Phylogeography and spatial structure of the lowland tapir (Tapirus terrestris, Perissodactyla: Tapiridae) in South America.

We sequenced the mitochondrial cytochrome b gene of 141 lowland tapirs (Tapirus terrestris) - representing the largest geographical distribution sample of this species studied across of South America to date. We compare our new data regard to two previous works on population structure and molecular systematics of T. terrestris. Our data agree with the Thoisy et al.'s work in (1) the Northern Western Amazon basin was the area with the highest gene diversity levels in T. terrestris, being probably the area of initial diversification; (2) there was no clear association between haplogroups and specific geographical areas; (3) there were clear population decreases during the last glacial maximum for the different haplogroups detected, followed by population expansions during the Holocene; and (4) our temporal splits among different T. terrestris haplogroups coincided with the first molecular clock approach carried out by these authors (fossil calibration). Nevertheless, our study disagreed regard to other aspects of the Thoisy et al.'s claims: (1) meanwhile, they detected four relevant clades in their data, we put forward six different relevant clades; (2) the Amazon River was not a strong barrier for haplotype dispersion in T. terrestris; and (3) we found reciprocal monophyly between T. terrestris and T. pinchaque. Additionally, we sequenced 42 individuals (T. terrestris, T. pinchaque, T. bairdii, and the alleged "new species", T. kabomani) for three concatenated mitochondrial genes (Cyt-b, COI, and COII) agreeing quite well with the view of Voss et al., and against of the claims of Cozzuol et al. Tapirus kabomani should be not considered as a full species with the results obtained throughout the mitochondrial sequences.

Molecular phylogenetics and phylogeography of all the Saimiri taxa (Cebidae, Primates) inferred from mt COI and COII gene sequences.

Some previous genetic studies have been performed to resolve the molecular phylogenetics of the squirrel monkeys (Saimiri). However, these studies did not show consensus in how many taxa are within this genus and what the relationships among them are. For this reason, we sequenced 2,237 base pairs of the mt COI and COII genes in 218 Saimiri individuals. All, less 12 S. sciureus sciureus from French Guyana, were sampled in the wild. These samples represented all the living Saimiri taxa recognized. There were four main findings of this study. (1) Our analysis detected 17 different Saimiri groups: albigena, cassiquiarensis, five polyphyletic macrodon groups, three polyphyletic ustus groups, sciureus, collinsi, boliviensis, peruviensis, vanzolinii, oerstedii and citrinellus. Four different phylogenetic trees showed the Central American squirrel monkey (S. oerstedii) as the most differentiated taxon. In contrast, albigena was indicated to be the most recent taxon. (2) There was extensive hybridization and/or historical introgression among albigena, different macrodon groups, peruviensis, sciureus and collinsi. (3) Different tests showed that our maximum likelihood tree was consistent with two species of Saimiri: S. oerstedii and S. sciureus. If no cases of hybridization were detected implicating S. vanzolinii, this could be a third recognized species. (4) We also estimated that the first temporal splits within this genus occurred around 1.4-1.6 million years ago, which indicates that the temporal split events within Saimiri were correlated with Pleistocene climatic changes. If the biological species concept is applied because, in this case, it is operative due to observed hybridization in the wild, the number of species within this genus is probably more limited than recently proposed by other authors. The Pleistocene was the fundamental epoch when the mitochondrial Saimiri diversification process occurred.