Simulating the evolutionary trajectories of metabolic pathways for insect symbionts in the Sodalis genus

Abstract

1AbstractInsect-bacterial symbioses are ubiquitous, but there is still much to uncover about how these relationships establish, persist and evolve. The tsetse endosymbiont Sodalis glossinidius displays intriguing metabolic adaptations to its microenvironment, but the process by which this relationship evolved remains to be elucidated. The recent chance discovery of the free-living secies of the Sodalis genus, S. praecaptivus, provides a serendipitous starting point from which to investigate the evolution of this symbiosis. Here, we present a flux balance model for S. praecaptivus. Metabolic modelling is used in combination with a multi-objective evolutionary algorithm to explore the trajectories that S. glossinidius may have undertaken after becoming internalised. The time-dependent loss of key genes is shown to influence the evolved populations, providing possible targets for future in vitro genetic manipulation. This method provides an unusually detailed perspective on possible evolutionary trajectories for S. glossinidius in this fundamental process of evolutionary and ecological change.