Bacteriophage adhered to mucus provide a novel mucosal immune system (P3166)

Abstract

Abstract Mucosal surfaces serve as a primary entry point for multiple pathogens and are therefore principal sites of immune defense. Here we demonstrate through in vitro and in silico studies that increased phage adherence to the host mucosal layer, provides a novel immune defense mechanism. We show that compared to the surrounding environment, phage-to-bacteria ratios were increased on all mucosal surfaces sampled ranging from cnidarians to humans. This increased phage abundance protects the underlying epithelium from bacterial infection. Enrichment of phage on mucus occurs via interactions between host mucin glycoproteins and phage immunoglobulin-like protein domains exposed on phage capsids. Metagenomic analysis found these immunoglobulin-like proteins present in many environments, particularly those adjacent to mucosal surfaces. Preliminary glycan microarrays and 2D gel electrophoresis show that phage adherence can rapidly adapt to hosts mucus glycan profiles, and in response, the host may regulate its mucus glycosylation to select for a beneficial phage community. This adaptation between phage and host provide a mechanism for the manipulation and selection of the mucosal microbiota. Based on these observations, we present the Bacteriophage Adherence to Mucus (BAM) model describing a phage-derived mucosal immunity with potential applicability to all mucosal surfaces, thus opening a novel field of immunological study.