Analysis of CRISPR–Cas system and antimicrobial resistance in Staphylococcus coagulans isolates

Abstract

Abstract CRISPR–Cas system contributes adaptive immunity to protect the bacterial and archaeal genome against invading mobile genetic elements. In this study, an attempt was made to characterize the CRISPR–Cas system in Staphylococcus coagulans, the second most prevalent coagulase positive staphylococci causing skin infections in dogs. Out of 45 S. coagulans isolates, 42/45 (93·33%) strains contained CRISPR–Cas system and 45 confirmed CRISPR system was identified in 42 S. coagulans isolates. The length of CRISPR loci ranged from 167 to 2477 bp, and the number of spacers in each CRISPR was varied from two spacers to as high as 37 numbers. Direct repeat (DR) sequences were between 30 and 37, but most (35/45) of the DRs contained 36 sequences. The predominant S. coagulans strains 29/45 did not possess any antimicrobial resistant genes (ARG); 26/29 strains contained Type IIC CRISPR–Cas system. Three isolates from Antarctica seals neither contain CRISPR–Cas system nor ARG. Only 15/45 S. coagulans strains (33·33%) harboured at least one ARG and 13/15 of them were having mecA gene. All the methicillin susceptible S. coagulans isolates contained Type IIC CRISPR–Cas system. In contrast, many (10/13) S. coagulans isolates which were methicillin resistant had Type IIIA CRISPR–Cas system, and this Type IIIA CRISPR–Cas system was present within the SCCmec mobile genetic element. Hence, this study suggests that Type II CRISPR–Cas in S. coagulans isolates might have played a possible role in preventing acquisition of plasmid/phage invasion and Type IIIA CRISPR–Cas system may have an insignificant role in the prevention of horizontal gene transfer of antimicrobial resistance genes in S. coagulans species.