Comparative genomics highlight the importance of lineage-specific gene families in evolutionary divergence of the coral genus, Montipora

Background Scleractinian corals of the genus Montipora (Anthozoa, Cnidaria) possess some unusual biological traits, such as vertical transmission of algal symbionts; however, the genetic bases for those traits remain unknown. We performed extensive comparative genomic analyses among members of the family Acroporidae ( Montipora , Acropora, and Astreopora ) to explore genomic novelties that might explain unique biological traits of Montipora using improved genome assemblies and gene predictions for M. cactus , M. efflorescens and Astreopora myriophthalma . Results We obtained genomic data for the three species of comparable high quality to other published coral genomes. Comparative genomic analyses revealed that the gene families restricted to Montipora are significantly more numerous than those of Acropora and Astreopora , but their functions are largely unknown. The number of gene families specifically expanded in Montipora was much lower than the number specifically expanded in Acropora . In addition, we found that evolutionary rates of the Montipora- specific gene families were significantly higher than other gene families shared with Acropora and/or Astreopora . Of 40 gene families under positive selection (Ka/Ks ratio > 1) in Montipora , 30 were specifically detected in Montipora- specific gene families. Comparative transcriptomic analysis of early life stages of Montipora , which possesses maternally inherited symbionts, and Acropora , which lacks them, revealed that most gene families continuously expressed in Montipora , but not expressed in Acropora do not have orthologs in Acropora. Among the 30 Montipora -specific gene families under positive selection, 27 are expressed in early life stages. Conclusions Lineage-specific gene families were important to establish the genus Montipora , particularly genes expressed throughout early life stages, which under positive selection, gave rise to biological traits unique to Montipora. Our findings highlight evolutionarily acquired genomic bases that may support symbiosis in these stony corals and provide novel insights into mechanisms of coral-algal symbiosis, the physiological foundation of coral reefs.