Abstract
Bacterial persistence has been extensively studied as a possible explanation for strain survival under stress; however, in Enterococcus spp., this ability is still an understudied phenomenon. In this study, 40 Enterococcus spp. isolates of human clinical (n = 10), veterinary commensal (n = 10), veterinary clinical (n = 10) and veterinary environmental (hospital surfaces) (n = 10) origins, were exposed to a high concentration of ciprofloxacin. Time–kill curves were established, after which antimicrobial susceptibility profiles were reassessed. Subsequently, the only presumptive persister was selected for Whole-Genome Sequencing, together with one isolate showing no evidence of persister formation. Comparative genomic analyses were conducted to identify genetic variations between exposed and non-exposed isolates and to explore potential genetic determinants associated with persistence. Observed genetic features present in the persister isolate included toxin–antitoxin systems, a cold-shock protein and the tyrosine-type recombinase/integrase XerC, which may represent putative candidates for further investigation. Interestingly, the majority of toxin–antitoxin system-associated genes were found in plasmids. This study represents an important step towards a better understanding of persistence development in Enterococcus spp.; however, validation using other methodologies such as RNA-sequencing is an important next step.