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SQM2.20: Semiempirical quantum-mechanical scoring function yields DFT-quality protein–ligand binding affinity predictions in minutes

Adam Pecina, Jindřich Fanfrlík, Martin Lepšı́k, Jan Řezáč

2024Nature Communications42 citationsDOIOpen Access PDF

Abstract

Abstract Accurate estimation of protein–ligand binding affinity is the cornerstone of computer-aided drug design. We present a universal physics-based scoring function, named SQM2.20, addressing key terms of binding free energy using semiempirical quantum-mechanical computational methods. SQM2.20 incorporates the latest methodological advances while remaining computationally efficient even for systems with thousands of atoms. To validate it rigorously, we have compiled and made available the PL-REX benchmark dataset consisting of high-resolution crystal structures and reliable experimental affinities for ten diverse protein targets. Comparative assessments demonstrate that SQM2.20 outperforms other scoring methods and reaches a level of accuracy similar to much more expensive DFT calculations. In the PL-REX dataset, it achieves excellent correlation with experimental data (average R 2 = 0.69) and exhibits consistent performance across all targets. In contrast to DFT, SQM2.20 provides affinity predictions in minutes, making it suitable for practical applications in hit identification or lead optimization.

Topics & Concepts

Benchmark (surveying)Binding affinitiesComputer scienceProtein ligandAffinitiesFunction (biology)QuantumQuantum chemicalLigand (biochemistry)AlgorithmChemistryPhysicsQuantum mechanicsMoleculeBiologyReceptorStereochemistryEvolutionary biologyOrganic chemistryGeographyBiochemistryGeodesyComputational Drug Discovery MethodsProtein Structure and DynamicsRNA and protein synthesis mechanisms
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