Ensemble-based enzyme design can recapitulate the effects of laboratory directed evolution in silico

By Aron Broom, Rojo V. Rakotoharisoa, Michael Thompson1, Niayesh Zarifi, Erin Nguyen, Nurzhan Mukhametzhanov, Lin Liu, James Fraser2, Roberto A. Chica

1. University of California - San Francisco 2. University of California-San Francisco

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Type

journal-article

Author

Aron Broom and Rojo V. Rakotoharisoa and Michael C. Thompson and Niayesh Zarifi and Erin Nguyen and Nurzhan Mukhametzhanov and Lin Liu and James S. Fraser and Roberto A. Chica

Citation

Broom, A. et al., 2020. Ensemble-based enzyme design can recapitulate the effects of laboratory directed evolution in silico. Nature Communications, 11(1). Available at: http://dx.doi.org/10.1038/s41467-020-18619-x.

Abstract

Abstract The creation of artificial enzymes is a key objective of computational protein design. Although de novo enzymes have been successfully designed, these exhibit low catalytic efficiencies, requiring directed evolution to improve activity. Here, we use room-temperature X-ray crystallography to study changes in the conformational ensemble during evolution of the designed Kemp eliminase HG3 (kcat/KM 146 M−1s−1). We observe that catalytic residues are increasingly rigidified, the active site becomes better pre-organized, and its entrance is widened. Based on these observations, we engineer HG4, an efficient biocatalyst (kcat/KM 103,000 M−1s−1) containing key first and second-shell mutations found during evolution. HG4 structures reveal that its active site is pre-organized and rigidified for efficient catalysis. Our results show how directed evolution circumvents challenges inherent to enzyme design by shifting conformational ensembles to favor catalytically-productive sub-states, and suggest improvements to the design methodology that incorporate ensemble modeling of crystallographic data.

DOI

Funding

NSF-STC Biology with X-ray Lasers (NSF-1231306)