Abstract
Staphylococcus aureus infections are hard to treat due to the emergence of antibiotic resistant strains, as well as their ability to form biofilms. The MazEF toxin-antitoxin system is thought play a role in bacterial biofilm phenotype as well as antibiotic resistance. In S. aureus, the physiologic function of the mazEF gene in the disease transition from acute to chronic infection is not well understood. In methicillin resistant S. aureus (MRSA), loss of mazF expression results in loss of resistance to first generation cephalosporins. mazF::tn displayed sensitivity while the isogenic wild type (WT) remained resistant. mazF::tn displayed significantly increased growth of biofilms on metal implants over 48 h compared to WT and the complemented transposon mutant. mazF::tn biofilms displayed significantly decreased antibiotic tolerance to vancomycin and cefazolin in comparison to WT and complement biofilms. Mice given mazF::tn in a sepsis model displayed less abscess burden and increased survival (100%) when treated with cefazolin compared to WT bacteremia treated with cefazolin (20%). mazF::tn periprosthetic joint infections displayed increased biofilm burden at acute time points and decreased biofilm burden at chronic time points. Our data suggests MazEF in MRSA is responsible for controlling growth of biofilms, antibiotic tolerance, and influence chronic infections in vivo.