Probing interspecies metabolic interactions within a synthetic binary microbiome using genome-scale modeling

Kiumars Badr; Q. Peter He; Jin Wang

doi:10.20517/mrr.2023.70

Microbiome Research Reports ›› 2024, Vol. 3 ›› Issue (3) :31 DOI: 10.20517/mrr.2023.70

Original Article

Probing interspecies metabolic interactions within a synthetic binary microbiome using genome-scale modeling

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Abstract

Aim: Metabolic interactions within a microbial community play a key role in determining the structure, function, and composition of the community. However, due to the complexity and intractability of natural microbiomes, limited knowledge is available on interspecies interactions within a community. In this work, using a binary synthetic microbiome, a methanotroph-photoautotroph (M-P) coculture, as the model system, we examined different genome-scale metabolic modeling (GEM) approaches to gain a better understanding of the metabolic interactions within the coculture, how they contribute to the enhanced growth observed in the coculture, and how they evolve over time.

Methods: Using batch growth data of the model M-P coculture, we compared three GEM approaches for microbial communities. Two of the methods are existing approaches: SteadyCom, a steady state GEM, and dynamic flux balance analysis (DFBA) Lab, a dynamic GEM. We also proposed an improved dynamic GEM approach, DynamiCom, for the M-P coculture.

Results: SteadyCom can predict the metabolic interactions within the coculture but not their dynamic evolutions; DFBA Lab can predict the dynamics of the coculture but cannot identify interspecies interactions. DynamiCom was able to identify the cross-fed metabolite within the coculture, as well as predict the evolution of the interspecies interactions over time.

Conclusion: A new dynamic GEM approach, DynamiCom, was developed for a model M-P coculture. Constrained by the predictions from a validated kinetic model, DynamiCom consistently predicted the top metabolites being exchanged in the M-P coculture, as well as the establishment of the mutualistic N-exchange between the methanotroph and cyanobacteria. The interspecies interactions and their dynamic evolution predicted by DynamiCom are supported by ample evidence in the literature on methanotroph, cyanobacteria, and other cyanobacteria-heterotroph cocultures.

Keywords

Synthetic microbiome / methanotroph-photoautotroph coculture / interspecies metabolic interactions / genome-scale metabolic modeling / steady state modeling / dynamic modeling

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Kiumars Badr, Q. Peter He, Jin Wang. Probing interspecies metabolic interactions within a synthetic binary microbiome using genome-scale modeling. Microbiome Research Reports, 2024, 3(3): 31 DOI:10.20517/mrr.2023.70

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