TY - JOUR T1 - Comparative Genomics of <em>Staphylococcus</em> Reveals Determinants of Speciation and Diversification of Antimicrobial Defense JF - bioRxiv DO - 10.1101/277400 SP - 277400 AU - Rosanna Coates-Brown AU - Josephine Moran AU - Pisut Pongchaikul AU - Alistair Darby AU - Malcolm J. Horsburgh Y1 - 2018/01/01 UR - http://biorxiv.org/content/early/2018/03/07/277400.abstract N2 - The bacterial genus Staphylococcus comprises diverse species with most being described as colonizers of human and animal skin. A relational analysis of features that discriminate its species and contribute to niche adaptation and survival remains to be fully described. In this study, an interspecies, whole-genome comparative analysis of 21 Staphylococcus species was performed based on their orthologues. Three well-defined multi-species groups were identified: group A (including aureus/epidermidis); group B (including saprophyticus/xylosus) and group C (including pseudintermedius/delphini). The machine learning algorithm Random Forest was applied to identify variable orthologues that drive formation of the Staphylococcus species groups A-C. Orthologues driving staphylococcal infrageneric diversity comprised regulatory, metabolic and antimicrobial resistance proteins. Notably, the BraSR (NsaRS) two-component system (TCS) and its associated BraDE transporters that regulate antimicrobial resistance distinguish group A Staphylococcus species from others in the genus that lack the BraSR TCS. Divergence of BraSR and GraSR antimicrobial peptide survival TCS and their associated transporters was observed across the staphylococci, likely reflecting niche specific evolution of these TCS/transporters and their specificities for AMPs. Experimental evolution, with selection for resistance to the lantibiotic nisin, revealed multiple routes to resistance and differences in the selection outcomes of the BraSR- positive species S. hominis and S. aureus. Selection supported a role for GraSR in nisin survival responses of the BraSR-negative group B species S. saprophyticus. Our study reveals diversification of antimicrobial-sensing TCS across the staphylococci and hints at differential relationships between GraSR and BraSR in those species positive for both TCS.Importance The genus Staphylococcus includes species that are commensals and opportunist pathogens of humans and animals. Identifying the features that discriminate species of staphylococci is relevant to understanding niche selection and the structure of their microbiomes. Moreover, the determinants that structure the community are relevant for strategies to modify the frequency of individual species associated with dysbiosis and disease. In this study, we identify orthologous proteins that discriminate genomes of staphylococci. In particular, species restriction of a major antimicrobial survival system, BraSR (NsaRS), to a group of staphylococci dominated by those that can colonize human skin. The diversity of antimicrobial sensing loci was revealed by comparative analysis and experimental evolution with selection for nisin resistance identified the potential for variation in antimicrobial sensing in BraRS-encoding staphylococci. This study provides insights into staphylococcal species diversity. ER -