Alignment-based Protein Mutational Landscape Prediction: Doing More with Less

Marina Abakarova; Céline Marquet; Michael Rera; Burkhard Rost; Elodie Laine

doi:10.1093/gbe/evad201

Alignment-based Protein Mutational Landscape Prediction: Doing More with Less

Marina Abakarova, Céline Marquet, Michael Rera, Burkhard Rost, Elodie Laine

Informatik 12 - Lehrstuhl für Bioinformatik

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

7 Zitate (Scopus)

Abstract

The wealth of genomic data has boosted the development of computational methods predicting the phenotypic outcomes of missense variants. The most accurate ones exploit multiple sequence alignments, which can be costly to generate. Recent efforts for democratizing protein structure prediction have overcome this bottleneck by leveraging the fast homology search of MMseqs2. Here, we show the usefulness of this strategy for mutational outcome prediction through a large-scale assessment of 1.5M missense variants across 72 protein families. Our study demonstrates the feasibility of producing alignment-based mutational landscape predictions that are both high-quality and compute-efficient for entire proteomes. We provide the community with the whole human proteome mutational landscape and simplified access to our predictive pipeline.

Originalsprache	Englisch
Aufsatznummer	evad201
Fachzeitschrift	Genome Biology and Evolution
Jahrgang	15
Ausgabenummer	11
DOIs	https://doi.org/10.1093/gbe/evad201
Publikationsstatus	Veröffentlicht - 1 Nov. 2023

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abstract = "The wealth of genomic data has boosted the development of computational methods predicting the phenotypic outcomes of missense variants. The most accurate ones exploit multiple sequence alignments, which can be costly to generate. Recent efforts for democratizing protein structure prediction have overcome this bottleneck by leveraging the fast homology search of MMseqs2. Here, we show the usefulness of this strategy for mutational outcome prediction through a large-scale assessment of 1.5M missense variants across 72 protein families. Our study demonstrates the feasibility of producing alignment-based mutational landscape predictions that are both high-quality and compute-efficient for entire proteomes. We provide the community with the whole human proteome mutational landscape and simplified access to our predictive pipeline.",

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AU - Abakarova, Marina

AU - Marquet, Céline

AU - Rera, Michael

AU - Rost, Burkhard

AU - Laine, Elodie

N1 - Publisher Copyright: © The Author(s) 2023. Published by Oxford University Press on behalf of Society for Molecular Biology and Evolution.

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N2 - The wealth of genomic data has boosted the development of computational methods predicting the phenotypic outcomes of missense variants. The most accurate ones exploit multiple sequence alignments, which can be costly to generate. Recent efforts for democratizing protein structure prediction have overcome this bottleneck by leveraging the fast homology search of MMseqs2. Here, we show the usefulness of this strategy for mutational outcome prediction through a large-scale assessment of 1.5M missense variants across 72 protein families. Our study demonstrates the feasibility of producing alignment-based mutational landscape predictions that are both high-quality and compute-efficient for entire proteomes. We provide the community with the whole human proteome mutational landscape and simplified access to our predictive pipeline.

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KW - evolution

KW - genotype-phenotype relationship

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Alignment-based Protein Mutational Landscape Prediction: Doing More with Less

Abstract

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