Reinforcement Learning for Bioretrosynthesis

Mathilde Koch; Thomas Duigou; Jean-Loup Faulon

doi:10.1021/acssynbio.9b00447

Reinforcement Learning for Bioretrosynthesis

Mathilde Koch, Thomas Duigou, Jean-Loup Faulon

Chemical Biology and Biological Chemistry

Université Paris-Saclay

Research output: Contribution to journal › Article › peer-review

Abstract

Metabolic engineering aims to produce chemicals of interest from living organisms, to advance toward greener chemistry. Despite efforts, the research and development process is still long and costly, and efficient computational design tools are required to explore the chemical biosynthetic space. Here, we propose to explore the bioretrosynthesis space using an artificial intelligence based approach relying on the Monte Carlo Tree Search reinforcement learning method, guided by chemical similarity. We implement this method in RetroPath RL, an open-source and modular command line tool. We validate it on a golden data set of 20 manually curated experimental pathways as well as on a larger data set of 152 successful metabolic engineering projects. Moreover, we provide a novel feature that suggests potential media supplements to complement the enzymatic synthesis plan.

Original language	English
Journal	ACS Synthetic Biology
Early online date	16 Dec 2019
DOIs	https://doi.org/10.1021/acssynbio.9b00447
Publication status	Published - 2019

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10.1021/acssynbio.9b00447

Manchester Synthetic Biology Research Centre for Fine and Speciality Chemicals
Scrutton, N. (PI), Azapagic, A. (CoI), Balmer, A. (CoI), Barran, P. (CoI), Breitling, R. (CoI), Delneri, D. (CoI), Dixon, N. (CoI), Faulon, J.-L. (CoI), Flitsch, S. (CoI), Goble, C. (CoI), Goodacre, R. (CoI), Hay, S. (CoI), Kell, D. (CoI), Leys, D. (CoI), Lloyd, J. (CoI), Lockyer, N. (CoI), Martin, P. (CoI), Micklefield, J. (CoI), Munro, A. (CoI), Pedrosa Mendes, P. (CoI), Randles, S. (CoI), Salehi Yazdi, F. (CoI), Shapira, P. (CoI), Takano, E. (CoI), Turner, N. (CoI) & Winterburn, J. (CoI)
14/11/14 → 13/05/20
Project: Research

Cite this

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title = "Reinforcement Learning for Bioretrosynthesis",

abstract = "Metabolic engineering aims to produce chemicals of interest from living organisms, to advance toward greener chemistry. Despite efforts, the research and development process is still long and costly, and efficient computational design tools are required to explore the chemical biosynthetic space. Here, we propose to explore the bioretrosynthesis space using an artificial intelligence based approach relying on the Monte Carlo Tree Search reinforcement learning method, guided by chemical similarity. We implement this method in RetroPath RL, an open-source and modular command line tool. We validate it on a golden data set of 20 manually curated experimental pathways as well as on a larger data set of 152 successful metabolic engineering projects. Moreover, we provide a novel feature that suggests potential media supplements to complement the enzymatic synthesis plan.",

author = "Mathilde Koch and Thomas Duigou and Jean-Loup Faulon",

year = "2019",

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language = "English",

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AU - Koch, Mathilde

AU - Duigou, Thomas

AU - Faulon, Jean-Loup

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AB - Metabolic engineering aims to produce chemicals of interest from living organisms, to advance toward greener chemistry. Despite efforts, the research and development process is still long and costly, and efficient computational design tools are required to explore the chemical biosynthetic space. Here, we propose to explore the bioretrosynthesis space using an artificial intelligence based approach relying on the Monte Carlo Tree Search reinforcement learning method, guided by chemical similarity. We implement this method in RetroPath RL, an open-source and modular command line tool. We validate it on a golden data set of 20 manually curated experimental pathways as well as on a larger data set of 152 successful metabolic engineering projects. Moreover, we provide a novel feature that suggests potential media supplements to complement the enzymatic synthesis plan.

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DO - 10.1021/acssynbio.9b00447

M3 - Article

C2 - 31841626

SN - 2161-5063

JO - ACS Synthetic Biology

JF - ACS Synthetic Biology

ER -

Reinforcement Learning for Bioretrosynthesis

Abstract

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Manchester Synthetic Biology Research Centre for Fine and Speciality Chemicals

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