Resolution of the laurasiatherian phylogeny: evidence from genomic data.

Despite great progress over the past decade, some portions of the mammalian tree of life remain unresolved. In particular, relationships among the different orders included within the supraordinal group Laurasiatheria have been proven difficult to determine, and have received poor support in the vast majority of phylogenomic studies of mammalian systematics. We estimated interordinal relationships within Laurasiatheria using sequence data from 3733 protein-coding genes. Our study included data from from 11 placental mammals, corresponding to five of the six orders of Laurasiatheria, plus five outgroup species. Ingroup and outgroup species were chosen to maximize the number single-copy ortholog genes for which sequence data was available for all species in our study. Phylogenetic analyses of the concatenated dataset using maximum likelihood and Bayesian methods resulted on an identical and well supported topology in all alignment strategies compared. Our analyses provide high support for the sister relationship between Chiroptera and Cetartiodactyla and also provide support for placing Perissodactyla as sister to Carnivora. We obtained maximal estimates of bootstrap support (100%) and posterior probability (1.00) for all nodes within Laurasiatheria. Our study provides a further demonstration of the utility of very large and conserved genomic dataset to clarify our understanding of the evolutionary relationships among mammals.

How to Make a Dolphin: Molecular Signature of Positive Selection in Cetacean Genome.

Cetaceans are unique in being the only mammals completely adapted to an aquatic environment. This adaptation has required complex changes and sometimes a complete restructuring of physiology, behavior and morphology. Identifying genes that have been subjected to selection pressure during cetacean evolution would greatly enhance our knowledge of the ways in which genetic variation in this mammalian order has been shaped by natural selection. Here, we performed a genome-wide scan for positive selection in the dolphin lineage. We employed models of codon substitution that account for variation of selective pressure over branches on the tree and across sites in a sequence. We analyzed 7,859 nuclear-coding ortholog genes and using a series of likelihood ratio tests (LRTs), we identified 376 genes (4.8%) with molecular signatures of positive selection in the dolphin lineage. We used the cow as the sister group and compared estimates of selection in the cetacean genome to this using the same methods. This allowed us to define which genes have been exclusively under positive selection in the dolphin lineage. The enrichment analysis found that the identified positively selected genes are significantly over-represented for three exclusive functional categories only in the dolphin lineage: segment specification, mesoderm development and system development. Of particular interest for cetacean adaptation to an aquatic life are the following GeneOntology targets under positive selection: genes related to kidney, heart, lung, eye, ear and nervous system development.