Journal Article10.1002/advs.202402918
MuToN Quantifies Binding Affinity Changes upon Protein Mutations by Geometric Deep Learning
Yongmei Hu,Zhi‐Ping Liu +1 more
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TL;DR: A geometric deep learning framework called MuToN is introduced for quantifying protein binding affinity change upon residue mutations, designed with geometric attention networks, and it captures changes in the protein binding interfaces of mutated complexes and assesses the allosteric effects of amino acids.
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Abstract: Abstract Assessing changes in protein–protein binding affinity due to mutations helps understanding a wide range of crucial biological processes within cells. Despite significant efforts to create accurate computational models, predicting how mutations affect affinity remains challenging due to the complexity of the biological mechanisms involved. In the present work, a geometric deep learning framework called MuToN is introduced for quantifying protein binding affinity change upon residue mutations. The method, designed with geometric attention networks, is mechanism‐aware. It captures changes in the protein binding interfaces of mutated complexes and assesses the allosteric effects of amino acids. Experimental results highlight MuToN's superiority compared to existing methods. Additionally, MuToN's flexibility and effectiveness are illustrated by its precise predictions of binding affinity changes between SARS‐CoV‐2 variants and the ACE2 complex.
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Citations
Linking Protein Stability to Pathogenicity: Predicting Clinical Significance of Single-Missense Mutations in Ocular Proteins Using Machine Learning
Iyad Majid,Yuri V. Sergeev +1 more
TL;DR: Researchers developed a machine learning program to predict the clinical significance of single-missense mutations in ocular proteins, revealing a strong link between pathogenic mutations and protein instability, particularly in alpha-helices and active sites.
MuToN Quantifies Binding Affinity Changes upon Protein Mutations by Geometric Deep Learning
Yongmei Hu,Zhi‐Ping Liu +1 more
TL;DR: A geometric deep learning framework called MuToN is introduced for quantifying protein binding affinity change upon residue mutations, designed with geometric attention networks, and it captures changes in the protein binding interfaces of mutated complexes and assesses the allosteric effects of amino acids.
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