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

The application of Poisson distribution statistics in ion channel reconstitution to determine oligomeric architecture

During reconstitution, membrane proteins are randomly inserted into liposomes according to Poisson distribution statistics. When the protein to lipid ratios in the reconstitution mixture are varied systematically, the characteristics of this statistical capture permit inferences about the proteins themselves, such as the number of subunits that assemble into a single functional unit. This chapter describes the Poisson distribution as applied to the reconstitution of membrane proteins into proteoliposomes and focuses on an application whereby this statistical behavior is used to determine the number of ion channel subunits that assemble into a functional pore. Practical considerations for performing these experiments are emphasized. Harnessing Poisson dilution statistics provides a function-based method to determine ion channel oligomerization, complementing other biophysical, biochemical, or structural approaches.

The crystal structure of a voltage-gated sodium channel

Voltage-gated sodium (Na(V)) channels initiate electrical signalling in excitable cells and are the molecular targets for drugs and disease mutations, but the structural basis for their voltage-dependent activation, ion selectivity and drug block is unknown. Here we report the crystal structure of a voltage-gated Na(+) channel from Arcobacter butzleri (NavAb) captured in a closed-pore conformation with four activated voltage sensors at 2.7 Å resolution. The arginine gating charges make multiple hydrophilic interactions within the voltage sensor, including unanticipated hydrogen bonds to the protein backbone. Comparisons to previous open-pore potassium channel structures indicate that the voltage-sensor domains and the S4-S5 linkers dilate the central pore by pivoting together around a hinge at the base of the pore module. The NavAb selectivity filter is short, ∼4.6 Å wide, and water filled, with four acidic side chains surrounding the narrowest part of the ion conduction pathway. This unique structure presents a high-field-strength anionic coordination site, which confers Na(+) selectivity through partial dehydration via direct interaction with glutamate side chains. Fenestrations in the sides of the pore module are unexpectedly penetrated by fatty acyl chains that extend into the central cavity, and these portals are large enough for the entry of small, hydrophobic pore-blocking drugs. This structure provides the template for understanding electrical signalling in excitable cells and the actions of drugs used for pain, epilepsy and cardiac arrhythmia at the atomic level.

Direct evidence that receptor site-4 of sodium channel gating modifiers is not dipped in the phospholipid bilayer of neuronal membranes

In a recent note to Nature, R. MacKinnon has raised the possibility that potassium channel gating modifiers are able to partition in the phospholipid bilayer of neuronal membranes and that by increasing their partial concentration adjacent to their receptor, they affect channel function with apparent high affinity (Lee and MacKinnon (2004) Nature 430, 232-235). This suggestion was adopted by Smith et al. (Smith, J. J., Alphy, S., Seibert, A. L., and Blumenthal, K. M. (2005) J. Biol. Chem. 280, 11127-11133), who analyzed the partitioning of sodium channel modifiers in liposomes. They found that certain modifiers were able to partition in these artificial membranes, and on this basis, they have extrapolated that scorpion beta-toxins interact with their channel receptor in a similar mechanism as that proposed by MacKinnon. Since this hypothesis has actually raised a new conception, we examined it in binding assays using a number of pharmacologically distinct scorpion beta-toxins and insect and mammalian neuronal membrane preparations, as well as by analyzing the rate by which the toxin effect on gating of Drosophila DmNa(v)1 and rat brain rNa(v)1.2a develops. We show that in general, scorpion beta-toxins do not partition in neuronal membranes and that in the case in which a depressant beta-toxin partitions in insect neuronal membranes, this partitioning is unrelated to its interaction with the receptor site and the effect on the gating properties of the sodium channel. These results negate the hypothesis that the high affinity of beta-toxins for sodium channels is gained by their ability to partition in the phospholipid bilayer and clearly indicate that the receptor site for scorpion beta-toxins is accessible to the extracellular solvent.

Molecular mechanism of convergent regulation of brain Na(+) channels by protein kinase C and protein kinase A anchored to AKAP-15

Activation of D1-like dopamine (DA) receptors reduces peak Na(+) current in hippocampal neurons voltage-dependent in a manner via phosphorylation of the alpha subunit. This modulation is dependent upon activation of cAMP-dependent protein kinase (PKA) and requires phosphorylation of serine 573 (S573) in the intracellular loop connecting homologous domains I and II (L(I-II)) by PKA anchored to A kinase anchoring protein-15 (AKAP-15). Activation of protein kinase C (PKC) also reduces peak Na(+) currents and enhances the strength of the PKA modulatory pathway. Here we probe the molecular mechanism responsible for the convergent effects of PKA and PKC on brain Na(v)1.2a channels. Analysis of the interaction of AKAP-15 with the intracellular loops of the Na(v)1.2a channel shows that it binds to L(I-II), thereby targeting PKA directly to its sites of phosphorylation on the Na(+) channel by specific protein-protein interactions. Mutagenesis and expression experiments indicate that reduction of peak Na(+) current by PKC requires S554 and S573 in L(I-II) in addition to S1506 in the inactivation gate. In addition, PKC-dependent phosphorylation of S576 in L(I-II) is necessary for enhancement of PKA modulation of brain Na(+) channels. When S576 is phosphorylated by PKC, the increase in modulation by PKA activation requires phosphorylation of S687 in L(I-II). Thus, the maximal modulation of these Na(+) channels by concurrent activation of PKA and PKC requires phosphorylation at four distinct sites in L(I-II): S554, S573, S576, and S687. This convergent regulation provides a novel mechanism by which information from multiple signaling pathways may be integrated at the cellular level in the hippocampus and throughout the central nervous system.

1H NMR structure of an antifungal gamma-thionin protein SIalpha1: similarity to scorpion toxins

The three-dimensional structure of the Sorghum bicolor seed protein gamma-thionin SIalpha1 has been determined by 2D 1H nuclear magnetic resonance (NMR) spectroscopy. The secondary structure of this 47-residue antifungal protein with four disulphide bridges consists of a three-stranded antiparallel sheet and one helix. The helix is tethered to the sheet by two disulphide bridges which link two successive turns of the helix to alternate residues i, i+2 in one strand. Possible binding sites for antifungal activity are discussed. The same fold has been observed previously in several scorpion toxins.

High affinity binding of pyrethroids to the alpha subunit of brain sodium channels

Na+ channels are the primary molecular targets of the pyrethroid insecticides. Na+ channels consisting of only a type IIA alpha subunit expressed in Chinese hamster ovary cells responded to pyrethroid treatment in a normal manner: a sustained Na+ current was induced progressively after each depolarizing pulse in a train of stimuli, and this Na+ current decayed slowly on repolarization. These modified Na+ channels could be reactivated at much more negative membrane potentials (V0.5 = -139 mV) than unmodified Na+ channels (V0.5 = -28 mV). These results indicate that pyrethroids can modify the functional properties of the Na+ channel alpha subunit expressed alone by blocking their inactivation, shifting their voltage dependence of activation, and slowing their deactivation. To demonstrate directly the specific interaction of pyrethroids with the alpha subunit of voltage-gated Na+ channels, a radioactive photosensitive derivative, [3H]RU58487, was used in binding and photolabeling studies. In the presence of a low concentration of the nonionic detergent Triton X-100, specific pyrethroid binding to Na+ channels in rat brain membrane preparations could be measured and reached 75% of total binding under optimal conditions. Binding approached equilibrium within 1 hr at 4 degrees, dissociated with a half-time of approximately 10 min, and had K(D) values of approximately 58-300 nM for three representative pyrethroids. Specific pyrethroid binding was enhanced by approximately 40% in the presence of 100 nM alpha-scorpion toxin, but no allosteric enhancement was observed in the presence of toxins acting at other Na+ channel receptor sites. Extensive membrane washing increased specific binding to 89%. Photolabeling with [3H]RU58487 under these optimal binding conditions revealed a radiolabeled band with an apparent molecular mass of 240 kDa corresponding to the Na+ channel alpha subunit. Anti-peptide antibodies recognizing sequences within the alpha subunit were able to specifically immunoprecipitate the covalently modified channel. Together, these results demonstrate that the pyrethroids can modify the properties of cells expressing only the alpha subunit of Na+ channels and can bind specifically to a receptor site on the alpha subunit.

Site of covalent labeling by a photoreactive batrachotoxin derivative near transmembrane segment IS6 of the sodium channel alpha subunit

The binding site for batrachotoxin, a lipid-soluble neurotoxin acting at Na+ channel receptor site 2, was localized using a photoreactive radiolabeled batrachotoxin derivative to covalently label purified and reconstituted rat brain Na+ channels. In the presence of the brevetoxin 1 from Ptychodiscus brevis and the pyrethroid RU51049, positive allosteric enhancers of batrachotoxin binding, a protein with an apparent molecular mass of 240 kDa corresponding to the Na+ channel alpha subunit was specifically covalently labeled. The region of the alpha subunit specifically photolabeled by the photoreactive batrachotoxin derivative was identified by antibody mapping of proteolytic fragments. Even after extensive trypsinization, and anti-peptide antibody recognizing an amino acid sequence adjacent to Na+ channel transmembrane segment IS6 was able to immunoprecipitate up to 70% of the labeled peptides. Analysis of a more complete digestion with trypsin or V8 protease indicated that the batrachotoxin receptor site is formed in part by a portion of domain I. The identification of a specifically immunoprecipitated photolabeled 7.3-kDa peptide containing transmembrane segment S6 from domain I restricted the site of labeling to residues Asn-388 to Glu-429 if V8 protease digestion was complete or Leu-380 to Glu-429 if digestion was incomplete. These results implicate the S6 transmembrane region of domain I of the Na+ channel alpha subunit as an important component of the batrachotoxin receptor site.

Lidocaine has different effects and potencies on muscle and brain sodium channels

Lidocaine effects were studied at the single channel level on batrachotoxin-activated eel electroplax (muscle-derived) and on rat brain sodium channels in planar lipid bilayers to investigate whether these effects were the same on structurally different sodium channels. Lidocaine blocked the open state of brain channels with the same voltage dependence, but with 15-times as high a potency as muscle-derived channels. In brain channels, but not muscle-derived ones, the level of the open channel block showed periods of relief. Lidocaine at microM concentrations stabilized the highest conductance state in both channel types and at mM concentrations stabilized subconductance-like states in electroplax, but not in brain channels. In both channel types, lidocaine increased the lifetime and rate of entry to a long-nonconducting state. Since both channel types were studied under identical lipid and ionic conditions, the observed functional differences in the lidocaine action (effects, potency) must reflect channel structural differences.

[3H]-lifarizine, a high affinity probe for inactivated sodium channels

1. [3H]-lifarizine bound saturably and reversibly to an apparently homogeneous class of high affinity sites in rat cerebrocortical membranes (Kd = 10.7 +/- 2.9 nM; Bmax = 5.10 +/- 1.43 pmol mg-1 protein). 2. The binding of [3H]-lifarizine was unaffected by sodium channel toxins binding to site 1 (tetrodotoxin), site 3 (alpha-scorpion venom) or site 5 (brevetoxin), Furthermore, lifarizine at concentrations up to 10 microM had no effect on [3H]-saxitoxin (STX) binding to toxin site 1. Lifarizine displaced [3H]-batrachotoxinin-A 20-alpha-benzoate (BTX) binding with moderate affinity (pIC50 7.31 +/- 0.24) indicating an interaction with toxin site 2. However, lifarizine accelerated the dissociation of [3H]-BTX and decreased both the affinity and density of sites labelled by [3H]-BTX, suggesting an allosteric interaction with toxin site 2. 3. The binding of [3H]-lifarizine was voltage-sensitive, binding to membranes with higher affinity than to synaptosomes (pIC50 for cold lifarizine = 7.99 +/- 0.09 in membranes and 6.68 +/- 0.14 in synaptosomes). Depolarization of synaptosomes with 130 mM KCl increased the affinity of lifarizine almost 10 fold (pIC50 = 7.86 +/- 0.25). This suggests that lifarizine binds selectively to inactivated sodium channels which predominate both in the membrane preparation and in the depolarized synaptosomal preparation. 4. There was negligible [3H]-lifarizine and [3H]-BTX binding to solubilized sodium channels, although [3H]-STX binding was retained under these conditions. 5. The potencies of a series of compounds in displacing [3H]-lifarizine from rat cerebrocortical membranes correlated well with their affinities for inactivated sodium channels estimated from whole-cell voltage clamp studies in the mouse neuroblastoma cell line, NIE-115 (r=0.96).6. These results show that [3H]-lifarizine is a high affinity ligand for neuronal sodium channels which potently and selectively labels a site, allosterically linked to toxin binding site 2, associated within activated sodium channels.

Renaturation of the brain myelin proteins by octyl glucoside detergent

The secondary structure of myelin proteins undergoes a deep change when the membrane is delipidated and suspended in an aqueous buffer containing phosphate and sulfate anions. However, when increasing concentrations of octyl glucoside are dissolved in this saline medium, proteins recover gradually its native secondary structure, reaching a maximum for a detergent/protein ratio which, in addition, is optimal for maximal membrane solubilization. Larger amounts of detergent, however, reverted the effect. Results are explained in terms of anion-lipid and detergent-lipid interactions. Quantitative estimates on the spectral profiles let us find the optimal detergent-protein stoichiometry for preserving almost completely the native secondary structure of myelin proteins while keeping maximal solubilization. These findings are of great importance for reconstitution experiments designed with the goal of determining the biological functions of myelin proteins.

Oligosaccharide composition of the neurotoxin-responsive sodium channel of mouse neuroblastoma and requirement of sialic acid for biological activity

A glycoprotein, M(r) 200,000, which has the biological activity of the neurotoxin-responsive Na+ channel, was isolated from a clonal line of mouse neuroblastoma cells, N-18. The glycoprotein was purified to homogeneity in 18% yield by methods used to purify glycoproteins, which included metabolic labeling of the cells with L-[3H]fucose and binding of the radioactive glycoproteins to WGA- and lentil-Sepharose, and DEAE-cellulose. The glycoprotein has biological activity of neurotoxin-responsive ion flux when reconstituted into artificial phospholipid vesicles. This activity was shown to depend on the presence of sialic acid since treatment of the purified, reconstituted glycoprotein with Vibrio cholerae neuraminidase abolished the response to neurotoxins of 86Rb flux. The [3H]fucose-containing glycopeptides derived by Pronase digestion of the glycoprotein were characterized by affinity to immobilized lectins and contained di-, tri-, and tetra-antennary oligosaccharides in a ratio of 2:4:3. Most of the glycopeptides were sialylated as shown by binding characteristics to immobilized serotonin-Sepharose with and without neuraminidase. The structure of the diantennary oligosaccharides was elucidated by 500-MHz 1H NMR spectroscopy. The Con A-bound fraction contains alpha-NeuNAc-(2-->6)-bound group on the GlcNAc5' antenna and an alpha-NeuNAc-(2-->3)-bound groups on the GlcNAc5 antenna. An alpha-L-fucosyl group is (1-->6)-bound to the Asn core GlcNAc1 residue.

Voltage-sensitive Na+ channels in mammalian peripheral nerves detected using scorpion toxins

The localization of voltage-sensitive sodium channels was investigated in mouse, rat and rabbit sciatic nerves using iodinated alpha- and beta-Scorpion toxins (ScTx) as specific probes. Saturable specific binding for a beta-ScTx was detected in mouse sciatic nerve homogenates (Kd = 90 pM, binding site capacity = 90 fmol mg-1 protein). LM autoradiographic studies demonstrated that the two types of ScTx stained the Ranvier nodes of the myelinated fibres, and also showed a clear but weaker labelling of the unmyelinated Remak bundles. In the sciatic nerve, which is widely considered as a model 'myelinated nerve', the nodal membrane represented only a small fraction of the total axonal membranes (0.2% and 0.05% for mouse and rabbit sciatic nerves respectively). Therefore, despite their high channel density, nodal membranes contribute only a small proportion of the total labelling by beta-ScTx (15% and 2.3% for mouse and rabbit sciatic nerves respectively), with the major contribution to labelling arising from unmyelinated axons. The distribution of specific binding sites for a beta-Scorpion toxin was then analysed in cross-sections of rabbit sciatic nerve at the EM level. The quantitative analysis of autoradiograms involved three methods, the 50% probability circle method, and two cross-fire analyses using either systematically distributed hypothetical sources or hypothetical sources only located on the plasma membranes of axons and of Schwann cells associated with unmyelinated Remak bundles. No specific beta-Scorpion toxin binding sites were detected at the plasma membrane of Schwann cells from either myelinated fibres or unmyelinated bundles, or at the internodal surface of myelinated axons. Sites were only detected at the surface of unmyelinated axons and at nodal axolemma. Their density in unmyelinated axons was found to be in the range of 1-6 per micron2 of plasma membrane surface area by combining quantitative EM autoradiography and stereological measurements.

Effects of ions and ionic channel activators or blockers on release of alpha-MSH from perifused rat hypothalamic slices

The involvement of sodium and chloride ions in the process of alpha-melanocyte-stimulating hormone (a-MSH) release from hypothalamic neurons was investigated using perifused rat hypothalamic slices. Three different stimuli were found to increase a-MSH release from hypothalamic slices: high K+ concentration (50 mM), veratridine (50 microM), and the Na+/K(+)-ATPase inhibitor ouabain (1 mM). Spontaneous or K(+)-evoked a-MSH release was insensitive to the specific Na+ channel blocker tetrodotoxin (TTX; 1.5 microM) and to the blocker of K+ channels tetraethylammonium (TEA; 30 mM) or 4-aminopyridine (4-AP; 4 mM). In contrast, blockage of ouabain-sensitive Na+/K(+)-ATPase increased the resting level of a-MSH and caused a dramatic potentiation of K(+)-evoked a-MSH release. The Na+ channel activator veratridine (50 microM) triggered a-MSH release. This stimulatory effect was blocked by TTX and prolonged by TEA application, indicating the occurrence of voltage-sensitive Na+ and K+ channels on a-MSH neurons. Replacement of Na+ by impermeant choline ions from 95 to 60 mM did not alter K(+)-evoked a-MSH release. Conversely, dramatic reduction of the external Na+ concentration to 16 mM caused a robust increase of a-MSH secretion from hypothalamic neurons, likely through activation of the Na+/Ca2+ exchange system. These data indicate that the depolarizing effect of K+ results from direct activation of voltage-operated Ca2+ channels. The lack of effect of TEA on basal a-MSH release prompted us to investigate the possible involvement of chloride ions in the regulation of the spontaneous activity of a-MSH neurons. Substitution of Cl- for impermeant acetate ions did not affect basal or K(+)-evoked a-MSH release.(ABSTRACT TRUNCATED AT 250 WORDS)

Photoaffinity labeling of the receptor site for alpha-scorpion toxins on purified and reconstituted sodium channels by a new toxin derivative

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

Characterization of alpha-melanocyte-stimulating hormone (alpha-MSH)-like peptides in discrete regions of the rat brain. In vitro release of alpha-MSH from perifused hypothalamus and amygdala

The neuropeptide alpha-melanocyte-stimulating hormone (alpha-MSH) is synthesized by discrete populations of hypothalamic neurons which project in different brain regions including the cerebral cortex, hippocampus and amygdala nuclei. The purpose of the present study was to identify the alpha-MSH-immunoreactive species contained in these different structures and to compare the ionic mechanisms underlaying alpha-MSH release at the proximal and distal levels, i.e. within the hypothalamus and amygdala nuclei, respectively. The molecular forms of alpha-MSH-related peptides stored in discrete areas of the brain were characterized by combining high-performance liquid chromatography (HPLC) separation and radioimmunoassay detection. In mediobasal and dorsolateral hypothalamic extracts, HPLC analysis confirmed the existence of a major immunoreactive peak which co-eluted with the synthetic des-N alpha-acetyl alpha-MSH standard. In contrast, 3 distinct forms of immunoreactive alpha-MSH, which exhibited the same retention times as synthetic des-, mono- and di-acetyl alpha-MSH, were resolved in amygdala nuclei, hippocampus, cortex and medulla oblongata extracts. The proportions of acetylated alpha-MSH (authentic alpha-MSH plus diacetyl alpha-MSH) contained in these extrahypothalamic structures were, respectively, 78, 80, 60 and 92% of the total alpha-MSH immunoreactivity. In order to compare the ionic mechanisms underlaying alpha-MSH release from hypothalamic and extrahypothalamic tissues, we have investigated in vitro the secretion of alpha-MSH by perifused slices of hypothalamus and amygdala nuclei. High potassium concentrations induced a marked increase of alpha-MSH release from both tissue preparations. However, a higher concentration of KCl was required to obtain maximal stimulation of amygdala nuclei (90 mM) than hypothalamic tissue (50 mM).(ABSTRACT TRUNCATED AT 250 WORDS)

Two-dimensional probability density analysis of single channel currents from reconstituted acetylcholine receptors and sodium channels

Two-dimensional probability density analysis of single channel current recordings was applied to two purified channel proteins reconstituted in planar lipid bilayers: Torpedo acetylcholine receptors and voltage-sensitive sodium channels from rat brain. The information contained in the dynamic history of the gating process, i.e., the time sequence of opening and closing events was extracted from two-dimensional distributions of transitions between identifiable states. This approach allows one to identify kinetic models consistent with the observables. Gating of acetylcholine receptors expresses "memory" of the transition history: the receptor has two channel open (O) states; the residence time in each of them strongly depends on both the preceding open time and the intervening closed interval. Correspondingly, the residence time in the closed (C) states depends on both the preceding open time and the preceding closed time. This result confirms the scheme that considers, at least, two transition pathways between the open and closed states and extends the details of the model in that it defines that the short-lived open state is primarily entered from long-lived closed states while the long-lived open state is accessed mainly through short-lived closed states. Since ligand binding to the acetylcholine-binding sites is a reaction with channel closed states, we infer that the longest closed state (approximately 19 ms) is unliganded, the intermediate closed state (approximately 2 ms) is singly liganded and makes transitions to the short open state (approximately 0.5 ms) and the shortest closed state (approximately 0.4 ms) is doubly liganded and isomerizes to long open states (approximately 5 ms). This is the simplest interpretation consistent with available data. In contrast, sodium channels modified with batrachotoxin to eliminate inactivation show no correlation in the sequence of channel opening and closing events, i.e., have no memory of the transition history. This result is, therefore, consistent with any kinetic scheme that considers a single transition pathway between open and closed states, and confirms the C-C-O model previously inferred from one-dimensional distribution analysis. The strategy described should be of general validity in the analysis of single channel events from channel proteins in both natural and reconstituted membranes.

Three-dimensional model of the insect-directed scorpion toxin from Androctonus australis Hector and its implication for the evolution of scorpion toxins in general

The three-dimensional structure of the insect-directed toxin from the scorpion Androctonus australis Hector has been modelled using computer graphics and energy-minimization techniques. The model-building procedure was based on the known high resolution structures of two scorpion toxins of different types: toxin II from A. australis Hector, an alpha-toxin, and variant 3 from Centruroides sculpturatus Ewing that belongs to the beta-toxin structural group. Although the insect-directed toxin has one atypical disulfide bridge, the general structural features of the scorpion toxin family, including the presence of a "conserved-hydrophobic" surface, seem to be well-conserved. However, the orientation and length of some loops and regions thought to be important for toxicity are different for alpha-toxins, beta-toxins, and the insect-directed toxin. Thus, the binding of a scorpion toxin to its site on the Na+ channel seems to be based on (1) the presence of a surface containing a series of conserved and/or hydrophobic residues, more or less common to all these molecules, and (2) an adjacent area that modulates the specificity of the interaction.

Sodium channel activation does not alter lipid metabolism in cultured neuroblastoma cells

The interaction of voltage-sensitive Na+-channels and membrane lipid metabolism was examined by incubating cultured neuroblastoma cells with neurotoxins which alter the voltage-dependent relationship between the closed and open conformation of the channel protein. Guanidinium flux rate, a measure of Na+-channel activation, was increased 10-fold by the combined action of veratridine (100 microM) and scorpion venom (28 micrograms/ml). This response was completely blocked by tetrodotoxin (1 microM). Under the same experimental conditions, the toxins did not increase the efflux of [3H]arachidonic acid from prelabeled cell membrane lipids or stimulate uptake of exogenous [3H]arachidonic acid. In addition, altering membrane fatty acid composition by incubating cells for 24 hr in a medium containing 50 microM arachidonic or oleic acid did not alter guanidinium flux rates relative to that of control cultures. When cells were pulsed with 32Pi for 60 min and stimulated by veratridine plus scorpion venom for an additional 30 min, uptake of 32Pi into phosphatidylinositol was reduced; stimulating cells with bradykinin, a receptor agonist which activates the inositol cycle, promoted a 3.8 fold increase. Polyphosphoinositide turnover was not affected by Na+-channel activation, but was stimulated by bradykinin. These results suggest that voltage-sensitive Na+-channel activation in cultured neuroblastoma cells can function independent of membrane phospholipid and fatty acid metabolism.

The sodium channel of excitable and non-excitable cells

Excitation and conduction in the majority of excitable cells, as originally described in the squid axon, are initiated by a transient and highly selective increase of the membrane Na conductance, which allows this ion to move passively down its electrochemical gradient (Hodgkin & Katz, 1949; Hodgkin & Huxley, 1952). The term ‘Na channel’ was introduced to describe the mechanism involved in this conductance change (Hodgkin & Keynes, 1955).

Structure and function of sodium channel

The primary structures of the Electrophorus electroplax sodium channel and two distinct sodium channel large polypeptides from rat brain have been deduced by cloning and sequencing the cDNAs. The sodium channel molecule contains four internal repeats with homologous amino acid sequences, which are oriented presumably in a pseudosymmetric fashion across the membrane, thus forming the channel. The mRNAs generated by transcription of the cloned cDNAs encoding the rat brain sodium channel large polypeptides, when injected into Xenopus oocytes, direct the formation of functional sodium channels. The transmembrane topology of the sodium channel molecule and the structure that may be involved in the voltage-dependent gating of the channel are discussed.

Expression of functional sodium channels from cloned cDNA

The voltage-gated sodium channel is a transmembrane protein essential for the generation of action potentials in excitable cells. It has been reported that sodium channels purified from the electric organ of the electric eel, Electrophorus electricus, and from chick cardiac muscle consist of a single polypeptide of relative molecular mass (Mr) approximately 260,000, whereas those purified from rat brain and from rat and rabbit skeletal muscle contain, in addition to the large polypeptide, one or two smaller polypeptides of Mr 33,000-43,000. The primary structures of the Electrophorus sodium channel and two distinct sodium channel large polypeptides (designated as sodium channels I and II) from rat brain have been elucidated by cloning and sequencing the complementary DNAs. The purified sodium channel preparations from Electrophorus electroplax and from mammalian muscle and brain, when reconstituted into lipid vesicles or planar lipid bilayers, exhibit some functional activities. The successful reconstitution with the Electrophorus preparation would imply that the large polypeptide alone is sufficient to form functional sodium channels. However, studies with the rat brain preparation suggest that the smaller polypeptide of Mr 36,000 is also required for the integrity of the saxitoxin (STX) or tetrodotoxin (TTX) binding site of the sodium channel. Here we report that the messenger RNAs generated by transcription of the cloned cDNAs encoding the rat brain sodium channel large polypeptides, when injected into Xenopus oocytes, can direct the formation of functional sodium channels.