The saxitoxin/tetrodotoxin binding site on cloned rat brain IIa Na channels is in the transmembrane electric field.

The rat brain IIa (BrIIa) Na channel alpha-subunit and the brain beta 1 subunit were coexpressed in Xenopus oocytes, and peak whole-oocyte Na current (INa) was measured at a test potential of -10 mV. Hyperpolarization of the holding potential resulted in an increased affinity of STX and TTX rested-state block of BrIIa Na channels. The apparent half-block concentration (ED50) for STX of BrIIa current decreased with hyperpolarizing holding potentials (Vhold). At Vhold of -100 mV, the ED50 was 2.1 +/- 0.4 nM, and the affinity increased to a ED50 of 1.2 +/- 0.2 nM with Vhold of -140 mV. In the absence of toxin, the peak current amplitude was the same for all potentials negative to -90 mV, demonstrating that all of the channels were in a closed conformation and maximally available to open in this range of holding potentials. The Woodhull model (1973) was used to describe the increase of the STX ED50 as a function of holding potential. The equivalent electrical distance of block (delta) by STX was 0.18 from the extracellular milieu when the valence of STX was fixed to +2. Analysis of the holding potential dependence of TTX block yielded a similar delta when the valence of TTX was fixed to +1. We conclude that the guanidinium toxin site is located partially within the transmembrane electric field. Previous site-directed mutagenesis studies demonstrated that an isoform-specific phenylalanine in the BrIIa channel is critical for high affinity toxin block.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential expression of sodium channel activities during the development of chick skeletal muscle cells in culture

The expression of Na+ channels during differentiation of cultured embryonic chick skeletal muscle cells was investigated using saxitoxin (STX) and batrachotoxin (BTX), which previously have been shown to interact with distinct, separate receptor sites of the voltage-sensitive Na+ channel of excitable cells. In the present study, parallel measurements of binding of [3H]-STX (STX) and of BTX-activated 22Na+ uptake (Na influx) were made in order to establish the temporal relationship of the appearance of these two Na+ channel activities during myogenesis. Na influx was clearly measurable in 2-d cells; from day 3 to day 7 the maximum Na influx approximately doubled when measured with saturating BTX concentrations potentiated by Leiurus scorpion toxin, while the apparent affinity of BTX, measured without scorpion toxin, also increased. Saturable STX binding did not appear consistently until day 3; from then until day 7 the STX binding capacity increased about threefold, whereas the equilibrium dissociation constant (KD) decreased about fourfold. Although Na influx in cells of all ages was totally inhibited by STX or tetrodotoxin (TTX) at 10 microM, lower concentrations (2-50 nM) blocked the influx in 7-d cells much more effectively than that in 3-d cells, where half the flux was resistant to STX at 20-50 nM. Similar but smaller differences characterized the block by TTX. In addition, when protein synthesis is inhibited by cycloheximide, both Na influx and STX binding activities disappear more rapidly in 3-d than in 7-d cells, which shows that these functions are less stable metabolically in the younger cells.     

Specificity for block by saxitoxin and divalent cations at a residue which determines sensitivity of sodium channel subtypes to guanidinium toxins

bTyrosine 401 of the skeletal muscle isoform (mu 1) of the rat muscle Na channel is an important determinant of high affinity block by tetrodotoxin (TTX) and saxitoxin (STX) in Na-channel isoforms. In mammalian heart Na channels, this residue is substituted by cysteine, which results in low affinity for TTX/STX and enhanced sensitivity to block by Zn2+ and Cd2+. In this study, we investigated the molecular basis for high affinity block of Na channels by STX and divalent cations by measuring inhibition of macroscopic Na+ current for a series of point mutations at residue Tyr401 of the rat mu 1 Na channel expressed in Xenopus oocytes. Substitution of Tyr401 by Gly, Ala, Ser, Cys, Asp, His, Trp, and Phe produced functional Na+ currents without major perturbation of gating or ionic selectivity. High affinity block by STX and neosaxitoxin (NEO) with Ki values in the range of 2.6-18 nM required Tyr, Phe, or Trp, suggestive of an interaction between an aromatic ring and a guanidinium group of the toxin. The Cys mutation resulted in a 7- and 23-fold enhancement of the dissociation rate of STX and NEO, respectively, corresponding to rapid toxin dissociation rates of cardiac Na channels. High affinity block by Zn2+ (Ki = 8-23 microM) required Cys, His, or Asp, three residues commonly found to coordinate directly with Zn2+ in metalloproteins. For the Cys mutant of mu 1 and also for the cardiac isoform Na channel (rh1) expressed in the L6 rat muscle cell line, inhibition of macroscopic Na+ conductance by Zn2+ reached a plateau at 85-90% inhibition, suggesting the presence of a substate current. The Asp mutant also displayed enhanced affinity for inhibition of conductance by Ca2+ (Ki = 0.3 mM vs approximately 40 mM in wild type), but block by Ca2+ was incomplete, saturating at approximately 69% inhibition. In contrast, Cd2+ completely blocked macroscopic current in the Cys mutant and the L6 cell line. These results imply that the magnitude of substate current depends on the particular residue at position 401 and the species of divalent cation. The His mutant also exhibited enhanced sensitivity to block by H+ with a pKa of approximately 7.5 for the His imidazole group. Our findings provide further evidence that residue 401 of mu 1 is located within the outer vestibule of the Na channel but external to the single-filing region for permeant ions.     

Periodate treatment reduces the tetrodotoxin-sensitivity of voltage-gated Na+ channels

(1) Voltage-clamped nerve fibres of the frog Rana esculenta were treated with periodate in the extracellular solution. (2) Periodate treatment irreversibly reduced the effect of tetrodotoxin (TTX) on the Na+ currents. (3) The effect of saxitoxin (STX) was also reduced but less than that of TTX. (4) The presence of STX during the application of periodate to the nerve fibre almost completely prevented the effect of the chemical reagent on the TTX sensitivity of the Na+ channels. (5) The reduction of the TTX effect is not due to the reaction of small amounts of periodate with the diol group of this toxin, because the effect was seen after prolonged washing with reagent-free Ringer solution with or without high amounts of ribose. (6) Carboxyl groups present in the Na+ channel seem to be quite important for the binding of TTX and STX. Periodate modifies several amino acid side chains, however, it does not attack carboxyl groups in a peptide chain. Thus, these results suggest that periodate modifies a further group critically involved in the binding of TTX and STX.     

Tonic and phasic guanidinium toxin-block of skeletal muscle Na channels expressed in Mammalian cells

The blockage of skeletal muscle sodium channels by tetrodotoxin (TTX) and saxitoxin (STX) have been studied in CHO cells permanently expressing rat Nav1.4 channels. Tonic and use-dependent blockage were analyzed in the framework of the ion-trapped model. The tonic affinity (26.6 nM) and the maximum affinity (7.7 nM) of TTX, as well as the "on" and "off" rate constants measured in this preparation, are in remarkably good agreement with those measured for Nav1.2 expressed in frog oocytes, indicating that the structure of the toxin receptor of Nav1.4 and Nav1.2 channels are very similar and that the expression method does not have any influence on the pore properties of the sodium channel. The higher affinity of STX for the sodium channels (tonic and maximum affinity of 1.8 nM and 0.74 nM respectively) is explained as an increase on the "on" rate constant (approximately 0.03 s(-1) nM(-1)), compared to that of TTX (approximately 0.003 s(-1) nM(-1)), while the "off" rate constant is the same for both toxins (approximately 0.02 s(-1)). Estimations of the free-energy differences of the toxin-channel interaction indicate that STX is bound in a more external position than TTX. Similarly, the comparison of the toxins free energy of binding to a ion-free, Na(+)- and Ca(2+)-occupied channel, is consistent with a binding site in the selectivity filter for Ca(2+) more external than for Na(+). This data may be useful in further attempts at sodium-channel pore modeling.     

Saxitoxin and tetrodotoxin. Electrostatic effects on sodium channel gating current in crayfish axons.

The effects of extracellular saxitoxin (STX) and tetrodotoxin (TTX) on gating current (IgON) were studied in voltage clamped crayfish giant axons. At a holding potential (VH) of -90 mV, integrated gating charge (QON) was found to be 56% suppressed when 200 nM STX was added to the external solution, and 75% suppressed following the addition of 200 nM TTX. These concentrations of toxin are sufficiently high to block greater than 99% of sodium channels. A smaller suppression of IgON was observed when 1 nM STX was used (KD = 1-2 nM STX). The suppression of IgON by external toxin was found to be hold potential dependent, with only minimal suppression observed at the most hyperpolarized hold potentials, -140 to -120 mV. The maximal effect of these toxins on IgON was observed at hold potentials where the QON vs. VH plot was found to be steepest, -100 to -80 mV. The suppression of IgON induced by TTX is partially relieved following the removal of fast inactivation by intracellular treatment with N-bromoacetamide (NBA). The effect of STX and TTX on IgON is equivalent to a hyperpolarizing shift in the steady state inactivation curve, with 200 nM STX and 200 nM TTX inducing shifts of 4.9 +/- 1.7 mV and 10.0 +/- 2.1 mV, respectively. Our results are consistent with a model where the binding of toxin displaces a divalent cation from a negatively charged site near the external opening of the sodium channel, thereby producing a voltage offset sensed by the channel gating apparatus.     

Kinetic basis for insensitivity to tetrodotoxin and saxitoxin in sodium channels of canine heart and denervated rat skeletal muscle

The single-channel blocking kinetics of tetrodotoxin (TTX), saxitoxin (STX), and several STX derivatives were measured for various Na-channel subtypes incorporated into planar lipid bilayers in the presence of batrachotoxin. The subtypes studied include Na channels from rat skeletal muscle and rat brain, which have high affinity for TTX/STX, and Na channels from denervated rat skeletal muscle and canine heart, which have about 20-60-fold lower affinity for these toxins at 22 degrees C. The equilibrium dissociation constant of toxin binding is an exponential function of voltage (e-fold per 40 mV) in the range of -60 to +60 mV. This voltage dependence is similar for all channel subtypes and toxins, indicating that this property is a conserved feature of channel function for batrachotoxin-activated channels. The decrease in binding affinity for TTX and STX in low-affinity subtypes is due to a 3-9-fold decrease in the association rate constant and a 4-8-fold increase in the dissociation rate constant. For a series of STX derivatives, the association rate constant for toxin binding is approximately an exponential function of net toxin charge in membranes of neutral lipids, implying that there is a negative surface potential due to fixed negative charges in the vicinity of the toxin receptor. The magnitude of this surface potential (-35 to -43 mV at 0.2 M NaCl) is similar for both high- and low-affinity subtypes, suggesting that the lower association rate of toxin binding to toxin-insensitive subtypes is not due to decreased surface charge but rather to a slower protein conformational step. The increased rates of toxin dissociation from insensitive subtypes can be attributed to the loss of a few specific bonding interactions in the binding site such as loss of a hydrogen bond with the N-1 hydroxyl group of neosaxitoxin, which contributes about 1 kcal/mol of intrinsic binding energy.     

Isolation of membranes enriched in "tetrodotoxin-insensitive" saxitoxin-binding sites from mammalian ventricle. Receptor solubilization

Purification and characterization of Na+ channel protein from mammalian ventricular myocytes has heretofore been complicated by the low concentration of Na+ channels and by the finding that mammalian ventricles contain both tetrodotoxin (TTX)-sensitive channels (TSC), with high affinity for saxitoxin (STX), and TTX-insensitive channels (TIC), with low affinity for STX. Most (perhaps all) of the sodium current for myocardial cell action potentials is carried by TIC. Most, if not all, of the cardiac TSC reside in nerves innervating the heart. To isolate TIC in sufficient quantity for further study, we prepared t-tubular sarcolemmal vesicles from large (sheep) hearts with techniques designated to minimize contamination from nerve plasmalemma. Discontinuous sucrose density gradient centrifugation of these membranes produced membrane vesicles, some of which contained no detectable TSC (range 94-100% TIC, or 0-6% TSC), at a concentration of 200-1500 fmol total sites/mg protein, with yields of 4.0-25.0 mg protein/100 g starting material (ventricle). TTX-insensitive STX-binding sites were solubilized from the membranes by 1% digitonin (and with less stability by Triton X-100). The equilibrium binding constant and dissociation rate coefficient for STX binding to the digitonin-solubilized sites were similar to those of the binding sites for the unsolubilized membranes. Unlabeled TTX competed with [3H]STX for the site with 14 times less affinity than did unlabeled STX. Digitonin-solubilized sites had a half-life for STX binding of about 24 h. Binding could be further stabilized by addition of Mg2+ or Ca2+ and exogenous phospholipid.     

Kinetic analysis of the action of Leiurus scorpion alpha-toxin on ionic currents in myelinated nerve

The effects of a neurotoxin, purified from the venom of the scorpion Leiurus quinquestriatus, on the ionic currents of toad single myelinated fibers were studied under voltage-clamp conditions. Unlike previous investigations using crude scorpion venom, purified Leiurus toxin II alpha at high concentrations (200-400 nM) did not affect the K currents, nor did it reduce the peak Na current in the early stages of treatment. The activation of the Na channel was unaffected by the toxin, the activation time course remained unchanged, and the peak Na current vs. voltage relationship was not altered. In contrast, Na channel inactivation was considerably slowed and became incomplete. As a result, a steady state Na current was maintained during prolonged depolarizations of several seconds. These steady state Na currents had a different voltage dependence from peak Na currents and appeared to result from the opening of previously inactivated Na channels. The opening kinetics of the steady state current were exponential and had rates approximately 100-fold slower than the normal activation processes described for transitions from the resting state to the open state. In addition, the dependence of the peak Na current on the potential of preceding conditioning pulses was also dramatically altered by toxin treatment; this parameter reached a minimal value near a membrane potential of -50 mV and then increased continuously to a "plateau" value at potentials greater than +50 mV. The amplitude of this plateau was dependent on toxin concentration, reaching a maximum value equal to approximately 50% of the peak current; voltage-dependent reversal of the toxin's action limits the amplitude of the plateauing effect. The measured plateau effect was half-maximum at a toxin concentration of 12 nM, a value quite similar to the concentration producing half of the maximum slowing of Na channel inactivation. The results of Hill plots for these actions suggest that one toxin molecule binds to one Na channel. Thus, the binding of a single toxin molecule probably both produces the steady state currents and slows the Na channel inactivation. We propose that Leiurus toxin inhibits the conversion of the open state to inactivated states in a voltage-dependent manner, and thereby permits a fraction of the total Na permeability to remain at membrane potentials where inactivation is normally complete.     

Batrachotoxin-modified sodium channels in planar lipid bilayers. Characterization of saxitoxin- and tetrodotoxin-induced channel closures

The guanidinium toxin-induced inhibition of the current through voltage-dependent sodium channels was examined for batrachotoxin-modified channels incorporated into planar lipid bilayers that carry no net charge. To ascertain whether a net negative charge exists in the vicinity of the toxin-binding site, we studied the channel closures induced by tetrodotoxin (TTX) and saxitoxin (STX) over a wide range of [Na+]. These toxins carry charges of +1 and +2, respectively. The frequency and duration of the toxin-induced closures are voltage dependent. The voltage dependence was similar for STX and TTX, independent of [Na+], which indicates that the binding site is located superficially at the extracellular surface of the sodium channel. The toxin dissociation constant, KD, and the rate constant for the toxin-induced closures, kc, varied as a function of [Na+]. The Na+ dependence was larger for STX than for TTX. Similarly, the addition of tetraethylammonium (TEA+) or Zn++ increased KD and decreased kc more for STX than for TTX. These differential effects are interpreted to arise from changes in the electrostatic potential near the toxin-binding site. The charges giving rise to this potential must reside on the channel since the bilayers had no net charge. The Na+ dependence of the ratios KDSTX/KDTTX and kcSTX/kcTTX was used to estimate an apparent charge density near the toxin-binding site of about -0.33 e X nm-2. Zn++ causes a voltage-dependent block of the single-channel current, as if Zn++ bound at a site within the permeation path, thereby blocking Na+ movement. There was no measurable interaction between Zn++ at its blocking site and STX or TTX at their binding site, which suggests that the toxin-binding site is separate from the channel entrance. The separation between the toxin-binding site and the Zn++ blocking site was estimated to be at least 1.5 nm. A model for toxin-induced channel closures is proposed, based on conformational changes in the channel subsequent to toxin binding.     

Use-dependent block of the voltage-gated Na+ channel by tetrodotoxin and saxitoxin: Effect of pore mutations that change ionic selectivity

Voltage-gated Na⁺ channels (NaV channels) are specifically blocked by guanidinium toxins such as tetrodotoxin (TTX) and saxitoxin (STX) with nanomolar to micromolar affinity depending on key amino acid substitutions in the outer vestibule of the channel that vary with NaV gene isoforms. All NaV channels that have been studied exhibit a use-dependent enhancement of TTX/STX affinity when the channel is stimulated with brief repetitive voltage depolarizations from a hyperpolarized starting voltage. Two models have been proposed to explain the mechanism of TTX/STX use dependence: a conformational mechanism and a trapped ion mechanism. In this study, we used selectivity filter mutations (K1237R, K1237A, and K1237H) of the rat muscle NaV1.4 channel that are known to alter ionic selectivity and Ca²⁺ permeability to test the trapped ion mechanism, which attributes use-dependent enhancement of toxin affinity to electrostatic repulsion between the bound toxin and Ca²⁺ or Na⁺ ions trapped inside the channel vestibule in the closed state. Our results indicate that TTX/STX use dependence is not relieved by mutations that enhance Ca²⁺ permeability, suggesting that ion–toxin repulsion is not the primary factor that determines use dependence. Evidence now favors the idea that TTX/STX use dependence arises from conformational coupling of the voltage sensor domain or domains with residues in the toxin-binding site that are also involved in slow inactivation.     

Saxitoxin blocks batrachotoxin-modified sodium channels in the node of Ranvier in a voltage-dependent manner.

The inhibition by saxitoxin (STX) of single Na channels incorporated into planar lipid bilayers and modified by batrachotoxin (BTX) previously has been shown to be voltage dependent (Krueger, B.K.,J.F. Worley, and R. J. French, 1983, Nature [Lond.], 303:172-175; Moczydlowski, E., S. Hall, S. S. Garber, G. S. Strichartz, and C. Miller, 1984, J. Gen. Physiol., 84:687-704). We tested for such a voltage dependence of STX block of the Na current in voltage-clamped frog nodes of Ranvier. The block by STX of normal Na channels showed no modulation in response to maintained (20 s) changes of the membrane potential or to a train of brief pulses to potentials more positive than the holding potential. However, when the nodal channels were modified by BTX, the train of pulses produced a modulation of the block of the Na current by STX. The modulation of STX block depended on the voltage of the conditioning pulses and this voltage dependence agreed well with that predicted from the single channel studies over the membrane potential range used in those studies. In addition, we found that the voltage dependence of STX block was manifest only at potentials equal to or more positive than required to activate the channels. Most of the apparent differences among data from single channels in bilayers, equilibrium binding studies of STX, and the experiments described here are resolved by the hypotheses that (a) STX binding to open channels is voltage dependent, and (b) the affinities of STX for closed and inactivated channels are independent of voltage, equal, and less than the open channel affinity at potentials less than 0 mV. Whether these hypotheses apply to the STX block of all Na channels or just of BTX-modified channels remains to be determined.     

Use-dependent block with tetrodotoxin and saxitoxin at frog Ranvier nodes I. Intrinsic channel and toxin parameters

The use-dependent phasic blockage of sodium channels by tetrodotoxin (TTX) and saxitoxin (STX) was examined in frog nodes of Ranvier using trains of depolarizing pulses. The decline of the peak Na⁺ current from its initial value (I ₀) before the train to a stationary value (I ) after the train was more pronounced at more negative holding potentials. The relationship betweenI /I ₀ and holding potential was fitted by a sigmoid function which yielded values for the steepness of the voltage dependencies of around –15 mV for TTX and – 8 mV for STX. Similar values were obtained at toxin concentrations of 4 and 8 nM. The higher voltage sensitivity of STX versus TTX is interpreted in terms of the higher charge and the faster binding kinetics of STX. These differences also explain the frequency dependence of the decline of Na⁺ currents with STX (between 0.5 and 2 Hz) and the frequency independence with TTX. Variation of the pulse amplitude in a train of conditioning pulses revealed that the magnitude of the use-dependent actions of STX parallels the steady-state Na⁺ inactivation curveh . Inhibition of inactivation, by pre-treatment with chloramine-T, did not, however, abolish the use dependence. Instead, it introduced a change in the time constants of the decline of the Na⁺ currents and the magnitude became independent of the holding potential.     

Stimulation pulse characteristics and electrode configuration determine site of excitation in isolated mammalian skeletal muscle: implications for fatigue.

We examined whether electrical field stimulation with varying characteristics could excite isolated mammalian skeletal muscle through different sites. Supramaximal (20-V, 0.1-ms) pulse stimulation with transverse wire or parallel plate electrodes evoked similar forces in nonfatigued slow-twitch soleus and fast-twitch extensor digitorum longus (EDL) muscles from mice. d-tubocurarine shifted the twitch force-stimulation strength relationship toward higher pulse strengths with both electrode configurations in soleus muscle, suggesting that weaker pulses excite muscle via neuromuscular transmission. With wire stimulation, movement of the recording electrode along the muscle caused a delay between the stimulus artifact and the peak of the action potential, consistent with action potential propagation along the sarcolemma. TTX abolished all contractions evoked with 20-V, 0.1-ms pulses, suggesting that excitation occurred via voltage-dependent Na+ channels and, hence, muscle action potentials. TTX did not prevent force development with > or = 0.4-ms pulses in soleus or 1-ms pulses in EDL muscle. Furthermore, myoplasmic Ca2+ (i.e., the fura 2 ratio) and sarcomere shortening were greater during tetanic stimulation with 2.0-ms than with 0.5-ms pulses in flexor digitorum brevis fibers from rats. TTX prevented all shortening and Ca2+ release with 0.5-ms, but not 2.0-ms, pulses, indicating that longer pulses can directly trigger Ca2+ release. Hence, proper interpretation of mechanistic studies requires precise understanding of how muscles are excited; otherwise, incorrect conclusions can be made. Using this new understanding, we showed that disrupted propagation of action potentials along the surface membrane is a major cause of fatigue in soleus muscle that is focally and continuously stimulated at 125 Hz.     

Effects of deuterium oxide on the rate and dissociation constants for saxitoxin and tetrodotoxin action. Voltage-clamp studies on frog myelinated nerve

The actions of tetrodotoxin (TTX) and saxitoxin (STX) in normal water and in deuterium oxide (D2O) have been studied in frog myelinated nerve. Substitution of D2O for H2O in normal Ringer's solution has no effect on the potency of TTX in blocking action potentials but increases the potency of STX by approximately 50%. Under voltage clamp, the steady-state inhibition of sodium currents by 1 nM STX is doubled in D2O as a result of a halving of the rate of dissociation of STX from the sodium channel; the rate of block by STX is not measurably changed by D2O. Neither steady-state inhibition nor the on- or off-rate constants of TTX are changed by D2O substitution. The isotopic effects on STX binding are observed less than 10 min after the toxin has been added to D2O, thus eliminating the possibility that slow-exchange (t 1/2 greater than 10 h) hydrogen-binding sites on STX are involved. The results are consistent with a hypothesis that attributes receptor-toxin stabilization to isotopic changes of hydrogen bonding; this interpretation suggests that hydrogen bonds contribute more to the binding of STX than to that of TTX at the sodium channel.     

Differences in saxitoxin and tetrodotoxin binding revealed by mutagenesis of the Na+ channel outer vestibule.

The marine guanidinium toxins, saxitoxin (STX) and tetrodotoxin (TTX), have played crucial roles in the study of voltage-gated Na+ channels. Because they have similar actions, sizes, and functional groups, they have been thought to associate with the channel in the same manner, and early mutational studies supported this idea. Recent experiments by. Biophys. J. 67:2305-2315) have suggested that the toxins bind differently to the isoform-specific domain I Phe/Tyr/Cys location. In the adult skeletal muscle Na+ channel isoform (microliter), we compared the effects on both TTX and STX affinities of mutations in eight positions known to influence toxin binding. The results permitted the assignment of energies contributed by each amino acid to the binding reaction. For neutralizing mutations of Asp400, Glu755, and Lys1237, all thought to be part of the selectivity filter of the channel, the loss of binding energy was identical for the two toxins. However, the loss of binding energy was quite different for vestibule residues considered to be more superficial. Specifically, STX affinity was reduced much more by neutralizations of Glu758 and Asp1532. On the other hand, mutation of Tyr401 to Cys reduced TTX binding energy twice as much as it reduced STX binding energy. Kinetic analysis suggested that all outer vestibule residues tested interacted with both toxins early in the binding reaction (consistent with larger changes in the binding than unbinding rates) before the transition state and formation of the final bound complex. We propose a revised model of TTX and STX binding in the Na+ channel outer vestibule in which the toxins have similar interactions at the selectivity filter, TTX has a stronger interaction with Tyr401, and STX interacts more strongly with the more extracellular residues.     

Slow currents through single sodium channels of the adult rat heart

The currents through single Na+ channels from the sarcolemma of ventricular cells dissociated from adult rat hearts were studied using the patch-clamp technique. All patches had several Na+ channels; most had 5-10, while some had up to 50 channels. At 10 degrees C, the conductance of the channel was 9.8 pS. The mean current for sets of many identical pulses inactivated exponentially with a time constant of 1.7 +/- 0.6 ms at -40 mV. Careful examination of the mean currents revealed a small, slow component of inactivation at pulse potentials ranging from -60 to -30 mV. The time constant of the slow component was between 8 and 14 ms. The channels that caused the slow component had the same conductance and reversal potential as the fast Na+ currents and were blocked by tetrodotoxin. The slow currents appear to have been caused by repeated openings of one or more channels. The holding potential influenced the frequency with which such channel reopening occurred. The slow component was prominent during pulses from a holding potential of -100 mV, while it was very small during pulses from -140 mV. Ultraslow currents through the Na+ channel were observed occasionally in patches that had large numbers of channels. They consisted of bursts of 10 or more sequential openings of a single channel and lasted for up to 150 ms. We conclude that the single channel data cannot be explained by standard models, even those that have two inactivated states or two open states of the channel. Our results suggest that Na+ channels can function in several different "modes," each with a different inactivation rate.     

Competitive binding interaction between Zn2+ and saxitoxin in cardiac Na+ channels. Evidence for a sulfhydryl group in the Zn2+/saxitoxin binding site.

Mammalian heart Na+ channels exhibit approximately 100-fold higher affinity for block by external Zn2+ than other Na+ channel subtypes. With batrachotoxin-modified Na+ channels from dog or calf heart, micromolar concentrations of external Zn2+ result in a flickering block to a substate level with a conductance of approximately 12% of the open channel at -50 mV. We examined the hypothesis that, in this blocking mode, Zn2+ binds to a subsite of the saxitoxin (STX) binding site of heart Na+ channels by single-channel analysis of the interaction between Zn2+ and STX and also by chemical modification experiments on single heart Na+ channels incorporated into planar lipid bilayers in the presence of batrachotoxin. We found that external Zn2+ relieved block by STX in a strictly competitive fashion. Kinetic analysis of this phenomenon was consistent with a scheme involving direct binding competition between Zn2+ and STX at a single site with intrinsic equilibrium dissociation constants of 30 nM for STX and 30 microM for Zn2+. Because high-affinity Zn2(+)-binding sites often include sulfhydryl groups as coordinating ligands of this metal ion, we tested the effect of a sulfhydryl-specific alkylating reagent, iodoacetamide (IAA), on Zn2+ and STX block. For six calf heart Na+ channels, we observed that exposure to 5 mM IAA completely abolished Zn2+ block and concomitantly modified STX binding with at least 20-fold reduction in affinity. These results lead us to propose a model in which Zn2+ binds to a subsite within or near the STX binding site of heart Na+ channels. This site is also presumed to contain one or more cysteine sulfhydryl groups.     

Use-dependent block with tetrodotoxin and saxitoxin at frog Ranvier nodes II. Extrinsic influence of cations

Use-dependent declines of Na⁺ currents in myelinated frog nerve fibres were measured during a train of depolarizing pulses in solutions containing tetrodotoxin (TTX) or saxitoxin (STX). The following effects of external monovalent (Na⁺), divalent (Ca²⁺, Mg²⁺) and trivalent (La²⁺) cations on use dependence were found: Increasing the Ca²⁺ concentration from 2 to 8 mM shifts its voltage dependence by 20 mV whereas no significant use-dependent decline occurred at 0.2 mM Ca²⁺. Doubling the external Na⁺ concentration in 0.2 mM Ca²⁺ solutions did not initiate phasic block. External Mg²⁺ ions induced a smaller, and La²⁺ ions a larger, use dependence. The time constants of the current decline were 4-fold greater in 1.08 mM La²⁺. The static block of Na⁺ currents by La³⁺ could be directly demonstrated by the relief of block during a train of pulses. The results are qualitatively explained by a toxin binding site at the Na⁺ channel whose affinity for TTX or STX depends oni) the gating conformation of the channel, probably the inactivation andii) the occupancy of a blocking site by di- or trivalent external cations.