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RESEARCH PRODUCT

A genome-scale study of metabolic complementation in endosymbiotic consortia: the case of the cedar aphid

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AbstractBacterial endosymbionts and their insect hosts establish an intimate metabolic relationship. Bacteria offer a variety of essential nutrients to their hosts, whereas insect cells provide the necessary sources of matter and energy to their tiny metabolic allies. These nutritional complementations sustain themselves on a diversity of metabolite exchanges between the cell host and the reduced yet highly specialized bacterial metabolism –which, for instance, overproduces a small set of essential amino acids and vitamins. A well-known case of metabolic complementation is provided by the cedar aphidCinara cedrithat harbors two co-primary endosymbionts,Buchnera aphidicolaBCc andCa.Serratia symbiotica SCc, and in which some metabolic pathways are partitioned between different partners. Here we present a genome scale metabolic network (GEM) for the bacterial consortium from the cedar aphidiBSCc. The analysis of this GEM allows us the confirmation of cases of metabolic complementation previously described by genome analysis (i.e. tryptophan and biotin biosynthesis) and the proposal of a hitherto unnoticed event of metabolic pathway sharing between the two endosymbionts, namely the biosynthesis of tetrahydrofolate.In silicoknock-out experiments withiBSCc showed that the consortium metabolism is a highly integrated yet fragile network. We also have explored the evolutionary pathways leading to the emergence of metabolic complementation between reduced metabolisms starting from individual, complete networks. Our results suggest that, during the establishment of metabolic complementation in endosymbionts, adaptive evolution is more significant than previously thought.