscles in vivo denervated for the same length of time. Sodium currents in organ-cultured muscle fibres are similar to innervated fibres except that in the temperature range 0-20 degrees C (a) in the steady state, the voltage distribution of inactivation in cultured fibres is shifted negatively some 20 mV; (b) at the same temperature and membrane potential, the time constant of inactivation in cultured fibres is about twice that of innervated fibres. Potassium currents in innervated and cultured fibres at 15 degrees C can be fitted with the Hodgkin-Huxley n variable raised to the second power. Despite the large range we would estimate that the maximum value of the steady-state potassium conductance of cultured fibres is about one-half that of innervated fibres. The estimated maximum amount of charge moved in cultured fibre is about one-third that in innervated fibres. Compared to innervated fibres, culturing doubles the kinetics of the decay phase of charge movement. The possibility of a negative shift of the voltage distribution of charge movements in cultured fibres is discussed.

A new preparation for recording single-channel currents from skeletal muscle

Spherical vesicles of sarcolemma (media diameter, 78 microns) were prepared from frog skeletal muscle by prolonged exposure to enzymes (collagenase, then protease) and to isotonic KCl solutions, which promote swelling of muscle fibres. Patch clamp recording was used to measure unitary K and Na currents from this preparation. Na and K channels had conductances around 15 pS and their kinetic properties appeared unaltered by vesicle formation.

Extracellular ions and excitation-contraction coupling in frog twitch muscle fibres

Intracellular calcium transients were recorded from voltage-clamped frog twitch muscle fibres using Arsenazo III. The possible role of extracellular ions in excitation-contraction (e.-c.) coupling was examined using ion substitutions and blocking drugs in the bathing medium. Parameters measured included the Arsenazo response size to a standard depolarizing pulse (5 ms, 0 mV) and the strength-duration curve for threshold Arsenazo signal. Addition of tetrodotoxin (TTX) decreased the response size to small (-30 mV, 5 ms), but not large (+30 mV, 10 ms) depolarizations, probably because of poor voltage clamp of the tubular membrane in the absence of TTX. Clamping TTX-treated fibres with the wave form of a recorded action potential gave an Arsenazo response similar to that elicited by the normal action potential (at 10 degrees C). Complete substitution of sodium (by choline, lithium or Tris) or chloride (by methyl sulphate or maleate) in the bathing solution gave no appreciable changes in the size of the Arsenazo response. Reduction of extracellular free [Ca2+] to low levels using EGTA caused a slight reduction in the calcium signal elicited by the standard depolarization (to 74% after a few hours, and to 62% after 2 days; temperature 5-10 degrees C). The strength-duration curve was unchanged. Arsenazo responses about 75% of the control size could be elicited in high potassium solution (42 mM-K2SO4) by strong (+80 mV, 20 ms) depolarizations, after re-polarizing the fibres to -90 mV for a few minutes. The voltage dependence of activation was shifted to more positive potentials in this solution. Tetraethylammonium (TEA) bromide at a concentration of 20 mM did not alter the Arsenazo signal, whilst 120 mM-TEA reduced the response by 25%. 3,4-diaminopyridine (DAP) reduced the size of the Arsenazo signal at a concentration of 5 mM, and caused spontaneous release of calcium from the sarcoplasmic reticulum (s.r.) in the absence of membrane potential changes. The Arsenazo signal elicited by an action potential was enhanced by 1 mM-DAP, because of prolongation of the action potential, but was depressed by higher concentrations. We conclude that e.-c. coupling does not involve the influx of any external ions into the muscle fibre. If a current flow between the T-tubules and the s.r. is involved in e.-c. coupling, then this is probably carried by an efflux of potassium ions.

Rapidly activating hydrogen ion currents in perfused neurones of the snail, Lymnaea stagnalis

Cells from the circumoesophageal nerve ring of the pond snail Lymnaea stagnalis were internally perfused with solutions containing Cs aspartate, EGTA and pH buffers. Time-dependent, voltage-dependent 'residual' outward currents were observed at positive potentials. They were found to be carried largely by H+. The outward H+ currents were reduced by high internal pH, low external pH, external Cd2+ and 4-aminopyridine. External tetraethylammonium ions reduced the H+ currents but had a more effective blocking action on the K+ currents in these cells. All five agents reduced the maximum H+ conductance. In addition Cd2+, low external pH and high internal pH were found to shift the voltage dependence of the H+ current to more positive potentials. There was no significant difference between H+ currents recorded with the internal pCa2+ about 7 and those recorded with the internal pCa2+ near 5. It is likely that the H+ channel described here provides the basis for the increase in H+ permeability described by Thomas & Meech (1982) in depolarized Helix neurones. As judged by their sensitivity to different antagonists, H+ channels are unlike any other previously described channel. They are highly selective for protons and we suggest that their role in molluscan neurones is to compensate for the rapid intracellular acidification which is generated by trains of action potentials (Ahmed & Connor, 1980).

Saturation of calcium channels and surface charge effects in skeletal muscle fibres of the frog

Voltage-clamp and current-clamp experiments were performed to study Ca2+ and Ba2+ permeation through Ca channels in intact twitch skeletal muscle fibres of the frog. Surface charge effects were taken into consideration. Ca2+ (ICa) or Ba2+ (IBa) currents, or Ca2+ and Ba2+ action potentials were recorded in the presence of external tetraethylammonium (TEA+) ions and by replacing C1- for CH3SO3-. To further block K+ outward currents, muscles were incubated in a K+-free, TEA+ and Cs+-containing solution prior to experiments. When 10 mM-Ca2+ was replaced by 10 mM-Ba2+, the I/V curve for the peak inward current shifted by 15-20 mV to more negative potentials and the maximal peak inward current increased from -39 +/- 2 mA cm-3 (5) to -51 +/- 3 mA cm-3 (7). The decay of ICa and IBa followed a simple exponential time course and became faster for large depolarizations. The overshoot of the action potentials changed 29 +/- 3 mV or 32 +/- 3 mV for a 10-fold change in the Ca2+ or Ba2+ concentrations respectively. Ca2+ action potentials were 15-20 mV larger than Ba2+ action potentials. The maximum rate of rise Vmax and the Ca2+ or Ba2+ conductance GC2+ during the plateau tend to saturate as divalent cation concentration was increased. The Michaelis constant (Km) values obtained were respectively: 5.6 and 6.0 mM for Ca2+ and 12.5 and 8.0 mM for Ba2+. When Ca2+ or Ba2+ concentrations were increased, the effective threshold of the inward current Theff and the membrane potential E* at Vmax shifted to more positive potentials along the voltage axis. These shifts were similar for Theff and E* and were more pronounced for Ca2+ than for Ba2+. Voltage shifts could be adequately quantified by the Gouy-Chapman theory with a density of surface charges near Ca channels of 0.20 e nm-2 and including a specific binding constant for Ca2+ of 45 +/- 4 m-1. The fractional increase of the Ca2+ and Ba2+ calculated concentrations at the membrane surface near the channel was smaller than the corresponding one in the bulk solution. This partially explained the reported saturation. Saturation was still present in the Vmax of GC2+ curves corrected for surface concentration. The corrected Km values for the Vmax data were 60 mM for Ca2+ and 350 mM for Ba2+.(ABSTRACT TRUNCATED AT 400 WORDS)

Potent excitatory effect of maitotoxin on Ca channels in the insect skeletal muscle

The effect of maitotoxin (MTX), the most potent marine toxin as yet known, was studied using the skeletal muscle of the larval meal worm, Tenebrio molitor. In normal saline, Tenebrio muscles responded with the spike to direct stimulation. In the saline containing tetraethylammonium (TEA) the all-or-none action potential which had characteristic plateau was elicited by membrane depolarization. When MTX (5 X 10(-9) to 10(-8) g/ml) in the TEA saline was added, the plateau of action potential was prolonged more than in the saline containing TEA alone. Furthermore, MTX lowered the threshold, so that action potentials were readily evoked in the saline containing MTX. In either case, effects, of MTX were antagonized by Co2+. These results suggest that MTX activates the voltage-dependent Ca2+ channels in the insect muscle.

Differential effects of strychnine on two types of vascular muscle

Strychnine (10(-5)-3 x 10(-4) M) increased the amplitude and duration of the spontaneous electrical and mechanical activity of the rat isolated portal vein. Similar effects were seen with tetraethylammonium and 4-aminopyridine. This stimulant action of strychnine was unaffected by tetrodotoxin (3 x 10(-7) M) or prazosin (5 x 10(-8) M) but was significantly reduced by verapamil (3 x 10(-8) M). On the isolated aorta, only inhibitory actions of strychnine were observed, yet tetraethylammonium and 4-aminopyridine had excitatory actions. It is suggested that the stimulant actions of strychnine on the portal vein are likely to be due to a reduction in potassium conductance and/or an increase in calcium conductance of the smooth muscle cell membrane.