A scorpion alpha-like toxin that is active on insects and mammals reveals an unexpected specificity and distribution of sodium channel subtypes in rat brain neurons.

Several scorpion toxins have been shown to exert their neurotoxic effects by a direct interaction with voltage-dependent sodium channels. Both classical scorpion alpha-toxins such as Lqh II from Leiurus quiquestratus hebraeus and alpha-like toxins as toxin III from the same scorpion (Lqh III) competitively interact for binding on receptor site 3 of insect sodium channels. Conversely, Lqh III, which is highly toxic in mammalian brain, reveals no specific binding to sodium channels of rat brain synaptosomes and displaces the binding of Lqh II only at high concentration. The contrast between the low-affinity interaction and the high toxicity of Lqh III indicates that Lqh III binding sites distinct from those present in synaptosomes must exist in the brain. In agreement, electrophysiological experiments performed on acute rat hippocampal slices revealed that Lqh III strongly affects the inactivation of voltage-gated sodium channels recorded either in current or voltage clamp, whereas Lqh II had weak, or no, effects. In contrast, Lqh III had no effect on cultured embryonic chick central neurons and on sodium channels from rat brain IIA and beta1 subunits reconstituted in Xenopus oocytes, whereas sea anemone toxin ATXII and Lqh II were very active. These data indicate that the alpha-like toxin Lqh III displays a surprising subtype specificity, reveals the presence of a new, distinct sodium channel insensitive to Lqh II, and highlights the differences in distribution of channel expression in the CNS. This toxin may constitute a valuable tool for the investigation of mammalian brain function.

Interactions of delta-conotoxins with alkaloid neurotoxins reveal differences between the silent and effective binding sites on voltage-sensitive sodium channels.

The delta-conotoxin-TxVIA from Conus textile (delta TxVIA) is a mollusk-specific conotoxin that slows sodium channel inactivation exclusively in mollusk neuronal membranes but reveals high-affinity binding to both mollusk (effective binding) and rat brain (silent binding) neuronal membranes, despite not having any toxic effect in vertebrates in vivo and in vitro. Using binding studies with radioactive delta TxVIA we demonstrate that a different mollusk-specific conotoxin, delta-conotoxin-GmVIA from the venom of Conus gloriamaris, possesses "silent" and effective binding properties in rat brain and mollusk sodium channels, respectively. Binding studies and electrophysiological tests with both vertebrate muscle and insect neuronal preparations have indicated that the silent binding sites of delta TxVIA are highly conserved in a wide range of distinct vertebrate and insect sodium channels. Direct probing of receptor site 2 by a tritiated derivative of batrachotoxin ([3H]BTX-B) revealed that [3H]BTX-B binding in mollusk sodium channels is of high affinity with no addition of enhancing ligands, unlike [3H]BTX-B binding in rat brain. In contrast to the negative allosteric modulation of delta TxVIA binding by veratridine, delta TxVIA is not able to affect the binding of [3H]BTX-B in mollusk neuronal membranes but reduces [3H]BTX-B binding in rat brain in the presence of alpha-scorpion toxins. The latter finding indicates the existence of a pharmacological distinction between the silent and effective binding sites of delta TxVIA and points out possible functionally important structural differences between molluscan and rat brain sodium channels.