equisimilis) origin. Therefore, it’s possible that human S. canis infection has been underestimated [13, 15]. Investigating this problem, Broyles et al. [22] performed a survey of human invasive infection using techniques capable of distinguishing S. canis from S. dysgalactiae subsp. equisimilis. Results showed a low frequency of S. canis in blood samples. However, their study was biased towards the characterization of isolates from blood samples (isolates from other check details body sites were less
likely to be characterized). In humans, STSS and NF are serious diseases typically caused by S. pyogenes infection. The emergence of strikingly similar STSS and NF in cats and dogs coupled with the close relationship between the causal species prompted preliminary investigation and subsequent discovery of two shared virulence factors between these species [23]. To shed light on the molecular basis of S. canis virulence and further investigate the role S. pyogenes and other species of Streptococcus may have played in its evolution we determined the first selleck inhibitor genome sequence for this pathogen and compared Temozolomide ic50 it to an extensive range of streptococcal genomes (40 species,
213 strains). In addition, we explored population structure among canine, feline, and bovine isolates. Our findings reveal a diverse array of genes within the S. canis genome homologous to known virulence factors, including several established virulence factors from S. pyogenes, Streptococcus agalactiae, and Streptococcus pneumoniae. We found evidence
for multiple LGT events between S. canis and (i) other bovine mastitis causing pathogens, and (ii) the human pathogen Tau-protein kinase Streptococcus urinalis, suggesting LGT in both shared bovine and human environments. This LGT was mediated by a variety of mobile genetic elements [plasmid, phage, integrative conjugative element] that carried many of the virulence factors, highlighting the importance of LGT in the evolution of this pathogen and the potential for its emergence as a zoonotic pathogen. Result and discussion Assembly and general features of the genome Roche/454 pyrosequencing produced 128,749 single-end reads and 140,788 paired-end reads that were assembled into 91 contigs (>200 bp) and eight scaffolds, representing an average 23X site coverage. Utilizing additional Illumina/Sanger sequencing and alignment to an optical map, the eight scaffolds were assembled into a single 2,267,856 bp contig. Unfortunately, we were unable to obtain sequence for one small section of the genome (Figure 1). The gap was within a collagen-like surface protein. The best BLAST hit at the NCBI nr database for each gene fragment (SCAZ3_06900 and SCAZ3_06785) was to an identically annotated gene within S. agalactiae (A909), (each fragment shared approximately 75% sequence identity). Alignment of the S. canis fragments to this gene suggested that we were missing approximately 1.6 kb. For S.