Mechanistic model of nutrient uptake explains dichotomy between marine oligotrophic and copiotrophic bacteria

Abstract

AbstractMarine heterotrophic bacteria use a spectrum of nutrient uptake strategies, from that of copiotrophs—which dominate in nutrient-rich environments—to that of oligotrophs—which dominate in nutrient-poor environments. While copiotrophs possess numerous phosphotransferase systems (PTS), oligotrophs lack PTS and rely on ATP-binding cassette (ABC) transporters, which use binding proteins. Here we present a molecular-level model that explains the dichotomy between oligotrophs and copiotrophs as the consequence of trade-offs between PTS and ABC transport. When we approximate ABC transport in Michaelis–Menten form, we find, contrary to the canonical formulation, that its half-saturation concentration KM is not a constant but instead a function of binding protein abundance. Thus, oligotrophs can attain nanomolar KM values using binding proteins with micromolar dissociation constants and while closely matching transport and metabolic capacities. However, this requires large periplasms and high abundances of binding proteins, whose slow diffusion limits uptake rate. We conclude that the use of binding proteins is critical for oligotrophic survival yet severely constrains maximal growth rates, thus fundamentally shaping the divergent evolution of oligotrophs and copiotrophs.