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Optimal protein production by a synthetic microbial consortium: coexistence, distribution of labor, and syntrophy
- 1.0583797 - BC 2024 RIV DE eng J - Journal Article
Martínez, Carlos - Cinquemani, E. - de Jong, H. - Gouze, J.
Optimal protein production by a synthetic microbial consortium: coexistence, distribution of labor, and syntrophy.
Journal of Mathematical Biology. Roč. 87, č. 1 (2023), č. článku 23. ISSN 0303-6812. E-ISSN 1432-1416
R&D Projects: GA MŠMT(CZ) EF18_053/0016982
Institutional support: RVO:60077344
Keywords : division-of-labor * Microbial consortia * Pareto optimality * Dynamical systems * Production of recombinant proteins
OECD category: Ecology
Impact factor: 2.2, year: 2023
Method of publishing: Open access
https://doi.org/10.1007/s00285-023-01935-3
The bacterium E. coli is widely used to produce recombinant proteins such as growth hormone and insulin. One inconvenience with E. coli cultures is the secretion of acetate through overflow metabolism. Acetate inhibits cell growth and represents a carbon diversion, which results in several negative effects on protein production. One way to overcome this problem is the use of a synthetic consortium of two different E. coli strains, one producing recombinant proteins and one reducing the acetate concentration. In this paper, we study a mathematical model of such a synthetic community in a chemostat where both strains are allowed to produce recombinant proteins. We give necessary and sufficient conditions for the existence of a coexistence equilibrium and show that it is unique. Based on this equilibrium, we define a multi-objective optimization problem for the maximization of two important bioprocess performance metrics, process yield and productivity. Solving numerically this problem, we find the best available trade-offs between the metrics. Under optimal operation of the mixed community, both strains must produce the protein of interest, and not only one (distribution instead of division of labor). Moreover, in this regime acetate secretion by one strain is necessary for the survival of the other (syntrophy). The results thus illustrate how complex multi-level dynamics shape the optimal production of recombinant proteins by synthetic microbial consortia.
Permanent Link: https://hdl.handle.net/11104/0351796
Number of the records: 1