Mitochondrial DNA based phylogeny of the woodpecker genera Colaptes and Piculus, and implications for the history of woodpecker diversification in South America.

The woodpecker genus Colaptes (flickers) has its highest diversity in South America and the closely related genus Piculus is restricted to South and Central America. Two species of flickers occur in North America, and one species is endemic to Cuba. We conducted a Bayesian phylogenetic analysis of three mitochondrial encoded genes (cyt b, COI, 12S rRNA) and confirmed that the two genera are paraphyletic. Three species historically classified as Piculus are actually flickers. We found that the Cuban endemic C. fernandinae is the most basal species within the flickers and that the Northern Flicker is the next most basal species within the Colaptes lineage. The South American clade is most derived. The age of the South American diversification is estimated to be 3.6MY, which is synchronous with the emergence of the Isthmus of Panama. The pattern of diversification of South American flickers is common among South American woodpeckers. Although woodpeckers have their greatest diversity in South America, we hypothesize that woodpeckers (Family Picidae) originated in Eurasia, dispersed to North America via the Bering land bridge, and multiple lineages entered South America as the Isthmus approached its final closing.

Molecular phylogenetic relationships of Xiphidiopicus percussus, Melanerpes, and Sphyrapicus (Aves: Picidae) based on cytochrome B sequence.

The endemic woodpecker, Xiphidiopicus percussus, from Cuba has been postulated as the sister taxon to the Hispaniolan woodpecker (Melanerpes striatus) and its relationships to the genera Sphyrapicus and Melanerpes have been speculated. We used mitochondrial cytochrome b sequences from a collection of New World picids to investigate the phylogenetic relationships among these species using maximum parsimony and maximum likelihood approaches. Our data suggest that X. percussus is the sister taxon to the Melanerpes woodpeckers, which appear to group into a single distinct clade. Xiphidiopicus percussus is not the sister taxon to M. striatus as has been postulated [Olson, S., 1972. The generic distinction of the Hispaniolan Woodpecker, Chryserpes striatus (Aves: Picidae). Proc. Biol. Soc. Wash. 85, 499-508]. The genus Sphyrapicus appears to have diverged earlier than Xiphidiopicus. Divergence estimates from the cytochrome b sequences indicate that Xiphidiopicus probably diverged sometime in the late Miocene-early Pliocene, and the endemic contemporary species X. percussus on Cuba may be a relict from a group that originated in Central America or North America.

Molecular phylogenetic relationships based on mitochondrial and nuclear gene sequences for the Todies (Todus, Todidae) of the Caribbean.

We used mitochondrial/nuclear gene sequence analyses to determine the historical relationships of the endemic species of Todus (Aves: Todidae) from the Caribbean. We collected 1920-bp of nucleotide sequence data from the mitochondrial genes cytochrome b, ATPase 6, ATPase 8, and 591-bp of the single-copy nuclear gene c-mos for all Todus species and representatives of their outgroup taxa (Hylomanes, Barypthengus, Chloroceryle, Ceryle, and Galbula) to reconstruct the evolutionary history (via parsimony and maximum likelihood) of the five Todus species. The substitution rates among the mitochondrial genes were found to be much higher than the substitution rate for the c-mos gene, consequently resulting in higher substitutional saturation for the mitochondrial genes. When we applied weighting schemes to account for the variance in substitutional heterogeneity among the genes then parsimony and likelihood analyses both demonstrate that the genus Todus is monophyletic and closer to the Hylomanes and Barypthengus genera than the Chloroceryle and Ceryle genera. The mitochondrial-gene trees and nuclear-gene trees both show similar results, thus providing support for the relationships among the taxa from loci within two independently evolving genomes. The nuclear gene c-mos was found, therefore, to be a viable nuclear gene candidate for resolving intermediate and deep divergences.