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.     

Synthesis of new, highly radioactive tetrodotoxin derivatives and their binding properties to the sodium channel

The Pfitzner-Moffatt oxidation procedure has been used to prepare five derivatives of tetrodotoxin by covalent attachment of the oxidized toxin to lysine, glycine, beta-alanine or ethylenediamine. These derivates reach specific radioactivities between 5 and 45 Ci/mmol. The equilibrium properties of binding of these tetrodotoxin derivatives to membrane-embedded or solubilized sodium channels from crustacean nerves have been analysed and compared to the binding properties of tritiated tetrodotoxin and saxitoxin to the same biological systems. All these highly radiolabelled derivatives associate to the tetrodotoxin binding component with properties similar to those of tetrodotoxin itself. The synthetic route described in this paper may be used to prepare other types of tetrodotoxin derivatives such as fluorescent derivatives for example.     

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.     

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.     

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.     

Properties of the tetrodotoxin binding component in plasma membranes isolated from Electrophorus electricus.

The biochemical properties of the electrically excitable sodium channels in the electroplaque of Electrophorus electricus were investigated using tritiated tetrodotoxin (TTX) as a specific membrane probe. Membrane fragments from the electroplaque were isolated essentially by differential centrifugation and characterized with respect to the plasma membrane markers acetylcholine receptors, acetylcholinesterase, (Na+ + K+)ATPase, and [3H]TTX binding. Equilibrium binding studies showed that [3H]TTX bound to a single population of noninteracting receptor sites with an apparent dissociation constant of 6 +/- 1 X 10(-9) M. The toxin-membrane complex dissociated with a first-order rate constant of 0.012 sec-1. Studies on the pH dependence of complex formation demonstrated the requirement for an ionizable, functional group with a pK of 5.3 and this group has been shown to be a carboxyl. Treatment of the membranes with trimethyloxonium tetrafluoroborate, a carboxyl group modifying reagent, resulted in an irreversible loss in the binding of [3H]TTX, which could be prevented by low concentrations of TTX or saxitoxin. This decrease was due to a reduction in the total number of binding sites and not to a decrease in toxin binding affinities. The relative binding affinities of various monovalent alkali metal and polyatomic cations for the TTX-receptor site showed that this site displayed cation discrimination properties which were similar to those reported previously for the electrically excitable sodium channel in intact nerve fibers. A possible role for this site in the ion selectivity of the sodium channel is proposed.     

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.     

Electrophysiological characterization, solubilization and purification of the Tityus gamma toxin receptor associated with the gating component of the Na+ channel from rat brain

Electrophysiological studies with neuroblastoma cells have shown that toxin gamma from the venom of the scorpion Tityus serrulatus is a new toxin specific for the gating system of the Na+ channel. The procedure which solubilizes the tetrodotoxin receptor from rat brain also solubilizes the Tityus gamma toxin receptor. Binding experiments on the solubilized receptor with a radioiodinated derivative of Tityus gamma toxin have shown: (i) that the TiTx gamma-receptor complex is very stable with a dissociation constant of 8.6 X 10(-12) M and a very slow dissociation (T 1/2 = 15 h); (ii) that the toxin recognizes a class of sites with a 1:1 stoichiometry with those for tetrodotoxin (Bmax = 1.3 pmol/mg protein). The radioiodinated Tityus gamma-receptor complex has been substantially purified by ion-exchange chromatography, lectin affinity chromatography and sucrose gradient sedimentation. A ratio of one Tityus gamma toxin binding site per tetrodotoxin binding site was found throughout the purification. The purified material exhibited a sedimentation coefficient of 10.4S and had an apparent mol. wt. of 270 000 on SDS-gel electrophoresis. No other polypeptide chains were demonstrated to be associated with this large protein in the Tityus gamma receptor. The main conclusion is that the tetrodotoxin binding site associated with the selectivity filter of the Na+ channel and the Tityus gamma toxin binding site associated with the gating component are probably carried by the same polypeptide chain.     

Application of photoactivatable fluorescent active-site directed probes to serine-containing enzymes

A photoactivatable fluorescent anthraniloyl group has been directed to the active-site serine group of alpha-chymotrypsin and trypsin. The acylated derivatives are nonfluorescent until irradiated. When activated by light a highly reactive nitrene is generated which is capable of covalent insertion into the protein matrix. The resultant insertion product of this photolysis is a highly fluorescent reporter group which has little rotational mobility and is cross-linked through the serine to the protein matrix in the active site region of the protein. Because of the sensitivity to the polarity of the environment shown by the anthraniloyl chromophore, the dipolar relaxation characteristics of the cross-linked through the serine to the protein matrix in the active site region of the protein. Because of the sensitivity to the polarity of the environment shown by the anthraniloyl chromophore, the dipolar relaxation characteristics of the cross-linked enzyme and deacylated enzyme were determined. These measurements show that little relaxation occurs on the nanosecond time scale for the cross-linked enzyme, but upon deacylation of the serine increased dipolar relaxation of the protein with the attached reporter group is observed. The use of these active-site directed photoactivatable fluorescent probes can be extended to probe the active-site structure of complex enzymes and conformational dynamics of active-site regions in proteins and to serve as potential functional site labels in fluorescence resonance energy transfer measurements.     

A rapid purification procedure for tetrodotoxin derivatives by high-performance liquid chromatography

A simple procedure for purification of tetrodotoxin (TTX) derivatives by high-performance liquid chromatography is described. Chemically oxidized TTX, C₁₁-nortetrodotoxin (nor-TTX), was purified and collected by reverse-phase chromatography. The separation of nor-TTX from unreacted TTX was excellent and recovery of nor-TTX was more than 90%. The isolated nor-TTX was further coupled with lysine, and the coupled product was purified again by high-performance liquid chromatography on a cation-exchange column. The separation of all compounds required less than 15 min. The uv monitoring at 230 nm allowed the detection of TTX derivatives at the 2- to 3-ng level.     

Interaction of nonylguanidine with the sodium channel.

Alkyl and aromatic guanidines interact strongly with the tetrodotoxin (TTX)- receptor site in eel electroplaque membranes, showing competition with TTX. That these guanidines could be useful as highly reversible small molecular weight blockers of Na+ currents is therefore suggested. We have investigated the mechanisms of interaction of one of these derivatives, nonylguanidine, by studying its effects on Na+ currents in squid giant axons using voltage clamp techniques. Although nonylguanidine competed with TTX for binding to eel electroplaque membrane fragments (Ki = 1.8 X 10(-5) M), it reversibly blocked both inward and outward Na+ currents in intact axons only if applied to the interior. In axons with the Na+ inactivation removed by papain nonylguanidine produced a time-dependent block very similar to that reported for strychnine and pancuronium. The reduction of steady-state currents in these axons was also voltage-dependent, with increasing block observed with increasing step depolarization. These results suggest that nonylguanidine binds to a site accessible from the axoplasmic side of the channel, simulating Na+ inactivation in papain-treated axons and competing with the normal inactivation process in untreated axons. The competition between internal nonylguanidine and external TTX may result from perturbation by the positively charged nonylguanidine of the TTX-binding site from within the channel itself.     

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.     

Batrachotoxin-activated Na+ channels in planar lipid bilayers. Competition of tetrodotoxin block by Na+

Single Na+ channels from rat skeletal muscle plasma membrane vesicles were inserted into planar lipid bilayers formed from neutral phospholipids and were observed in the presence of batrachotoxin. The batrachotoxin-modified channel activates in the voltage range -120 to - 80 mV and remains open almost all the time at voltages positive to -60 mV. Low levels of tetrodotoxin (TTX) induce slow fluctuations of channel current, which represent the binding and dissociation of single TTX molecules to single channels. The rates of association and dissociation of TTX are both voltage dependent, and the association rate is competitively inhibited by Na+. This inhibition is observed only when Na+ is increased on the TTX binding side of the channel. The results suggest that the TTX receptor site is located at the channel's outer mouth, and that the Na+ competition site is not located deeply within the channel's conduction pathway.     

The Na+ channel in mammalian cardiac cells. Two kinds of tetrodotoxin receptors in rat heart membranes

The properties of interaction of both tetrodotoxin (TTX) and tritiated ethylenediamine tetrodotoxin [3H] en-TTX) were studied in rat heart membranes at different stages of development and in cultured cells. Studies by electrophysiology and by 22Na+ flux measurements on cardiac cultured cells indicate that the functional form of the Na+ channel is of low affinity for TTX (250-700 nM). Binding experiments (bioassay and [3H]en-TTX binding) on cultured cardiac cells from newborn rats indicate the presence of both high and low affinity binding sites for TTX with dissociation constants (Kd) of 1.6 and 135 nM, respectively. On homogenates of hearts taken just after birth, [3H]en-TTX binding reveals no high affinity binding site for TTX but the presence of a low affinity binding site with a Kd of 125 nM. This result was confirmed by kinetic studies and competition experiments. Conversely, binding studies on homogenates and extensively purified membranes from adult ventricles reveal the presence of both high and low affinity binding sites for TTX with Kd values of 1.5 and 170 nM, respectively. The maximum binding capacity for the low affinity binding sites is 45 times higher than that of the high affinity binding sites. High affinity sites do not exist at the fetal stage or at birth, but after 5 days their number gradually increases to reach a maximum level around 45 days after birth. Conversely, the number of low affinity binding sites is essentially invariant between birth and adulthood. Monolayers of cardiac cells from hearts at 2 days after birth which have no high affinity TTX-binding sites in vivo develop both high and low affinity binding sites for TTX in vitro. The results presented here are the first direct demonstration of the coexistence in rat heart plasma membrane of two families of binding sites for TTX.     

On the molecular mechanisms of neutralization of a cobra neurotoxin by specific antibodies

Examination of 76 homologous neurotoxin sequences suggested that the "toxic" domain of these compounds consists of twelve highly conserved residues. Five of these, namely Lys-27, Trp-29, Asp-31, Arg-33 and Glu-38, together with a variant residue at position 36 are organized into a pattern which resembles that of d-tubocurarine. Two lines of experimental evidence are in agreement with the proposed topology of the "toxic" site in Naja nigricollis toxin alpha--Three highly conserved residues (Lys-27, Trp-29 and Lys-47) have been modified individually in toxin alpha. These modifications induce a decrease in binding affinity of toxin alpha for its target, the nicotinic acetylcholine receptor. In contrast, modifications of three residues (Leu-1, Lys-15 and Lys-51) excluded from the "toxic" domain, do not alter the binding properties of toxin alpha.--Five toxin derivatives carrying a nitroxide group at residues 1, 15, 27, 47 or 51 have been prepared. ESR spectra have been recorded for each derivative in both the free state and bound to the receptor. Mobility of the probes of the residues excluded from the "toxic" site is not altered upon receptor binding. In contrast mobility of the nitroxide of the presumed "toxic" Lys-47 becomes markedly reduced after toxin receptor complex formation. Lys-27 nitroxide is immobilized in both the free and bound state. The antigenic structure of N. nigricollis toxin alpha has been partially clarified using two different approaches. --Fifteen antigenically important residues of toxin alpha have been identified by analyzing cross-reactions between toxin alpha and eleven homologous neurotoxins, using polyclonal antibodies.--- One monoclonal antibody (M alpha 1) specific for toxin alpha has been prepared. Competition experiments, made with (3H) toxin alpha, six mono modified toxin derivatives or alpha three homologous neurotoxins, showed that the binding site of (M alpha 1) comprises the N-terminal group, Lys-15, Pro-18 and probably Thr-16. This site is topographically different from the "toxic" domain. (M alpha 1) inhibits the toxicity of toxin alpha under both in vivo and in vitro conditions. In addition, (M alpha 1) is capable of "removing" toxin molecules bound to the receptor, allowing a rapid recovery of the functional properties of the receptor.     

A structural model of the tetrodotoxin and saxitoxin binding site of the Na+ channel.

Biophysical evidence has placed the binding site for the naturally occurring marine toxins tetrodotoxin (TTX) and saxitoxin (STX) in the external mouth of the Na+ channel ion permeation pathway. We developed a molecular model of the binding pocket for TTX and STX, composed of antiparallel beta-hairpins formed from peptide segments of the four S5-S6 loops of the voltage-gated Na+ channel. For TTX the guanidinium moiety formed salt bridges with three carboxyls, while two toxin hydroxyls (C9-OH and C10-OH) interacted with a fourth carboxyl on repeats I and II. This alignment also resulted in a hydrophobic interaction with an aromatic ring of phenylalanine or tyrosine residues for the brainII and skeletal Na+ channel isoforms, but not with the cysteine found in the cardiac isoform. In comparison to TTX, there was an additional interaction site for STX through its second guanidinium group with a carboxyl on repeat IV. This model satisfactorily reproduced the effects of mutations in the S5-S6 regions and the differences in affinity by various toxin analogs. However, this model differed in important ways from previously published models for the outer vestibule and the selectivity region of the Na+ channel pore. Removal of the toxins from the pocket formed by the four beta-hairpins revealed a structure resembling a funnel that terminated in a narrowed region suitable as a candidate for the selectivity filter of the channel. This region contained two carboxyls (Asp384 and Glu942) that substituted for molecules of water from the hydrated Na+ ion. Simulation of mutations in this region that have produced Ca2+ permeation of the Na+ channel created a site with three carboxyls (Asp384, Glu942, and Glu1714) in proximity.     

A non-natural amino acid for efficient incorporation into proteins as a sensitive fluorescent probe.

A small and highly fluorescent non-natural amino acid that contains an anthraniloyl group (atnDap) was incorporated into various positions of streptavidin. The positions were directed by a CGGG/CCCG four-base codon/anticodon pair. The non-natural mutants were obtained in excellent yields and some of them retained strong biotin-binding activity. The fluorescence wavelength as well as the intensity of the anthraniloyl group at position 120 were sensitive to biotin binding. These unique properties indicate that the atnDap is the most suitable non-natural amino acid for a position-specific fluorescent labeling of proteins that is highly sensitive to microenvironmental changes.     

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.     

Photoaffinity labeling of the tetrodotoxin binding component ofElectrophorus electricus electroplax

Radioactive azide derivatives of tetrodotoxin (TTX) were synthesized using 2-nitro-4-azidephenyl-[3H]beta alanine for the purpose of photolabeling of the Na channel. Three azide derivatives, N1, N2 and N3, were separated by ion exchange chromatography on Bio-Rex 70 resin and reversed phase high performance liquid chromatography. N3 was more stable and obtained at a higher yield than the other two derivatives. Bioactivity of N3 was one-twentieth of that of TTX. N3 showed reversible binding to membranes of Electrophorus electricus electroplax in the dark with Kd = 30 nM and B max = 5.2 pmol/mg protein. By photoirradiation, irreversible binding of N3 to the membranes was observed. A N3 binding component was solubilized by lubrol PX and partially purified from the electroplax membranes by Sephadex G25 and Sepharose 6B column chromatography. The component, purified 500 fold from the starting membranes, showed molecular weight of 10,000.     

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.