The sodium channel in non-impulsive cells. Interaction with specific neurotoxins.

The cell line C9 used in this paper has a resting potential of --50 mV (+/- 10 mV) but is unable to generate an action potential upon electrical stimulation. The cell membrane has receptors for the selectivity filter toxin tetrodotoxin as well as for the gating system toxins, veratridine, scorpion toxin and sea anemone toxin. The Na+ channel which remains silent to electrical stimulation in the absence of toxins can be chemically activated by the gating system toxins. This has been demonstarted by electrophysiological techniques and by 22Na+ flux studies. The electrophysiological approach has shown that the sea anemone toxin is able to induce a spontaneous slow-wave activity inhibited by tetrodotoxin. 22Na+ influx analyses have shown that veratridine and the sea anemone toxin produce an important increase of the initial rate of 22Na+ influx into the C9 cell. The stimulation of 22Na+ entry by these gating system toxins is similar to that found using spiking neuroblastoma cells. Veratridine and the sea anemone toxin on one hand as well as veratridine and the scorpion toxin on the other hand are synergistic in their action to stabilize an open and highly permeable form of the sodium channel. Stimulation of 22Na+ entry into the cell through the sodium channel maintained open by the gating system neurotoxins is completely suppressed by tetrodotoxin.     

Interaction of pyrethroids with the Na channel in mammalian neuronal cells in culture

The interaction of a series of pyrethroids with the Na⁺ channel of mouse neuroblastoma cells has been followed using both an electrophysiological and a ²²Na⁺ influx approach. By themselves, pyrethroids do not stimulate ²²Na⁺ entry through the Na⁺ channel (or the stimulation they give is too small to be analyzed). However, they stimulate ²²Na⁺ entry when used in conjuction with other toxins specific for the gating system of the channel. These include batrachotoxin, veratridine, dihydrograyanotoxin II or polypeptide toxins like sea anemone and scorpion toxins. This stimulatory effect is fully inhibited by tetrodotoxin with a dissociation constant of 1.6 nM for the tetrodotoxin-receptor complex. Half-maximum saturation of the pyrethroid receptor on the Na⁺ channel is observed in the micromolar range for the most active pyrethroids, Decis and RU 15525. The synergism observed between the effect of pyrethroids on ²²Na⁺ influx on the one hand, and the effects of sea anemone toxin II, Androctonus scorpion toxin II, batrachotoxin, veratridine and dihydrograyanotoxin II on the other, indicates that the binding component for pyrethroids on the Na⁺ channel is distinct from the other toxin receptors. It is also distinct from the tetrodotoxin receptor.Some of the pyrethroids used in this study bind to the Na⁺ channel but are unable to stimulate ²²Na⁺ entry. These inactive compounds behave as antagonists of the active pyrethroids.An electrophysiological approach has shown that pyrethroids by themselves are active on the Na⁺ channel of mammalian neurones, and essentially confirm the conclusions made from ²²Na⁺ flux measurements.Pyrethroids are also active on C9 cells in which Na⁺ channels are ‘silent’, that is, not activatable by electrical stimulation. Pyrethroids chemically activate the silent Na⁺ channel in a manner similar to that with veratridine, batrachotoxin, or polypeptide toxins, which are known to slow down the inactivation process of a functional Na⁺ channel.     

Induction of recA protein in Escherichia coli by three platinum (II) compounds

The Na⁺ channels of Chinese Hamster lung fibroblasts have receptor sites for tetrodotoxin, batrachotoxin, veratridine, dihydrograyanotoxin, scorpion and sea anemone toxins. The binding properties of these toxic compounds were determined and shown to be very similar to those found in a variety of excitable cells. Electrophysiological experiments indicate that these Na⁺ channels cannot be electrically activated unless previously treated by veratridine.     

Sodium channel activity in brain membrane fractions isolated from rats of different ages

The Na⁺ channel activity (tetrodotoxin sensitive ²²Na⁺ flux induced by veratridine and/or anemone toxin II) was studied in two fractions of brain cell plasma membranes, named A and B, isolated by the method of Gray and Whittaker ((1962) J. Anat. 96, 79–87) from rats 5, 10, 30 and 60 days old. The ²²Na⁺ flux was measured in membrane vesicles formed by the isolated membranes, in the absence of drugs (control), in the presence of veratridine, and in the presence of veratridine plus tetrodotoxin. Fraction A consists primarily of neuronal and glial membranes in rats of 5 and 10 days of age, while in the older rats this fraction becomes enriched in myelin. In Fraction A of 5-day-old and 10-day-old rats, veratridine (25 μM) increases the ²²Na⁺ flux 2.4- and 1.6-fold, respectively, and the increment continues to diminish with age, until it becomes negligible in the 60-day-old rats. Fraction B consists of synaptosomes and membrane vesicles, and at the four ages studied veratridine (25 μM) causes an increment of the ²²Na⁺ flux of about 2.5-fold. Fractions A and B from 10-day-old rats, and Fraction B from 60-day-old rats, which are sensitive to veratridine, also respond to anemone toxin II. When veratridine is used in presence of anemone toxin II (0.5 μM), the $\text{K}{}_{0.5}$ for veratridine is diminished and the maximum ²²Na⁺ flux is increased. The increments of ²²Na⁺ flux caused by veratridine and/or anemone toxin II in Fractions A and B are blocked by tetrodotoxin ($\text{K}{}_{0.5}$ approx. 5 nM). Fraction A from 60-day-old rats could be subfractionated by osmotic shock and sucrose gradient centrifugation to obtain three subfractions, two of which are enriched in axolemma and display Na⁺ chennel activity. The other subfraction is enriched in myelin and shows no Na⁺ channel actiivty. The plasma membrane preparations from young rats (up to 10 days) are devoid of myelin and are useful for studies of Na⁺ channel activity.     

Binding of scorpion and sea anemone neurotoxins to a common site related to the action potential Na+ ionophore in neuroblastoma cells.

The protein neurotoxin II from the venom of the scorpion $\text{Androctonus}\text{australis}$ Hector was labeled with ¹²⁵I by the lactoperoxidase method to a specific radioactivity of about 100 μCi/μg without loss of biological activity. The labeled neurotoxin binds specifically to a single class of non intereacting binding sites of high affinity (K_D = 0.3 – 0.6 nM) and low capacity (4000 – 8000 sites/cell) to electrically excitable neuroblastoma cells. Relation of these sites to the action potential Na⁺ channel is derived from identical concentration dependence of scorpion toxin binding and increase in duration and amplitude of action potential. The protein neurotoxin II from the sea anemone $\text{Anemona sulcata}$ also affects the closing of the action potential Na⁺ ionophore in nerve axons. The unlabelled sea anemone toxin modifies ¹²⁵I-labeled scorpion toxin II binding to neuroblastoma cells by increasing the apparent K_D for labeled scorpion toxin without modification of the number of binding sites. It is concluded that both $\text{Androctonus}$ scorpion toxin II and $\text{Anemona}$ sea anemone toxin II interact competitively with a regulatory component of the action potential Na⁺ channel.     

Interactions of neurotoxins with the action potential Na+ ionophore

Four neurotoxins that activate the action potential Na⁺ ionophore of electrically excitable neuroblastoma cells interact with two distinct classes of sites, one specific for the alkaloids veratridine, batrachotoxin, and aconitine, and the second specific for scorpion toxin. Positive heterotropic cooperativity is observed between toxins bound at these two classes of sites. Tetrodotoxin, a specific inhibitor of the action potential Na⁺ current, inhibits activation by each of these toxins in a noncompetitive manner (K_I = 4–8 nM). These results suggest the existence of three functionally separable components of the action potential Na⁺ ionophore: two regulatory components, which bind activating neurotoxins and interact allosterically in controlling the activity of a third ion-transport component, which binds tetrodotoxin. The dissociation constant for scorpion toxin binding is increased 10-fold by depolarization of the cells with K⁺, suggesting that the scorpion toxin binding site is located on a voltage-sensitive regulatory component of the ionophore.     

Stimulation of sodium and calcium uptake by scorpion toxin in chick embryo heart cells

Scorpion toxins, the basic miniprotiens of scorpion venom, stimulated the passive uptake of Na⁺ and Ca²⁺ in chick ermbryo heart cells. Half-maximum stimulation was obtained for 20–30 nM Na⁺ and 40–50 nM Ca²⁺. Scorpion toxin-activated Na⁺ and Ca²⁺ uptakes were fully inhibited by tetrodotoxin, a specific inhibitor of the action potential Na⁺ ionophore in excitable membranes. Half-maximum inhibition was obtained with the same concentration of tetrodotoxin (10 nm) for both Na⁺ and Ca²⁺. Scorpion toxin-stimulated Ca²⁺ uptake was dependent on extracellular Na⁺ concentration and was not inhibited by Ca²⁺ channel blocking drugs which are inactive on heart cell action potential. Thus, in heart cells scorpion toxin affects the passive Ca²⁺ transport, which is coupled to passive Na⁺ ionphore. Other results suggest that (1) tetrodotoxin and scorpion toxin bind to different sites of the sarcolemma and (2) binding of scorpion toxin to its specific sites may unmask latent tetrodotoxin — sensitive fast channels.     

Purification and pharmacological properties of eight sea anemone toxins from Anemonia sulcata, Anthopleura xanthogrammica, Stoichactis giganteus, and Actinodendron plumosum

Eight different polypeptide toxins from sea anemones of four different origins (Anemonia sulcata, Anthopleura xanthogrammica, Stoichactis giganteus, and Actinodendron plumosum) have been studied. Three of these toxins are new; the purification procedure for the five other ones has been improved. Sea anemone toxins were assayed (i) for their toxicity to crabs and mice, (ii) for their affinity for the specific sea anemone toxin receptor situated on the Na+ channels of rat brain synaptosomes, and (iii) for their capacity to increase, in synergy with veratridine, the rate of 22Na+ entry into neuroblastoma cells via the Na+ channel. Some of the toxins are more active on crustaceans, whereas others are more toxic to mammals. A very good correlation exists between the toxic activity to mice, the affinity of the toxin for the Na+ channel in rat brain synaptosomes, and the stimulating effect on 22 Na+ uptake by neuroblastoma cells. The observation has also been made that the most cationic toxins are also the most active on mammals and the least active on crustaceans. Toxicities (LD50) to mice of the most active sea anemone toxins and of the most active scorpion toxins are similar, and sea anemone toxins at high enough concentrations prevent binding of scorpion toxins to their receptor. However, scorpion toxins have affinities for the Na+ channel which are approximately 60 times higher than those found for the most active sea anemone toxins. Three sea anemone toxins appear to be more interesting than toxin II from A. sulcata (the "classical" sea anemone toxin) for studies of the Na+ channel structure and mechanism when the source of the channel is of a mammalian origin. Two of these three toxins can be radiolabeled with iodine while retaining their toxic activity; they appear to be useful tools for future biochemical studies of the Na+ channel.     

Modulation of human Nav1.7 channel gating by synthetic α-scorpion toxin OD1 and its analogs

Nine different voltage-gated sodium channel isoforms are responsible for inducing and propagating action potentials in the mammalian nervous system. The Na_v1.7 channel isoform plays an important role in conducting nociceptive signals. Specific mutations of this isoform may impair gating behavior of the channel resulting in several pain syndromes. In addition to channel mutations, similar or opposite changes in gating may be produced by spider and scorpion toxins binding to different parts of the voltage-gated sodium channel. In the present study, we analyzed the effects of the α-scorpion toxin OD1 and 2 synthetic toxin analogs on the gating properties of the Na_v1.7 sodium channel. All toxins potently inhibited channel inactivation, however, both toxin analogs showed substantially increased potency by more than one order of magnitude when compared with that of wild-type OD1. The decay phase of the whole-cell Na⁺ current was substantially slower in the presence of toxins than in their absence. Single-channel recordings in the presence of the toxins revealed that Na⁺ current inactivation slowed due to prolonged flickering of the channel between open and closed states. Our findings support the voltage-sensor trapping model of α-scorpion toxin action, in which the toxin prevents a conformational change in the domain IV voltage sensor that normally leads to fast channel inactivation.     

Polypeptide neurotoxins modify gating and apparent single-channel conductance of veratridine-activated sodium channels in planar lipid bilayers

Summary The effects of scorpion and sea anemone polypeptide toxins on partially purified veratridine (VER)-activated Na channels from rat brain were studied at the single-channel level in planar lipid bilayers. The probability of the VER-activated channel being open (P _o ) increased with depolarization;P _o was 0.5 at –40 to –50 mV. Saxitoxin (STX) blocked VER-activated channels with an apparent dissociation constant of about 1nm at –45 mV. The apparent single-channel conductance was approximately 9 pS, similar to that seen in VER-activated Na channels from skeletal muscle transverse tubules. Addition of sea anemone or scorpion polypeptide toxins to VER-activated Na channels resulted in a 19% increase in apparent single-channel conductance and a hyperpolarizing shift in theP _o vs. V _m relation such that the channels were more likely to be open at potentials <40 mV. These effects of the polypeptide toxins on the single-channel properties of VER-activated Na channels may account for the previously described potentiation of VER action by polypeptide toxins.     

Sodium channels in presynaptic nerve terminals. Regulation by neurotoxins

Regulation of Na+ channels by neurotoxins has been studied in pinched- off nerve endings (synaptosomes) from rat brain. Activation of Na+ channels by the steroid batrachotoxin and by the alkaloid veratridine resulted in an increase in the rate of influx of 22Na into the synaptosomes. In the presence of 145 mM Na+, these agents also depolarized the synaptosomes, as indicated by increased fluorescence in the presence of a voltage-sensitive oxacarbocyanine dye [diO-C5(3)]. Polypeptide neurotoxins from the scorpion Leiurus quinquestriatus and from the sea anemone Anthopleura xanthogrammica potentiated the stimulatory effects of batrachotoxin and veratridine on the influx of 22Na into synaptosomes. Saxitoxin and tetrodotoxin blocked the stimulatory effects of batrachotoxin and veratridine, both in the presence and absence of the polypeptide toxins, but did not affect control 22Na influx or resting membrane potential. A three-state model for Na+ channel operation can account for the effects of these neurotoxins on Na+ channels as determined both by Na+ flux measurements in vitro and by electrophysiological experiments in intact nerve and muscle.     

Tetrodotoxin-insensitive sodium channels. Binding of polypeptide neurotoxins in primary cultures of rat muscle cells

The binding of 125I-labeled derivatives of scorpion toxin and sea anemone toxin to tetrodotoxin-insensitive sodium channels in cultured rat muscle cells has been studied. Specific binding of 125I-labeled scorpion toxin and 125I-labeled sea anemone toxin was each blocked by either native scorpion toxin or native sea anemone toxin. K0.5 for block of binding by several polypeptide toxins was closely correlated with K0.5 for enhancement of sodium channel activation in rat muscle cells. These results directly demonstrate binding of sea anemone toxin and scorpion toxin to a common receptor site on the sodium channel. Binding of both 125I-labeled toxin derivatives is enhanced by the alkaloids aconitine and batrachotoxin due to a decrease in KD for polypeptide toxin. Enhancement of polypeptide toxin binding by aconitine and batrachotoxin is precisely correlated with persistent activation of sodium channels by the alkaloid toxins consistent with the conclusion that there is allosteric coupling between receptor sites for alkaloid and polypeptide toxins on the sodium channel. The binding of both 125I-labeled scorpion toxin and 125I-labeled sea anemone toxin is reduced by depolarization due to a voltage-dependent increase in KD. Scorpion toxin binding is more voltage-sensitive than sea anemone toxin binding. Our results directly demonstrate voltage-dependent binding of both scorpion toxin and sea anemone toxin to a common receptor site on the sodium channel and introduce the 125I-labeled polypeptide toxin derivatives as specific binding probes of tetrodotoxin-insensitive sodium channels in cultured muscle cells.     

Functional differentiation of a human ganglion cell derived neuroblastoma cell line SH-SY5Y induced by a phorbol ester (TPA)

When the human neuroblastoma cell line SH-SY5Y is exposed to 12-o-tetradecanoyl-phorbol-13-acetate (TPA) the cells grow long processes indicative of neural differentiation. Concomitantly there is an increase in the resting membrane potential from ?44 ± 2 mV found in untreated cells to ?63 ± 4 mV after induction. The TPA treated cells are depolarized when the external potassium concentration is increased to 46 mM and upon addition of veratridine. In contrast to the untreated cells depolarization in differentiated cells leads to an increase in the rate of Ca²⁺ influx. This increase in Ca²⁺ influx is blocked by the Ca²⁺ channel antagonist, verapamil, while the Na⁺ channel blocker tetrodotoxin only marginally inhibits the K⁺ depolarization-induced Ca²⁺ influx.The results suggest that the induction of morphological differentiation in this cell line is associated with the appearance of features of excitable cells.     

Effects of neurotoxins (veratridine, sea anemone toxin, tetrodotoxin) on transmitter accumulation and release by nerve terminals in vitro.

Two of the tree toxic compounds used in this work, veratridine and the sea anemone toxin, provoke neurotransmitter release from synaptosomes; the third one, tetrodotoxin, prevents the action of both veratridine and the sea anemone toxin. The half-maximum effects of veratridine and sea anemone toxin actions on synaptosomes are K0.5 = 10 and 0.02 micronM, respectively. Although veratridine and the sea anemone toxin similarly provoke neurotransmitter release, they act on different receptor structures in the membrane. Tetrodotoxin antagonizes the effects of both veratridine and the sea anemone toxin. The half-maximum inhibitory concentration of tetrodotoxin is K0.5 = 4 nM for veratridine and 7.9 nM for ATXII. It is very similar to the dissociation constant measured from direct binding experiments with the radioactive toxin. The analysis of this antagonistic action offers an easy in vitro assay for tetrodotoxin interaction with its receptor.     

Anemone toxin II receptor site of the lobster nerve sodium channel. Studies in membrane vesicles and in proteoliposomes

The receptor-site for the sea anemone toxin II from Anemonia sulcata (ATX) and its functional relationship with the Na+ channel were studied in plasma membrane preparations from lobster walking leg nerves. The modification of the 22Na influx by ATX was determined in membrane vesicles and in proteoliposomes prepared by reconstitution of detergent-extracted, unfractionated membrane particles into soybean liposomes. The effects of two other toxins, veratridine (VER) and tetrodotoxin (TTX), which bind to Na+ channel receptor-sites other than that for polypeptide toxins, were also studied, ATX and VER stimulated 22Na flux into membrane vesicles with K0.5 values in the order of 10(-7) and 10(-5) M, respectively. Positive cooperativity among these toxins was also seen; ATX displaces the K0.5 for VER towards lower VER concentrations. TTX abolishes the 22Na influx increment caused by ATX and/or VER with a K0.5 in the order of 10(-8) M. In proteoliposomes, in contrast, ATX modified the 22Na influx only at high concentrations (greater than 1 microM) and in the presence of VER. VER stimulation and TTX inhibition of the VER and the VER plus ATX modified fluxes, had the same characteristics as in the vesicle preparations. Measurable ATX and VER toxin effects were only seen in the presence of an outwardly directed K+ gradient for both vesicles and proteoliposomes. Detergent treatment and the reconstitution procedure seem to affect the functional properties of the ATX receptor site whereas the VER and the TTX sites remain unaltered.     

Purification, sequence, and pharmacological properties of sea anemone toxins from Radianthus paumotensis. A new class of sea anemone toxins acting on the sodium channel

Four new toxins have been isolated from the sea anemone Radianthus paumotensis: RpI, RpII, RpIII, and RpIV. They are polypeptides comprised of 48 or 49 amino acids; the sequence of RpII has been determined. Toxicities of these toxins in mice and crabs are similar to those of the other known sea anemone toxins, but they fall into a different immunochemically defined class. The sequence of RpII shows close similarities with the N-terminal end (up to residue 20) of the previously sequenced long sea anemone toxins, but most of the remaining part of the molecule is completely different. Like the other sea anemone toxins, Radianthus toxins are active on sodium channels; they slow down the inactivation process. Through their Na+ channel action, Radianthus toxins stimulate Na+ influx into tetrodotoxin-sensitive neuroblastoma cells and tetrodotoxin-resistant rat skeletal myoblasts. The efficiency of the toxins is similar in the two cellular systems. In that respect, Radianthus toxins behave much more like scorpion neurotoxins than sea anemone toxins from Anemonia sulcata or Anthopleura xanthogrammica. In binding experiments to synaptosomal Na+ channels, Radianthus toxins compete with toxin II from the scorpion Androctonus australis but not with toxins II and V from Anemonia sulcata.     

Sea anemone toxin and scorpion toxin share a common receptor site associated with the action potential sodium ionophore.

Toxin II isolated from the sea anemone Anemonia sulcata enhances activation of the action potential sodium ionophore of electrically excitable neuroblastoma cells by veratridine and batrachotoxin. This heterotropic cooperative effect is identical to that observed previously with scorpion toxin but occurs at a 110-fold higher concentration. Depolarization of the neuroblastoma cells inhibits the effect of sea anemone toxin as observed previously for scorpion toxin. Specific scorpion toxin binding is inhibited by sea anemone toxin with KD approximately equal to 90 nM. These results show that the polypeptides scorpion toxin and sea anemone toxin II share a common receptors site associated with action potential sodium ionophores.     

Electrophysiological studies on embryonic heart cells in culture. Scorpion toxin as a tool to reveal latent fast sodium channel

Trypsin-dispersed heart cells were obtained from 11-day-old chick embryos. After culture as unstirred suspensions in dimethylsulfoxide-containing medium, spherical aggregates of cells beating spontaneously and apparently synchronously for months were obtained. Two kinds of cell were characterized by electrophysiological recordings: (1) cells with a slow rate of depolarizing phase showing tetrodotoxin-resistant action potential and blocked by D 600 (‘slow’ cells); (2) cells with high value of rising phase which was strongly decreased by tetrodotoxin and in which D 600 provoked uncoupling of excitation-contraction (‘fast’ cells).Toxin II from Androctonus australis scorpion venom increased the duration of action potential, which was ascribed to a slowing down of Na⁺ current inactivation and enhance the maximum rate of depolarization, especially in slow cells. Effects were antagonized by tetrodotoxin in both fast and slow cells. Washing experiments confirmed the results of previous studies, namely that tetrodotoxin and scorpion toxin bind to different receptors. It is concluded that slow cells with tetrodotoxin-resistant action potential contain latent fast Na⁺ channels that are revealed (activated) by toxin binding to the membrane.     

Up-Regulation of Functional Voltage-Dependent Sodium Channels by Insulin in Cultured Bovine Adrenal Chromaffin Cells

Abstract: Treatment of cultured bovine adrenal chromaffin cells with 100 nM insulin raised [³H]saxitoxin ([³H]STX) binding in a time-dependent manner (t_1/2 = 26 h). Insulin (100 nM for 4 days) increased the B_max of [³H]STX binding by 49% without changing the K_D value and also augmented the maximal influx of ²²Na⁺ due to 560 µM veratridine by 39% without altering the EC₅₀ value of veratridine. The stimulatory effect of insulin on ²²Na⁺ influx was concentration-dependent with an EC₅₀ of 3 nM, whereas insulin-like growth factor (IGF)-I had little effect at 1 nM. Ptychodiscus brevis toxin-3 allosterically potentiated veratridine (100 µM)-induced ²²Na⁺ influx by approximately twofold in both insulin-treated cells and untreated cells. Veratridine-induced ⁴⁵Ca²⁺ influx via voltage-dependent Ca²⁺ channels and catecholamine secretion were also enhanced by insulin treatment, whereas insulin did not alter nicotine-induced ²²Na⁺ influx via the nicotinic receptor-ion channel complex and high-K⁺ (direct activation of voltage-dependent Ca²⁺ channels)-induced ⁴⁵Ca²⁺ influx. Stimulatory effects of insulin on [³H]STX binding and veratridine-induced ²²Na⁺ influx were nullified by simultaneous treatment with either 5,6-dichlorobenzimidazole riboside, an inhibitor of RNA synthesis, or cycloheximide, an inhibitor of protein synthesis, whereas insulin treatment did not appreciably increase the level of mRNA encoding the Na⁺ channel α-subunit. These results suggest that the binding of insulin to insulin (but not IGF-I) receptors mediates the up-regulation of functional Na⁺ channel expression at plasma membranes; this up-regulation may be due, at least in part, to the de novo synthesis of an as yet unidentified protein(s).