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Long-term homeostasis in microbial consortia via auxotrophic cross-feeding

Nicolas E. Grandel, Amanda M. Alexander, Xiao Peng, Caroline Palamountain, Razan N. Alnahhas, Andrew J. Hirning, Krešimir Josić́, Matthew R. Bennett

2025Nature Communications9 citationsDOIOpen Access PDF

Abstract

Synthetic microbial consortia are collections of multiple strains or species of engineered organisms living in a shared ecosystem. Because they can separate metabolic tasks among different strains, synthetic microbial consortia have applications in developing biomaterials, biomanufacturing, and biotherapeutics. However, synthetic consortia often require burdensome control mechanisms to ensure that consortia members remain at the correct proportions. Here, we present a simple method for controlling consortia proportions using cross-feeding in continuous auxotrophic co-culture. We use mutually auxotrophic E. coli with different essential gene deletions and regulate the growth rates of members of the consortium via cross-feeding of the missing nutrients in each strain. We demonstrate precise regulation of the proportions by exogenous addition of the missing nutrients. We also model the co-culture’s behavior using a system of ordinary differential equations that enable us to predict its response to changes in nutrient concentrations. Our work provides a powerful tool for consortia proportion control with minimal metabolic costs to the constituent strains. Synthetic microbial consortia are collections of strains which can segregate metabolic tasks for efficient use in biomaterials, biomanufacturing, and biotherapeutics. Here, the authors present a method to maintain and tune the ratio of two co-cultured bacterial strains via growth medium manipulation.

Topics & Concepts

AuxotrophyComputational biologySynthetic biologyBiologySystems biologyGeneMetabolic engineeringMetabolic pathwayBacteriaChemistryBiochemistryNutrientEscherichia coli ProteinsBiochemical engineeringMetabolic networkOrganismMicrobiologyComputer scienceWork (physics)BiotechnologyEscherichia coliMicrobial metabolismNutrient sensingMetabolismHomeostasisEssential nutrientRegulation of gene expressionModel organismMicrobial Metabolic Engineering and BioproductionGene Regulatory Network Analysis3D Printing in Biomedical Research