Discovery of novel gain-of-function mutations guided by structure-based deep learning

Raghav Shroff; Austin W. Cole; Daniel J. Diaz; Barrett R. Morrow; Isaac Donnell; Ankur Annapareddy; Jimmy Gollihar; Andrew D. Ellington; Ross Thyer

doi:10.1021/acssynbio.0c00345

Discovery of novel gain-of-function mutations guided by structure-based deep learning

Raghav Shroff, Austin W. Cole, Daniel J. Diaz, Barrett R. Morrow, Isaac Donnell, Ankur Annapareddy, Jimmy Gollihar, Andrew D. Ellington, Ross Thyer

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

48 Scopus citations

Abstract

Despite the promise of deep learning accelerated protein engineering, examples of such improved proteins are scarce. Here we report that a 3D convolutional neural network trained to associate amino acids with neighboring chemical microenvironments can guide identification of novel gain-of-function mutations that are not predicted by energetics-based approaches. Amalgamation of these mutations improved protein function in vivo across three diverse proteins by at least 5-fold. Furthermore, this model provides a means to interrogate the chemical space within protein microenvironments and identify specific chemical interactions that contribute to the gain-of-function phenotypes resulting from individual mutations.

Original language	English (US)
Pages (from-to)	2927-2935
Number of pages	9
Journal	ACS Synthetic Biology
Volume	9
Issue number	11
DOIs	https://doi.org/10.1021/acssynbio.0c00345
State	Published - Nov 20 2020

Keywords

Computational protein design
Machine learning
Neural networks
Protein engineering

ASJC Scopus subject areas

Biomedical Engineering
Biochemistry, Genetics and Molecular Biology (miscellaneous)

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10.1021/acssynbio.0c00345

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title = "Discovery of novel gain-of-function mutations guided by structure-based deep learning",

abstract = "Despite the promise of deep learning accelerated protein engineering, examples of such improved proteins are scarce. Here we report that a 3D convolutional neural network trained to associate amino acids with neighboring chemical microenvironments can guide identification of novel gain-of-function mutations that are not predicted by energetics-based approaches. Amalgamation of these mutations improved protein function in vivo across three diverse proteins by at least 5-fold. Furthermore, this model provides a means to interrogate the chemical space within protein microenvironments and identify specific chemical interactions that contribute to the gain-of-function phenotypes resulting from individual mutations.",

keywords = "Computational protein design, Machine learning, Neural networks, Protein engineering",

author = "Raghav Shroff and Cole, {Austin W.} and Diaz, {Daniel J.} and Morrow, {Barrett R.} and Isaac Donnell and Ankur Annapareddy and Jimmy Gollihar and Ellington, {Andrew D.} and Ross Thyer",

note = "Funding Information: Funding from the Welch Foundation (F-1654), the ARO (SP0036191-PROJ0009952 via MURI), and the NSF (1541244) is acknowledged. Publisher Copyright: {\textcopyright} 2020 American Chemical Society",

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doi = "10.1021/acssynbio.0c00345",

language = "English (US)",

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AU - Diaz, Daniel J.

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AU - Donnell, Isaac

AU - Annapareddy, Ankur

AU - Gollihar, Jimmy

AU - Ellington, Andrew D.

AU - Thyer, Ross

N1 - Funding Information: Funding from the Welch Foundation (F-1654), the ARO (SP0036191-PROJ0009952 via MURI), and the NSF (1541244) is acknowledged. Publisher Copyright: © 2020 American Chemical Society

PY - 2020/11/20

Y1 - 2020/11/20

N2 - Despite the promise of deep learning accelerated protein engineering, examples of such improved proteins are scarce. Here we report that a 3D convolutional neural network trained to associate amino acids with neighboring chemical microenvironments can guide identification of novel gain-of-function mutations that are not predicted by energetics-based approaches. Amalgamation of these mutations improved protein function in vivo across three diverse proteins by at least 5-fold. Furthermore, this model provides a means to interrogate the chemical space within protein microenvironments and identify specific chemical interactions that contribute to the gain-of-function phenotypes resulting from individual mutations.

AB - Despite the promise of deep learning accelerated protein engineering, examples of such improved proteins are scarce. Here we report that a 3D convolutional neural network trained to associate amino acids with neighboring chemical microenvironments can guide identification of novel gain-of-function mutations that are not predicted by energetics-based approaches. Amalgamation of these mutations improved protein function in vivo across three diverse proteins by at least 5-fold. Furthermore, this model provides a means to interrogate the chemical space within protein microenvironments and identify specific chemical interactions that contribute to the gain-of-function phenotypes resulting from individual mutations.

KW - Computational protein design

KW - Machine learning

KW - Neural networks

KW - Protein engineering

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Discovery of novel gain-of-function mutations guided by structure-based deep learning

Abstract

Keywords

ASJC Scopus subject areas

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