Abstract
The extremely fast rate of phenotypic and ecological adaptation of species during explosive adaptive radiations on islands remains one of the most intriguing evolutionary phenomena. Low genetic diversity of island populations may present an obstacle for fast adaptive changes, as natural selection needs genetic variation from which to select. Hybridisation of closely related species and interspecific gene flow may provide the genetic variation needed for natural selection. Although multiple cases of interspecific hybridisation are known, there is little evidence that it may play a role in adaptive evolution. We will use the Hawaiian endemic plant genus Schiedea (Caryophyllaceae) to infer the role of interspecific gene flow in adaptive radiation. This genus presents one of the most impressive recent adaptive radiations in plants, as it has evolved very diverse morphological forms (ranging from vines to perennial herbes and woody bushes) and colonised a wide range of ecological niches in just a few million years. To assess the role of gene flow between the species during adaptive radiation in Schiedea we will (i) estimate what proportion of genes show evidence for interspecific introgression, and (ii) test whether positive selection could have caused the spread of genes across several species. The spread of a positively selected allele across several species should distort the phylogeny of that gene, making it incompatible with the phylogenies of other genes not affected by interspecific introgression. We will estimate the proportion of genes with distorted phylogenies in genus Schiedea and will test whether the distortion could have been caused by the spread of advantageous alleles across several species.