[Mechanism of action of neurotoxins acting on the inactivation of voltage-gated sodium channels].

Abstract

This review focuses on the mechanism(s) of action of neurotoxins acting on the inactivation of voltage-gated Na channels. Na channels are transmembrane proteins which are fundamental for cellular communication. These proteins form pores in the plasma membrane allowing passive ionic movements to occur. Their opening and closing are controlled by gating systems which depend on both membrane potential and time. Na channels have three functional properties, mainly studied using electrophysiological and biochemical techniques, to ensure their role in the generation and propagation of action potentials: 1) a highly selectivity for Na ions, 2) a rapid opening ("activation"), responsible for the depolarizing phase of the action potential, and 3) a late closing ("inactivation") involved in the repolarizing phase of the action potential. As an essential protein for membrane excitability, the Na channel is the specific target of a number of vegetal and animal toxins which, by binding to the channel, alter its activity by affecting one or more of its properties. At least six toxin receptor sites have been identified on the neuronal Na channel on the basis of binding studies. However, only toxins interacting with four of these sites (sites 2, 3, 5 et 6) produce alterations of channel inactivation. The maximal percentage of Na channels modified by the binding of neurotoxins to sites 2 (batrachotoxin and some alkaloids), 3 (alpha-scorpion and sea anemone toxins), 5 (brevetoxins and ciguatoxins) et 6 (delta-conotoxins) is different according to the site considered. However, in all cases, these channels do not inactivate. Moreover, Na channels modified by toxins which bind to sites 2, 5 and 6 activate at membrane potentials more negative than do unmodified channels. The physiological consequences of Na channel modifications, induced by the binding of neurotoxins to sites 2, 3, 5 and 6, are (i) an inhibition of cellular excitability due to an important membrane depolarization (site 2), (ii) a decrease of cellular excitability due to an important increase in the action potential duration (site 3) and (iii) an increase in cellular excitability which results in spontaneous and repetitive firing of action potentials (sites 5 and 6). The biochemical and electrophysiological studies performed with these toxins, as well as the determination of their molecular structure, have given basic information on the function and structure of the Na channel protein. Therefore, various models representing the different states of Na channels have been proposed to account for the neurotoxin-induced modifications of Na inactivation. Moreover, the localization of receptor binding sites 2, 3, 5 et 6 for these toxins on the neuronal Na channel has been deduced and the molecular identification of the recognition site(s) for some of them has been established on the alpha sub-unit forming the Na channel protein.