Mapping the molecular structure of the voltage-dependent sodium channel. Distances between the tetrodotoxin and Leiurus quinquestriatus quinquestriatus scorpion toxin receptors

The Leiurus quinquestriatus quinquestriatus receptor site of the voltage-dependent sodium channel has been characterized using several fluorescent scorpion toxins. The derivatives show fluorescence enhancements upon binding to the receptor site on the channel together with blue shifts. The fluorescence properties of the bound probes indicate a conformationally flexible, hydrophobic site. Binding of tetrodotoxin has no effect on the fluorescence spectra of the bound derivatives, whereas binding of the allosteric activator batrachotoxin enhances the fluorescence about 2-fold and causes a red shift in the emission spectra, suggesting a batrachotoxin-induced conformational change in the scorpion toxin receptor. The distance between the tetrodotoxin receptor and the Leiurus scorpion toxin receptor on the channel was measured by fluorescence resonance energy transfer. Five different chromophoric scorpion toxin derivatives were used as energy transfer acceptors or donors with anthraniloyltetrodotoxin or N-methylanthraniloylglycine-tetrodotoxin as the energy donor or acceptor. Because of the presence of three tetrodotoxin receptors for each Leiurus receptor, the positions of the donors and acceptors were exchanged. Efficiencies of transfer were measured by both donor quenching and sensitized emission. The average distance of separation between these sites is 35 A. Upon batrachotoxin addition, this distance changes to 42 A indicating a conformational change in one subunit of the channel or a change in the interaction between two subunits coupled to the batrachotoxin-binding site. On the basis of these studies, we present a model suggesting that tetrodotoxin binds to a subunit/site which is extracellularly placed and is 35 A from the Leiurus subunit/site which is located in a protein cleft of the channel which extends partly into the membrane, and undergoes a neurotoxin and voltage-dependent conformational change.     

Structural mapping of the voltage-dependent sodium channel. Distance between the tetrodotoxin and Centruroides suffusus suffusus II beta-scorpion toxin receptors

A 7- dimethylaminocoumarin -4-acetate fluorescent derivative of toxin II from the venom of the scorpion Centruroides suffusus suffusus (Css II) has been prepared to study the structural, conformational, and cellular properties of the beta-neurotoxin receptor site on the voltage-dependent sodium channel. The derivative retains high affinity for its receptor site on the synaptosomal sodium channel with a KD of 7 nM and site capacity of 1.5 pmol/mg of synaptosomal protein. The fluorescent toxin is very environmentally sensitive and the fluorescence emission upon binding indicates that the Css II receptor is largely hydrophobic. Binding of tetrodotoxin or batrachotoxin does not alter the spectroscopic properties of bound Css II, whereas toxin V from Leiurus quinquestriatus effects a 10-nm blue shift to a more hydrophobic environment. This is the first direct indication of conformational coupling between these separate neurotoxin receptor sites. The distance between the tetrodotoxin and Css II scorpion toxin receptors on the sodium channel was measured by fluorescence resonance energy transfer. Efficiencies were measured by both donor quenching and acceptor-sensitized emission. The distance between these two neurotoxin sites is about 34 A. The implications of these receptor locations together with other known molecular distances are discussed in terms of a molecular structure of the voltage-dependent sodium channel.     

Photoaffinity labeling of the receptor site forα-Scorpion toxins on purified and reconstituted sodium channels by a new toxin derivative

1. A methyl-4-azidobenzimidyl (MAB) derivative of the alpha-scorpion toxin from Leiurus quinquestriatus (LqTx) specifically labels only the alpha subunit of the rat brain sodium channel in synaptosomes or in purified and reconstituted sodium-channel preparations. 2. Unlike previous photoreactive toxin derivaties, binding and photolabeling by MAB-LqTx are allosterically modulated by tetrodotoxin and batrachotoxin, as observed for native LqTx binding to sodium channels in synaptosomes. 3. Proteolytic cleavage of the alpha subunit photolabeled with MAB-LqTx shows that the label is located within a 60 to 70-kDa protease-resistant core structure in domain I of the sodium-channel alpha subunit. 4. MAB-LqTx will be valuable in further defining the structure-activity relationships at the alpha-scorpion toxin receptor site.     

Preparation and characterization of fluorescent scorpion toxins from Leiurus quinquestriatus quinquestriatus as probes of the sodium channel of excitable cells

Fluorescent derivatives of scorpion toxin V from Leiurus quinquestriatus quinquestriatus have been prepared so that the topographical, dynamic, and cellular properties of the neurotoxin receptor site on the voltage-dependent sodium channel could be studied. Four different modification strategies have been pursued in which acylated, amidinylated, thio-amidinylated, and reductively alkylated scorpion toxins were prepared. Acylation induces a loss of net positive charge on the toxin and these derivatives are purified by preparative isoelectric focusing and ion-exchange chromatography. Amidinylation and reductive alkylation preserve the protonation state of the toxin and maintain the native tertiary structure of the toxin. Because the native toxin does not contain cysteine, we have introduced new sulfhydryls through modification with the cyclic imidoester 2-iminothiolane which also preserves the net charge on the toxin. Novel purification methods with small amounts of toxin by immunoprecipitation using antibodies directed against the chromophores or through covalent thiol-disulfide exchange chromatography have been utilized. The biological activities, equilibrium binding, and spectroscopic properties indicate that these derivatives retain high affinity for the sodium channel and are as active or only 2-3 times less active than L. quinquestriatus V toxin itself. The spectroscopic properties of these fluorescent derivatives cover the absorption range from 290 to 470 nm, and fluorescence emissions range from 360 to 550 nm where suitable filters and spectral overlap with previously synthesized fluorescent tetrodotoxin can be found. The fluorescent properties in particular show excellent environmental sensitivity and are suitable for probing the molecular dynamics of the toxin receptor and for topographic mapping of the sodium channel by fluorescence resonance energy transfer measurements.     

Functional unit size of the neurotoxin receptors on the voltage-dependent sodium channel

Radiation inactivation was used in situ to determine the functional unit sizes of the neurotoxin receptors of the voltage-dependent sodium channel from rat brain. Frozen or lyophilized synaptosomes were irradiated with high energy electrons generated by a linear accelerator and assayed for [3H]saxitoxin, 125I-Leiurus quinquestriatus quinquestriatus (alpha-scorpion toxin), 125I-Centruroides suffusus suffusus (beta-scorpion toxin), and batrachotoxinin-A 20 alpha-[3H]benzoate binding activity. The functional unit size of the neurotoxin receptors determined in situ by target analysis are 220,000 for saxitoxin, 263,000 for alpha-scorpion toxin, and 45,000 for beta-scorpion toxin. Analysis of the inactivation curve for batrachotoxinin-A 20 alpha-benzoate binding to the channel yields two target sizes of Mr approximately 287,000 (50%) and approximately 51,000 (50%). The results are independent of the purity of the membrane preparation. Comparison of the radiation inactivation data with the protein composition of the rat brain sodium channel indicates that there are at least two functional components.     

Tetrodotoxin-insensitive sodium channels. Binding of polypeptide neurotoxins in primary cultures of rat muscle cells

The binding of 125I-labeled derivatives of scorpion toxin and sea anemone toxin to tetrodotoxin-insensitive sodium channels in cultured rat muscle cells has been studied. Specific binding of 125I-labeled scorpion toxin and 125I-labeled sea anemone toxin was each blocked by either native scorpion toxin or native sea anemone toxin. K0.5 for block of binding by several polypeptide toxins was closely correlated with K0.5 for enhancement of sodium channel activation in rat muscle cells. These results directly demonstrate binding of sea anemone toxin and scorpion toxin to a common receptor site on the sodium channel. Binding of both 125I-labeled toxin derivatives is enhanced by the alkaloids aconitine and batrachotoxin due to a decrease in KD for polypeptide toxin. Enhancement of polypeptide toxin binding by aconitine and batrachotoxin is precisely correlated with persistent activation of sodium channels by the alkaloid toxins consistent with the conclusion that there is allosteric coupling between receptor sites for alkaloid and polypeptide toxins on the sodium channel. The binding of both 125I-labeled scorpion toxin and 125I-labeled sea anemone toxin is reduced by depolarization due to a voltage-dependent increase in KD. Scorpion toxin binding is more voltage-sensitive than sea anemone toxin binding. Our results directly demonstrate voltage-dependent binding of both scorpion toxin and sea anemone toxin to a common receptor site on the sodium channel and introduce the 125I-labeled polypeptide toxin derivatives as specific binding probes of tetrodotoxin-insensitive sodium channels in cultured muscle cells.     

The sodium channel from rat brain. Reconstitution of voltage-dependent scorpion toxin binding in vesicles of defined lipid composition

Purified sodium channels incorporated into phosphatidylcholine (PC) vesicles mediate neurotoxin-activated 22Na+ influx but do not bind the alpha-scorpion toxin from Leiurus quinquestriatus (LqTx) with high affinity. Addition of phosphatidylethanolamine (PE) or phosphatidylserine to the reconstitution mixture restores high affinity LqTx binding with KD = 1.9 nM for PC/PE vesicles at -90 mV and 36 degrees C in sucrose-substituted medium. Other lipids tested were markedly less effective. The binding of LqTx in vesicles of PC/PE (65:35) is sensitive to both the membrane potential formed by sodium gradients across the reconstituted vesicle membrane and the cation concentration in the extravesicular medium. Binding of LqTx is reduced 3- to 4-fold upon depolarization to 0 mV from -50 to -60 mV in experiments in which [Na+]out/[Na+]in is varied by changing [Na+]in or [Na+]out at constant extravesicular ionic strength. It is concluded that the purified sodium channel contains the receptor site for LqTx in functional form and that restoration of high affinity, voltage-dependent binding of LqTx by the purified sodium channel requires an appropriate ratio of PC to PE and/or phosphatidylserine in the vesicle membrane.     

Binding of scorpion toxin to receptor sites associated with sodium channels in frog muscle. Correlation of voltage-dependent binding with activation.

Purified scorpion toxin (Leiurus quinquestriatus) slows inactivation of sodium channels in frog muscle at concentrations in the range of 17-170 nM. Mono[125I]iodo scorpion toxin binds to a single class of sites in frog sartorius muscle with a dissociation constant of 14 nM and a binding capacity of 13 fmol/mg wet weight. Specific binding is inhibited more than 90% by 3 microM sea anemone toxin II and by depolarization with 165 mM K+. Half-maximal inhibition of binding is observed on depolarization to -41 mV. The voltage dependence of scorpion toxin binding is correlated with the voltage dependence of activation of sodium channels. Removal of calcium from the bathing medium shifts both activation and inhibition of scorpion toxin binding to more negative membrane potentials. The results are considered in terms of the hypothesis that activation of sodium channels causes a conformational change in the scorpion toxin receptor site resulting in reduced affinity for scorpion toxin.     

Activation of the Voltage-Sensitive Sodium Channel by a β-Scorpion Toxin in Rat Brain Nerve-Ending Particles

Neurotoxins purified from scorpion venoms previously had been divided into two classes according to their binding properties in rat brain synaptosomes. However, the pharmacological action of beta-scorpion toxin (beta-ScTx) on this preparation has not yet been described. In this report we show that a beta-ScTx induced an increase in 22Na+ uptake through synaptosomal voltage-sensitive sodium channels since this stimulation was abolished by tetrodotoxin (TTX). The increase was smaller than with veratridine and no synergy was observed between beta-ScTx and veratridine, as is the case for alpha-scorpion toxin (alpha-ScTx) and veratridine. The effects of alpha- and beta-ScTx were additive and the concentration-effect curves for each type of toxin were not modified by the other, suggesting that these two types of toxins act through distinct and noninteracting receptor sites. This was confirmed by the absence of mutual modification of the equilibrium and kinetic binding properties. beta-ScTx was shown to inhibit the uptake and to stimulate the release of [3H]gamma-aminobutyric acid. These effects were blocked by TTX, and no synergy was observed with veratridine. It was concluded that all these effects are mediated by the activation of voltage-sensitive sodium channels induced by the binding of beta-ScTx to a receptor site (site 4) distinct from those for other neurotoxins acting on sodium channels.     

Specific inhibition of [3H] saxitoxin binding to skeletal muscle sodium channels by geographutoxin II, a polypeptide channel blocker

Geographutoxin II (GTX II), a peptide toxin isolated from Conus geographus, inhibited [3H]saxitoxin binding to receptor sites associated with voltage-sensitive Na channels in rat skeletal muscle homogenates and rabbit T-tubular membranes with K0.5 values of 60 nM for homogenates and 35 nM for T-tubular membranes in close agreement with concentrations that block muscle contraction. Scatchard analysis of [3H]saxitoxin binding to T-tubular membranes gave values of KD = 9.3 nM and Bmax = 300 fmol/mg of protein and revealed a primarily competitive mode of inhibition of saxitoxin binding by GTX II. The calculated KD values for GTX II were 24 nM for T-tubules and 35 nM for homogenates, respectively. In rat brain synaptosomes, GTX II caused a similar inhibitory effect on [3H]saxitoxin binding at substantially higher concentrations (K0.5 = 2 microM). In contrast, binding of [3H]batrachotoxin A 20-alpha-benzoate and 125I-labeled scorpion toxin to receptor sites associated with Na channels in synaptosomes was not affected by GTX II at concentrations up to 10 microM. Furthermore, [3H]saxitoxin binding to membranes of rat superior cervical ganglion was only blocked 10% by GTX II at 10 microM. These results indicate that GTX II interacts competitively with saxitoxin in binding at neurotoxin receptor site 1 on the sodium channel in a highly tissue-specific manner. GTX II is the first polypeptide ligand for this receptor site and the first to discriminate between this site on nerve and adult muscle sodium channels.     

Structural implications on the interaction of scorpion alpha-like toxins with the sodium channel receptor site inferred from toxin iodination and pH-dependent binding

The alpha-like toxin from the venom of the scorpion Leiurus quinquestriatus hebraeus (Lqh III) binds with high affinity to receptor site 3 on insect sodium channels but does not bind to rat brain synaptosomes. The binding affinity of Lqh III to cockroach neuronal membranes was fivefold higher at pH 6.5 than at pH 7.5. This correlated with an increase in the electropositive charge on the toxin surface resulting from protonation of its four histidines. Radioiodination of Tyr(14) of Lqh III abolished its binding to locust but not cockroach sodium channels, whereas the noniodinated toxin bound equally well to both neuronal preparations. Radioiodination of Tyr(10) or Tyr(21) of the structurally similar alpha-toxin from L. quinquestriatus hebraeus (LqhalphaIT), as well as their substitution by phenylalanine, had only minor effects on binding to cockroach neuronal membranes. However, substitution of Tyr(21), but not Tyr(14), by leucine decreased the binding affinity of LqhalphaIT approximately 87-fold. Thus, Tyr(14) is involved in the bioactivity of Lqh III to locust receptor site 3 and is not crucial for the binding of LqhalphaIT to this site. In turn, the aromatic ring of Tyr(21) takes part in the bioactivity of LqhalphaIT to insects. These results highlight subtle architectural variations between locust and cockroach receptor site 3, in addition to previous results demonstrating the competence of Lqh III to differentiate between insect and mammalian sodium channel subtypes.     

The carbohydrate moieties of the beta-subunit of Na+, K(+)-ATPase: their lateral motions and proximity to the cardiac glycoside site.

The beta-subunit associated with the catalytic (alpha) subunit of the mammalian Na+, K(+) -ATPase is a transmembrane glycoprotein with three extracellularly located N-glycosylation sites. Although beta appears to be essential for a functional enzyme, the role of beta and its sugars remains unknown. In these studies, steady-state and dynamic fluorescence measurements of the fluorophore lucifer yellow (LY) covalently linked to the carbohydrate chains of beta have demonstrated that the bound probes are highly solvent exposed but restricted in their diffusional motions. Furthermore, the probes' environments on beta were not altered by Na+ or K+ or ouabain-induced enzyme conformational changes, but both divalent cation and oligomycin addition evoked modest changes in LY fluorescence. Frequency domain measurements reflecting the Förster fluorescence energy transfer (FET) occurring between anthroylouabain (AO) bound to the cardiac glycoside receptor site on alpha and the carbohydrate-linked LY demonstrated their close proximity (18 A). Additional FET determinations made between LY as donor and erythrosin-5-isothiocyanate, covalently bound at the enzyme's putative ATP binding site domain, indicated that a distance of about 85 A separates these two regions and that this distance is reduced upon divalent cation binding and increased upon the Na+E1-->K+E2 conformational transition. These data suggest a model for the localization of the terminal moieties of the oligosaccharides that places them, on average, about 18 A from the AO binding site and this distance or less from the extracellular membrane surface.     

Simultaneous modifications of sodium channel gating by two scorpion toxins.

The effects of purified scorpion toxins from two different species on the kinetics of sodium currents were evaluated in amphibian myelinated nerves under voltage clamp. A toxin from Leiurus quinquestriatus slowed and prevented sodium channel inactivation, exclusively, and a toxin from Centruroides sculpturatus Ewing reduced transient sodium currents during a maintained depolarization, and induced a novel inward current that appeared following repolarization, as previously reported by Cahalan (1975, J. Physiol. [Lond.]. 244:511-534) for the crude scorpion venom. Both of these effects were observed in fibers treated with both of these toxins, and the kinetics of the induced current were modified in a way that showed that the same sodium channels were modified simultaneously by both toxins. Although the toxins can act on different sites, the time course of the action of C. sculpturatus toxin was accelerated in the presence of the L. quinquestriatus toxin, indicating some form of interaction between the two toxin binding sites.     

Binding of [3H]batrachotoxinin A-20-alpha-benzoate to a high affinity site associated with house fly head membranes

1. [3H]Batrachotoxinin A-20-alpha-benzoate (BTX-B), a radioligand that labels the alkaloid activator recognition site of the voltage-sensitive sodium channel, was bound specifically to high affinity, saturable sites in a subcellular preparation from house fly (Musca domestica L.) heads that was shown previously to contain binding sites for other sodium channel-directed ligands. 2. Specific binding of [3H]BTX-B was observed in the presence of 140 mM sodium or potassium and was inhibited by choline ion. 3. Saturating concentrations of scorpion (Leiurus quinquestriatus) venom stimulated the specific binding of [3H]BTX-B four-fold, increasing the proportion of specific binding of 10 nM [3H]BTX-B from less than 15% to 40%. Equilibrium dissociation studies in the presence of scorpion venom gave an equilibrium dissociation constant (KD) for [3H]BTX-B of 80 nM and a maximal binding capacity (Bmax) of 1.5 pmol/mg protein. 4. Parallel experiments in the absence of venom gave a KD value of 140 nM and a Bmax of 1.3 pmol/mg protein, indicating that scorpion venom stimulated [3H]BTX-B binding by increasing the affinity of this site approximately two-fold. 5. The specific binding of [3H]BTX-B was inhibited by the sodium channel activators aconitine and batrachotoxin and, to a lesser extent, by the anticonvulsant diphenylhydantoin. However, several other sodium channel-directed neurotoxins known to exert allosteric effects on the binding of [3H]BTX-B to mammalian brain preparations did not affect the binding of [3H]BTX-B to house fly head membranes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Scorpion venom (Leiurus quinquestriatus) elicits accumulations of inositol phosphates and cyclic AMP in guinea pig cortical synaptoneurosomes

Scorpion (Leiurus quinquestriatus) venom (ScV) stimulated accumulations of cyclic AMP and turnover of phosphatidylinositol in guinea pig cortical synaptoneurosomes. The concentrations of ScV that were necessary to increase cyclic [3H]AMP accumulation were lower than those required to stimulate formation of [3H]inositol phosphates from phosphatidylinositol. In the presence of 10 microM 2-chloroadenosine, ScV induced a dose-dependent synergistic accumulation of cyclic AMP with an EC50 value that was comparable to the EC50 required for stimulation of phosphatidylinositol turnover. Tetrodotoxin partially inhibited cyclic AMP accumulations elicited by ScV indicating that at least part of such responses are due to activation of voltage-dependent sodium channel. Tetrodotoxin virtually completely blocked formation of inositol phosphate stimulated by ScV. High concentrations of Mg2+ (30 mM) did not block responses to ScV indicating that release of neurotransmitters was not involved. Membrane potential changes could not be detected at concentrations of ScV that triggered the biochemical responses. Stimulation of phosphatidylinositol turnover by ScV appears to depend on an increase in influx of Na+ in synaptoneurosomes, presumably due to slowing of the inactivation of voltage-dependent sodium channels by alpha-scorpion toxin, a component of ScV. At least in part, the stimulation of cyclic AMP accumulation by ScV correlates with increases in phosphatidylinositol turnover.     

Reconstitution of the voltage-sensitive sodium channel of rat brain from solubilized components

The voltage-sensitive sodium channel of rat brain synaptosomes was solubilized with sodium cholate. The solubilized sodium channel migrated on a sucrose density gradient with an apparent S20,w of approximately 12 S, retained [3H]saxitoxin ([3H]STX) binding activity that was labile at 36 degrees C but no longer bound 125I-labeled scorpion toxin (125I-ScTX). Following reconstitution into phosphatidylcholine vesicles, the channel regained 125I-ScTX binding and thermal stability of [3H]STX binding. Approximately 50% of the [3H]STX binding activity and 58% of 125I-ScTX binding activity were recovered after reconstitution. The reconstituted sodium channel bound STX and ScTX with KD values of 5 and 10 nM, respectively. Under depolarized conditions, veratridine enhanced the binding of 125I-ScTX with a K0.5 of 20 microM. These KD and K0.5 values are similar to those of the native synaptosome sodium channel. 125I-ScTX binding to the reconstituted sodium channel, as with the native channel, was voltage dependent. The KD for 125I-ScTX increased with depolarization. This voltage dependence was used to demonstrate that the reconstituted channel transports Na+. Activation of sodium channels by veratridine under conditions expected to cause hyperpolarization of the reconstituted vesicles increased 125I-ScTX binding 3-fold. This increased binding was blocked by STX with K0.5 = 5 nM. These data indicate that reconstituted sodium channels can transport Na+ and hyperpolarize the reconstituted vesicles. Thus, incorporation of solubilized synaptosomal sodium channels into phosphatidylcholine vesicles results in recovery of toxin binding and action at each of the three neurotoxin receptor sites and restoration of Na+ transport by the reconstituted channels.     

beta-Scorpion toxin modifies gating transitions in all four voltage sensors of the sodium channel

Several naturally occurring polypeptide neurotoxins target specific sites on the voltage-gated sodium channels. Of these, the gating modifier toxins alter the behavior of the sodium channels by stabilizing transient intermediate states in the channel gating pathway. Here we have used an integrated approach that combines electrophysiological and spectroscopic measurements to determine the structural rearrangements modified by the beta-scorpion toxin Ts1. Our data indicate that toxin binding to the channel is restricted to a single binding site on domain II voltage sensor. Analysis of Cole-Moore shifts suggests that the number of closed states in the activation sequence prior to channel opening is reduced in the presence of toxin. Measurements of charge-voltage relationships show that a fraction of the gating charge is immobilized in Ts1-modified channels. Interestingly, the charge-voltage relationship also shows an additional component at hyperpolarized potentials. Site-specific fluorescence measurements indicate that in presence of the toxin the voltage sensor of domain II remains trapped in the activated state. Furthermore, the binding of the toxin potentiates the activation of the other three voltage sensors of the sodium channel to more hyperpolarized potentials. These findings reveal how the binding of beta-scorpion toxin modifies channel function and provides insight into early gating transitions of sodium channels.     

Purification and characterization of a beta-toxin from the venom of the African scorpion Leiurus quinquestriatus

The venom of the African scorpion Leiurus quinquestriatus was subjected to high-performance ion-exchange chromatography. Among a large number (greater than 25) of small proteins and other substances, a protein component of approx. 6500 Da was purified. The effect of this toxin was tested on single myelinated nerve fibres of the frog Rana esculenta. Toxin concentrations less than 10 nM produced clear effects. Activation rather than inactivation of the voltage-dependent sodium channel was strongly affected. Thus, this toxin from an African scorpion acts like the beta-toxins present in the venom of North American scorpions.     

Differential labeling of the alpha and beta 1 subunits of the sodium channel by photoreactive derivatives of scorpion toxin

The separation of two photoreactive derivatives of the alpha-scorpion toxin from Leiurus quinquestriatus is described. When the two photoreactive derivatives were photolyzed separately in the presence of brain membranes containing voltage-sensitive sodium channels, one labeled the alpha subunit preferentially while the other labeled beta 1 more intensely than alpha. Batrachotoxin enhanced the efficiency of covalent labeling by the photoreactive derivatives of scorpion toxin. In all the labeling experiments, the specific incorporation of radioactive scorpion toxin was eliminated by an excess of nonradioactive scorpion toxin. The alpha polypeptide labeled in synaptosomes by photoreactive scorpion toxin was demonstrated by immunological techniques to be the same large polypeptide identified in sodium channels purified by their saxitoxin binding activity. The alpha and beta 1 subunits were detected by rapid photoaffinity labeling of a freshly prepared brain homogenate in the presence of a mixture of nine protease inhibitors, indicating that they are components of the sodium channel in intact brain tissue. The association of the covalently labeled polypeptides with the membrane was investigated by treatment of labeled synaptosomes with various agents known to remove proteins only indirectly attached to the lipid bilayer via a membrane-bound protein. In all cases, both the alpha and the beta 1 polypeptides remained in the membrane fraction following extraction. This confirms earlier proposals that the alpha polypeptide has a portion of its mass embedded within the lipid bilayer and suggests that the beta 1 polypeptide does as well.     

Batrachotoxinin-A 20-α-benzoate: A new radioactive ligand for voltage sensitive sodium channels

Batrachotoxinin-A 20--benzoate (BTX-B), an analog of the potent depolarizing agent batrachotoxin (BTX), was prepared by selective esterification of naturally occurring batrachotoxinin-A with benzoic acid. BTX-B depolarizes rat phrenic nerve-diaphragm preparations with a time course and concentration dependence virtually indistinguishable from that of BTX. A specific, saturable component of equilibrium binding of [³H]BTX-B to mouse cerebral cortex homogenates was measured, described by an equilibrium dissociation constant of 0.7 µM and a maximum number of binding sites of 90 pmol per gram of tissue (wet weight). Specific binding is inhibited by BTX and other BTX analogs, veratridine, and grayanotoxin but is unaffected by tetrodotoxin and cevine. Under conditions of this assay, neither crude Leiurus quinquestriatus scorpion venom nor purified sea anemone toxin have any effect on specific binding. The data support the conclusion that BTX-B interacts with a recognition site associated with voltage sensitive sodium channels which is identical to the recognition site for BTX.This work was supported by a grant from the Alabama Affiliate of the American Heart Association and a NIH grant NS 15617 to G.B.B. and by USPHS grant NS-12063 and Army research office grant 29-78-G-0203 to E.X.A.