On the Natural and Unnatural History of the Voltage-Gated Na(+) Channel.

This review glances at the voltage-gated sodium (Na(+)) channel (NaV) from the skewed perspective of natural history and the history of ideas. Beginning with the earliest natural philosophers, the objective of biological science and physiology was to understand the basis of life and discover its intimate secrets. The idea that the living state of matter differs from inanimate matter by an incorporeal spirit or mystical force was central to vitalism, a doctrine based on ancient beliefs that persisted until the last century. Experimental electrophysiology played a major role in the abandonment of vitalism by elucidating physiochemical mechanisms that explained the electrical excitability of muscle and nerve. Indeed, as a principal biomolecule underlying membrane excitability, the NaV channel may be considered as the physical analog or surrogate for the vital spirit once presumed to animate higher forms of life. NaV also epitomizes the "other secret of life" and functions as a quantal transistor element of biological intelligence. Subplots of this incredible but true story run the gamut from electric fish to electromagnetism, invention of the battery, venomous animals, neurotoxins, channelopathies, arrhythmia, anesthesia, astrobiology, etc.

Beta-subunit-dependent modulation of hSlo BK current by arachidonic acid.

In this study, we examined the effect of arachidonic acid (AA) on the BK alpha-subunit with or without beta-subunits expressed in Xenopus oocytes. In excised patches, AA potentiated the hSlo-alpha current and slowed inactivation only when beta2/3 subunit was co-expressed. The beta2-subunit-dependent modulation by AA persisted in the presence of either superoxide dismutase or inhibitors of AA metabolism such as nordihydroguaiaretic acid and eicosatetraynoic acid, suggesting that AA acts directly rather than through its metabolites. Other cis unsaturated fatty acids (docosahexaenoic and oleic acid) also enhanced hSlo-alpha + beta2 currents and slowed inactivation, whereas saturated fatty acids (palmitic, stearic, and caprylic acid) were without effect. Pretreatment with trypsin to remove the cytosolic inactivation domain largely occluded AA action. Intracellularly applied free synthetic beta2-ball peptide induced inactivation of the hSlo-alpha current, and AA failed to enhance this current and slow the inactivation. These results suggest that AA removes inactivation by interacting, possibly through conformational changes, with beta2 to prevent the inactivation ball from reaching its receptor. Our data reveal a novel mechanism of beta-subunit-dependent modulation of BK channels by AA. In freshly dissociated mouse neocortical neurons, AA eliminated a transient component of whole cell K(+) currents. BK channel inactivation may be a specific mechanism by which AA and other unsaturated fatty acids influence neuronal death/survival in neuropathological conditions.

Phylogenetic survey of soluble saxitoxin-binding activity in pursuit of the function and molecular evolution of saxiphilin, a relative of transferrin.

Saxiphilin is a soluble protein of unknown function which binds the neurotoxin, saxitoxin (STX), with high affinity. Molecular characterization of saxiphilin from the North American bullfrog, Rana catesbeiana, has previously shown that it is a member of the transferrin family. In this study we surveyed various animal species to investigate the phylogenetic distribution of saxiphilin, as detected by the presence of soluble [3H]STX binding activity in plasma, haemolymph or tissue extracts. We found that saxiphilin activity is readily detectable in a wide variety of arthropods, fish, amphibians, and reptiles. The pharmacological characteristics of [3H]STX binding activity in phylogenetically diverse species indicates that a protein homologous to bullfrog saxiphilin is likely to be constitutively expressed in many ectothermic animals. The results suggest that the saxiphilin gene is evolutionarily as old as an ancestral gene encoding bilobed transferrin, an Fe(2+)-binding and transport protein which has been identified in several arthropods and all the vertebrates which have been studied.

Expression of saxiphilin in insect cells and localization of the saxitoxin-binding site to the C-terminal domain homologous to the C-lobe of transferrins.

Saxiphilin is a plasma protein from the bullfrog (Rana catesbeiana) that is homologous to transferrin. Most known transferrins contain two binding sites for Fe3+/HCO3-, one in each of two homologous domains called the N-lobe and C-lobe. However, native saxiphilin does not bind Fe3+ but stoichiometrically binds one molecule of the neurotoxin saxitoxin (STX) with a dissociation constant (KD) of approximately 0.2 nM. To pursue structural analysis of the STX binding sites, cDNA encoding saxiphilin was used to construct a baculovirus expression vector that directs synthesis and secretion of a approximately 92-kDa recombinant saxiphilin protein (R-sax) in cultured insect cells. Culture medium harvested from infected cells contained 25-67 pmol of [3H]STX binding sites/mL with a KD of 0.22 nM. The kinetics and pH dependence (pK0.5 = 5.4) of [3H]STX binding to R-sax are similar to native saxiphilin, implying proper folding and functional activity. Another baculovirus expression vector was constructed to encode a deletion mutant of saxiphilin consisting of the first 20 N-terminal residues containing the secretory signal sequence spliced to the C-terminal, 361-residue fragment homologous to the C-lobe domain of transferrins. This vector directed the secretion of a approximately 38-kDa derivative of saxiphilin (C-sax) that was recognized by antisaxiphilin antibody. C-sax also exhibited [3H]STX binding activity with a lower affinity KD of approximately 0.9 nM, a 4-fold faster dissociation rate for [3H]STX than native saxiphilin, and a pH dependence (pK0.5 = 5.7) similar to R-sax (pK0.5 = 5.4).(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of saxitoxin binding to saxiphilin, a relative of the transferrin family that displays pH-dependent ligand binding.

Saxiphilin is a 91 kDa saxitoxin-binding protein that is homologous to members of the transferrin family of Fe(3+)-binding proteins noted for pH-dependent release of Fe3+. The mechanism of toxin binding to purified native saxiphilin from the bullfrog (Rana catesbeiana) was studied using [3H]saxitoxin. At pH 7.4 and 0 degrees C [3H]saxitoxin binds to a single site on saxiphilin with a KD of approximately 0.2 nM. The pH dependence of [3H]saxitoxin binding follows a one-site titration curve in the range of pH 9-4 with maximal binding from pH 9 to 7 and half-inhibition at pH 5.7. Inhibition of toxin binding at low pH is the combined result of a decrease in the rate of toxin association and an increase in the rate of toxin dissociation. The dependence of the apparent rate constants for [3H]saxitoxin association and dissociation on [H+] can be accounted for by a four-state model of allosteric interaction between the toxin-binding site and a single titratable residue of saxiphilin with a pKa of 7.2 in the toxin-free form and 4.3 in the toxin-bound form. From 0 to 25 degrees C, the temperature dependence of [3H]saxitoxin binding to saxiphilin is characterized by delta H degrees = -8.3 kcal mol-1, delta S degrees = 13.8 cal mol-1 K-1, and activation energies of 22.5 kcal mol-1 for dissociation and 11.1 kcal mol-1 for association. Binding of [3H]saxitoxin to saxiphilin is competitively inhibited with low affinity by a variety of divalent metal and lanthanide cations. Inhibition of toxin binding by the carboxyl-methylating reagent trimethyloxonium is prevented by pre-equilibration with [3H]saxitoxin, implicating the presence of one or more carboxyl groups in the binding site. Functional similarities suggest that the saxitoxin-binding site of saxiphilin is located in an interdomain cleft analogous to the location of one of the two homologous Fe(3+)-binding sites of transferrins. On the basis of residue substitutions between saxiphilin and transferrins, it is proposed that the saxitoxin-binding site is located in the carboxy terminal lobe of saxiphilin and that binding is modulated by protonation of a conserved histidine residue.

Saxitoxin and ouabain binding activity of isolated skeletal muscle membrane as indicators of surface origin and purity.

A simple biochemical method for identifying and distinguishing transverse tubule and sarcolemma membranes in preparations of skeletal muscle microsomes is proposed and evaluated. This method is based on the previous observation that the ratio of ouabain to saxitoxin binding sites is five-fold higher in the sarcolemma than the transverse tubule. We measured [3H]saxitoxin and [3H]ouabain binding to microsomes of frog, rat and rabbit muscle in the presence of detergents to expose latent sites. A high density fraction (30--40% sucrose) of the membranes was identified as transverse tubule on the basis of a low ouabain/saxitoxin ratio and its association with sarcoplasmic reticulum. A low density fraction (20--30% sucrose) was identified as transverse tubule containing variable amounts of sarcolemma as judged by a higher ratio of ouabain/saxitoxin sites. Our results suggest that this ratio can be used to determine the surface origin of muscle membrane preparations. Several different methods for purifying transverse tubules were compared by this technique.

Characterization of 2',3'-O-(2,4,6-trinitrocyclohexadienylidine)adenosine 5'-triphosphate as a fluorescent probe of the ATP site of sodium and potassium transport adenosine triphosphatase. Determination of nucleotide binding stoichiometry and ion-induced changes in affinity for ATP.

The fluorescent ATP derivative 2',3'-O-(2,4,6-trinitrocyclohexadienylidine) adenosine 5'-triphosphate (TNP-ATP) binds specifically with enhanced fluorescence to the ATP site of purified eel electroplax sodium-potassium adenosine triphosphatase, (Na,K)-ATPase. A single homogeneous high affinity TNP-ATP binding site with a KD of 0.04 to 0.09 microM at 3 degrees C and 0.2 to 0.7 microM at 21 degrees-25 degrees C was observed in the absence of ligands when binding was measured by fluorescence titration or with [3H]TNP-ATP. ATP and other nucleotides competed with TNP-ATP for binding with KD values similar to those previously determined for binding to the ATP site. Binding stoichiometries determined from Scatchard plot intercepts gave one TNP-ATP site/175,000 g of protein (range: 1.64 X 10(5) to 1.92 X 10(5) when (Na,K)-ATPase protein was determined by quantitative amino acid analysis. The ratio of [3H]ouabain sites to TNP-ATP sites was 0.91. These results are inconsistent with "half-of-sites" binding and suggest that there is one ATP and one ouabain site/alpha beta protomer. (Na,K)-ATPase maintained a high affinity for TNP-ATP regardless of the ligands present. K+ increased the KD for TNP-ATP about 5-fold and Na+ reversed the effect of K+. The effects of Na+, K+, and mg2+ on ATP binding at 3 degrees C were studied fluorimetrically by displacement of TNP-ATP by ATP. The results are consistent with competition between ATP and TNP-ATP for binding at a single site regardless of the metallic ions present. The derived KD values for ATP were : no ligands, 1 microM; 20 mM NaCl, 3-4 microM; 20 mM KCl, 15-19 microM; 20 mM Kcl + 4 mM MgCl2, 70-120 microM. These results suggests that a single ATP site exhibits a high or low affinity for ATP depending on the ligands present, so that high and low affinity ATP sites observed kinetically are interconvertible and do not co-exist independently. We propose that during turnover the affinity for ATP changes more than 100-fold owing to the conformational changes associated with ion binding, translocation, and release.

Inhibition of sodium and potassium adenosine triphosphatase by 2',3'-O-(2,4,6-trinitrocyclohexadienylidene) adenine nucleotides. Implications for the structure and mechanism of the Na:K pump.

Trinitrophenyl derivatives of adenine nucleotides (TNP-nucleotides: 2',3'-O-2,4,6-trinitrocyclohexadienylidene complexes at neutral or basic pH) are potent inhibitors of (Na,K)-ATPase activity. The inhibitory potency of the derivatives tested followed the sequence: TNP-ADP greater than TNP-ATP greater than TNP-AMP much greater than TNP-IMP greater than TNP-adenosine. In the presence of Na+ plus K+, high and low affinity activation of ATPase activity by ATP was observed. Under these conditions, TNP-ATP inhibited (Na,K)-ATPase activity competitively with respect to ATP at the kinetically defined "low affinity ATP site." In the presence of Na+ alone, only high affinity activation by ATP was observed. Under these conditions, TNP-ATP inhibited (Na)-ATPase and enzyme phosphorylation by competing with ATP at the kinetically defined "high affinity ATP site." The Ki values for inhibition were similar to the KD values determined by direct TNP-ATP binding measurements, indicating that the same TNP-ATP site is involved in the inhibition of (Na,K)-ATPase and (Na)-ATPase activities. We conclude that high and low affinity ATP "sites" are interconvertible (i.e. they represent two forms of the same site) and do not co-exist independently. TNP-ATP also inhibited competitively the K+-stimulated p-nitrophenyl phosphatase activity and enzyme phosphorylation by Pi, suggesting that the catalytic site for these substrates is associated with the TNP-ATP site. A kinetic model for (Na,K)-ATPase turnover based on a single ATP site which changes affinity during turnover is presented. The model was analyzed by the King-Altman (1956) J. Phys. Chem. 60, 1375-1378) method to obtain the steady state equation for the rate of ATP hydrolysis as a function of ATP concentration. Computer simulations using published values of the rate constants of intermediate steps suggest that the model is adequate to describe the observed dependence of enzyme activity on ATP concentration and the inhibition by TNP-ATP. The implications of these results on the structure and mechanism of the (Na,K) pump are discussed.