%0 Generic %A Zhang, Dao-Feng %A Zhi, Xiao-Yang %A Zhang, Jing %A Paoli, George %A Cui, Yan %A Shi, Chunlei %A Shi, Xianming %D 2017 %T Additional file 9: Table S2. of Preliminary comparative genomics revealed pathogenic potential and international spread of Staphylococcus argenteus %U https://springernature.figshare.com/articles/dataset/Additional_file_9_Table_S2_of_Preliminary_comparative_genomics_revealed_pathogenic_potential_and_international_spread_of_Staphylococcus_argenteus/5530759 %R 10.6084/m9.figshare.c.3911389_D9.v1 %2 https://springernature.figshare.com/ndownloader/files/9574441 %K Staphylococcus aureus %K Staphylococcus argenteus %K Staphylococcus schweitzeri %K Comparative genomics %K Virulence gene %K Capsular polysaccharides %K Agr %K Biogeographical structure %X Prevalence and relatedness of virulence genes among S. aureus complex (SAC) genomes. The presence/absence and interspecies divergence was analyzed for 111 virulence genes from 51 SAC genomes (30 S. aureus, 15 S. argenteus and 6 S. schweitzeri. Five virulence genes, sed, see, sej, selr and etb, are not listed in the table because they were not detected in any of the 51 SAC genomes examined. a *, these genes have tandem repeat regions, so the interspecies divergence of the nucleotide sequences may not clearly reflect the true evolutionary divergence. b The number of SAC genomes of each species harboring each virulence gene. c The gene family numbers as listed in Additional file 3: Table S1. d NA, not applicable; SA, S. aureus; SG, S. argenteus; SW, S. schweitzeri. e Maximum likelihood phylogenetic trees were contructed based on nucleotide sequence, using substitution matrix GTR and executing 100 rapid bootstrap inferences. The species names were omitted in tip labels. f p.g., pseudogene. (XLSX 1797 kb) %I figshare