Abstract
Surveys of microbial communities (metagenomics) or isolate genomes have revealed sequence-discrete species. That is, members of the same species usually show >95% Average Nucleotide Identity (ANI) of shared genes among themselves vs. <83% ANI to members of other species while genome pairs showing between 83-95% ANI are comparatively rare. In these surveys, aquatic bacteria of the ubiquitous SAR11 clade (Class Alphaproteobacteria), which play a major role in carbon cycling, are an outlier and often do not exhibit discrete species boundaries, suggesting the potential for alternate modes of genetic differentiation. To explore evolution in SAR11, we analyzed high-quality, single-cell amplified genomes (SAGs) and companion metagenomes from an oxygen minimum zone (OMZ) in the Eastern Tropical Pacific Ocean, where the SAR11 make up ~20% of the total microbial community. Our results show that SAR11 do form several sequence-discrete species, but their ANI range of discreteness is shifted to lower identities between 86-91%, with intra-species ANI ranging between 91-100%. Measuring recent gene exchange among these genomes based on a newly developed methodology revealed higher frequency of homologous recombination within compared to between species that affects sequence evolution at least twice as much as diversifying point mutation across the genome. Recombination in SAR-11 appears to be more promiscuous compared to other prokaryotic species and has facilitated the spreading of adaptive mutations within the species, further promoting the high intra-species diversity observed. These results implicate rampant, genome-wide homologous recombination as the mechanism that underlies the evolution of SAR11 into discrete species.
Competing Interest Statement
The authors have declared no competing interest.