Sodium channel and sodium pump in normal and pathological muscles from patients with myotonic muscular dystrophy and lower motor neuron impairment

TWO SODIUM TRANSPORT SYSTEMS HAVE BEEN ANALYZED IN THIS WORK: the voltage-sensitive sodium channel and the (Na(+), K(+)) ATPase pump. The sodium channel has been studied using a tritiated derivative of tetrodotoxin; the sodium pump has been studied using tritiated ouabain. Properties of interaction of tritiated tetrodotoxin and of tritiated ouabain with their respective receptors were observed in normal human skeletal muscle and in muscles of patients with myotonic muscular dystrophy and with lower motor neuron impairment. Levels of sodium pump and of sodium channels were measured at different stages of membrane purification. Microsomal fractions of normal human muscle have maximal binding capacities for tetrodotoxin of 230 fmol/mg of protein and of 7.4 pmol/mg of protein for ouabain. Dissociation constant for the complexes formed by the tetrodotoxin derivative and by ouabain with their respective receptors were 0.52 nM and 0.55 muM, respectively. In muscles from patients with myotonic muscular dystrophy, the maximal binding capacity for tetrodotoxin, i.e., the number of Na(+) channels was found to be very similar to that found for normal muscle. The maximal binding capacity for ouabain, i.e., the number of Na(+) pumps was three- to sixfold lower than in normal muscle. Dissociation constants for the complexes formed with the tetrodotoxin derivative and with ouabain were the same as for normal muscle. In muscles from patients with lower motor nerve impairment, the maximal binding capacities for tetrodotoxin and for ouabain were twice as high as in normal muscle. Again, dissociation constants for the complexes formed with the tetrodotoxin derivative and with ouabain were nearly unchanged as compared with normal muscle. These results suggest that sodium transport systems involved in the generation of action potentials and/or in the regulation of the resting potential are altered both in myotonic muscular dystrophy and in lower motor neuron impairment.

Developmental properties of the fast Na+ channel in embryonic cardiac cells using neurotoxins

This paper describes how neurotoxins specific of the fast Na+ channel are used to study its differentiation in embryonic cardiac cells during heart ontogenesis. Structural and functional differentiation of the fast Na+ channel have been followed using both electrophysiological and biochemical techniques.

1H nuclear-magnetic-resonance studies of the conformation of cardiotoxin VII2 from Naja mossambica mossambica

The membrane toxin VII2 from the venom of Naja mossambica mossambica was investigated in aqueous solution by one-dimensional and two-dimensional high-resolution nuclear magnetic resonance (NMR) techniques at 360 MHz. The spectral characterization included identification of the complete spin systems for several amino acid residues, nuclear Overhauser effect measurements, the use of chemically induced dynamic nuclear polarization and studies of the pH dependence of the NMR spectrum. Data from homologous toxins, in particular direct lytic factor 12B from Haemachatus haemachatus, were used to establish assignments of aromatic and methyl proton resonances. From these experiments a short, triple-stranded fragment of antiparallel beta structure could be determined, which includes the residues 23-27, 43-46 and 60-62. Furthermore, the nuclear Overhauser effect measurements indicate close proximity in the protein conformation of the aromatic rings of Trp-14, Tyr-25 and Tyr-59, and the side chain of Ile-46.

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.

Differentiation of the fast Na+ channel in embryonic heart cells: interaction of the channel with neurotoxins

The sensitivity of embryonic cardiac cells to tetrodotoxin (TTX) increases with age. At the early embryonic stage, the maximum upstroke velocity is not affected by the presence of TTX. In the course of both in ovo and in vitro development, this velocity reaches an adult-like value of 90-120 V/sec, which is decreased in the presence of TTX to 5-10 V/sec. The differentiation of the Na+ channel has been followed by using three types of specific toxins: (i) TTX or a tritiated derivative of it, (ii) a polypeptide toxin extracted from sea anemone, and (iii) the alkaloidic toxins veratridine and batrachotoxin. Electrophysiological, including voltage-clamp experiments, and biochemical studies have shown (i) that the TTX receptor and the fast Na+ channel machinery exist even when action potentials are insensitive to TTX--the channel is then in a nonfunctional or silent form that is revealed (or chemically activated) by both the alkaloids and the polypeptide toxin--and (ii) that the total number of Na+ channels increases during development by a factor of 4 or 5. In monolayers of cardiac cells insensitive to TTX in which all Na+ channels are in a nonfunctional form, the rate of degradation of the TTX receptor follows first-order kinetics with a half-time of 9 hr. In aggregates fully sensitive to TTX, the number of TTX receptors remains perfectly stable 24 hr after blockade of protein synthesis.

Synthesis and properties of new photoactivable derivatives of tetrodotoxin

The Pfitzner-Moffatt oxidation procedure has been used to prepare two new photoactivable derivatives of tetrodotoxin that have been synthesized with high specific radioactivities (17.5 Ci/mmol and 30 Ci/mmol). They specifically bind to axonal membranes with affinities of 5.2-14.2 nM. They dissociate from their membrane complex with half-lives of 10.8 and 20 min. In the dark, these compounds give a reversible block of the sodium channels. After ultraviolet irradiation, they induce an irreversible blockade of the nerve channels.

Structure-function relationships of sea anemone toxin II from Anemonia sulcata

Chemical modifications of sea anemone toxin II from Anemonia sulcata have been used to study the residues involved in its toxic action on crabs and mice and in its binding properties to the Na+ channel of rat brain synaptosomes. Guanidination of th epsilon-amino groups of lysines 35, 36, and 46 with O-methylisourea hydrogen sulfate did not change the net charge of the toxin molecule and had no effect upon its toxic and binding properties. Either acetylation or fluorescamine treatment of the toxin that destroyed the positive charges of the three epsilon-amino groups and of the alpha-amino function of Gly produced an almost complete loss of toxicity and a considerable decrease in the binding activity. Iodination of the toxin on His induced practically no loss of toxic or binding properties. Carbethoxylation of both histidines 32 and 37 with diethyl pyrocarbonate provoked an important decrease of both the toxicity and the binding activity. Modifications of the guanidine side chain of Arg with 1,2-cyclohexanedione fully destroyed both toxicity and binding of the toxin to the Na+ channel. Modification of the carboxylate functions of Asp, Asp, and of the COOH-terminal Gln with glycine ethyl ester in the presence of a soluble carbodiimide completely abolished the toxicity but left the affinity for the sea anemone toxin receptor unchanged. The antagonist character of this carboxylate-modified derivative was further confirmed by electrophysiological and Na+ flux experiments. The theoretical and practical significance of these results are discussed.

Freeze-fracture study of cardiotoxin action on axonal membrane and axonal membrane lipid vesicles

Freeze-fracture electron microscopy was used to follow morphological changes induced by Naja mossambica mossambica venom cardiotoxins on crab axonal membranes and thier lipids. It was shown that the extent of morphological changes depended drastically on the purity of cardiotoxin preparations and on their nature. Highly purified cardiotoxin induced mainly fusion of membrane or lipid vesicles. The extent of fusion and other morphological changes depended on the nature of cardiotoxin used: VII4 cardiotoxin induced only fusion while VII1 led to further modifications of membranes and liposomes. The most spectacular morphological changes were observed with axonal membranes treated with cardiotoxin containing traces of venom phospholipase A2. At low cardiotoxin concentration (10(-7)-10(-5) M) important intramembrane particle aggregation was observed and at higher concentrations (more than 10(-4) M) intramembrane particles disappeared from the membrane and were found in solution. The membrane vesicles, devoid of intramembrane particles, were observed to fuse rapidly into liposome-like aggregates. These morphological changes are interpreted as being due to the removal of intrinsic membrane proteins from the membrane by the combined action of cardiotoxin and phospholipase A2.

Transition temperatures of the electrical activity of ion channels in the nerve membrane

The temperature dependence of some of the electrical characteristics of neuronal membranes from Aplysia giant neurons and crustacean and cuttlefish giant axons has been analyzed. Arrhenius plots for the maximum rate of depolarization of (V+max) or repolarization (V-max) of the action potential, for the resting membrane conductance, and for the speed of propagation of the action potential, exhibited clear breaks at characteristic temperatures between 17 and 20 degrees C. Lobster giant axons and frog nodes of Ranvier were voltage-clamped at different temperatures between 5 and 30 degrees C. Arrhenius plots for relaxation times related to the opening and closing processes affecting the Na+ and K+ channels were linear. No 'transition' temperature was detected. However, clear-cut changes in (Formula: see text) Na+ and K+ currents, were consistantly observed around 18 degrees C. Values for (Formula: see text) plateaued above 18 degrees C, then decreased gradually as a function of reduced temperature. Variations in temperature between 1 and 30 degrees C did not alter the binding properties of [3H]tetrodotoxin to a purified crab axonal membrane. Pharmacological properties of the Na+ channel are sensitive to temperature. The temperature-dependent effect of veratridine has been studied and indicates a change in properties of the Na+ channel below 20 degrees C. These results support the possibility that the fluidity of membrane lipids in the ionic channel microenvironment may influence the degree to which the channel can open.

Compared properties of central and peripheral binding sites for phencyclidine

Phencyclidine and its derivatives bind specifically and reversibly to rat brain and peripheral organs. Binding characteristics are different in brain, lung, kidney, heart and liver. Affinities of phencyclidines for the brain receptor but not those for peripheral organs are correlated with the pharmacological activities of phencyclidines as measured in the rotarod test.

Binding of phencyclidine to rat brain membranes: technical aspect

[3H]Phencyclidine has a tendency to adsorb to filters used in binding experiments. The spinal binding techniques that should be used to overcome this difficulty are described. The affinity of [3H]phencyclidine for its brain receptor was 4 times higher in a medium containing 5 mM salt than in a medium containing 50 mM salt.

Affinity labeling of the digitalis receptor with p-nitrophenyltriazene-ouabain, a highly specific alkylating agent

Three derivatives of ouabain have been synthesized which alkylate the digitalis receptor. These derivatives were formed through reductive amination of p-nitrophenyltriazene (NPT) ethylenediamine to the periodate-oxidized rhamnose moiety of ouabain. The non-covalent binding of the ouabain derivatives (NPT-ouabain, designated I, II, and III) was followed (i) by their ability to inhibit the activity of sodium- and potassium-activated ATPase ((Na+,K+)-ATPase) purified from the electric organ of Electrophorus electricus, (ii) by the binding of [3H]NPT-ouabain I to the enzyme, and (iii) by the inhibition of [3H]ouabain binding with unlabeled NPT-ouabain I. Covalent modification of the digitalis site of (Na+,K+)-ATPase occurs after long periods of time. At pH 7.5 (25 degrees C) the best alkylating derivative, NPT-ouabain I, gives maximum covalent labeling after 6 h. Only the large polypeptide chain (Mr = 93,000) of the purified enzyme is specifically labeled with [3H]NPT-ouabain I while the glycoprotein chain (Mr = 47,000) is not significantly labeled. Labeling of a microsomal fraction of the electric organ with [3H]NPT-ouabain I gave the same type of gel pattern as that observed with the purified enzyme. [3H]NPT-ouabain I was also used to label the digitalis receptor in highly purified axonal membranes and in cardiac membranes prepared from embryonic chick heart. Although the (Na+,K+)-ATPase in both types of membranes has a low affinity for ouabain, [3H]NPT-ouabain I proved to be a very efficient affinity label for the digitalis receptor. In the complex mixture of polypeptides found in these membrane preparations, only a single polypeptide chain having a Mr = 93,000 is specifically labeled by [3H]NPT-ouabain I.

Toxin-induced K+ efflux through the Na+ channel of neuroblastoma cells

Neurotoxins which modify the gating system of the Na+ channel in neuroblastoma cells and increase the initial rate of 22Na+ influx through this channel also give rise to the efflux of 86Rb+ and 42K+. These effluxes are inhibited by tetrodotoxin and are dependent on the presence in the extracellular medium of cations permeable to the Na+ channel. These stimulated effluxes are not due to membrane depolarization or increases in the intracellular content of Na+ and Ca2+ which occur subsequent to the action of neurotoxins. The relationships of 22Na+ influx and 42K+ (or 86Rb+) effluxes to both the concentration of neurotoxins and the concentration of external permeant cations strongly suggest that the open form of the Na+ channel stabilized by neurotoxins permits an efflux of K+ ions. Our results indicate that for the efflux of each K+ ion there is a corresponding influx of two Na+ ions into the Na+ channel.

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 conjunction 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 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.

Identification of a tetrodotoxin-sensitive Na+ channel in a variety in fibroblast lines

The action potential Na+ ionophore of excitable cells can be activated either by alkaloid compounds such as veratridine, or by small polypeptide toxins extracted from scorpion venom or sea anemone. One of the main features of this Na+ channel is that it is blocked by tetrodotoxin (TTX). However, we report here that during analysis of Na+ influx in resting fibroblasts, we found that a variety of fibroblast lines also possess a TTX receptor. Veratridine and sea anemone toxin act synergistically to stimulate Na+ influx 7 to 10-fold in hamster and rat fibroblasts. As in excitable cells, this toxin-stimulated Na+ influx is blocked by TTX. Addition of serum to hamster fibroblasts arrested in G0 stimulates Na+ influx three-fold. Observations that TTX does not prevent serum-activated Na+ influx, initiation of DNA synthesis and cell proliferation suggest that the fast Na+ channel which we have identified in fibroblasts is not involved in growth control.