Microbial redox cycling enhances ecosystem thermodynamic efficiency and productivity

Microbial life in low-energy ecosystems relies on individual energy conservation, optimizing energy use in response to interspecific competition and mutualistic interspecific syntrophy. Our study proposes a novel community-level strategy for increasing energy use efficiency. By utilizing an oxidation-reduction (redox) reaction network model that represents microbial redox metabolic interactions, we investigated multiple species-level competition and cooperation within the network. Our results suggest that microbial functional diversity allows for metabolic handoffs, which in turn leads to increased energy use efficiency. Furthermore, the mutualistic division of labour and the resulting complexity of redox pathways actively drive material cycling, further promoting energy exploitation. Our findings reveal the potential of self-organized ecological interactions to develop efficient energy utilization strategies, with important implications for microbial ecosystem functioning and the co-evolution of life and Earth.

Automated summary

Microbial life in low-energy ecosystems relies on individual energy conservation and optimizing energy use in response to competition and mutualistic interactions. A new community-level strategy for increasing energy use efficiency is proposed, which involves microbial functional diversity and metabolic handoffs. The mutualistic division of labour and complexity of redox pathways promote material cycling and energy exploitation. These findings have important implications for microbial ecosystem functioning and the co-evolution of life and Earth.