Machine Learning‐Guided Computational Screening of New Candidate Reactions with High Bioorthogonal Click Potential

Author(s)

Stuyver, Thijs; Coley, Connor W

Abstract

Bioorthogonal click chemistry has become an indispensable part of the biochemist's toolbox. Despite the wide variety of applications that have been developed in recent years, only a limited number of bioorthogonal click reactions have been discovered so far, most of them based on (substituted) azides. In this work, we present a computational workflow to discover new candidate reactions with promising kinetic and thermodynamic properties for bioorthogonal click applications. Sampling only around 0.05 % of an overall search space of over 10,000,000 dipolar cycloadditions, we develop a machine learning model able to predict DFT‐computed activation and reaction energies within ∼2–3 kcal/mol across the entire space. Applying this model to screen the full search space through iterative rounds of learning, we identify a broad pool of candidate reactions with rich structural diversity, which can be used as a starting point or source of inspiration for future experimental development of both azide‐based and non‐azide‐based bioorthogonal click reactions.

Date issued

2023-05-16

URI

https://hdl.handle.net/1721.1/158191

Department

Massachusetts Institute of Technology. Department of Chemical Engineering
Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science

Journal

Chemistry – A European Journal

Publisher

Wiley

Citation

T. Stuyver, C. W. Coley, Chem. Eur. J. 2023, 29, e202300387.

Version: Final published version