Bacteriocin production augments niche competition by enterococci in the mammalian GI tract

Enterococcus faecalis (EF) is both a common commensal of the human gastrointestinal tract (GI) and a leading cause of hospital acquired infections(1). Systemic infections with multi-drug resistant enterococci occur subsequent to GI colonization(2). Preventing colonization by multi-drug resistant EF could therefore be a valuable approach to limiting infection. However, little is known about mechanisms EF uses to colonize and compete for stable gastrointestinal niches. Pheromone-responsive, conjugative plasmids encoding bacteriocins are common among enterococcal strains(3), and could modulate niche competition among enterococci or between enterococci and the intestinal microbiota. We developed a model of mouse gut colonization with EF without disrupting the microbiota, to evaluate the role of the conjugative plasmid pPD1 expressing bacteriocin 21(4) on enterococcal colonization. Here we show that EF harboring pPD1 replaces indigenous enterococci and outcompetes EF lacking pPD1. Furthermore, in the intestine, pPD1 is transferred to other EF strains by conjugation, enhancing their survival. Moreover, colonization with an EF strain carrying a conjugation-defective pPD1 mutant resulted in clearance of vancomycin-resistant enterococci, without plasmid transfer. Therefore bacteriocin expression by commensal bacteria can influence niche-competition in the GI tract, and bacteriocins, delivered by commensals that occupy a precise intestinal bacterial niche, may be an effective therapeutic approach to specifically eliminate intestinal colonization by multi-drug resistant bacteria, without profound disruption of the indigenous microbiota.