Positions under positive selection--key for selectivity and potency of scorpion alpha-toxins.

Alpha-neurotoxins target voltage-gated sodium channels (Na(v)s) and constitute an important component in the venom of Buthidae scorpions. These toxins are short polypeptides highly conserved in sequence and three-dimensional structure, and yet they differ greatly in activity and preference for insect and various mammalian Na(v)s. Despite extensive studies of the structure-function relationship of these toxins, only little is known about their evolution and phylogeny.

Fusion and retrotransposition events in the evolution of the sea anemone Anemonia viridis neurotoxin genes.

Sea anemones are sessile predators that use a variety of toxins to paralyze prey and foe. Among these toxins, Types I, II and III are short peptides that affect voltage-gated sodium channels. Anemonia viridis is the only sea anemone species that produces both Types I and III neurotoxin.

Intron retention as a posttranscriptional regulatory mechanism of neurotoxin expression at early life stages of the starlet anemone Nematostella vectensis.

Sea anemones use an arsenal of peptide neurotoxins accumulated in special stinging cells (nematocytes) for defense and predation. Intriguingly, genomic analysis of Nematostella vectensis revealed only a single toxin, Nv1 (N. vectensis toxin 1), encoded by multiple extremely conserved genes.

Concerted evolution of sea anemone neurotoxin genes is revealed through analysis of the Nematostella vectensis genome.

Gene families, which encode toxins, are found in many poisonous animals, yet there is limited understanding of their evolution at the nucleotide level. The release of the genome draft sequence for the sea anemone Nematostella vectensis enabled a comprehensive study of a gene family whose neurotoxin products affect voltage-gated sodium channels. All gene family members are clustered in a highly repetitive approximately 30-kb genomic region and encode a single toxin, Nv1.