Divergence between Drosophila santomea and allopatric or sympatric populations of D. yakuba using paralogous amylase genes and migration scenarios along the Cameroon volcanic line.

We have used two paralogous genes (Amyrel and Amy) of the amylase multigene family to reconstruct the phylogeny of the nine Drosophila melanogaster subgroup sister species, including D. santomea, the newly discovered endemic from São Tomé island. The evolutionary divergence of these genes is of special interest as it is suspected to result from physiological evolution via gene duplication. This paper describes the relationship between the geographical origin of the various strains and the patterns of mating and phylogeny, focusing on the evolution of D. santomea and its relationship to other species and their niches. The Amyrel and Amy data indicate that, contrary to expectations, the sympatric insular D. yakuba population is less closely related to D. santomea than allopatric mainland ones, suggesting that the extant insular D. yakuba population on São Tomé results from a recent secondary colonization. Data for sympatric and allopatric D. yakuba suggest that D. santomea arose from a mainland D. yakuba parental stock when montane habitats of the Cameroon volcanic line extended to lower altitudes during colder and less humid periods. Despite their different modes of evolution and different functions, the Amyrel and Amy genes provide remarkably consistent topologies and hence reflect the same history, that of the species.

Bacterial molecular phylogeny using supertree approach.

It has been claimed that complete genome sequences would clarify phylogenetic relationships between organisms but, up to now, no satisfying approach has been proposed to use efficiently these data. For instance, if the coding of presence or absence of genes in complete genomes gives interesting results, it does not take into account the phylogenetic information contained in sequences and ignores hidden paralogy by using a similarity-based definition of orthology. Also, concatenation of sequences of different genes takes hardly in consideration the specific evolutionary rate of each gene. At last, building a consensus tree is strongly limited by the low number of genes shared among all organisms. Here, we use a new method based on supertree construction, which permits to cumulate in one supertree the information and statistical support of hundreds of trees from orthologous gene families and to build the phylogeny of 33 prokaryotes and four eukaryotes with completely sequenced genomes. This approach gives a robust supertree, which demonstrates that a phylogeny of prokaryotic species is conceivable and challenges the hypothesis of a thermophilic origin of bacteria and present-day life. The results are compatible with the hypothesis of a core of genes for which lateral transfers are rare but they raise doubts on the widely admitted "complexity hypothesis" which predicts that this core is mainly implicated in informational processes.