Dynamic genetic adaptation of Bacteroides thetaiotaomicron murine gut colonization

Abstract

AbstractTo understand how a bacterium ultimately succeeds or fails in adapting to a new environment, it is essential to assess the temporal dynamics of its fitness over the course of colonization. The mammalian gut, into which exogenous microorganisms are regularly introduced, represents a biologically and clinically relevant system to explore microbial adaptational processes. In this study, we introduce a human-derived commensal organism, Bacteroides thetaiotaomicron, into the guts of germ-free mice to 1) determine whether the genetic requirements for colonization shift over time and, if so, 2) characterize the biological functions required for microbial survival at different points of colonization. The results of a high-throughput functional genetics assay (BarSeq), transcriptomics, and metabolomics converge on several conclusions. First, adaptation to the host gut occurs in distinct stages. We observed drastic changes in gene usage during the first week, shifting from high expression of amino acid biosynthesis to polysaccharide utilization genes. These changes were sustained thereafter, except for the continued upregulation of a single polysaccharide utilization locus responsible for the degradation of raffinose-family oligosaccharides rich in the standard chow diet fed to our mice. Spontaneous mutations in wildtype Bt also evolve around this locus, highlighting the importance of efficient carbohydrate metabolism in long-term persistence within a monoassociated gut. To improve microbiome-based therapies, it will be important to appreciate and meet the distinct needs of the organism during each stage of colonization.ImportanceMicrobes regularly disperse across and adapt to new environments and ecological niches. A clinically significant microbial niche home to trillions of microbes is the mammalian gut. Temporal processes of microbial adaptation over the course of gut colonization are poorly understood on a genetic, transcriptional, and metabolite level. In this study, we leverage a three-pronged approach to characterize gut colonization as a dynamic process with shifting genetic determinants of microbial fitness. This study sheds light on host colonization by Bacteroides thetaiotaomicron, an organism that is prevalent and dominant across healthy human microbiomes, and not only identifies key pathways involved in colonization, but determines the timing of when these pathways are most vital to colonization success. By demonstrating that the key determinants of colonization success in the gut change over time, the results of this study highlight the importance of considering ecological dynamics in developing more effective microbiome-based therapies.