Rapid genetic diversification of Bacteroides thetaiotaomicron in mono-associated mice revealed through deep population-level sequencing

Bacteria often feature short generation times and large populations, thereby allowing them to quickly evolve and adapt to new environments. Although it is known that gut bacteria can evolve on relatively short time scales, the extent of genetic diversification of bacteria in the gut environment remains underexplored. Here, we characterize the genetic diversification of the gut commensal Bacteroides thetaiotaomicron during 28 days of colonization of germ-free mice using deep shotgun sequencing as well as genome analysis of evolved isolates. We detect thousands of genetic polymorphisms as early as three days post inoculation and observe highly dynamic genetic diversity in the distal gut. We identify multiple haplotypes of a phase-variable polysaccharide utilization locus ( BT2260 - BT2268 ) and propose that phase variation may be an important mechanism for diversification and adaptation in the gut. In addition, we find evidence that hybrid two-component system ( HTCS) regulators are mutational hotspots. We identify multiple persistent and parallelly evolved genetic polymorphisms in genes, including the TonB-dependent transporter BT0867 - a homolog of BF3581 from the commensal colonization factor ( ccf ) in B. fragilis . Lastly, we find that the small intestine accumulated approximately 20 times more polymorphisms compared to the large intestine, highlighting overall the importance of studying spatiotemporal distribution of genetic variants. These results underscore the prevalence of rapid genetic diversification of gut bacteria, which may have important implications for adaptation as well as interactions in the microbiome and with the host.