Two modes of gating during late Na+ channel currents in frog sartorius muscle

Hypoxia increases persistent sodium current in rat ventricular myocytes

1. A persistent inward current activated by depolarization was recorded using the whole-cell, tight seal technique in rat isolated cardiac myocytes. The amplitude of the inward current increased when cells were exposed to a solution with low oxygen tension. 2. The persistent inward current had the characteristics of the persistent Na+ current described previously in rat ventricular myocytes: it was activated at negative potentials (-70 mV), reversed close to the equilibrium potential for Na+ (ENa), was blocked by TTX and was resistant to inactivation. 3. Persistent single Na+ channel currents activated by long (200-400 ms) depolarizations were recorded in cell-attached patches on isolated ventricular myocytes. Hypoxia increased the frequency of opening of the persistent Na+ channels. 4. Persistent Na+ channels recorded during hypoxia had characteristics similar to those of persistent Na+ channels recorded at normal oxygen tensions. They had a null potential at ENa, their amplitude varied with [Na+], they were resistant to inactivation and their mean open time increased with increasing depolarization. 5. The persistent Na+ channels in cell-attached patches were blocked by TTX (50 microM) in the patch pipette and by lidocaine (100 microM). 6. It was concluded that hypoxia increases the open probability of TTX-sensitive, inactivation-resistant Na+ channels. The voltage dependence of these channels, and their greatly increased activity during hypoxia, suggest that they may play an important role in the generation of arrhythmias during hypoxia.

Distinct modes of channel gating underlie inactivation of somatic K+ current in rat hippocampal pyramidal cells in vitro

1. We have used the cell-attached configuration of the patch-clamp recording method to characterize the biophysical properties of the voltage-gated K+ channel underlying a 4-aminopyridine (4-AP)- and tetraethylammonium (TEA)-sensitive K+ current (IK(AT)) in pyramidal cells of hippocampal slice cultures. 2. The unitary conductance of channels carrying IK(AT) current (KAT channels) was 19.1 +/- 5.1 pS with a physiological K+ gradient (2.7 mM external K+) and 39.0 +/- 3.6 pS with high external K+ (140 mM). The reversal potential changed with the external K+ concentration as expected for a channel with a dominant K+ selectivity. Channel activity was blocked under both conditions by either external application of 4-AP at 100 microM or by including 20 mM TEA in the pipette solution. 3. An analysis of kinetic behaviour showed that open times were distributed as a single exponential. The mean open time (+/- S.D.) was 4.4 +/- 1.4 ms at a voltage 30 mV positive to resting potential and increased with further depolarization to reach a value of 16.2 +/- 7.4 ms at 70 mV positive to the resting potential. At this depolarized potential, we observed bursts of channel openings with a mean burst duration around 100 ms. 4. With repeated depolarizing pulses, response failures of the KAT channel occurred in a non-random manner and were grouped (referred to as mode 0). This mode was associated with a voltage-dependent inactivation process of the channel and was favoured when the opening probability of the channel was reduced by increasing steady-state inactivation or by bath application of 4-AP. This is consistent with the localization of the binding site for 4-AP at or near the inactivation gate of the channel. 5. When KAT channel openings were elicited by 500 ms depolarizing steps, activity was either transient or it persisted throughout the duration of the pulse. These two modes of activity alternated in a random manner or occurred in groups giving rise to transient (time constant, 20-100 ms) or sustained ensemble currents. In the presence of low concentrations of 4-AP (20-40 microM), the transient pattern of activity was more frequently observed. 6. In addition to mode 0, we propose the existence of at least two further gating modes for KAT channels: mode T (transient current) and mode S (sustained current) that underlie the three decaying components of the IK(AT) ensemble current. These gating modes are probably under the control of intracellular factors that remain to be identified.

External pore residue mediates slow inactivation in mu 1 rat skeletal muscle sodium channels

1. Upon depolarization, voltage-gated sodium channels assume non-conducting inactivated states which may be characterized as "fast' or "slow' depending on the length of the repolarization period needed for recovery. Skeletal muscle Na+ channel alpha-subunits expressed in Xenopus laevis oocytes display anomalous gating behaviour, with substantial slow inactivation after brief depolarizations. We exploited this kinetic behaviour to examine the structural basis for slow inactivation. 2. While fast inactivation in Na+ channels is mediated by cytoplasmic occlusion of the pore by III-IV linker residues, the structural features of slow inactivation are unknown. Since external pore-lining residues modulate C-type inactivation in potassium channels, we performed serial cysteine mutagenesis in the permeation loop (P-loop) of the rat skeletal muscle Na+ channel (mu 1) to determine whether similarly placed residues are involved in Na+ channel slow inactivation. 3. Wild-type and mutant alpha-subunits were heterologously expressed in Xenopus oocytes, and Na+ currents were recorded using a two-electrode voltage clamp. Slow inactivation after brief depolarizations was eliminated by the W402C mutation in domain I. Cysteine substitution of the homologous tryptophan residues in domains II, III and IV did not alter slow inactivation. 4. Analogous to the W402C mutation, coexpression of the wild-type alpha-subunit with rat brain Na+ channel beta 1-subunit attenuated slow inactivation. However, the W402C mutation imposed a delay on recovery from fast inactivation, while beta 1-subunit coexpression did not. We propose that the W402C mutation and the beta 1-subunit modulate gating through distinct mechanisms. 5. Removal of fast inactivation in wild-type alpha-subunits with the III-IV linker mutation I1303Q; F1304Q; M1305Q markedly slowed the development of slow inactivation. We propose that slow inactivation in Na+ channels involves conformational changes in the external pore. Mutations that affect fast and slow inactivation appear to interact despite their remote positions in the channel.

Modal behavior of the mu 1 Na+ channel and effects of coexpression of the beta 1-subunit

The adult rat skeletal muscle Na+ channel alpha-subunit (mu 1) appears to gate modally with two kinetic schemes when the channel is expressed in Xenopus oocytes. In the fast mode mu 1 single channels open only once or twice per depolarizing pulse, but in the slow mode the channels demonstrate bursting behavior. Slow-mode gating was favored by hyperpolarized holding potentials and slow depolarizing rates, whereas fast-mode gating was favored by depolarized holding potentials and rapid depolarizations. Single-channel studies showed that coexpression of beta 1 reduces slow-mode gating, so that channels gate almost exclusively in the fast mode. Analysis of open-time histograms showed that mu 1 and mu 1 + beta 1 both have two open-time populations with the same mean open times (MOTs). The difference lies in the relative sizes of the long and short MOT components. When beta 1 was coexpressed with mu 1 in oocytes, the long MOT fraction was greatly reduced. It appears that although mu 1 and mu 1 + beta 1 share the same two open states, the beta 1-subunit favors the mode with the shorter open state. Examination of first latencies showed that it is likely that the rate of activation is increased upon coexpression with beta 1. Experiments also showed that the rate of activation for the fast mode of mu 1 is identical to that for mu 1 + beta 1 and is thus more rapid than the rate of activation for the slow mode. It can be concluded that beta 1 restores native-like kinetics in mu 1 by favoring the fast-gating mode.

Paramyotonia congenita: the R1448P Na+ channel mutation in adult human skeletal muscle

Twitch force and Na+ currents were investigated in a muscle biopsy specimen from a patient with paramyotonia congenita carrying the dominant Arg-1448-Pro mutation in the skeletal muscle sodium channel. Cooling of the muscle fibers caused sustained membrane depolarization that resulted in reduced twitch force. Membrane repolarization, produced by a K+ channel opener, partly prevented and antagonized the drop in twitch force. Patch-clamp recordings on sarcolemmal blebs revealed a distinctly slower Na+ current decay on paramyotonia congenita muscle compared to control muscle. In addition, patches with mutant Na+ channels showed a significantly higher frequency of steady-state openings, which increased with cooling. Activation of mutant channels was not affected, whereas the steady-state inactivation curve was shifted by -5 mV and showed less voltage dependence. We suggest that the weakness of cooled muscle can be explained by a combination of the increased steady-state Na+ current and the left-shifted inactivation curve.

Veratridine-enhanced persistent sodium current induces bursting in CA1 pyramidal neurons

The mechanism of veratridine-induced bursting activity was studied in rat hippocampal CA1 pyramidal neurons. Veratridine (0.1-0.3 microM) induces bursting in previously normal pyramidal neurons. The current-voltage curves of untreated neurons show a slight deviation from the linear Ohmic relation; this deviation is known as the "depolarizing rectification". Veratridine markedly accentuates the depolarizing rectification so that a zero slope or negative slope appears in the current-voltage curve of these neurons. Both the veratridine-induced bursting activity and negative slope resistance are blocked by small concentrations of tetrodotoxin or by raising the calcium concentration of the superfusion medium. Under single-electrode voltage clamping, a subthreshold persistent (slowly inactivating) sodium current, which can be recorded in untreated neurons, is found to be enhanced in the veratridine-treated neurons. This current is thought to be responsible for the slow depolarizing phase of bursting activity and the development of negative slope resistance in the current-voltage relationship. The present results demonstrate that veratridine enhances the slowly inactivating sodium current, leading to the development of negative slope resistance and induction of bursting in rat hippocampal CA1 pyramidal neurons.

Ion-channel defects and aberrant excitability in myotonia and periodic paralysis

The myotonias and periodic paralyses are a diverse group of skeletal muscle disorders that share a common pathophysiological mechanism: all are caused by derangements in the electrical excitability of the sarcolemma. Mutations within coding regions of ion-channel genes have been identified recently as the underlying molecular defects in these heritable disorders. Chloride-channel mutations cause a reduction in the resting conductance, which enhances excitability and gives rise to myotonia. By contrast, missense mutations in the L-type Ca2+ channel reduce the electrical excitability of the fiber and cause a form of periodic paralysis. Mutations of the sodium channel impair inactivation of the channel, which, depending on the type and severity of the functional defect, results in either paralysis or myotonia.

Voltage-dependent properties of three different gating modes in single cardiac Na+ channels

Three different modes of Na+ channel action, the F mode (fast inactivating), the S mode (slowly inactivating), and the P mode (persistent), were studied at different potentials in exceptionally small cell-attached patches containing one and only one channel. Switching between the modes was independent of voltage. In the F mode, the mean open time (tau o) at -30 and -40 mV was 0.14 and 0.16 ms, respectively, which was significantly larger than at -60 and 0 mV, where the values were 0.07 and 0.08 ms, respectively. The time before which half of the first channel openings occurred (t 0.5), decreased from 0.58 ms at -60 mV to 0.14 ms at 0 mV. The fit of steady-state activation with a Boltzmann function yielded a half-maximum value (V 0.5) at -48.1 mV and a slope (k) of 5.6 mV. The mean open time in the S mode increased steadily from 0.12 ms at -80 mV to 1.09 ms at -30 mV, but was not prolonged further at -20 mV (1.07 ms). Concomitantly, t 0.5 decreased from 1.61 ms at -80 mV to 0.22 ms at -20mV. Here the midpoint of steady-state activation was found at -61.2 mV, and the slope was 8.7 mV. The mean open time in the P mode increased from 0.07 ms at -60 mV to 0.45 ms at 0 mV and t 0.5 declined from 2.14 ms at -60 mV to 0.19 ms at +20 mV. Steady-state activation had its midpoint at -14.7 mV, and the slope was 10.9 mV. It is concluded that a single Na+ channel may switch among the F, S, and P mode and that the three modes differ by a characteristic pattern of voltage dependence of tau 0, t 0.5, and steady-state activation.

Molecular mechanism for an inherited cardiac arrhythmia

In the congenital long-QT syndrome, prolongation of the cardiac action potential occurs by an unknown mechanism and predisposes individuals to syncope and sudden death as a result of ventricular arrhythmias. Genetic heterogeneity has been demonstrated for autosomal dominant long-QT syndrome by the identification of multiple distinct loci, and associated mutations in two candidate genes have recently been reported. One form of hereditary long QT (LQT3) has been linked to a mutation in the gene encoding the human heart voltage-gated sodium-channel alpha-subunit (SCN5A on chromosome 3p21). Here we characterize this mutation using heterologous expression of recombinant human heart sodium channels. Mutant channels show a sustained inward current during membrane depolarization. Single-channel recordings indicate that mutant channels fluctuate between normal and non-inactivating gating modes. Persistent inward sodium current explains prolongation of cardiac action potentials, and provides a molecular mechanism for this form of congenital long-QT syndrome.

A critical role for transmembrane segment IVS6 of the sodium channel alpha subunit in fast inactivation

Fast Na+ channel inactivation is thought to occur by the binding of an intracellular inactivation gate to regions around or within the Na+ channel pore through hydrophobic interactions. Previous studies indicate that the intracellular loop between domains III and IV of the Na+ channel alpha subunit (LIII-IV) forms the inactivation gate. A three-residue hydrophobic motif (IFM) is an essential structural feature of the gate and may serve as an inactivation particle that binds within the pore. In this study, we used alanine-scanning mutagenesis to examine the functional role of amino acid residues in transmembrane segment IVS6 of the Na+ channel alpha subunit in fast inactivation. Mutant F1764A, in the center of IVS6, and mutant V1774A, near its intracellular end, exhibited substantial sustained Na+ currents at the end of 30-ms depolarizations. The double mutation F1764A/V1774A almost completely abolished fast inactivation, demonstrating a critical role for these amino acid residues in the process of inactivation. Single channel analysis of these three mutants revealed continued reopenings late in 40-ms depolarizing pulses, indicating that the stability of the inactivated state was substantially impaired compared with wild type. In addition, the cumulative first latency distribution for the V1774A mutation contained a new component arising from opening transitions from the destabilized inactivated state. Substitution of multiple amino acid residues showed that the disruption of inactivation was not correlated with the hydrophobicity of the substitution at position 1774, in contrast to the expectation if this residue interacts directly with the IFM motif. Thermodynamic cycle analysis of simultaneous mutations in the IFM motif and in IVS6 suggested that mutations in these two regions independently disrupt inactivation, consistent with the conclusion that they do not interact directly. Furthermore, a peptide containing the IFM motif (acetyl-KIFMK-amide) restored inactivation to the F1764A/V1774A IVS6 mutant, indicating that the binding site for the IFM motif remains intact in these mutants. These results suggest that the amino acid residues 1764 and 1774 in IVS6 do not directly interact with the IFM motif of the inactivation gate but instead play a novel role in fast inactivation of the Na+ channel.

Multimodal action of single Na+ channels in myocardial mouse cells

Unitary Na+ currents of myocardial mouse cells were studied at room temperature in 10 cell-attached patches, each containing one and only one channel. Small-pore patch pipettes (resistance 10-97 M omega when filled with 200% Tyrode's solution) with exceptionally thick walls were used. Observed were both rapidly inactivating (6 patches) and slowly inactivating (3 patches) Na+ currents. In one patch, a slow transition from rather fast to slow inactivation was detected over a time of 0.5 h. A short and a long component of the open-channel life time were recorded at the beginning, but only a short one at the end of the experiment. Concomitantly, the first latency was slowed. Amplitude histograms showed that the electrochemical driving force across the pore of the channel did not change during this time. In three patches, a fast and repetitive switching between different modes of Na+ channel action could be clearly identified by plotting the long-time course of the averaged current per trace. The ensemble-averaged current formed in each mode was different in kinetics and amplitude. Each mode had a characteristic mean open-channel life time and distribution of first latency, but the predominant single-channel current amplitude was unaffected by mode switches. It is concluded that two types of changes in kinetics may happen in a single Na+ channel: fast and reversible switches between different modes, and a slow loss of inactivation.

Model experiments on squid axons and NG108-15 mouse neuroblastoma x rat glioma hybrid cells

Three types of ionic current essentially determine the firing pattern of nerve cells: the persistent Na+ current, the M current and the low-voltage-activated Ca(2)+ current. The present article summarizes recent experiments concerned with the basic properties of these currents. Keynes and Meves (Proc R Soc Lond B (1993) 253, 61-68) studied the persistent or steady-state Na+ current on dialysed squid axons and measured the probability of channel opening both for the peak and the steady-state Na+ current (PF(peak) and PF(ss)) as a function of voltage. Whereas PF(peak) starts to rise at -50 mV and reaches a maximum at +40 to +50 mV, PF(ss) only begins to rise appreciably at around 0 mV and is still increasing at +100 mV. This differs from observations on vertebrate excitable tissues where the persistent Na+ current tums on in the threshold region and saturates at around 0 mV. Schmitt and Meves (Pflugers Arch (1993) 425, 134-139) recorded M current, a non-inactivating K+ current, from NGI08-15 neuroblastoma x glioma hybrid cells, voltage-clamped in the whole-cell mode, and studied the effects of phorbol 12,13-dibutyrate (PDB), an activator of protein kinase C (PKC), and arachidonic acid (AA). PDB and AA both decreased I(M), the effective concentrations being 0.1-1 mu M and 5-25 mu M, respectively; while the PDB effect was regularly observed, the M current depression by AA was highly variable from cell to cell. The PKC 19-31 peptide, an effective inhibitor of PKC, in a concentration of 1 muM almost totally prevented the effects of PDB and AA on M current, suggesting that both are mediated by PKC. Schmitt and Meves (Pflugers Arch (1994a) 426, Suppl R 59) measured low-voltage-activated (l-v-a) and high-voltage-activated (h-v-a) Ca2+ currents on NG108-15 cells and investigated the effect of AA and PDB on both types of current. At pulse potentials > -20 mV, AA (25-100 mu M) decreased 1-v-a and h-v-a I(Ca). The decrease was accompanied by a small negative shift and a slight flattening of the activation and inactivation curves of the l-v-a I(Ca). The AA effect was not prevented by 50 mu M eicosa-5,8,11,14-tetraynoic acid (ETYA), an inhibitor of AA metabolism, or PKC 19-31 peptide and not mimicked by 0.1-1 mu M PDB. Probably, AA acts directly on the channel protein or its lipid environment. The physiological relevance of these three sets of observations is briefly discussed.

The kinetics of voltage-gated ion channels

When Hodgkin & Huxley (1952) first embarked on the analysis of their voltageclamp data on the ionic currents in the squid giant axon, they hoped to be able to deduce a mechanism from it, but it soon became clear that the electrical data would by themselves yield only very general information about the class of system likely to be involved.

K(+)-aggravated myotonia: destabilization of the inactivated state of the human muscle Na+ channel by the V1589M mutation

1. Wild type (WT) and V1589M channels were expressed in human embryonic kidney (HEK293) cells for the study of the pathophysiology of the V1589M muscle Na+ channel mutation leading to K(+)-aggravated myotonia. 2. In comparison to WT, whole-cell recordings with V1589M channels showed an increased Na+ steady-state to peak current ratio (Iss/Ipeak) (3.15 +/- 0.70 vs. 0.87 +/- 0.10%, at -15 mV) and a significantly faster recovery from inactivation. The recovery time constants, tau r1 and tau r2, were decreased from 1.28 +/- 0.12 to 0.92 +/- 0.08 ms and from 4.74 +/- 0.94 to 2.66 +/- 0.51 ms for the WT and mutant channels, respectively. 3. Single-channel recordings with mutant channels showed higher probability of short isolated late openings (0.40 +/- 0.09 vs. 0.06 +/- 0.02, at -30 mV) and bursts of late openings (0.011 +/- 0.003 vs. 0.003 +/- 0.001, at -30 mV) compared to WT. 4. These results suggest that the mutation increases the probabilities for channel transitions from the inactivated to the closed and the opened states. 5. Increased extracellular concentrations of K+ had no effects on either V1589M or WT currents in HEK293 cells. The aggravation of myotonia seen in patients during increased serum K+ may arise from the associated membrane depolarization which favours the occurrence of late openings in the mutant channel.

Kinetic mode switch of rat brain IIA Na channels in Xenopus oocytes excised macropatches

Na currents recorded from outside-out macropatches excised from Xenopus oocytes expressing the alpha subunit of the rat brain Na channel IIA show at least two distinguishable components in their inactivation time course, with time constants differing about tenfold (tau h1 = approx. 150 microseconds and tau h2 = approx. 2 ms). In excised patches, the inactivation properties of Na currents changed with time, favoring the faster inactivation kinetics. Analysis of the fast and slow current kinetics shows that only the relative magnitudes of tau h1 and tau h2 components are altered without significant changes in the time constants of activation or inactivation. In addition, voltage dependence of both activation and steady-state inactivation of Na currents are shifted to more negative potentials in patches with predominantly fast inactivation, although reversal potentials and valences remained unaltered. We conclude that the two inactivation modes discerned in this study are conferred by two states of Na channel the interconversion of which are regulated by an as yet unknown mechanism that seems to involve cytosolic factors.

Late Na channels in cardiac cells: the physiological role of background Na channels

Two types of the late Na channels, burst and background, were studied in Purkinje and ventricular cells. In the whole-cell configuration, steady-state Na currents were recorded at potentials (-70 to -80 mV) close to the normal cell resting potential. The question of the contribution of late Na channels to this background Na conductance was investigated. During depolarization, burst Na channels were active for periods (up to approximately 5 s), which exceeded the action potential duration. However, they eventually closed without reopening, indicating the presence of slow and complete inactivation. When, at the moment of burst channel opening, the potential was switched to -80 mV, the channel closed quickly without reopening. We conclude that the burst Na channels cannot contribute significantly to the background Na conductance. Background Na channels undergo incomplete inactivation. After a step depolarization, their activity decreased in time, approaching a steady-state level. Background Na channel openings could be recorded at constant potentials in the range from -120 to 0 mV. After step depolarizations to potentials near -70 mV and more negative, a significant fraction of Na current was carried by the background Na channels. Analysis of the background channel behavior revealed that their gating properties are qualitatively different from those of the early Na channels. We suggest that background Na channels represent a special type of Na channel that can play an important role in the initiation of cardiac action potential and in the TTX-sensitive background Na conductance.

Gating of the squid sodium channel at positive potentials: II. Single channels reveal two open states

Single-channel recordings from squid axon Na+ channels were made under conditions of reverse sodium gradient. In the range of potentials studied, +40-(+)120 mV, channels opened promptly after depolarization, closed and reopened several times during the pulse. In patches containing only one channel, the distributions of open dwell times showed two components showing the existence of a second open state. The ensemble average of single-channel records showed incomplete inactivation that became more pronounced at more positive potentials, showing that the maintained phase of the current is the result of only one type of sodium channel with two open states. Analysis of bursts indicated that the dwell times of the events at the onset of the depolarization are longer than those later in the pulse. The dwell open times of the first events could be fitted with a single exponential. This indicated that the channels open preferentially through the first open state, the access to the second open state happening subsequently. Maximum likelihood analysis was used to evaluate several possible kinetic schemes incorporating a second open state. The best model to fit the data from single channels, and consistent with the data from macroscopic and gating currents, has a second open state evolving from the inactivated state. A kinetic model is proposed that incorporates information obtained from dialyzed axons.

Delayed depolarization and slow sodium currents in cutaneous afferents

1. Intraaxonal recordings were obtained in vitro from the sural nerve (SN), the muscle branch of the anterior tibial nerve (ATN), or the deafferented ATN (dATN) in 5- to 7-wk-old rats. Whole-nerve sucrose gap recordings were obtained from the SN and the ATN. This allowed study of cutaneous (SN), mixed motor and muscle afferent (ATN), and isolated muscle afferent (dATN) axons. 2. Application of the potassium channel blocking agent 4-aminopyridine (4-AP) to ATN or dATN resulted in a slight prolongation of the action potential. In contrast, a distinct delayed depolarization followed the axonal action potential in cutaneous afferents (SN) exposed to 4-AP. The delayed depolarization could be induced by a single whole-nerve stimulus or by injection of constant-current depolarizing pulses into individual axons. The delayed depolarization often gave rise to bursts of action potentials and was followed by a prominent afterhyperpolarization (AHP). 3. In paired-pulse experiments on single SN axons, the recovery time (half-amplitude of the action potential) was 3.06 +/- 1.82 (SE) ms (n = 12). After exposure to 4-AP the recovery time of the delayed depolarization was considerably longer (half-recovery time: 99.0 +/- 28.3 ms; n = 15) than that of the action potential (18.8 +/- 9.1 ms; n = 16). 4. Application of tetraethylammonium (TEA) to cutaneous or muscle afferents alone had little effect on single action potential waveform. However, TEA reduced the amplitude of the AHP elicited by a single stimulus in cutaneous afferent axons after exposure to 4-AP and resulted in repetitive spike discharge. 5. The delayed depolarization and spike burst activity induced by 4-AP in SN was present in Ca(2+)-free solutions containing 1 mM ethylene glycol-bis (beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid and was not blocked by Cd2+ (1.0 mM). 6. We obtained whole-cell patch-clamp recordings to study Na+ currents from either randomly selected dorsal root ganglion neurons or cutaneous afferent neurons identified by retrograde labeling with Fluoro-Gold. The majority of the randomly selected neurons had a singular kinetically fast Na+ current. In contrast, no identified cutaneous afferent neurons had a singular fast Na+ current. Rather, they had a combination of kinetically separable fast and slow currents or a singular relatively slow Na+ current.(ABSTRACT TRUNCATED AT 400 WORDS)

Sodium channel mutations in paramyotonia congenita uncouple inactivation from activation

Mutations in the adult human skeletal muscle Na+ channel alpha subunit cause the disease paramyotonia congenita. Two paramyotonia congenita mutations, R1448H and R1448C, substitute histidine and cysteine for arginine in the S4 segment of domain 4. These mutations, expressed in a cell line, have only small effects on the activation of Na+ currents, but mutant channels inactivate more slowly with less voltage dependence than wild-type channels and exhibit an enhanced rate of recovery from inactivation. Increase of extracellular pH made the rate of inactivation of R1448H similar to that of R1448C, suggesting that this residue has an extracellular location and that its charge is important for normal inactivation. Analysis of single-channel data reveals that mutant channels inactivate normally from closed states, but poorly from the open state. The data suggest a critical role for the S4 helix of domain 4 in coupling between activation and inactivation.

Sodium channel inactivation kinetics of rat sensory and motor nerve fibres and their modulation by glutathione

Na+ channel currents of rat motor and sensory nerve fibres were studied with the patch-clamp technique on enzymatically demyelinated axons. Differences between motor and sensory fibres in multi-channel inactivation kinetics and the gating of late single-channel currents were investigated. In the axon-attached mode, inactivation of multi-channel Na+ currents in sensory axons was best fitted with a single time constant while for motor axons two time constants were needed. Late single-channel currents in sensory axons were characterized by short openings whereas motor axons exhibited additional long single-channel openings. In contrast, in excised, inside-out membrane patches, no differences between motor and sensory fibres were found; in both types of fibre inactivation of multi-channel Na+ currents proceeded with two time constants and late single-channel currents showed short and long openings. After application of the reducing agent glutathione to the cytoplasmic side of excised inside-out patches, inactivation of Na+ currents in both motor and sensory fibres proceeded with a single, fast exponential time constant and late currents appeared with short openings only. These data indicate that the axonal metabolism may contribute to the different inactivation kinetics of Na+ current in motor and sensory nerve fibres.

Thermodynamic entropy of two conformational transitions of single Na+ channel molecules

Single cardiac Na+ channel currents were recorded with improved resolution (bandwidth up to 20 kHz) at two temperatures, 10 and 25 degrees C. The mean open time was determined at voltages between -50 and 0 mV by evaluation of the distribution of the event-related gaps in the center of the baseline noise. Fit of the voltage-dependent reciprocal mean open times at both temperatures allowed even for a single channel molecule to separate an entropic from an enthalpic part of activation energy for both deactivation and inactivation. Both entropies are positive and the entropy of deactivation exceeds that of inactivation by more than twice.

Structure, function and expression of voltage-dependent sodium channels

Voltage-dependent sodium channels control the transient inward current responsible for the action potential in most excitable cells. Members of this multigene family have been cloned, sequenced, and functionally expressed from various tissues and species, and common features of their structure have clearly emerged. Site-directed mutagenesis coupled with in vitro expression has provided additional insight into the relationship between structure and function. Subtle differences between sodium channel isoforms are also important, and aspects of the regulation of sodium channel gene expression and the modulation of channel function are becoming topics of increasing importance. Finally, sodium channel mutations have been directly linked to human disease, yielding insight into both disease pathophysiology and normal channel function. After a brief discussion of previous work, this review will focus on recent advances in each of these areas.

Slow and incomplete inactivations of voltage-gated channels dominate encoding in synthetic neurons

Electrically excitable channels were expressed in Chinese hamster ovary cells using a vaccinia virus vector system. In cells expressing rat brain IIA Na+ channels only, brief pulses (< 1 ms) of depolarizing current resulted in action potentials with a prolonged (0.5-3 s) depolarizing plateau; this plateau was caused by slow and incomplete Na+ channel inactivation. In cells expressing both Na+ and Drosophila Shaker H4 transient K+ channels, there were neuron-like action potentials. In cells with appropriate Na+/K+ current ratios, maintaining stimulation produced repetitive firing over a 10-fold range of frequencies but eventually led to "lock-up" of the potential at a positive value after several seconds of stimulation. The latter effect was due primarily to slow inactivation of the K+ currents. Numerical simulations of modified Hodgkin-Huxley equations describing these currents, using parameters from voltage-clamp kinetics studied in the same cells, accounted for most features of the voltage trajectories. The present study shows that insights into the mechanisms for generating action potentials and trains of action potentials in real excitable cells can be obtained from the analysis of synthetic excitable cells that express a controlled repertoire of ion channels.

Bursting of cardiac sodium channels after acute exposure to 3,5,3'-triiodo-L-thyronine

Physiological concentrations of 3,5,3'-triiodo-L-thyronine (T3) acutely increased burst-mode gating of Na+ channels in rabbit ventricular myocytes. Bursting was measured as the ratio of long events to the total number of events multiplied by 100 (%LE); a long event was defined as a set of openings or a single opening with a total duration greater than or equal to five times the control mean open time (MOT) for cell-attached patches. In the cell-attached configuration, adding either 5 or 50 nM T3 to the pipette increased the %LE. %LE had a biphasic voltage dependence and peaked at -50 mV, although the largest percentage change from control occurred between -30 and -40 mV. Neither unitary conductance nor the overall MOT was altered by T3-induced bursting. However, the MOT of openings within bursts increased, implying a kinetically distinct mode of channel gating during bursts. Long events sometimes were grouped into runs, but the more usual pattern suggested that modal shifts occurred in approximately 1 second. Similar behavior was observed with triiodothyroacetic acid, a T3 analogue that does not elicit protein synthesis. To investigate involvement of soluble second messengers, cell-attached recordings were made with and without T3 in the bath. Placed outside the pipette, 50 and 100 nM T3 failed to alter MOT, unitary current, or %LE. Na+ channel gating also was unaffected by patch excision and by exposing the cytoplasmic face of inside-out patches to 50 nM T3. Nevertheless, excision to the inside-out configuration with 5 nM T3 in the pipette dramatically increased the %LE and lengthened MOT. These results suggest that T3 induced Na+ channel bursting by an extranuclear mechanism that requires proximity of T3 to the extracellular face of the Na+ channel. Furthermore, T3 was not membrane permeant on the time scale of these experiments. Na+ channel bursting may contribute to the propensity for arrhythmias in hyperthyroidism and to the positive inotropic effect of acute T3 administration in the stunned and ischemic myocardium.

A molecular basis for gating mode transitions in human skeletal muscle Na+ channels

Recombinant sodium channel alpha subunits expressed in Xenopus oocytes display an anomalously slow rate of inactivation that arises from channels that predominantly exist in a slow gating mode [1,2]. Co-expression of Na+ channel beta 1 subunit with the human skeletal muscle Na+ channel alpha subunit increases the Na+ current and induces normal gating behavior in Xenopus laevis oocytes. The effects of the beta 1 subunit can be explained by an allosterically induced conformational switch of the alpha subunit protein that occurs upon binding the beta 1 subunit. This binding alters the free energy barriers separating distinct conformational states of the channel. The results illustrate a fundamental modulation of ion channel gating at the molecular level, and specifically demonstrate the importance of the beta 1 subunit for gating mode changes of Na+ channels.

Loss of Na+ channel inactivation by anemone toxin (ATX II) mimics the myotonic state in hyperkalaemic periodic paralysis

1. Mutations that impair inactivation of the sodium channel in skeletal muscle have recently been postulated to cause several heritable forms of myotonia in man. A peptide toxin from Anemonia sulcata (ATX II) selectively disrupts the inactivation mechanism of sodium channels in a way that mimics these mutations. We applied ATX II to rat skeletal muscle to test the hypothesis that myotonia is inducible by altered sodium channel function. 2. Single-channel sodium currents were measured in blebs of surface membrane that arose from the mechanically disrupted fibres. ATX II impaired inactivation as demonstrated by persistent reopenings of sodium channels at strongly depolarized test potentials. A channel failed to inactivate, however, in only a small proportion of the depolarizing steps. With micromolar amounts of ATX II, the ensemble average open probability at the steady state was 0.01-0.02. 3. Ten micromolar ATX II slowed the relaxation of tension after a single twitch by an order of magnitude. Delayed relaxation is the in vitro analogue of the stiffness experienced by patients with myotonia. However, peak twitch force was not affected within the range of 0-10 microM ATX II. 4. Intracellular injection of a long-duration, constant current pulse elicited a train of action potentials in ATX II-treated fibres. After-depolarizations and repetitive firing often persisted beyond the duration of the stimulus. Trains of action potentials varied spontaneously in amplitude and firing frequency in a similar way to the electromyogram of a myotonic muscle. Both the after-depolarization and the post-stimulus firing were abolished by detubulating the fibres with glycerol. 5. We conclude that a loss of sodium channel inactivation alone, without changes in resting membrane conductance, is sufficient to produce the electrical and mechanical features of myotonia. Furthermore, in support of previous studies on myotonic muscle from patients, this model provides direct evidence that only a small proportion of sodium channels needs to function abnormally to cause myotonia.

Sodium channel regulation in the nervous system: how the action potential keeps in shape

Multiple Na+ channel types, differing in functional properties, have been identified in the nervous system. The role of distinct alpha subunits in generating this functional diversity is discussed in light of the recent finding that the beta 1 subunit modulates Na+ channel function. Possible mechanisms involved in the regulation of the genes coding for the different subunits are also discussed.

Functional expression of sodium channel mutations identified in families with periodic paralysis

Two mutations in the sodium channel alpha subunit that have been implicated as the cause of periodic paralysis were studied by functional expression in a mammalian cell line. Both mutations disrupted inactivation without affecting the time course of the onset of the sodium current or the single-channel conductance. This is the same functional defect that was observed in myotubes cultured from affected patients and proves that these mutations are not benign polymorphisms. Unlike the currents in the myotubes, however, there was no consistent potassium dependence for the noninactivating component. These mutations also define new regions of the sodium channel alpha subunit that are involved in the process of inactivation.

Inward sodium current at resting potentials in single cardiac myocytes induced by the ischemic metabolite lysophosphatidylcholine

To investigate possible ionic current mechanisms underlying ischemic arrhythmias, we studied single Na+ channel currents in rat and rabbit cardiac myocytes treated with the ischemic metabolite lysophosphatidylcholine (LPC) using the cell-attached and excised inside-out patch-clamp technique at 22 degrees C. LPC has been reported previously to reduce open probability and to induce sustained open channel activity at depolarized potentials. We now report two new observations for Na+ currents in LPC-treated patches: 1) The activation-voltage relation of the peak of the ensemble currents is shifted in the negative (hyperpolarizing) direction by approximately 20 mV compared with control currents. This effect was observed in all patches for depolarizations from a holding potential of -150 mV to different test potentials. 2) In some LPC-treated patches, Na+ channels exhibited sustained bursting activity at potentials as negative as -150 mV, giving a nondecaying inward current. This bursting activity was accompanied by double and triple simultaneous openings and closings, suggesting tight cooperativity in channel gating. These LPC-modified channels were identified as Na+ channels, because their unitary conductance was the same as Na+ channels in control solutions, because the single channel current-voltage relation was extrapolated to reverse at the Na+ Nernst potential, and because the current was blocked by the local anesthetic QX-222. This novel depolarizing current may play a role in the electrophysiological abnormalities in ischemia, including abnormal automaticity and reentrant arrhythmias, and could be a target for antiarrhythmic drugs.

Na channels that remain open throughout the cardiac action potential plateau

In this paper we report the direct measurement of rare Na channel events that occur during the cardiac action potential, viz., channels that open at the upstroke and remain open throughout the plateau and early repolarization phase. The technique we use allows us to record channel activity and action potentials at the same time; thus, we are certain of when the Na channels open and when they finally close. The slow Na channels have the same voltage dependence, single-channel conductance, and TTX sensitivity as the fast Na channels, and they conduct Li. It therefore seems likely that the fast and the slow currents flow through the same channel. If this interpretation is correct, then the Na channel not only initiates the action potential but also helps to maintain its plateau. It is possible that the slow Na currents represent a separate collection of channels rather than a low-probability state of the fast Na channels. Regardless of which interpretation is correct, the present experiments allow us to assess the effect of the slow currents on action potential shape and on sustained Na entry.

Glutathione accelerates sodium channel inactivation in excised rat axonal membrane patches

The effects of glutathione were studied on the gating behaviour of sodium channels in membrane patches of rat axons. Depolarizing pulses from -120 to -40 mV elicited sodium currents of up to 500 pA, indicating the simultaneous activation of up to 250 sodium channels. Inactivation of these channels in the excised, inside-out configuration was fitted by two time constants (tau h1 = 0.81 ms; tau h2 = 5.03 ms) and open time histograms at 0 mV revealed a biexponential distribution of channel openings (tau short = 0.28 ms; tau long = 3.68 ms). Both, the slow time constant of inactivation and the long lasting single channel openings disappeared after addition of the reducing agent glutathione (2-5 mM) to the bathing solution. Sodium channels of excised patches with glutathione present on the cytoplasmatic face of the membrane had inactivation kinetics similar to channels recorded in the cell-attached configuration. These observations indicate that redox processes may contribute to the gating of axonal sodium channels.

Gating kinetics of batrachotoxin-modified Na+ channels in the squid giant axon. Voltage and temperature effects

The gating kinetics of batrachotoxin-modified Na+ channels were studied in outside-out patches of axolemma from the squid giant axon by means of the cut-open axon technique. Single channel kinetics were characterized at different membrane voltages and temperatures. The probability of channel opening (Po) as a function of voltage was well described by a Boltzmann distribution with an equivalent number of gating particles of 3.58. The voltage at which the channel was open 50% of the time was a function of [Na+] and temperature. A decrease in the internal [Na+] induced a shift to the right of the Po vs. V curve, suggesting the presence of an integral negative fixed charge near the activation gate. An increase in temperature decreased Po, indicating a stabilization of the closed configuration of the channel and also a decrease in entropy upon channel opening. Probability density analysis of dwell times in the closed and open states of the channel at 0 degrees C revealed the presence of three closed and three open states. The slowest open kinetic component constituted only a small fraction of the total number of transitions and became negligible at voltages greater than -65 mV. Adjacent interval analysis showed that there is no correlation in the duration of successive open and closed events. Consistent with this analysis, maximum likelihood estimation of the rate constants for nine different single-channel models produced a preferred model (model 1) having a linear sequence of closed states and two open states emerging from the last closed state. The effect of temperature on the rate constants of model 1 was studied. An increase in temperature increased all rate constants; the shift in Po would be the result of an increase in the closing rates predominant over the change in the opening rates. The temperature study also provided the basis for building an energy diagram for the transitions between channel states.

muI Na+ channels expressed transiently in human embryonic kidney cells: biochemical and biophysical properties

We describe the transient expression of the rat skeletal muscle muI Na+ channel in human embryonic kidney (HEK 293) cells. Functional channels appear at a density of approximately 30 in a 10 microns 2 patch, comparable to those of native excitable cells. Unlike muI currents in oocytes, inactivation gating is predominantly (approximately 97%) fast, although clear evidence is provided for noninactivating gating modes, which have been linked to anomalous behavior in the inherited disorder hyperkalemic periodic paralysis. Sequence-specific antibodies detect a approximately 230 kd glycopeptide. The majority of molecules acquire only neutral oligosaccharides and are retained within the cell. Electrophoretic mobility on SDS gels suggests the molecules may acquire covalently attached lipid. The channel is readily phosphorylated by activation of the protein kinase A and protein kinase C second messenger pathways.

The sodium channel activator Brevetoxin-3 uncovers a multiplicity of different open states of the cardiac sodium channel

The interaction of Brevetoxin 3 (Pbtx-3), a sodium channel activator, with the cardiac sodium channel was studied at the single channel level. It was found that Pbtx-3 (20 microM) shifted steady-state activation to negative potentials, without major effects on the time course of macroscopic activation or macroscopic currents decay, as calculated from averaged single-channel records. Single-channel open times were found to be prolonged. Under the influence of the toxin, sodium channel openings could be observed frequently even at maintained depolarisation. These openings occurred to at least nine different subconductance levels of the open state with smaller conductivities than the maximal one and differed in their open times. Current amplitudes of these open substates were found to cluster around certain amplitude values. Appearance of substates at maintained depolarisation was dependent on the transmembrane potential (Em): Substates with smaller conductivity appeared more frequently at lower Em values whereas at higher Em values substates with higher conductivity values dominated. Furthermore, it was demonstrated that appearance of substates did not result from incomplete recovery from inactivation. From these observations it was concluded that the open substates observed correspond to different conformational states of the channel's activation gates. Under physiological conditions, when the sodium channel opens directly from its closed state these 'incomplete'-open states of the cardiac sodium channel are obscured by fast gating transitions between the corresponding, electrically silent, preopen states. Thus, Pbtx-3 acts mainly via stabilisation of the channel's preopen and different open states. A classification of sodium channel modifiers, based on their interaction with different conformational states of the channel is suggested.

A macro cell-attached patch-clamp study of the properties of the Na current in the vicinity of the motor endplate region of frog single interosseal skeletal muscle fibres

A macro cell-attached patch-clamp technique using large (16 microns) electrodes was developed to study the properties of the Na current (INa) in the motor endplate region of frog interosseal muscle fibres (resting potential approx.-99 mV). The fibre isolation procedure allows the formation of gigaOhm seals and thus a good voltage-clamp control of the patch. At 22 degrees C, in the presence of 110 mM external [Na] and of K channel blockers, INa activates at -49.6 +/- 1.9 mV, reaches a maximum of 4.33 +/- 0.66 mA/cm2 at -7.5 +/- 2.5 mV and reverses at Vrev equal to +63.2 +/- 1.9 mV. There is no evidence for the presence of a tubular INa. When the [Na] in the recording pipette is changed, Vrev exactly follows the Nernst equation for Na ions. An internal [Na] of 9.69 mM is determined. The Na conductance is maximum (63.56 +/- 7.03 mS/cm2) at +8.9 +/- 3.0 mV and markedly decreases for potentials positive to +25 mV. In contrast, the Na permeability (maximum of 6.13 +/- 0.95 x 10(-4) cm/s at +51.4 +/- 5.6 mV) remains more constant at positive potentials. The Na channels are half-inactivated at -68.9 mV and half-activated at -37.9 mV. At the potential at which INa is maximum, the half-time of activation is 223.9 +/- 10.5 microseconds, the time to peak 365.7 +/- 13.5 microseconds and the time constant of inactivation 260.7 +/- 11.2 microseconds. The time constant of reactivation at -100 mV is 1.44 +/- 0.19 ms. These and other results show that INa can be adequately studied with this technique.

Poneratoxin, a new toxin from an ant venom, reveals an interconversion between two gating modes of the Na channels in frog skeletal muscle fibres

The effects of synthetic poneratoxin (PoTX), a new toxin isolated from the venom of the ant Paraponera clavata, were studied under current- and voltage-clamp conditions in frog skeletal muscle fibres. PoTX induces a concentration-dependent (10(-9) M-5 x 10(-6) M) prolongation of the action potentials and, at saturating concentration, a slow repetitive activity developing at negative potentials. PoTX specifically acts on voltage-dependent Na channels by decreasing the peak Na current (INa) and by simultaneously inducing a slow INa which starts to activate at -85 mV and inactivates very slowly. Both the fast and the slow components of INa are suppressed by tetrodotoxin and reverse at the same potential corresponding to the equilibrium potential for Na ions. The fast component of INa has voltage dependence, activation and steady-state inactivation almost similar to those of the control INa. The voltage dependence of the slow Na conductance is 40 mV more negative than that of the fast one. The results suggest that PoTX affects all the Na channels and that the fast and the slow INa components originate from a possible PoTX-induced interconversion between a fast and a slow operating mode of the Na channels.

REPETITIVE ELECTRICAL ACTIVITY OF THE MUSCLE MEMBRANE INDUCED IN CHLORIDE-FREE MEDIUM

1. Superficial fibres of frog skeletal muscle were electrically stimulated in Ringer solution where the chloride content had been replaced by various weakly permeant anions. Changes of the membrane potential were recorded at three different time scales. The complex response was initiated by a volley of fast repetitive action potentials (10-20 ms cycle length) superimposed on the ascending phase of a transient depolarization to -35 mV. The transient depolarization was followed by a membrane potential oscillation (0.3-0.6 s cycle length). The parameters of the volley and membrane potential oscillation were not greatly affected by the substituent anion. 2. The transient depolarization was fully abolished by tetrodotoxin (3 mumol/L), but left unaffected by nifedipine (5 mumol/L), or by the replacement of extracellular Ca for Ni or Co. Tetraethylammonium (20-40 mmol/L) increased the duration and amplitude of the transient depolarization. The shape of transient depolarization was uniform in a given fibre, in spite of its marked variability under different experimental conditions. 3. Single outward current pulses applied in chloride-free solution containing tetraethylammonium (20-40 mmol/L) evoked prolonged depolarizations to positive membrane potentials accompanied by increases in the specific membrane conductance. This slow response, which was also frequently observed in the absence of TEA, was mediated by Ca ions, as it was insensitive to tetrodotoxin (3 mumol/L) but abolished by nifedipine (10 mumol/L). 4. Two populations of the muscle fibres were observed during the slow response. Some fibres repolarized completely, while others failed to produce complete repolarization but formed a plateau between -20 and -30 mV, lasting for several minutes. When the external K concentration was abruptly increased to 5 or 10 mmol/L during the plateau of the slow response, repolarization and increase in membrane conductance were observed. 5. In muscle fibres, having osmotically disrupted T-system, the duration of transient depolarization was in the range of minutes, in contrast to the range of seconds observed in intact fibres. The volley was preserved in glycerol treated fibres, however, the baseline of discharges was close to the resting potential and the rate of depolarization of the baseline was significantly less in glycerol treated than in intact fibres. 6. These results are consistent with the existence of a second stable membrane potential level in skeletal muscle between -40 and -30 mV. The depolarization and repolarization during the membrane potential oscillation and transient depolarization can be regarded as a partial or full transition, respectively, between these two stable membrane potential levels, possibly due to the conductance changes of the inward rectifier K channels.(ABSTRACT TRUNCATED AT 400 WORDS)

Synaptically triggered action potentials begin as a depolarizing ramp in rat hippocampal neurones in vitro

1. During just-suprathreshold synaptic activation of CA1 pyramidal cells in rat hippocampal slices in vitro the action potential begins as a slow depolarizing ramp, superimposed on the underlying EPSP and forming an integral part of the action potential. We call this ramp a synaptic prepotential (SyPP). 2. In order to examine the SyPP, a procedure for subtraction of the underlying EPSP was necessary. Because action potentials were only elicited by a subset of EPSPs with larger than average amplitude, a subtraction of the mean subthreshold EPSP would not give valid results. Instead, an EPSP to be subtracted was selected from an assemblage of subthreshold EPSPs, so that its amplitude matched the initial part of the spike-generating EPSP. 3. Virtually all action potentials started with a SyPP. Using an amplitude criterion of 1 S.D. of the mean of the matching subthreshold EPSPs, just-suprathreshold EPSPs gave prepotentials in 72-100% of all action potentials from fifteen randomly selected cells. With a criterion of 2 S.D.S, the frequency of occurrence ranged from 36 to 100%. 4. With a constant stimulus strength, there was a certain variability of the spike latencies. Shorter latency spikes had steeper, but smaller SyPPs than later spikes, suggesting that the slope of SyPP influenced the timing of the cell discharge. 5. The SyPP was best fitted by a single, exponentially rising curve, and was both smaller and slower than the large amplitude action potential. Its amplitude was 1-6 mV and the time constant 1-5 ms, which was 10-50 times slower than that of the upstroke of the action potential. 6. A properly timed hyperpolarizing current pulse could block the large amplitude action potential, thereby unmasking the SyPP as an initial depolarizing ramp. 7. The SyPP was more sensitive than the large amplitude action potential to intracellular injection of QX-314, a lidocaine derivative. At the concentrations used (10 or 30 mM) no detectable changes were seen in the large amplitude action potential. 8. Droplet application of a specific N-methyl-D-aspartate receptor antagonist, DL-2-amino-5-phosphonovaleric acid (1 mM), reduced both the EPSP and the firing probability, but did not change the SyPP. 9. The SyPP amplitude and time course depended upon the membrane potential at which the cell was activated. Depolarization enhanced and prolonged the SyPP, while hyperpolarization gave opposite effects. In part, the depolarization-induced amplitude increase could be attributed to membrane accommodation. 10. Antidromically evoked action potentials never started with a prepotential.(ABSTRACT TRUNCATED AT 400 WORDS)

A sodium channel gating model based on single channel, macroscopic ionic, and gating currents in the squid giant axon

Sodium channel gating behavior was modeled with Markovian models fitted to currents from the cut-open squid giant axon in the absence of divalent cations. Optimum models were selected with maximum likelihood criteria using single-channel data, then models were refined and extended by simultaneous fitting of macroscopic ionic currents, ON and OFF gating currents, and single-channel first latency densities over a wide voltage range. Best models have five closed states before channel opening, with inactivation from at least one closed state as well as the open state. Forward activation rate constants increase with depolarization, and deactivation rate constants increase with hyperpolarization. Rates of inactivation from the open or closed states are generally slower than activation or deactivation rates and show little or no voltage dependence. Channels tend to reopen several times before inactivating. Macroscopic rates of activation and inactivation result from a combination of closed, open and inactivated state transitions. At negative potentials the time to first opening dominates the macroscopic current due to slow activation rates compared with deactivation rates: channels tend to reopen rarely, and often inactivate from closed states before they reopen. At more positive potentials, the time to first opening and burst duration together produce the macroscopic current.

Multiple gating modes and the effect of modulating factors on the microI sodium channel

Macroscopic current from the microI skeletal muscle sodium channel expressed in Xenopus oocytes shows inactivation with two exponential components. The major, slower component's amplitude decreases with rapid pulsing. When microI cRNA is coinjected with rat skeletal muscle or brain mRNA the faster component becomes predominant. Individual microI channels switch between two principal gating modes, opening either only once per depolarization, or repeatedly in long bursts. These two modes differ in both activation and inactivation kinetics. There is also evidence for additional gating modes. It appears that the equilibrium among gating modes is influenced by a modulating factor encoded in rat skeletal muscle and brain mRNA. The modal gating is similar to that observed in hyperkalemic periodic paralysis.

Voltage-sensitive Na+ channels: motifs, modes and modulation

Much recent progress has been made in understanding the structural organization and functional properties of voltage-dependent Na+ channels, in particular in the areas of activation, ion conductance, and inactivation. At the same time, however, electrophysiological studies have revealed new, more complex functional properties in the form of at least two gating modes and the existence of as yet unidentified modulatory factors.

Voltage-sensitive sodium channels: agents that perturb inactivation gating

In summary, the voltage-sensitive sodium channel from eel electroplax provides an optimal preparation for biochemical and biophysical studies of molecular structure and gating. We have demonstrated that the purified and reconstituted protein is capable of functioning normally, exhibiting, among other properties, voltage-dependent activation and inactivation gating mechanisms. We have been able to recreate the classical electrophysiological studies in which inactivation gating can be removed by proteolytic modification of the cytoplasmic surface of the molecule, and have mapped the probable site of modification to the peptide segment lying between subunit domains III and IV. We have demonstrated that the reconstituted protein undergoes interactions with the lidocaine derivative QX-314 which, at low concentrations, results in paradoxical activation of the channel and a facilitation of modification by oxidizing reagents that remove inactivation gating.

Multiple conductance states of the light-activated channel of Limulus ventral photoreceptors. Alteration of conductance state during light

The properties of light-dependent channels in Limulus ventral photoreceptors have been studied in cell-attached patches. Two sizes of single-channel events are seen during illumination. Previous work has characterized the large (40 pS) events; the goal of the current work was to characterize the small (15 pS) events and determine their relationship to the large events. The small events are activated by light rather than as a secondary result of the change in membrane voltage during light. The mean open time of the small events is 1.34 +/- 0.49 ms (mean +/- SD, n = 15), approximately 50% of that of the large events. The large and small events have the same reversal potential and a similar dependence of open-state probability on voltage. Evidence that these events are due to different conductance states of the same channel comes from analysis of relatively infrequent events showing a direct transition between the 15 and 40-pS levels. Furthermore, large and small events do not superpose, even at positive voltages when the probability of being open is very high, as would be predicted if the two-sized events were due to independent channels. Expression of the different conductance states is not random; during steady illumination there are alternating periods of several hundred milliseconds in which there are consecutive, sequential large events followed by periods in which there are consecutive, sequential small events. At early times during the response to a step of light, the large conductance state is preferentially expressed. At later times, there is an increase in the relative contribution of the low conductance state. These findings indicate that there is a process that changes the preferred conductance state of the channel. This alteration has functional importance in the process of light adaptation.

A sodium channel defect in hyperkalemic periodic paralysis: potassium-induced failure of inactivation

Hyperkalemic periodic analysis (HPP) is an autosomal dominant disorder characterized by episodic weakness lasting minutes to days in association with a mild elevation in serum K+. In vitro measurements of whole-cell currents in HPP muscle have demonstrated a persistent, tetrodotoxin-sensitive Na+ current, and we have recently shown by linkage analysis that the Na+ channel alpha subunit gene may contain the HPP mutation. In this study, we have made patch-clamp recordings from cultured HPP myotubes and found a defect in the normal voltage-dependent inactivation of Na+ channels. Moderate elevation of extracellular K+ favors an aberrant gating mode in a small fraction of the channels that is characterized by persistent reopenings and prolonged dwell times in the open state. The Na+ current, through noninactivating channels, may cause the skeletal muscle weakness in HPP by depolarizing the cell, thereby inactivating normal Na+ channels, which are then unable to generate an action potential. Thus the dominant expression of HPP is manifest by inactivation of the wild-type Na+ channel through the influence of the mutant gene product on membrane voltage.

BTX modification of Na channels in squid axons. I. State dependence of BTX action

The state dependence of Na channel modification by batrachotoxin (BTX) was investigated in voltage-clamped and internally perfused squid giant axons before (control axons) and after the pharmacological removal of the fast inactivation by pronase, chloramine-T, or NBA (pretreated axons). In control axons, in the presence of 2-5 microM BTX, a repetitive depolarization to open the channels was required to achieve a complete BTX modification, characterized by the suppression of the fast inactivation and a simultaneous 50-mV shift of the activation voltage dependence in the hyperpolarizing direction, whereas a single long-lasting (10 min) depolarization to +50 mV could promote the modification of only a small fraction of the channels, the noninactivating ones. In pretreated axons, such a single sustained depolarization as well as the repetitive depolarization could induce a complete modification, as evidenced by a similar shift of the activation voltage dependence. Therefore, the fast inactivated channels were not modified by BTX. We compared the rate of BTX modification of the open and slow inactivated channels in control and pretreated axons using different protocols: (a) During a repetitive depolarization with either 4- or 100-ms conditioning pulses to +80 mV, all the channels were modified in the open state in control axons as well as in pretreated axons, with a similar time constant of approximately 1.2 s. (b) In pronase-treated axons, when all the channels were in the slow inactivated state before BTX application, BTX could modify all the channels, but at a very slow rate, with a time constant of approximately 9.5 min. We conclude that at the macroscopic level BTX modification can occur through two different pathways: (a) via the open state, and (b) via the slow inactivated state of the channels that lack the fast inactivation, spontaneously or pharmacologically, but at a rate approximately 500-fold slower than through the main open channel pathway.