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Strain design optimization using reinforcement learning

Author

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  • Maryam Sabzevari
  • Sandor Szedmak
  • Merja Penttilä
  • Paula Jouhten
  • Juho Rousu

Abstract

Engineered microbial cells present a sustainable alternative to fossil-based synthesis of chemicals and fuels. Cellular synthesis routes are readily assembled and introduced into microbial strains using state-of-the-art synthetic biology tools. However, the optimization of the strains required to reach industrially feasible production levels is far less efficient. It typically relies on trial-and-error leading into high uncertainty in total duration and cost. New techniques that can cope with the complexity and limited mechanistic knowledge of the cellular regulation are called for guiding the strain optimization.In this paper, we put forward a multi-agent reinforcement learning (MARL) approach that learns from experiments to tune the metabolic enzyme levels so that the production is improved. Our method is model-free and does not assume prior knowledge of the microbe’s metabolic network or its regulation. The multi-agent approach is well-suited to make use of parallel experiments such as multi-well plates commonly used for screening microbial strains.We demonstrate the method’s capabilities using the genome-scale kinetic model of Escherichia coli, k-ecoli457, as a surrogate for an in vivo cell behaviour in cultivation experiments. We investigate the method’s performance relevant for practical applicability in strain engineering i.e. the speed of convergence towards the optimum response, noise tolerance, and the statistical stability of the solutions found. We further evaluate the proposed MARL approach in improving L-tryptophan production by yeast Saccharomyces cerevisiae, using publicly available experimental data on the performance of a combinatorial strain library.Overall, our results show that multi-agent reinforcement learning is a promising approach for guiding the strain optimization beyond mechanistic knowledge, with the goal of faster and more reliably obtaining industrially attractive production levels.Author summary: Engineered microbial cells offer a sustainable alternative solution to chemical production from fossil resources. However, to make the chemical production using microbial cells economically feasible, they need to be substantially optimized. Due to the biological complexity, this optimization to reach sufficiently high production is typically a costly trial and error process.

Suggested Citation

  • Maryam Sabzevari & Sandor Szedmak & Merja Penttilä & Paula Jouhten & Juho Rousu, 2022. "Strain design optimization using reinforcement learning," PLOS Computational Biology, Public Library of Science, vol. 18(6), pages 1-18, June.
    • Handle: RePEc:plo:pcbi00:1010177
    DOI: 10.1371/journal.pcbi.1010177
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    1. Jie Zhang & Søren D. Petersen & Tijana Radivojevic & Andrés Ramirez & Andrés Pérez-Manríquez & Eduardo Abeliuk & Benjamín J. Sánchez & Zak Costello & Yu Chen & Michael J. Fero & Hector Garcia Martin &, 2020. "Combining mechanistic and machine learning models for predictive engineering and optimization of tryptophan metabolism," Nature Communications, Nature, vol. 11(1), pages 1-13, December.
    2. Tijana Radivojević & Zak Costello & Kenneth Workman & Hector Garcia Martin, 2020. "A machine learning Automated Recommendation Tool for synthetic biology," Nature Communications, Nature, vol. 11(1), pages 1-14, December.
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