Mitochondrial DNA sequences from dried snake venom: a DNA barcoding approach to the identification of venom samples.

Outdated nomenclature and incorrect taxonomic characterisation of snake venoms in the current toxinological literature have serious implications for the replicability of results from snake venom toxin research. The situation has not improved, despite attempts to supply toxinologists with regular updates on snake systematics. Here, we demonstrate the successful extraction of DNA, and subsequent sequencing of the mitochondrial 12S gene, from dried snake venoms. This approach offers a new and potentially straightforward method for accurate species identification. Mitochondrial DNA (mtDNA) sequences isolated from snake venom can be used to clarify or validate snake species identification through comparison against existing sequences in the GenBank database, and through phylogenetic analyses with other sequences. Pooled venoms can also be screened a priori for the presence of multiple species, and the species names on the labels of commercial venoms verified. Moreover, if the species from which the venom sample has been taken is known, and the specimen is available as a voucher, the mtDNA sequence of the haplotype isolated from that species venom sample could serve as a sequence standard (or 'DNA barcode') for that species. Our new method of DNA barcoding venoms ensures the identification of venoms even after future taxonomic changes.

Molecular clocks and geological dates: cytochrome b of Anolis extremus substantially contradicts dating of Barbados emergence.

Even though molecular clocks vary in rate to some extent, they are widely used and very important in a range of evolutionary studies, not least in interpreting cause and colonization in phylogeography. Evolutionists may use island age and emergence to give the earliest possible date for colonization by a species and hence give the lower limit in a molecular clock calibration. The geology of the Lesser Antilles is well studied and Barbados, although composed of some ancient rocks, is thought to have emerged only about 1 million years ago (Ma). The cytochrome b mitochondrial gene is the most widely used gene in vertebrate phylogeography, and generally evolves at a rate of 1-2% per million years (Myr) for poikilothermic vertebrates. Divergence measured across almost all of this gene in the endemic anole (Anolis extremus) reveals a mean patristic distance of approximately 8.3% between this clade and its sister, together with distinct divergence and phylogeographical structure within Barbados. The divergence time, estimated by a range of procedures using four calibration points, is not in the least compatible with the proposed geological time of emergence of Barbados. Hence, either the molecular clock rate does not apply to the Barbadian anole population, or the geological dating of the emergence of Barbados is erroneous. The compatibility of geological times and molecular divergence of this complex on Martinique, together with relative rates tests comparing the rates on Barbados and Martinique, do not suggest atypical clock rates. The question of whether Barbados emerged much earlier than is currently thought, or whether the molecular clock assumptions are inappropriate, remains open.

Historical biogeography of the Western Rattlesnake (Serpentes: viperidae: Crotalus viridis), inferred from mitochondrial DNA sequence information.

We infer the phylogeography of the Western Rattlesnake (Crotalus viridis) using phylogenetic analysis of mitochondrial DNA sequences from 1345 bp of the genes for cytochrome b and NADH dehydrogenase subunit 4. Two main clades are revealed: one includes populations from east and south of the Rocky Mountains (conventionally referred to as Crotalus viridis viridis and C. v. nuntius), and the other consists of populations west of the Rocky Mountains. Within the western clade, a population from southern Arizona (C. v. cerberus) represents the sister taxon to the remaining western populations. The conventional subspecies recognized in this species do not fully correspond to the phylogenetic pattern, and a review of the systematic status of several populations is needed. Our data allow the inferences that small body size evolved twice and that the ability of one population (C. v. concolor) to secrete highly lethal toxins related to Mojave toxin arose within the complex. Our phylogeny should represent the basis for further studies on the causes of geographical variation in this complex.