Machine learning-coupled combinatorial mutagenesis enables resource-efficient engineering of CRISPR-Cas9 genome editor activities

Dawn G. L. Thean; Hoi Yee Chu; John H. C. Fong; Becky K. C. Chan; Peng Zhou; Cynthia C. S. Kwok; Yee Man Chan; Silvia Y. L. Mak; Gigi C. G. Choi; Joshua W. K. Ho; Zongli Zheng; Alan S. L. Wong

doi:10.1038/s41467-022-29874-5

Machine learning-coupled combinatorial mutagenesis enables resource-efficient engineering of CRISPR-Cas9 genome editor activities

Dawn G. L. Thean, Hoi Yee Chu, John H. C. Fong, Becky K. C. Chan, Peng Zhou, Cynthia C. S. Kwok, Yee Man Chan, Silvia Y. L. Mak, Gigi C. G. Choi, Joshua W. K. Ho, Zongli Zheng, Alan S. L. Wong^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

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Abstract

The genome-editing Cas9 protein uses multiple amino-acid residues to bind the target DNA. Considering only the residues in proximity to the target DNA as potential sites to optimise Cas9’s activity, the number of combinatorial variants to screen through is too massive for a wet-lab experiment. Here we generate and cross-validate ten in silico and experimental datasets of multi-domain combinatorial mutagenesis libraries for Cas9 engineering, and demonstrate that a machine learning-coupled engineering approach reduces the experimental screening burden by as high as 95% while enriching top-performing variants by ∼7.5-fold in comparison to the null model. Using this approach and followed by structure-guided engineering, we identify the N888R/A889Q variant conferring increased editing activity on the protospacer adjacent motif-relaxed KKH variant of Cas9 nuclease from Staphylococcus aureus (KKH-SaCas9) and its derived base editor in human cells. Our work validates a readily applicable workflow to enable resource-efficient high-throughput engineering of genome editor’s activity.

Original language	English
Article number	2219
Journal	Nature Communications
Volume	13
Online published	25 Apr 2022
DOIs	https://doi.org/10.1038/s41467-022-29874-5
Publication status	Published - 2022

Funding

This work was supported by the National Natural Science Foundation of China Excellent Young Scientists Fund (32022089), the Hong Kong Research Grants Council [17104619], and the Centre for Oncology and Immunology Limited under the Health@InnoHK Initiative funded by the Innovation and Technology Commission, The Government of Hong Kong SAR, China (to A.S.L.W.). A.S.L.W. is a Ming Wai Lau Centre for Reparative Medicine (MWLC) Associate Member, and this project was in part supported by the Ming Wai Lau Centre for Reparative Medicine Associate Member Programme. This work was also in part supported by AIR@InnoHK administered by Innovation and Technology Commission, The Government of Hong Kong SAR, China (to J.W.K.H.).

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This full text is made available under CC-BY 4.0. https://creativecommons.org/licenses/by/4.0/

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Thean, D. G. L., Chu, H. Y., Fong, J. H. C., Chan, B. K. C., Zhou, P., Kwok, C. C. S., Chan, Y. M., Mak, S. Y. L., Choi, G. C. G., Ho, J. W. K., Zheng, Z., & Wong, A. S. L. (2022). Machine learning-coupled combinatorial mutagenesis enables resource-efficient engineering of CRISPR-Cas9 genome editor activities. Nature Communications, 13, Article 2219. https://doi.org/10.1038/s41467-022-29874-5

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title = "Machine learning-coupled combinatorial mutagenesis enables resource-efficient engineering of CRISPR-Cas9 genome editor activities",

abstract = "The genome-editing Cas9 protein uses multiple amino-acid residues to bind the target DNA. Considering only the residues in proximity to the target DNA as potential sites to optimise Cas9{\textquoteright}s activity, the number of combinatorial variants to screen through is too massive for a wet-lab experiment. Here we generate and cross-validate ten in silico and experimental datasets of multi-domain combinatorial mutagenesis libraries for Cas9 engineering, and demonstrate that a machine learning-coupled engineering approach reduces the experimental screening burden by as high as 95% while enriching top-performing variants by ∼7.5-fold in comparison to the null model. Using this approach and followed by structure-guided engineering, we identify the N888R/A889Q variant conferring increased editing activity on the protospacer adjacent motif-relaxed KKH variant of Cas9 nuclease from Staphylococcus aureus (KKH-SaCas9) and its derived base editor in human cells. Our work validates a readily applicable workflow to enable resource-efficient high-throughput engineering of genome editor{\textquoteright}s activity.",

author = "Thean, {Dawn G. L.} and Chu, {Hoi Yee} and Fong, {John H. C.} and Chan, {Becky K. C.} and Peng Zhou and Kwok, {Cynthia C. S.} and Chan, {Yee Man} and Mak, {Silvia Y. L.} and Choi, {Gigi C. G.} and Ho, {Joshua W. K.} and Zongli Zheng and Wong, {Alan S. L.}",

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AU - Zhou, Peng

AU - Kwok, Cynthia C. S.

AU - Chan, Yee Man

AU - Mak, Silvia Y. L.

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AU - Ho, Joshua W. K.

AU - Zheng, Zongli

AU - Wong, Alan S. L.

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AB - The genome-editing Cas9 protein uses multiple amino-acid residues to bind the target DNA. Considering only the residues in proximity to the target DNA as potential sites to optimise Cas9’s activity, the number of combinatorial variants to screen through is too massive for a wet-lab experiment. Here we generate and cross-validate ten in silico and experimental datasets of multi-domain combinatorial mutagenesis libraries for Cas9 engineering, and demonstrate that a machine learning-coupled engineering approach reduces the experimental screening burden by as high as 95% while enriching top-performing variants by ∼7.5-fold in comparison to the null model. Using this approach and followed by structure-guided engineering, we identify the N888R/A889Q variant conferring increased editing activity on the protospacer adjacent motif-relaxed KKH variant of Cas9 nuclease from Staphylococcus aureus (KKH-SaCas9) and its derived base editor in human cells. Our work validates a readily applicable workflow to enable resource-efficient high-throughput engineering of genome editor’s activity.

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Machine learning-coupled combinatorial mutagenesis enables resource-efficient engineering of CRISPR-Cas9 genome editor activities

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