Mapping the site of block by tetrodotoxin and saxitoxin of sodium channel II

Ion permeation, divalent ion block, and chemical modification of single sodium channels. Description by single- and double-occupancy rate-theory models

Calcium ions, applied internally, externally, or symmetrically, have been used in conjunction with rate-theory modeling to explore the energy profile of the ion-conducting pore of sodium channels. The block, by extracellular and/or intracellular calcium, of sodium ion conduction through single, batrachotoxin-activated sodium channels from rat brain was studied in planar lipid bilayers. Extracellular calcium caused a reduction of inward current that was enhanced by hyperpolarization and a weaker block of outward current. Intracellular calcium reduced both outward and inward sodium current, with the block being weakly dependent on voltage and enhanced by depolarization. These results, together with the dependence of single-channel conductance on sodium concentration, and the effects of symmetrically applied calcium, were described using single- or double-occupancy, three-barrier, two-site (3B2S), or single-occupancy, 4B3S rate-theory models. There appear to be distinct outer and inner regions of the channel, easily accessed by external or internal calcium respectively, separated by a rate-limiting barrier to calcium permeation. Most of the data could be well fit by each of the models. Reducing the ion interaction energies sufficiently to allow a small but significant probability of two-ion occupancy in the 3B2S model yielded better overall fits than for either 3B2S or 4B3S models constrained to single occupancy. The outer ion-binding site of the model may represent a section of the pore in which sodium, calcium, and guanidinium toxins, such as saxitoxin or tetrodotoxin, compete. Under physiological conditions, with millimolar calcium externally, and high potassium internally, the model channels are occupied by calcium or potassium much of the time, causing a significant reduction in single-channel conductance from the value measured with sodium as the only cation species present. Sodium conductance and degree of block by external calcium are reduced by modification of single channels with the carboxyl reagent, trimethyloxonium (TMO) (Worley et al., 1986) Journal of General Physiology. 87:327-349). Elevations of only the outermost parts of the energy profiles for sodium and calcium were sufficient to account for the reductions in conductance and in efficacy of calcium block produced by TMO modification.

A characterization of the activating structural rearrangements in voltage-dependent Shaker K+ channels

In response to changes in membrane potential, voltage-dependent ion channel proteins undergo conformational rearrangements that lead to channel opening. These rearrangements move a net charge, measured as "gating current", across the membrane. Here we characterize the effects of the pharmacological blocker 4-aminopyridine on both the K+ and gating currents of wild-type and mutant Shaker K+ channels. Our results indicate that the activation of these channels involves two distinct types of structural rearrangement. In addition to independent Hodgkin and Huxley type rearrangements for each of the four subunits, which are responsible for most of the gating charge movement, Shaker channels interconvert between two quaternary conformations during activation. The transition between the two quaternary states moves about 10% of the total gating charge, and it is selectively blocked by 4-aminopyridine.

Kinetic effects of quaternary lidocaine block of cardiac sodium channels: a gating current study

The interaction of antiarrhythmic drugs with ion channels is often described within the context of the modulated receptor hypothesis, which explains the action of drugs by proposing that the binding site has a variable affinity for drugs, depending upon whether the channel is closed, open, or inactivated. Lack of direct evidence for altered gating of cardiac Na channels allowed for the suggestion of an alternative model for drug interaction with cardiac channels, which postulated a fixed affinity receptor with access limited by the conformation of the channel (guarded receptor hypothesis). We report measurement of the gating currents of Na channels in canine cardiac Purkinje cells in the absence and presence of QX-222, a quaternary derivative of lidocaine, applied intracellularly, and benzocaine, a neutral local anesthetic. These data demonstrate that the cardiac Na channel behaves as a modulated rather than a guarded receptor in that drug-bound channels gate with altered kinetics. In addition, the results suggest a new interpretation of the modulated receptor hypothesis whereby drug occupancy reduces the overall voltage-dependence of gating, preventing full movement of the voltage sensor.

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.

The microI skeletal muscle sodium channel: mutation E403Q eliminates sensitivity to tetrodotoxin but not to mu-conotoxins GIIIA and GIIIB

Voltage-sensitive Na channels from nerve and muscle are blocked by the guanidinium toxins tetrodotoxin (TTX) and saxitoxin (STX). Mutagenesis studies of brain RII channels have shown that glutamate 387 (E387) is essential for current block by these toxins. We demonstrate here that mutation of glutamate 403 (E403) of the adult skeletal muscle microI channel (corresponding to E387 of RII) also prevents current blockade by TTX and STX, and by neo-saxitoxin. However, the mutation fails to prevent blockade by the peptide neurotoxins, mu-conotoxin GIIIA and GIIIB; these toxins are thought to bind to the same or overlapping sites with TTX and STX. The E403Q mutation may have utility as a marker for exogenous Na channels in transgenic expression studies, since there are no known native channels with the same pharmacological profile.

A simple model for surface charge on ion channel proteins

We present a simple two-parameter model for surface charge directly associated with ion channels. A spherically symmetric "charged shell" models a distribution of surface charge arrayed about the channel entrance, with a corresponding set of image charges behind the plane of the membrane. The transition between a regime of buffered conductance and a regime of rapidly falling conductance at very low ionic strength is found to depend on the magnitude of the surface charge as well as the separation between the charge and the channel entrance. This resolves an apparent discrepancy between the experimental findings of Naranjo and Latorre (1993. Biophys. J. 64:1038-1050) and previous theoretical computations. The charged-shell model is used in a comparative study of the toad skeletal muscle conductance data of Naranjo and Latorre, the rat skeletal muscle conductances of Ravindran et al. (1992. Biophys. J. 61:494-508), and a second set of rat muscle conductances presented in this paper.

Differential contribution by conserved glutamate residues to an ion-selectivity site in the L-type Ca2+ channel pore

In voltage-gated cation channels, it is thought that residues responsible for ion-selectivity are located within the pore-lining SS1-SS2 segments. In this study, we compared the ion permeation properties of mutant calcium channels in which highly conserved glutamate residues, located at analogous positions in the SS2 regions of all four motifs, were individually replaced. All of the mutants exhibited a loss of selectivity for divalent over monovalent cations. However, the permeation properties of the individual mutants varied in a position dependent manner. The results provide strong evidence that these glutamate residues, positioned at equivalent locations in the aligned sequences, play significantly different roles in forming the selectivity barrier of the calcium channel, and are probably arranged in an asymmetrical manner inside the ion-conducting pore.

Na+ channels in cardiac and neuronal cells derived from a mouse embryonal carcinoma cell line

1. Cells from a pluripotent murine embryonal carcinoma cell line (P19) were differentiated in vitro into cells with neurone- and cardiac-like phenotypes. Cells treated with 0.5 microM retinoic acid developed into neurone-like cells possessing extensive neurites. Dimethyl sulphoxide treatment (0.5%) produced large, spontaneously contracting cell aggregates with many properties of cardiac cells. 2. The neurone- and cardiac-like cells contained voltage-sensitive Na+ channels with properties similar to those of native neuronal and cardiac cells. 3. We used whole-cell patch clamp techniques to measure inward currents from the neurone- and cardiac-like cells. Undifferentiated (untreated) cells had only small inward currents (peak of -0.15 nA in 150 mM external Na+). The peak inward current in the neurone-like and cardiac-like cells was -1.2 nA (in 154 mM external Na+) and -2.8 nA (in only 46 mM Na+), respectively. These large currents were absent when the external solution contained no Na+. 4. Tetrodotoxin (TTX) blocked the Na+ currents in the neurone- and cardiac-like cells in a dose-dependent manner. The Kd for TTX block of the Na+ current in the neurone-like cells was 6.7 nM. The Na+ current in the cardiac-like cells was much more resistant to TTX; the half-blocking concentration was two orders of magnitude higher, 710 nM. 5. The kinetic properties of the Na+ channel currents in the neurone- and cardiac-like cells were similar but developed over somewhat different voltage ranges. The voltage sensitivity of activation was similar in both cell types but the activation mid-point voltage was different: -12 mV in the neuronal cells and -34 mV for cardiac cells. Inactivation of the neuronal Na+ channels had a mid-point near -47 mV and was more sensitive to the membrane voltage than inactivation of the cardiac channels. The mid-point of inactivation for the cardiac Na+ channels was -80 mV.

Structure and function of voltage-gated ion channels

The principal subunits of the voltage-gated Na+, Ca2+ and K+ channels are members of a related gene family and are functionally autonomous in voltage-dependent activation, ion conductance and inactivation. In this article, recent work locating the structural elements that are responsible for these three basic functions of the voltage-gated ion channels is reviewed. These studies reveal strong functional analogies among the different ion channels and suggest that the striking differences in their properties arise as variations on a common structural and functional theme.

Ultra-deep blockade of Na+ channels by a quaternary ammonium ion: catalysis by a transition-intermediate state?

1. Individual Na+ channels from isolated guinea-pig ventricular heart cells were studied using the patch-clamp technique. To localize the selectivity region of the channels we investigated their blockade by a permanently charged quaternary ammonium ion (QX-314, 2-(triethylamino)-N-(2,6-dimethylphenyl)acetamide, 0-5 mM) that was applied to the cytoplasmic side of the channel. 2. Resolution of individual blocking events was enhanced by covalent removal of fast inactivation following brief internal exposure to the enzyme papain. The improved resolution reveals the existence of two distinct modalities of blockade: reduction of unitary current, and millisecond interruptions of current. 3. Both modes of internal block could be potentiated by lowering external Na+ concentration. This finding argues that the two corresponding sites of interaction are both located within the channel pore. 4. Analysis of the voltage dependence of block placed both binding sites deep within the pore, at 70% of the electric field from the cytoplasmic entrance. Combined with recent studies localizing block by external Cd2+, the present results argue that the selectivity region of Na+ channels is quite narrow (spanning about 10% of the electric field), and located near the external side of the channel. 5. The manner in which the two blocking processes interact, along with the physical proximity of their binding sites, leads us to propose that the block configuration responsible for the reduction in unitary current serves as a transition intermediate that catalyses formation of the discrete-block complex.

Structure, function and expression of voltage-dependent sodium channels

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

Deduced amino acid sequence of a putative sodium channel from the scyphozoan jellyfish Cyanea capillata

Members of the phylum Cnidaria are the lowest extant organisms to possess a nervous system and are the first that are known to contain cells that produce action potentials carried exclusively by Na+ ions. They thus occupy an important position in the evolution of Na+ channels. A cDNA encoding a 198-kDa protein with high sequence identity to known Na+ channels was isolated from the scyphozoan jellyfish Cyanea capillata. The similarity between this and other Na+ channels is greatest in the transmembrane segments and the putative pore region and less so in the cytoplasmic loops that link the four domains of the protein. Phylogenetic analysis of the deduced protein reveals that it is closely related to known Na+ channels, particularly those of squid and Drosophila, and more distantly separated from Ca2+ channels. Scrutiny of the Cyanea channel in regions corresponding to those purported to form the tetrodotoxin receptor and selectivity filter of Na+ channels in higher animals reveals several anomalies that suggest that current models of the location of the tetrodotoxin binding site and Na+ channel selectivity filter are incomplete.

Role of H5 domain in determining pore diameter and ion permeation through cyclic nucleotide-gated channels

Ion permeation through membrane channels is thought to be governed by a narrow region of the channel pore termed the selectivity filter, which has been proposed to discriminate among ions by both specific binding and molecular sieving, as determined by pore diameter. Recent evidence suggests that a conserved domain (known as H5, P or SS1-SS2) in voltage-gated potassium, sodium and calcium channels contributes to the lining of the pore. Here we investigate whether the H5 domain determines pore diameter and examine the role of pore diameter in controlling ion permeation. These studies rely on differences in single channel conductance, ion selectivity and apparent pore diameter between cyclic nucleotide-gated channels cloned from bovine retina and catfish olfactory neurons. Using chimaeric retinal-olfactory channels, we find that the H5 domain determines these differences in permeation properties, providing structural evidence that the cyclic nucleotide-gated channels are indeed members of the voltage-gated channel family. Moreover, these results show directly that the H5 domain helps form the selectivity filter and that molecular sieving is important in controlling ion permeation.

Single-channel current/voltage relationships of two kinds of Na+ channel in vertebrate sensory neurons

The electrical signals of nerve and muscle are fundamentally dependent on the voltage-gated Na+ channel, which is responsible for the rising phase of the action potential. At least two kinds of Na+ channel are expressed in the membrane of frog dorsal root ganglion (DRG) cells: Na+ channels with fast kinetics that are blocked by tetrodotoxin (TTX) at high affinity, and Na+ channels with slower kinetics that are insensitive to TTX. Recordings of single-channel currents from frog DRG cells, under conditions favoring Na+ as the charge carrier, reveal two distinct amplitudes of single-channel events. With 300 mM external Na+, single-channel events that can be measured in the presence of 1 microM TTX have a slope conductance 7.5 pS. In the absence of TTX, events with a slope conductance of 14.9 pS dominate. Ensemble averages of the smaller single-channel events display the slower kinetics characteristic of the macroscopic TTX-insensitive Na+ currents, and ensemble averages of the larger events display the faster kinetics characteristic of the TTX-sensitive currents. The results are consistent with the idea that the toxin-binding site is sufficiently close to the pore to influence ion permeation.

Responsiveness of cardiac Na+ channels to a site-directed antiserum against the cytosolic linker between domains III and IV and their sensitivity to other modifying agents

Elementary Na+ currents were recorded in inside-out patches from neonatal rat heart cardiocytes to analyze the influence of a site-directed polyclonal anti-serum against the linker region between the domains III and IV (amino acids 1489-1507 of the cardiac Na+ channel protein) on Na+ channel gating and to test whether this part of the alpha-subunit may be considered as a target for modifying agents such as the (-)-enantiomer of DPI 201-106. Anti-SLP 1 serum (directed against amino acids 1490-1507) evoked, usually within 10-15 min after cytosolic administration, modified Na+ channel activity. Antiserum-modified Na+ channels retain a single open state but leave, at -60 mV for example, their conducting configuration consistently with an about threefold lower rate than normal Na+ channels. Another outstanding property of noninactivating Na+ channels, enhanced burst activity, may be quite individually pronounced, a surprising result which is difficult to interpret in terms of structure-function relations. Removal of inactivation led to an increase of reconstructed peak INa (indicating a rise in NPo) and changed INa decay to obey second-order kinetics, i.e., open probability declined slowly but progressively during membrane depolarization. The underlying deactivation process is voltage dependent and responds to a positive voltage shift with a deceleration but may operate even at the same membrane potential with different rates. Iodate-modified Na+ channels exhibit very similar properties including a conserved conductance. They are likewise controlled by an efficient, voltage-dependent deactivation process.(ABSTRACT TRUNCATED AT 250 WORDS)

Primary structure and functional expression of the omega-conotoxin-sensitive N-type calcium channel from rabbit brain

The complete amino acid sequence of a rabbit brain calcium channel (BIII) has been deduced by cloning and sequencing the cDNA. The open reading frame encodes 2339 amino acids, which corresponds to an M(r) of 261,167. A phylogenetic tree representing evolutionary relationships indicates that BIII is grouped together with the other rabbit brain calcium channels, BI and BII, into a subfamily that is distinct from the dihydropyridine-sensitive L-type subfamily. Transient expression in cultured skeletal muscle myotubes derived from muscular dysgenic mice demonstrates that the BIII channel mediates an omega-conotoxin-sensitive calcium current with kinetics and voltage dependence like those previously reported for whole-cell N-type current. Cell-attached patch recordings, with isotonic barium as the charge carrier, revealed distinct single channels with an average slope conductance of 14.3 pS.

Periodic paralysis, myotonia congenita and sarcolemmal ion channels: a success of the candidate gene approach

The classification of periodic paralyses and myotonic syndromes has been a subject of debates for the last 40 yr. Recent advances in molecular biology have led geneticists to reconsider this old question, using a candidate gene approach. Two groups of disorders have now emerged: (1) muscle sodium channel-associated diseases which include hyperkalemic periodic paralysis and its clinical variants, as well as paramyotonia congenita; (2) muscle chloride channel-associated disorders which comprise both the dominant and recessive form of myotonia congenita. This review is focussed on these recent discoveries.

Structural determinants of ion selectivity in brain calcium channel

Glutamic acid residues in the SS2 segment of the internal repeats III and IV of the brain calcium channel BI were subjected to single point mutations. The mutant channels were tested for macroscopic current properties and sensitivities to inorganic blockers. The mutation that replaces glutamic acid 1,469 with glutamine altered ion-selection properties and strongly reduced the sensitivity to Cd2+, whereas the analogous mutation of glutamic acid 1,765 exerted smaller effects on ion-selection properties. Our results indicate that these glutamic acid residues, equivalently positioned in the aligned sequences, play different roles in the selective permeability of the calcium channel.

Divalent cation competition with [3H]saxitoxin binding to tetrodotoxin-resistant and -sensitive sodium channels. A two-site structural model of ion/toxin interaction

Monovalent and divalent cations competitively displace tetrodotoxin and saxitoxin (STX) from their binding sites on nerve and skeletal muscle Na channels. Recent studies of cloned cardiac (toxin-resistant) and brain (toxin-sensitive) Na channels suggest important structural differences in their toxin and divalent cation binding sites. We used a partially purified preparation of sheep cardiac Na channels to compare monovalent and divalent cation competition and pH dependence of binding of [3H]STX between these toxin-resistant channels and toxin-sensitive channels in membranes prepared from rat brain. The effects of several chemical modifiers of amino acid groups were also compared. Toxin competition curves for Na+ in heart and Cd2+ in brain yielded similar KD values to measurements of equilibrium binding curves. The monovalent cation sequence for effectiveness of [3H]STX competition is the same for cardiac and brain Na channels, with similar KI values for each ion and slopes of -1. The effectiveness sequence corresponds to unhydrated ion radii. For seven divalent cations tested (Ca2+, Mg2+, Mn2+, Co2+, Ni2+, Cd2+, and Zn2+) the sequence for [3H]STX competition was also similar. However, whereas all ions displaced [3H]STX from cardiac Na channels at lower concentrations, Cd2+ and Zn2+ did so at much lower concentrations. In addition, and by way of explication, the divalent ion competition curves for both brain and cardiac channels (except for Cd2+ and Zn2+ in heart and Zn2+ in brain) had slopes of less than -1, consistent with more than one interaction site. Two-site curves had statistically better fits than one-site curves. The derived values of KI for the higher affinity sites were similar between the channel types, but the lower affinity KI's were larger for heart. On the other hand, the slopes of competition curves for Cd2+ and Zn2+ were close to -1, as if the cardiac Na channel had one dominant site of interaction or more than one site with similar values for KI. pH titration of [3H]STX binding to cardiac channels showed a pKa of 5.5 and a slope of 0.6-0.9, compared with a pKa of 5.1 and slope of 1 for brain channels. Tetramethyloxonium (TMO) treatment abolished [3H]STX binding to cardiac and brain channels and STX protected channels, but the TMO effect was less dramatic for cardiac channels. Trinitrobenzene sulfonate preferentially abolished [3H]STX binding to brain channels by action at an STX protected site.(ABSTRACT TRUNCATED AT 400 WORDS)

Sodium channel gene defects in the periodic paralyses

Abnormal Na+ currents that produce membrane depolarization have been associated with the episodes of muscle weakness that are the hallmark of the periodic paralyses. There is now strong evidence that various point mutations in the gene encoding the adult skeletal muscle voltage-dependent Na+ channel produce these abnormal currents, and are responsible for the expression of the disease phenotype.

Molecular basis for pharmacological differences between brain and cardiac sodium channels

Sodium channels from brain and heart, whose primary structures are known, differ in their sensitivity to block by the guadinium toxins tetrodotoxin and saxitoxin and to block by external Zn2+ and Cd2+. Studies using site-directed mutagenesis have identified the SS2 and adjacent regions of all four repeats as critical determinants for toxin sensitivity. Within and in the immediate vicinities of the SS2 segments, there are only two amino-acid differences between rat brain sodium channel II and rat heart I sodium channel, both located in repeat I. Here we show that replacement of phenylalanine 385 of brain sodium channel by cysteine that is present at the equivalent position in heart channel (F385C) not only reduces sensitivity to the guadinium toxins but also increases sensitivity to Zn2+ and Cd2+, thus conferring properties of heart sodium channel on brain sodium channel. Replacement of asparagine at the second non-conserved position by arginine (N388R) only marginally affects sensitivity to the toxins, Zn2+ or Cd2+, but this mutation markedly reduces sensitivity to block by Ca2+ and Co2+. The double mutant channel (F385C.N388R) shows combined properties of the two mutant channels. These results give a structural insight into the different properties of the two channel proteins.

Chimeric study of sodium channels from rat skeletal and cardiac muscle

Two isoforms of voltage-dependent Na channels, cloned from rat skeletal muscle, were expressed in Xenopus oocytes. The currents of rSkM1 and rSkM2 differ functionally in 4 properties: (i) tetrodotoxin (TTX) sensitivity, (ii) mu-conotoxin (mu-CTX) sensitivity, (iii) amplitude of single channel currents, and (iv) rate of inactivation. rSkM1 is sensitive to both TTX and mu-CTX. rSkM2 is resistant to both toxins. Currents of rSkM1 have a higher single channel conductance and a slower rate of inactivation than those of rSkM2. We constructed (i) chimeras by interchanging domain 1 (D1) between the two isoforms, (ii) block mutations of 22 amino acids in length that interchanged parts of the loop between transmembrane segments S5 and S6 in both D1 and D4, and (iii) point mutations in the SS2 region of this loop in D1. The TTX sensitivity could be switched between the two isoforms by the exchange of a single amino acid, tyrosine-401 in rSkM1 and cysteine-374 in rSkM2 in SS2 of D1. By contrast most chimeras and point mutants had an intermediate sensitivity to mu-CTX when compared with the wild-type channels. The point mutant rSkM1 (Y401C) had an intermediate single-channel conductance between those of the wild-type isoforms, whereas rSkM2 (C374Y) had a slightly lower conductance than rSkM2. The rate of inactivation was found to be determined by multiple regions of the protein, since chimeras in which D1 was swapped had intermediate rates of inactivation compared with the wild-type isoforms.

Primary structure, chromosomal localization, and functional expression of a voltage-gated sodium channel from human brain

A cDNA library derived from human cerebral cortex was screened for the presence of sodium channel alpha subunit-specific clones. Ligation of three overlapping clones generated a full-length cDNA clone, HBA, that provided the complete nucleotide sequence coding for a protein of 2005 amino acids. The predicted structure suggests four homologous repeats and exhibits greatest homology and structural similarity to the rat brain sodium channel II. A second cDNA clone, HBB, that encodes a different subtype of sodium channel was isolated. Hybridization of DNA fragments from the 3' untranslated region of HBA and PCR with primers derived from HBB with human-hamster somatic cell hybrids localized these clones to human chromosome 2. In situ hybridization to human metaphase chromosomes mapped the structural genes for both HBA and HBB sodium channels to chromosome 2q23-24.3. The sodium channel HBA gene product was expressed by transfection in CHO cells. Expressed HBA currents were voltage-dependent, sodium-selective, and tetrodotoxin-sensitive and, thus, exhibit the biophysical and pharmacological properties characteristic of sodium channels.

The glial voltage-gated sodium channel: cell- and tissue-specific mRNA expression

Previous electrophysiological and pharmacological studies on central and peripheral glia revealed the presence of voltage-gated Na channels with properties that are similar but not identical to those of neuronal Na channels. Here we report the isolation and characterization of a cDNA encoding the C-terminal portion of a putative glial Na-channel (Na-G) alpha subunit. The amino acid sequence deduced from this cDNA indicates that the Na-G represents a separate molecular class within the mammalian Na-channel multigene family. By Northern blot, RNase protection, and in situ hybridization assays, we demonstrate that, in addition to brain astroglia, the Na-G mRNA is expressed in cultures of Schwann cells derived from dorsal root ganglia or from sciatic nerve. In vivo, the Na-G mRNA is detected not only in brain, dorsal root ganglia, and sciatic nerve, but also in tissues outside the nervous system including cardiac and skeletal muscle and lung. Its level varies according to the tissue and is developmentally regulated. The sequence and expression data concur in designating Na-G as an distinct type of Na channel, presumably with low sensitivity to tetrodotoxin.

Proposed tertiary structure of the sodium channel

On the basis of our recent results of the complete amino acid sequence of the squid Loligo bleekeri sodium channel deduced by cloning and sequence analysis of the complementary DNA (Sato, C. and Matsumoto, G. Biochem. Biophys. Res. Comm. 186, 1), we have proposed a tertiary structure model of the sodium channel where the transmembrane segments are octagonally aligned and the four linkers of S5-6 between segments S5 and S6 play a crucial role in the activation gate, voltage sensor and ion selective pore, which can slide, depending on membrane potentials, along inner walls consisting of segments S2 and S4 alternately. The proposed model is contrasted with that of Noda et al. (Nature 320; 188-192, 1986).

A new look at the mechanism of activation and inactivation of voltage-gated ion channels

Studies on the kinetics of activation and inactivation of the sodium channels of the squid giant axon, on the sodium gating current, and on the properties of the non-inactivating steady-state current, are briefly reviewed. Taken in conjunction with recent evidence on the structure of voltage-gated ion channels, they have led to the development of a series-parallel model of the sodium channel that can be regarded as a modernized version of the Hodgkin-Huxley model, with some novel features. It is suggested that activation results from conformational changes brought about by the four S4 voltage sensors operating in parallel, each of which makes two discrete steps to reach the fully activated state of the channel. There follows a voltage-independent hydration step, and the channel is ready to open. Inactivation is a potential-dependent process involving a third transition of voltage sensor S4d alone, which, rather than bringing a ball and chain blocking group into position to close the channels, serves to switch the system so that it passes from an initial activated mode, in which there is a high probability of arriving at an open state with a brief latency, to a second steady-state mode, in which the probability of opening is very much lower.

Molecular localization of an ion-binding site within the pore of mammalian sodium channels

Sodium channels are the major proteins that underlie excitability in nerve, heart, and skeletal muscle. Chemical reaction rate theory was used to analyze the blockage of single wild-type and mutant sodium channels by cadmium ions. The affinity of cadmium for the native tetrodotoxin (TTX)-resistant cardiac channel was much higher than its affinity for the TTX-sensitive skeletal muscle isoform of the channel (microliters). Mutation of Tyr401 to Cys, the corresponding residue in the cardiac sequence, rendered microliters highly susceptible to cadmium blockage but resistant to TTX. The binding site was localized approximately 20% of the distance down the electrical field, thus defining the position of a critical residue within the sodium channel pore.

The structure and function of Na+ channels

The past year has seen major advances in our understanding of voltage-gated ion channels through a powerful combination of patch-clamp and molecular biological techniques. These approaches have identified regions (in some cases single amino acid residues) that are essential for voltage-dependent activation and inactivation, lining of the pore, and regulation of channel function.

A mutant of TTX-resistant cardiac sodium channels with TTX-sensitive properties

The cardiac sodium channel alpha subunit (RHI) is less sensitive to tetrodotoxin (TTX) and saxitoxin (STX) and more sensitive to cadmium than brain and skeletal muscle (microliter) isoforms. An RHI mutant, with Tyr substituted for Cys at position 374 (as in microliter) confers three properties of TTX-sensitive channels: (i) greater sensitivity to TTX (730-fold); (ii) lower sensitivity to cadmium (28-fold); and (iii) altered additional block by toxin upon repetitive stimulation. Thus, the primary determinant of high-affinity TTX-STX binding is a critical aromatic residue at position 374, and the interaction may take place possibly through an ionized hydrogen bond. This finding requires revision of the sodium channel pore structure that has been previously suggested by homology with the potassium channel.

Photolabeled sites with a tetrodotoxin derivative in the domain III and IV of the electroplax sodium channel

Forty three percent of the labeled sites, at least, in the electroplax sodium channel with a photoactivable tetrodotoxin derivative were identified by probing protease-digested labeled fragments with several sequence-directed antibodies. They are located in the loop between segments S5 and S6 of domain IV, as well as the region containing transmembrane segment S6 and adjacent extracellular and cytoplasmic sequences in domain III. No photolabeled fragments were detected in the corresponding region of domain I. These results suggest that C-11 of tetrodotoxin where the photoreactive moiety is attached orients to the region between S5 and S6 in domain III and IV. Probable orientation of the tetrodotoxin molecule in sodium channels is considered by taking together with the recent report of the site-directed mutagenesis.

Calcium channel characteristics conferred on the sodium channel by single mutations

The sodium channel, one of the family of structurally homologous voltage-gated ion channels, differs from other members, such as the calcium and the potassium channels, in its high selectivity for Na+. This selectivity presumably reflects a distinct structure of its ion-conducting pore. We have recently identified two clusters of predominantly negatively charged amino-acid residues, located at equivalent positions in the four internal repeats of the sodium channel as the main determinants of sensitivity to the blockers tetrodotoxin and saxitoxin. All site-directed mutations reducing net negative charge at these positions also caused a marked decrease in single-channel conductance. Thus these two amino-acid clusters probably form part of the extracellular mouth and/or the pore wall of the sodium channel. We report here the effects on ion selectivity of replacing lysine at position 1,422 in repeat III and/or alanine at position 1,714 in repeat IV of rat sodium channel II (ref. 3), each located in one of the two clusters, by glutamic acid, which occurs at the equivalent positions in calcium channels. These amino-acid substitutions, unlike other substitutions in the adjacent regions, alter ion-selection properties of the sodium channel to resemble those of calcium channels. This result indicates that lysine 1,422 and alanine 1,714 are critical in determining the ion selectivity of the sodium channel, suggesting that these residues constitute part of the selectivity filter of the channel.

A possible biological role of the electron transfer between tyrosine and tryptophan. Gating of ion channels

Experiments have demonstrated that four tryptophan residues are located near the tetrodotoxin binding site in Na+ channels, and that conserved tyrosine and tryptophan residues are located in the pore-forming region of voltage-sensitive K+ channels. This paper proposes an activation mechanism involving electron transfer between these residues. The K+ channel may be closed by four tyrosine residues forming hydrogen bonds with each other. After electron transfer, these hydrogen bonds will be broken, thereby opening the channel. The Na+ channel could be activated by a similar mechanism. This idea can be tested directly by observing tyrosine or tryptophan radicals when the channels are in the open state.