Thermodynamics and H2 Transfer in a Methanogenic, Syntrophic Community

• Published in: PLoS computational biology Vol. 11; no. 7; p. e1004364
• Main Authors: Hamilton, Joshua J, Calixto Contreras, Montserrat, Reed, Jennifer L
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 01.07.2015; Public Library of Science (PLoS)
• Subjects: Computer Simulation; Deltaproteobacteria - metabolism; Energy Transfer - physiology; Hydrogen - metabolism; Methane - metabolism; Methanospirillum - metabolism; Microbial Consortia - physiology; Models, Biological; Symbiosis - physiology; Thermodynamics
• ISSN: 1553-7358; 1553-734X; 1553-7358
• DOI: 10.1371/journal.pcbi.1004364

Microorganisms in nature do not exist in isolation but rather interact with other species in their environment. Some microbes interact via syntrophic associations, in which the metabolic by-products of one species serve as nutrients for another. These associations sustain a variety of natural communities, including those involved in methanogenesis. In anaerobic syntrophic communities, energy is transferred from one species to another, either through direct contact and exchange of electrons, or through small molecule diffusion. Thermodynamics plays an important role in governing these interactions, as the oxidation reactions carried out by the first community member are only possible because degradation products are consumed by the second community member. This work presents the development and analysis of genome-scale network reconstructions of the bacterium Syntrophobacter fumaroxidans and the methanogenic archaeon Methanospirillum hungatei. The models were used to verify proposed mechanisms of ATP production within each species. We then identified additional constraints and the cellular objective function required to match experimental observations. The thermodynamic S. fumaroxidans model could not explain why S. fumaroxidans does not produce H2 in monoculture, indicating that current methods might not adequately estimate the thermodynamics, or that other cellular processes (e.g., regulation) play a role. We also developed a thermodynamic coculture model of the association between the organisms. The coculture model correctly predicted the exchange of both H2 and formate between the two species and suggested conditions under which H2 and formate produced by S. fumaroxidans would be fully consumed by M. hungatei.