We recently showed that human gut Bacteroidales species secrete antimicrobial proteins (BSAPs), and we characterized in vitro the first such BSAP produced by Bacteroides fragilis. In this study, we identified a second potent BSAP produced by the ubiquitous and abundant human gut species Bacteroides uniformis. The two BSAPs contain a membrane attack complex/perforin (MACPF) domain but share very little sequence similarity. We identified the target molecules of BSAP-sensitive cells and showed that each BSAP targets a different class of surface molecule: BSAP-1 targets an outer membrane protein of sensitive B. fragilis strains, and BSAP-2 targets the O-antigen glycan of lipopolysaccharide (LPS) of sensitive B. uniformis strains. Species-wide genomic and phenotypic analyses of B. fragilis and B. uniformis showed that BSAP-producing strains circumvent killing by synthesizing an orthologous nontargeted surface molecule. The BSAP genes are adjacent to the gene(s) encoding their target replacements, suggesting coacquisition. Using a gnotobiotic mouse competitive-colonization model, we found that the BSAP surface targets are important for colonization of the mammalian gut, thereby explaining why they are maintained in sensitive strains and why they were replaced rather than deleted in BSAP-producing strains. Using isogenic BSAP-producing, -sensitive, and -resistant strains, we show that a BSAP-producing strain outcompetes a sensitive strain but not a resistant strain in the mammalian gut. Human gut metagenomic datasets reveal that BSAP-1-sensitive strains do not cooccur with BSAP-1-producing strains in human gut microbiotas, further supporting the idea that BSAPs are important competitive factors with relevance to the strain-level composition of the human gut microbiota.

IMPORTANCE We know relatively little about the ecology of the human intestinal microbiota and the combination of factors that dictate which strains and species occupy an individual’s gut microbial community. Interference competition, mediated by bacterial factors that directly harm other members, is beginning to be appreciated as important in contributing to species- and strain-level dynamics of abundant gut bacteria. Here, we show that gut Bacteroidales secrete antimicrobial proteins (BSAPs) that antagonize strains of the same species. We show that BSAPs target molecules of sensitive cells that are important for gut colonization and therefore are maintained in sensitive cells. In an experimental animal model of gut colonization, a BSAP-1-producing strain antagonized and outcompeted an isogenic sensitive strain. Furthermore, metagenomic analyses showed that BSAP-1-producing and -sensitive strains are not found together in human gut microbiotas. These data suggest that BSAPs are strong ecological drivers shaping the strain-level composition of gut communities.