Litcius/Paper detail

Water Network-Augmented Two-State Model for Protein–Ligand Binding Affinity Prediction

Xiaoyang Qu, Lina Dong, Ding Luo, Yubing Si, Binju Wang

2023Journal of Chemical Information and Modeling15 citationsDOI

Abstract

Water network rearrangement from the ligand-unbound state to the ligand-bound state is known to have significant effects on the protein-ligand binding interactions, but most of the current machine learning-based scoring functions overlook these effects. In this study, we endeavor to construct a comprehensive and realistic deep learning model by incorporating water network information into both ligand-unbound and -bound states. In particular, extended connectivity interaction features were integrated into graph representation, and graph transformer operator was employed to extract features of the ligand-unbound and -bound states. Through these efforts, we developed a water network-augmented two-state model called ECIFGraph::HM-Holo-Apo. Our new model exhibits satisfactory performance in terms of scoring, ranking, docking, screening, and reverse screening power tests on the CASF-2016 benchmark. In addition, it can achieve superior performance in large-scale docking-based virtual screening tests on the DEKOIS2.0 data set. Our study highlights that the use of a water network-augmented two-state model can be an effective strategy to bolster the robustness and applicability of machine learning-based scoring functions, particularly for targets with hydrophilic or solvent-exposed binding pockets.

Topics & Concepts

Virtual screeningComputer scienceArtificial intelligenceRobustness (evolution)Machine learningGraphLigand (biochemistry)Docking (animal)Drug discoveryTheoretical computer scienceChemistryReceptorNursingGeneMedicineBiochemistryComputational Drug Discovery MethodsMachine Learning in Materials ScienceProtein Structure and Dynamics