Comparison of ionic selectivity of batrachotoxin-activated channels with different tetrodotoxin dissociation constants

Bioactive alkaloids from the venom of Dendrobatoidea Cope, 1865: a scoping review

Bioactive compounds derived from secondary metabolism in animals have refined selectivity and potency for certain biological targets. The superfamily Dendrobatoidea is adapted to the dietary sequestration and secretion of toxic alkaloids, which play a role in several biological activities, and thus serve as a potential source for pharmacological and biotechnological applications. This article constitutes a scoping review to understand the trends in experimental research involving bioactive alkaloids derived from Dendrobatoidea based upon scientometric approaches. Forty-eight (48) publications were found in 30 journals in the period of 60 years, between 1962 and 2022. More than 23 structural classes of alkaloids were cited, with 27.63% for batrachotoxins, 13.64% for pyridinics, with an emphasis on epibatidine, 16.36% for pumiliotoxins, and 11.82% for histrionicotoxins. These tests included in vivo (54.9%), in vitro (39.4%), and in silico simulations (5.6%). Most compounds (54.8%) were isolated from skin extracts, whereas the remainder were obtained through molecular synthesis. Thirteen main biological activities were identified, including acetylcholinesterase inhibitors (27.59%), sodium channel inhibitors (12.07%), cardiac (12.07%), analgesic (8.62%), and neuromuscular effects (8.62%). The substances were cited as being of natural origin in the "Dendrobatidae" family, genus "Phyllobates," "Dendrobates," and seven species: Epipedobates tricolor, Phyllobates aurotaenia, Oophaga histrionica, Oophaga pumilio, Phyllobates terribilis, Epipedobates anthonyi, and Ameerega flavopicta. To date, only a few biological activities have been experimentally tested; hence, further studies on the bioprospecting of animal compounds and ecological approaches are needed.

The envenomation of general physiology throughout the last century

Sack discusses the evolution of toxin research in JGP over the last 100 years.

Toxins are the poisonous products of organisms. Toxins serve vital defensive and offensive functions for those that harbor them: stinging scorpions, pesticidal plants, sanguinary snakes, fearless frogs, sliming snails, noxious newts, and smarting spiders. For physiologists, toxins are integral chemical tools that hijack life’s fundamental processes with remarkable molecular specificity. Our understanding of electrophysiological phenomena has been transformed time and time again with the help of some terrifying toxins. For this reason, studies of toxin mechanism are an important and enduring facet of The Journal of General Physiology (JGP). This Milestone in Physiology reflects on toxins studied in JGP over its first 100 years, what they have taught us, and what they have yet to reveal.

Identification of new batrachotoxin-sensing residues in segment IIIS6 of the sodium channel

Ion permeation through voltage-gated sodium channels is modulated by various drugs and toxins. The atomistic mechanisms of action of many toxins are poorly understood. A steroidal alkaloid batrachotoxin (BTX) causes persistent channel activation by inhibiting inactivation and shifting the voltage dependence of activation to more negative potentials. Traditionally, BTX is considered to bind at the channel-lipid interface and allosterically modulate the ion permeation. However, amino acid residues critical for BTX action are found in the inner helices of all four repeats, suggesting that BTX binds in the pore. In the octapeptide segment IFGSFFTL in IIIS6 of a cockroach sodium channel BgNa(V), besides Ser_3i15 and Leu_3i19, which correspond to known BTX-sensing residues of mammalian sodium channels, we found that Gly_3i14 and Phe_3i16 are critical for BTX action. Using these data along with published data as distance constraints, we docked BTX in the Kv1.2-based homology model of the open BgNa(V) channel. We arrived at a model in which BTX adopts a horseshoe conformation with the horseshoe plane normal to the pore axis. The BTX ammonium group is engaged in cation-π interactions with Phe_3i16 and BTX moieties interact with known BTX-sensing residues in all four repeats. Oxygen atoms at the horseshoe inner surface constitute a transient binding site for permeating cations, whereas the bulky BTX molecule would resist the pore closure, thus causing persistent channel activation. Our study reinforces the concept that steroidal sodium channel agonists bind in the inner pore of sodium channels and elaborates the atomistic mechanism of BTX action.

Natural products from ginseng inhibit [3H]batrachotoxinin A 20-alpha-benzoate binding to Na+ channels in mammalian brain

A [(3)H]batrachotoxinin A-20alpha-benzoate ([(3)H]BTX-B) binding assay was used to investigate the interaction of two ginseng aglycones (20(S)protopanaxadiol and 20(S)protopanaxatriol) and Rh(2) (a monoglucoside of 20(S)protopanaxadiol) with voltage-gated sodium channels in mouse brain. All compounds inhibited the binding of [(3)H]BTX-B and IC(50)s were established at 42 microM (20(S)protopanaxadiol), 79 microM (20(S)protopanaxatriol) and 162 microM (Rh(2)). Scatchard analysis confirmed that 20(S)protopanaxadiol and Rh-2 reduced the B(max) of [(3)H]BTX-B binding while Rh(2) also increased the K(d). At IC(50) concentrations and above, 20(S)protopanaxadiol and Rh(2) increased the dissociation of the [(3)H]BTX-B:sodium channel complex above that produced by a saturating concentration of veratridine, but failed to reduce the rate of association of [(3)H]BTX-B with sodium channels. Reversal of the inhibition of [(3)H]BTX-B binding by 20(S)protopanaxadiol and Rh(2) occurred slowly. We conclude that the 20(S)protopanaxadiol and the less potent inhibitor Rh(2) destabilize BTX-B-activated sodium channels through non-covalent allosteric modification of neurotoxin binding site 2.

Conotoxins as sensors of local pH and electrostatic potential in the outer vestibule of the sodium channel

We examined the block of voltage-dependent rat skeletal muscle sodium channels by derivatives of mu-conotoxin GIIIA (muCTX) having either histidine, glutamate, or alanine residues substituted for arginine-13. Toxin binding and dissociation were observed as current fluctuations from single, batrachotoxin-treated sodium channels in planar lipid bilayers. R13X derivatives of muCTX only partially block the single-channel current, enabling us to directly monitor properties of both muCTX-bound and -unbound states under different conditions. The fractional residual current through the bound channel changes with pH according to a single-site titration curve for toxin derivatives R13E and R13H, reflecting the effect of changing the charge on residue 13, in the bound state. Experiments with R13A provided a control reflecting the effects of titration of all residues on toxin and channel other than toxin residue 13. The apparent pKs for the titration of residual conductance are shifted 2-3 pH units positive from the nominal pK values for histidine and glutamate, respectively, and from the values for these specific residues, determined in the toxin molecule in free solution by NMR measurements. Toxin affinity also changes dramatically as a function of pH, almost entirely due to changes in the association rate constant, kon. Interpreted electrostatically, our results suggest that, even in the presence of the bound cationic toxin, the channel vestibule strongly favors cation entry with an equivalent local electrostatic potential more negative than -100 mV at the level of the "outer charged ring" formed by channel residues E403, E758, D1241, and D1532. Association rates are apparently limited at a transition state where the pK of toxin residue 13 is closer to the solution value than in the bound state. The action of these unique peptides can thus be used to sense the local environment in the ligand--receptor complex during individual molecular transitions and defined conformational states.

Mechanisms of cation permeation in cardiac sodium channel: description by dynamic pore model

The selective permeability to monovalent metal cations, as well as the relationship between cation permeation and gating kinetics, was investigated for native tetrodotoxin-insensitive Na-channels in guinea pig ventricular myocytes using the whole-cell patch clamp technique. By the measurement of inward unidirectional currents and biionic reversal potentials, we demonstrate that the cardiac Na-channel is substantially permeable to all of the group Ia and IIIa cations tested, with the selectivity sequence Na(+) >/= Li(+) > Tl(+) > K(+) > Rb(+) > Cs(+). Current kinetics was little affected by the permeant cation species and concentrations tested (</=160 mM), suggesting that the permeation process is independent of the gating process in the Na-channel. The permeability ratios determined from biionic reversal potentials were concentration and orientation dependent: the selectivity to Na(+) increased with increasing internal [K(+)] or external [Tl(+)]. The dynamic pore model describing the conformational transition of the Na-channel pore between different selectivity states could account for all the experimental data, whereas conventional static pore models failed to fit the concentration-dependent permeability ratio data. We conclude that the dynamic pore mechanism, independent of the gating machinery, may play an important physiological role in regulating the selective permeability of native Na-channels.

Effect of omega-conotoxin GVIA on tetrodotoxin-insensitive acetylcholine release by nicotine in guinea-pig bladder

1. Contractile responses and acetylcholine release evoked by nicotine and electrical field stimulation (EFS) were determined by isotonic transducer and radioimmunoassay, respectively. 2. Nicotine-induced contraction was reduced to 30% by nicotinic receptor antagonist, hexamethonium but was insensitive to tetrodotoxin. EFS-induced contraction was abolished by tetrodotoxin but was insensitive to hexamethonium. Replacement of external Na by choline completely abolished the contractile responses evoked by nicotine and EFS. 3. Both contractions evoked by nicotine and EFS were inhibited by omega-conotoxin GVIA, and inhibitory effects of the toxin were greater in low Ca concentrations. 4. In the condition that external Na or Ca is omitted from physiological solution, acetylcholine release evoked by nicotine was not observed. Nicotine-induced acetylcholine release was partially inhibited by omega-conotoxin but was insensitive to tetrodotoxin. 5. In conclusion, nicotine interacts with nicotinic receptors located on nerve terminals and produces transmitter release which depends on external Na through tetrodotoxin-insensitive mechanisms. It is suggested that voltage-dependent omega-conotoxin sensitive Ca channels are partially involved in the nicotine-induced transmitter release.

Carbodiimide modification reduces the conductance and increases the tetrodotoxin sensitivity in batrachotoxin-modified sodium channels

The relationship between the channel entrance and the tetrodotoxin (TTX) binding site was investigated by chemical modification at the extracellular surface of bilayer-incorporated batrachotoxin-(BTX) modified sodium channels using an impermeant carbodiimide in the presence or absence of exogenous nucleophiles. Two (classes of) groups could be modified such that the open-channel conductance was decreased while TTX binding was unaffected, and TTX did not protect against this modification. Because the final conductance level depends on the exogenous nucleophile, each covalent modification appears to involve a carboxyl group. In addition, a third (carboxyl) group could be modified such that TTX binding affinity was increased. These results suggest that the channel entrance and the TTX binding site are spatially separate, which supports previous suggestions that the mechanism by which guanidinium toxins close sodium channels involves a conformational change subsequent to toxin binding.

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

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

Voltage-dependent tetrodotoxin binding to single batrachotoxin-modified Na channels recorded from intact neuroblastoma cells

To clarify the voltage-dependent actions of tetrodotoxin (TTX) on Na channels in cellular membranes, we examined the TTX block of single batrachotoxin-modified Na channels in neuroblastoma cells. We found these Na channels had a high affinity for TTX which decreased e-fold per 35.5 mV depolarization. The decrease in affinity resulted primarily from a decrease in the blocking rate for TTX; the unblocking rate increased slightly with depolarization. While the voltage-dependence of TTX binding to neuroblastoma Na channels was similar to that reported in purified Na channels incorporated in bilayers, the magnitude and voltage-dependence of the rate constants were quite different.

Ion permeation in normal and batrachotoxin-modified Na+ channels in the squid giant axon

Na+ permeation through normal and batrachotoxin (BTX)-modified squid axon Na+ channels was characterized. Unmodified and toxin-modified Na+ channels were studied simultaneously in outside-out membrane patches using the cut-open axon technique. Current-voltage relations for both normal and BTX-modified channels were measured over a wide range of Na+ concentrations and voltages. Channel conductance as a function of Na+ concentration curves showed that within the range 0.015-1 M Na+ the normal channel conductance is 1.7-2.5-fold larger than the BTX-modified conductance. These relations cannot be fitted by a simple Langmuir isotherm. Channel conductance at low concentrations was larger than expected from a Michaelis-Menten behavior. The deviations from the simple case were accounted for by fixed negative charges located in the vicinity of the channel entrances. Fixed negative charges near the pore mouths would have the effect of increasing the local Na+ concentration. The results are discussed in terms of energy profiles with three barriers and two sites, taking into consideration the effect of the fixed negative charges. Either single- or multi-ion pore models can account for all the permeation data obtained in both symmetric and asymmetric conditions. In a temperature range of 5-15 degrees C, the estimated Q10 for the conductance of the BTX-modified Na+ channel was 1.53. BTX appears not to change the Na+ channel ion selectively (for the conditions used) or the surface charge located near the channel entrances.

Interaction of monovalent cations with tetrodotoxin and saxitoxin binding at sodium channels of frog myelinated nerve

Na currents and Na-current fluctuations were measured in myelinated frog nerve fibres to study interactions between monovalent externally applied cations and the binding of the Na-channel blockers tetrodotoxin (TTX) or saxitoxin (STX). Adding 110 mM NaCl to Ringer's solution increased the maximum peak Na conductance by a factor of 2.51 in the presence of 12 nM TTX and by a factor of 2.43 in the presence of 4 nM STX. According to the analysis of Na-current fluctuations this increase of the Na conductance is mainly caused by an increase of the number N of unblocked Na channels per node, while the conductance of a single channel saturates in the hyperosmolar solutions. The increase of N is interpreted by displacement of TTX or STX from Na channels by external Na+. Relief of TTX blockage was also observed by adding 110 mM chloride salts of Li+, hydrazine+, guanidine+ and K+ to Ringer, but not in Ringer + 110 mM tetramethylammonium chloride or 250 mM sucrose. The increase of N by the external cations is a saturating function of the permeability of the Na channel to these ions. The results are interpreted by a toxin receptor in a superficial prefilter to the Na channel, which contributes to cation discrimination at the outer channel region.

A single point mutation confers tetrodotoxin and saxitoxin insensitivity on the sodium channel II

A single point mutation of the rat sodium channel II reduces its sensitivity to tetrodotoxin and saxitoxin by more than three orders of magnitude. The mutation replaces glutamic acid 387 with a glutamine and has only slight effects on the macroscopic current properties, as measured under voltage-clamp in Xenopus oocytes injected with the corresponding cDNA-derived mRNA.

Batrachotoxin-modified sodium channels from squid optic nerve in planar bilayers. Ion conduction and gating properties

Squid optic nerve sodium channels were characterized in planar bilayers in the presence of batrachotoxin (BTX). The channel exhibits a conductance of 20 pS in symmetrical 200 mM NaCl and behaves as a sodium electrode. The single-channel conductance saturates with increasing the concentration of sodium and the channel conductance vs. sodium concentration relation is well described by a simple rectangular hyperbola. The apparent dissociation constant of the channel for sodium is 11 mM and the maximal conductance is 23 pS. The selectivity determined from reversal potentials obtained in mixed ionic conditions is Na+ approximately Li+ greater than K+ greater than Rb+ greater than Cs+. Calcium blocks the channel in a voltage-dependent manner. Analysis of single-channel membranes showed that the probability of being open (Po) vs. voltage relation is sigmoidal with a value of 0.5 between -90 and -100 mV. The fitting of Po requires at least two closed and one open state. The apparent gating charge required to move through the whole transmembrane voltage during the closed-open transition is four to five electronic charges per channel. Distribution of open and closed times are well described by single exponentials in most of the voltage range tested and mean open and mean closed times are voltage dependent. The number of charges associated with channel closing is 1.6 electronic charges per channel. Tetrodotoxin blocked the BTX-modified channel being the blockade favored by negative voltages. The apparent dissociation constant at zero potential is 16 nM. We concluded that sodium channels from the squid optic nerve are similar to other BTX-modified channels reconstituted in bilayers and to the BTX-modified sodium channel detected in the squid giant axon.

Symmetry and asymmetry of permeation through toxin-modified Na+ channels

Single Na+ channels from rat skeletal muscle were inserted into planar lipid bilayers in the presence of either 200 nM batrachotoxin (BTX) or 50 microM veratridine (VT). These toxins, in addition to their ability to shift inactivation of voltage-gated Na+ channels, may be used as probes of ion conduction in these channels. Channels modified by either of the toxins have qualitatively similar selectivity for the alkali cations (Na+ approximately Li+ greater than K+ greater than Rb+ greater than Cs+). Biionic reversal potentials, for example, were concentration independent for all ions studied. Na+/K+ and Na+/Rb+ reversal potentials, however, were dependent on the orientation of the ionic species with respect to the intra- or extracellular face of the channel, whereas Na+/Li+ biionic reversal potentials were not orientation dependent. A simple, four-barrier, three-well, single-ion occupancy model was used to generate current-voltage relationships similar to those observed in symmetrical solutions of Na, K, or Li ions. The barrier profiles for Na and Li ions were symmetric, whereas that for K ions was asymmetric. This suggests the barrier to ion permeation for K ions may be different than that for Na and Li ions. With this model, these hypothetical energy barrier profiles could predict the orientation-dependent reversal potentials observed for Na+/K+ and Na+/Rb+. The energy barrier profiles, however, were not capable of describing biionic Na/Li ion permeation. Together these results support the hypothesis that Na ions have a different rate determining step for ion permeation than that of K and Rb ions.

Permeation and block of N-methyl-D-aspartic acid receptor channels by divalent cations in mouse cultured central neurones

1. Spinal cord and hippocampal neurones in cell culture were voltage clamped using the tight-seal, whole-cell recording technique. The concentration of sodium and a series of divalent cations in the extracellular media was varied to study permeation through excitatory amino acid receptor channels activated by the selective agonists N-methyl-D-aspartic acid (NMDA), kainic acid and quisqualic acid. 2. On raising the extracellular calcium concentration, with [Na+]o held constant at 105 mM, the reversal potential of responses to NMDA shifted in the depolarizing direction. This shift was adequately described by the extended constant-field equation over the range 0.3-50 mM-calcium. Using ionic activity coefficients we calculate a value of PCa/PNa = 10.6. Under the same experimental conditions the reversal potential of responses to kainic and quisqualic acids was much less affected by raising the calcium concentration, such that PCa/PNa = 0.15. A depolarizing shift of the NMDA reversal potential was also recorded during application of 20 mM-barium, strontium or manganese, suggesting permeation of these ions. The permeability sequence was Ca2+ greater than Ba2+ greater than Sr2+ much greater than Mn2+. No depolarizing shift of the NMDA reversal potential occurred during application of 20 mM-cobalt, magnesium or nickel. 3. In experiments in which the extracellular Na+ concentration was varied the extended constant-field equation was adequate in predicting shifts of the NMDA reversal potential recorded on varying [Na+]o over the range 50-150 mM, but failed to accurately predict the reversal potential of responses to NMDA with 10 mM-[Ca2+]o and only 10 or 20 mM-[Na+]o. These results imply an apparent increase in PCa/PNa on lowering [Na+]o and may result from interaction of permeant ions within the channel. 4. Barium and to a lesser extent calcium, but not strontium (all 20 mM), reduced the slope conductance of responses to NMDA recorded within +/- 15 mV of the reversal potential; over this limited range of membrane potential the current-voltage relationship remained linear in the presence of each of these ions. In contrast manganese produced a strong, voltage-dependent block of responses to NMDA, similar to that produced by magnesium, such that even close to the reversal potential the NMDA current-voltage relationship was highly non-linear. Thus manganese both permeates and blocks the NMDA receptor channel. 5. Raising the extracellular calcium concentration, from 0.1 to 5 mM, had two effects on the conductance mechanism activated by NMDA.(ABSTRACT TRUNCATED AT 400 WORDS)

Open sodium channel properties of single canine cardiac Purkinje cells

Open channel properties of canine cardiac Purkinje cell Na+ channels were studied with single channel cell-attached recording and with whole cell macroscopic current recording in internally perfused cells. Single channel currents and membrane currents increased with an increase in Na+ concentration, but showed evidence of saturation. Assuming first-order binding, the Km for Na+ was 370 mM. PCs/PNa was 0.020 and PK/PNa was 0.094. The current-voltage relationship for single channels showed prominent flattening in the hyperpolarizing direction. This flattening was accentuated by 10 mM Ca2+ and was greatly reduced in O mM Ca2+, indicating that the rectification was a consequence of Ca2+ block of the Na+ channels. A similar instantaneous current-voltage relationship was seen for the whole cell membrane currents. These results demonstrate that the cardiac channel shows substantial Ca2+ block, although it is relatively insensitive to tetrodotoxin. The Na+ and Ca2+ binding properties could be modeled by the four-barrier Eyring rate theory model, with similar values to those reported for the neuroblastoma Na+ channel (Yamamoto, D.,J.Z. Yeh, and T. Narahashi, 1984, Biophys J., 45:337-344).

Batrachotoxin-modified sodium channels in planar lipid bilayers. Ion permeation and block

Batrachotoxin-modified, voltage-dependent sodium channels from canine forebrain were incorporated into planar lipid bilayers. Single-channel conductances were studied for [Na+] ranging between 0.02 and 3.5 M. Typically, the single-channel currents exhibited a simple two-state behavior, with transitions between closed and fully open states. Two other conductance states were observed: a subconductance state, usually seen at [NaCl] greater than or equal to 0.5 M, and a flickery state, usually seen at [NaCl] less than or equal to 0.5 M. The flickery state became more frequent as [NaCl] was decreased below 0.5 M. The K+/Na+ permeability ratio was approximately 0.16 in 0.5 and 2.5 M salt, independent of the Na+ mole fraction, which indicates that there are no interactions among permeant ions in the channels. Impermeant and permeant blocking ions (tetraethylammonium, Ca++, Zn++, and K+) have different effects when added to the extracellular and intracellular solutions, which indicates that the channel is asymmetrical and has at least two cation-binding sites. The conductance vs. [Na+] relation saturated at high concentrations, but could not be described by a Langmuir isotherm, as the conductance at low [NaCl] is higher than predicted from the data at [NaCl] greater than or equal to 1.0 M. At low [NaCl] (less than or equal to 0.1 M), increasing the ionic strength by additions of impermeant monovalent and divalent cations reduced the conductance, as if the magnitude of negative electrostatic potentials at the channel entrances were reduced. The conductances were comparable for channels in bilayers that carry a net negative charge and bilayers that carry no net charge. Together, these results lead to the conclusion that negative charges on the channel protein near the channel entrances increase the conductance, while lipid surface charges are less important.

Single Na+ channels activated by veratridine and batrachotoxin

Voltage-sensitive Na+ channels from rat skeletal muscle plasma membrane vesicles were inserted into planar lipid bilayers in the presence of either of the alkaloid toxins veratridine (VT) or batrachotoxin (BTX). Both of these toxins are known to cause persistent activation of Na+ channels. With BTX as the channel activator, single channels remain open nearly all the time. Channels activated with VT open and close on a time scale of 1-10 s. Increasing the VT concentration enhances the probability of channel opening, primarily by increasing the rate constant of opening. The kinetics and voltage dependence of channel block by 21-sulfo-11-alpha-hydroxysaxitoxin are identical for VT and BTX, as is the ionic selectivity sequence determined by bi-ionic reversal potential (Na+ approximately Li+ greater than K+ greater than Rb+ greater than Cs+). However, there are striking quantitative differences in open channel conduction for channels in the presence of the two activators. Under symmetrical solution conditions, the single channel conductance for Na+ is about twice as high with BTX as with VT. Furthermore, the symmetrical solution single channel conductances show a different selectivity for BTX (Na+ greater than Li+ greater than K+) than for VT (Na+ greater than K+ greater than Li+). Open channel current-voltage curves in symmetrical Na+ and Li+ are roughly linear, while those in symmetrical K+ are inwardly rectifying. Na+ currents are blocked asymmetrically by K+ with both BTX and VT, but the voltage dependence of K+ block is stronger with BTX than with VT. The results show that the alkaloid neurotoxins not only alter the gating process of the Na+ channel, but also affect the structure of the open channel. We further conclude that the rate-determining step for conduction by Na+ does not occur at the channel's "selectivity filter," where poorly permeating ions like K+ are excluded.

Intracellular tetraethylammonium ions enhance group Ia excitatory post-synaptic potentials evoked in cat motoneurones

Single fibre group Ia excitatory post-synaptic potentials (e.p.s.p.s) were recorded in cat spinal motoneurones after the neurones were injected with tetraethylammonium (TEA) ions. TEA injection increased the peak amplitude of most e.p.s.p.s. The time course of e.p.s.p.s generated at the soma was unaffected, but the time course of e.p.s.p.s generated in the dendrites was prolonged. The membrane time constant did not change after TEA injection. Somatic e.p.s.p.s were voltage clamped after TEA was injected. The reversal potential for these e.p.s.p.s was more positive than for e.p.s.p.s unaffected by TEA. Composite e.p.s.p.s added linearly, or greater than linearly, whereas in motoneurones without TEA they added linearly or less than linearly. The enhanced amplitude and prolonged time course observed in dendritic e.p.s.p.s after TEA injection was reduced by small hyperpolarizing currents. Greater than linear summation of composite e.p.s.p.s was converted to linear summation by small hyperpolarizing currents. The increase in somatic e.p.s.p.s was attributed to a more positive reversal potential for the e.p.s.p.s. We suggest that TEA decreases the relative permeability of K+ in the subsynaptic channels. We propose that in the presence of TEA, dendritic depolarization activates an inward current which amplifies and prolongs synaptic potentials spreading towards the soma.

Voltage-dependent gating of veratridine-modified Na channels

Na channels of frog muscle fibers treated with 100 microM veratridine became transiently modified after a train of repetitive depolarizations. They open and close reversibly with a gating process whose midpoint lies 93 mV more negative than the midpoint of normal activation gating and whose time course shows no appreciable delay in the opening or closing kinetics but still requires more than two kinetic states. Like normal activation, the voltage dependence of the modified gating can be shifted by changing the bathing Ca2+ concentration. The instantaneous current-voltage relation of veratridine-modified channels is curved at potentials negative to -90 mV, as if external Ca ions produced a voltage-dependent block but also permeated. Modified channels probably carry less current than normal ones. When the concentration of veratridine is varied between 5 and 100 microM, the initial rate of modification during a pulse train is directly proportional to the concentration, while the rate of recovery from modification after the train is unaffected. These are the properties expected if drug binding and modification of channels can be equated. Hyperpolarizations that close modified channels slow unbinding. Allethrin and DDT also modify channels. They bind and unbind far faster than veratridine does, and their binding requires open channels.

Blocking mechanisms of batrachotoxin-activated Na channels in artificial bilayers

The effects of various pharmacological agents that block single batrachotoxin-activated Na channels from rat muscle can be described in terms of three modes of action that correspond to at least three different binding sites. Guanidinium toxins such as tetrodotoxin, saxitoxin, and a novel polypeptide, mu-conotoxin GIIIA, act only from the extra-cellular side and induce discrete blocked states that correspond to residence times of individual toxin molecules. Such toxins apparently do not deeply penetrate the channel pore since the voltage dependence of block is insensitive to toxin charge and block is not relieved by internal Na+. Many nonspecific organic cations, including charged anesthetics, exhibit a voltage-dependent block that is enhanced by depolarization when present on the inside of the channel. This site is probably within the pore, but binding to this site is weak, as indicated by fast blockade that often appears as lowered channel conductance. A separate class of neutral and tertiary amine anesthetics such as benzocaine and procaine induce discrete closed states when added to either side of the membrane. This blocking effect can be explained by preferential binding to closed states of the channel and appears to be due to a modulation of channel gating.

Permeability of the squid giant axon to organic cations and small nonelectrolytes

The permeability of the Na channel of squid giant axon to organic cations and small nonelectrolytes was studied. The compounds tested were guanidinium, formamidinium, and 14C-labeled urea, formamide, thiourea, and acetone. Permeability was calculated from measurements of reversal potential and influx on internally perfused, voltage clamped squid axons. The project had two objectives: (1) to determine whether different methods of measuring the permeability of organic cations yield similar values and (2) to see whether neutral analogs of the organic cations can permeate the Na channel. Our results show that the permeability ratio of sodium to a test ion depends upon the ionic composition of the solution used. This finding is consistent with the view put forward previously that the Na channel can contain more than one ion at a time. In addition, we found that the uncharged analogs of permeant cations are not measurably permeant through the Na channel, but instead probably pass through the lipid bilayer.

Functional reconstitution of the purified brain sodium channel in planar lipid bilayers

The ion conduction and voltage dependence of sodium channels purified from rat brain were investigated in planar lipid bilayers in the presence of batrachotoxin. Single channel currents are clearly resolved. Channel opening is voltage dependent and favored by depolarization. The voltage at which the channel is open 50% of the time is -91 +/- 17 mV (SD, n = 22) and the apparent gating charge is approximately 4. Tetrodotoxin reversibly blocks the ionic current through the sodium channels. The Ki for the tetrodotoxin block is 8.3 nM at -50 mV and is voltage dependent with the Ki increasing e-fold for depolarizations of 43 mV. The single channel conductance, gamma, is ohmic. At 0.5 M salt concentrations gamma = 25 pS for Na+, 3.5 pS for K+, and 1.2 pS for Rb+. This study demonstrates that the purified brain sodium channel--which consists of three polypeptide subunits: alpha (Mr approximately 260,000), beta 1 (Mr approximately 39,000), and beta 2 (Mr approximately 37,000)--exhibits the same voltage dependence, neurotoxin sensitivity, and ionic selectivity associated with native sodium channels.

The effect of Tityus serrulatus scorpion toxin gamma on Na channels in neuroblastoma cells

The effects of highly purified toxin gamma from the venom of the scorpion Tityus serrulatus (TiTx gamma) on nerve membrane ionic channels have been investigated using the suction electrodes voltage clamp technique on neuroblastoma cells. The amplitude of the normally voltage-dependent Na current is reversible reduced by approximately 50% after 15-105 nM TiTx gamma, whereas even the highest toxin concentrations have no significant effect on the outward K current in the presence of tetrodotoxin. TiTx gamma causes a transient inward current to appear at membrane potentials between -70 and -40 mV, a potential region in which no significant inward current is observed in control experiments. Tetrodotoxin (300 nM) rapidly blocks both the TiTx gamma-induced inward current and the remaining normally voltage-dependent Na current. The binding of radiolabelled TiTx gamma to the Na channels in the neuroblastoma cell membrane is prevented by native TiTx gamma with a K0.5 = 0.75 nM. Both activation and inactivation of the TiTx gamma-induced Na current are shifted 30-40 mV towards more negative potential values as compared to normally voltage-dependent Na current. The TiTx gamma-induced Na current exhibits sigmoidal activation kinetics and relatively slow, exponential inactivation kinetics. The local anesthetic procaine at an external concentration of 1 mM blocks more effectively the remaining normally voltage-dependent Na current than the TiTx gamma-induced Na current. Both Na current components are equally blocked by 1 mM of the local anesthetic propoxycaine. The relation between the effects of TiTx gamma on Nat channels and those of other known neurotoxins those of other known neurotoxins specific of this channel is discussed.(ABSTRACT TRUNCATED AT 250 WORDS)

The molecular basis of neuronal excitability

Neurons process and transmit information in the form of electrical signals. Their electrical excitability is due to the presence of voltage-sensitive ion channels in the neuronal plasma membrane. In recent years, the voltage-sensitive sodium channel of mammalian brain has become the first of these important neuronal components to be studied at the molecular level. This article describes the distribution of sodium channels among the functional compartments of the neuron and reviews work leading to the identification, purification, and characterization of this membrane glycoprotein.

Single sodium channels from rat brain incorporated into planar lipid bilayer membranes

A voltage- and time-dependent conductance for sodium ions is responsible for the generation of impulses in most nerve and muscle cells. Changes in the sodium conductance are produced by the opening and closing of many discrete transmembrane channels. We present here the first report of electrical recordings from voltage-dependent sodium channels incorporated into planar lipid bilayers. In bilayers with many channels, batrachotoxin (BTX) induced a steady-state sodium current that was blocked by saxitoxin (STX) at nanomolar concentrations. All channels appeared in the bilayer with their STX blocking sites facing the side of vesicle addition, allowing us to define that as the extracellular side. Current fluctuations due to the opening and closing of single BTX-activated sodium channels were voltage-dependent (unit conductance, 30 pS in 0.5 M NaCl): the channels closed at large hyperpolarizing potentials. Slower fluctuations of the same amplitude, due to the blocking and unblocking of individual channels, were seen after addition of STX. Block of the sodium channels by STX was voltage-dependent, with hyperpolarizing potentials favouring block. The voltage-dependent gating, ionic selectivity and neurotoxin sensitivity suggest that these are the channels that normally underlie the sodium conductance change during the nerve impulse.

Ion selectivity of the nerve membrane sodium channel incorporated into liposomes

Tetrodotoxin-sensitive sodium channels of lobster nerve membranes were incorporated into soybean liposomes by the freeze-thaw-sonication procedure and their ionic selectivity was studied. Veratridine and grayanotoxin-I were used to activate the sodium channels and the increment of the ionic flux through them was specifically abolished by tetrodotoxin. The drug-sensitive 22Na+, 42K+, 86Rb+ and 137Cs+ influxes were measured. The permeability ratios calculated directly from ion fluxes showed that the channels preferably allow the passage of Na+. No anion influx ([32P]phosphate, [35S]sulfate, 36Cl) sensitive to the drugs was observed. The data reveal that the sodium channels incorporated into liposomes remain cation-selective and discriminate among different cations.

Batrachotoxin modifies the gating kinetics of sodium channels in internally perfused neuroblastoma cells

We have studied the effects of batrachotoxin (BTX) on sodium channels in hybrid mouse neuroblastoma cells NG108-15 by using the suction pipet voltage clamp method. BTX-modified sodium channels activate with first-order kinetics and, over most of the potential range, activate more slowly than normal sodium channels. The peak conductance-voltage curve and the time constant of activation-versus-voltage curve for BTX-modified sodium channels are shifted about 50 mV in the hyperpolarizing direction compared to the corresponding curves for normal sodium channels. There is no change in the slope of the conductance-voltage curve. These results suggest that BTX slows down one of the steps leading to channel opening, which consequently becomes rate-limiting. In addition, BTX eliminates both fast and slow inactivation.

Effect of toxins isolated from the venom of the scorpion Centruroides sculpturatus on the Na currents of the node of Ranvier

1. The effect of various toxin fractions isolated by Watt et al. (1978) from the venom of the scorpion Centruroides sculpturatus Ewing on the Na currents of the node of Ranvier has been studied with the voltage clamp method. 2. The toxin fractions were applied externally. The most potent fractions were toxins III, IV and V which were effective in concentrations of 0.33-3.33 microgram/ml. The effect of toxins III and IV was quite different from that of toxin V. 3. In toxin III or IV - treated nodes a strong depolarizing pulse was followed by a transient shift of the negative resistance branch of the INa (E) curve to more negative potentials. The amount of shift varied between -10 and -60 mV. A 500 ms depolarizing pulse of small amplitude produced a slowly developing Na inward current which slowly decayed after the end of the pulse. Inactivation was incomplete, even with 500 ms pulses to 0 mV. 4. The transient shift of the INa (E) curve was not seen in nodes treated with toxin V. This toxin merely caused slow and incomplete Na inactivation. The effect of toxin IV was not suppressed by a four times higher concentration of toxin V, suggesting that the two toxins act on different receptors. 5. Toxin I acted like toxin IV but was about 10 times less potent. The effect of high concentrations of variants 1, 2, 3, 5, 6 resembled tha of toxin V. 6. All effects observed with toxin III or IV were also seen with the whole venom (cf. Cahalan 1975).

Properties of toxin-resistant sodium channels produced by chemical modification in frog skeletal muscle

1. Single skeletal muscle fibres from the frog Rana pipiens were treated with the carboxyl group modifying reagent trimethyloxonium ion (TMO) and voltage clamped by the method of Hille & Campbell (1976). 2. TMO treatment reduced current through sodium channels to 0.33 +/- 0.03 that before treatment, but only 45 +/- 3% of this remaining current was blocked by 1 microM-tetrodotoxin (TTX) and only 37 +/- 5% by 100 nM-saxitoxin (STX). 3. This toxin resistance persisted in 90 microM-TTX, was not due to inactivation of toxin nor to components of the reaction solution other than TMO, but was prevented by the presence of 100 nM-STX during treatment with TMO. TMO-modified sodium channels can be blocked by the local anaesthetic lidocaine. 4. The permeabilities of TMO-modified channels to hydroxylammonium, ammonium, guanidinium, aminoguanidinium, methylammonium and tetramethylammonium ions relative to sodium were not significantly different from the permeabilities of untreated sodium channels. 5. Hydrogen ions blocked TMO-modified sodium channels, but the apparent pKa for block at +38 mV of 5.07 was significantly less than the corresponding value of 5.32 in untreated sodium channels. 6. It is suggested that TMO produces toxin resistance by esterifying an ionized carboxyl group which is an essential part of the toxin binding site. Such esterification would electrostatically reduce the local cation concentration, thus reducing the apparent pKa of hydrogen ion block and the single-channel conductance (Sigworth & Spalding, 1980). 7. It is concluded that the sodium channel contains a second acid group, near but distinct from an acid group previously hypothesized to be part of the selectivity filter and hydrogen ion binding site (Hille, 1971, 1972, 1975a).

Trypsin-induced masking of tetrodotoxin receptor of the sodium channels in mollusc neurons

At the early stage of trypsin treatment of mollusc neurons tetrodotoxin cannot block the Na+ current. In the course of further exposure of neurones to trypsin, tetrodotoxin-sensitivity is restored completely, so its temporal loss results from shielding rather than destruction of the tetrodotoxin-binding site. Pronase and papain do not affect the tetrodotoxin action on the Na+ current.