Genome analyses show strong selection on coloration, morphological and behavioral phenotypes in birds-of-paradise

Background The diverse array of phenotypes and lekking behaviors in birds-of-paradise have long excited scientists and laymen alike. Remarkably, almost nothing is known about the genomics underlying this iconic radiation. Currently, there are 41 recognized species of birds-of-paradise, most of which live on the islands of New Guinea. In this study we sequenced genomes of representatives from all five major clades recognized within the birds-of-paradise family (Paradisaeidae). Our aim was to characterize genomic changes that may have been important for the evolution of the groups extensive phenotypic diversity. Results We sequenced three de novo genomes and re-sequenced two additional genomes representing all major clades within the birds-of-paradise. We found genes important for coloration, morphology and feather development to be under positive selection. GO enrichment of positively selected genes on the branch leading to the birds-of-paradise shows an enrichment for collagen, glycogen synthesis and regulation, eye development and other categories. In the core birds-of-paradise, we found GO categories for startle response (response to predators) and olfactory receptor activity to be enriched among the gene families expanding significantly faster compared to the other birds in our study. Furthermore, we found novel families ofretrovirus-like retrotransposons active in all three de novo genomes since the early diversification of the birds-of-paradise group, which could have potentially played a role in the evolution of this fascinating group of birds. Conclusion Here we provide a first glimpse into the genomic changes underlying the evolution of birds-of- paradise. Our aim was to use comparative genomics to study to what degree the genomic landscape of birds-of-paradise deviates from other closely related passerine birds. Given the extreme phenotypic diversity in this family, our prediction was that genomes should be able to reveal features important for the evolution of this amazing radiation. Overall, we found a strong signal for evolution on mechanisms important for coloration, morphology, sensory systems, as well as genome structure.