Comparative pharmacology and cloning of two novel arachnid sodium channels: Exploring the adaptive insensitivity of scorpion to its toxins.

Scorpion toxins have been found lacking effect on Na(+) current of its own sodium channel, whereas the molecular mechanism remains mystery. In this study, the binding affinity of pharmacologically distinct scorpion toxins was found much weaker to scorpion (Buthus martensii) nerve synaptosomes than to spider (Ornithoctonus huwena) ones. The sodium channel cDNA from these two species were further cloned. The deduced proteins contain 1871 and 1987 amino acids respectively. Several key amino acid substitutions, i.e., A1610V, I1611L and S1617K, are found in IVS3-S4 constituting receptor site-3, and for receptor site-4, two residues (Leu-Pro) are inserted near IIS4 of scorpion sodium channel.

The cDNA and genomic DNA organization of a novel toxin SHT-I from spider Ornithoctonus huwena.

In present study the full-length cDNA of a novel toxin from the venom gland of spider Ornithoctonus huwena, named as SHT-I, has been cloned using the strategy of rapid amplification of cDNA ends, and then the whole genomic sequence of SHT-I (Selenocosmia huwena toxin-I) was determined using sequence-specific primers synthesized based on the acquired 3' and 5' ends of SHT-I cDNA sequence. It is unexpectedly found that intron was lacking in the genomic sequence of SHT-I. The result might evoke an interesting question whether the gene code of inhibitor cystine-knot peptides from spider venom is distinct from that of those known toxic peptides of scorpion and cone snail.

Molecular mechanism of scorpion neurotoxins acting on sodium channels: insight into their diverse selectivity.

Scorpion toxins that affect sodium channel gating traditionally are divided into alpha- and beta-classes. They show vast diversity in their selectivity for phyletic- or isoform-specific sodium channels. This article discusses the molecular mechanism of the selectivity. Moreover, a phylogenetic tree of scorpion toxins has been constructed, which, together with the worldwide distribution of toxins and the zoogeographic dispersion of the studied genera, offers an insight into the evolution of diverse scorpion toxins.