Abstract
Given their recent switch to a vertically-transmitted intracellular lifestyle, the chemosynthetic bacteria associated with deep-sea vesicomyid clams are an excellent model system to study the processes underlying reductive genome evolution. In this study, we provide the first estimates of the relative contributions of drift, recombination and selection in shaping the ongoing reductive genome evolution in these symbionts. To do so, we compared the genomes of endosymbionts associated with 11 vesicomyid clam species to that of closely related free-living bacteria and their respective hosts’ mitochondria. Our investigation confirmed that neutral evolutionary processes were the dominant driver of reductive genome evolution in this group and highlighted the important role of horizontal gene transfer in mitigating genome erosion. Finally, a genome-wide screen for episodic positive selection across the symbiont phylogeny revealed the pervasive role of selective processes in maintaining symbiont functional integrity.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
In this version, we expand the scope of the manuscript to include comparisons with other symbionts and free-living bacteria.