Simultaneous design of fermentation and microbe

Ziegler, Anita L.; Manchanda, Ashutosh; Stumm, Marc-Daniel; Blank, Lars M.; Mitsos, Alexander

doi:10.48550/ARXIV.2401.16188

Preprint

FZJ-2024-03067

Simultaneous design of fermentation and microbe

Ziegler, A. L.RWTH* ; Manchanda, A.RWTH* ; Stumm, M.-D.RWTH* ; Blank, L. M.RWTH* ; Mitsos, A. (Corresponding author)FZJ*RWTH*

2024
arXiv

arXiv (2024) [10.48550/ARXIV.2401.16188]

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Please use a persistent id in citations: doi:10.48550/ARXIV.2401.16188 doi:10.34734/FZJ-2024-03067

Abstract: Constraint-based optimization of microbial strains and model-based bioprocess design have been used extensively to enhance yields in biotechnological processes. However, strain and process optimization are usually carried out in sequential steps, causing underperformance of the biotechnological process when scaling up to industrial fermentation conditions. Herein, we propose the optimization formulation SimulKnock that combines the optimization of a fermentation process with metabolic network design in a bilevel optimization program. The upper level maximizes space-time yield and includes mass balances of a continuous fermentation, while the lower level is based on flux balance analysis. SimulKnock predicts optimal gene deletions and finds the optimal trade-off between growth rate and product yield. Results of a case study with a genome-scale metabolic model of E. coli indicate higher space-time yields than a sequential approach using OptKnock for almost all target products considered. By leveraging SimulKnock, we reduce the gap between strain and process optimization.

Keyword(s): Optimization and Control (math.OC) ; FOS: Mathematics

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