Litcius/Paper detail

Baseline Model for Predicting Protein–Ligand Unbinding Kinetics through Machine Learning

Nurlybek Amangeldiuly, Dmitry S. Karlov, Maxim V. Fedorov

2020Journal of Chemical Information and Modeling32 citationsDOI

Abstract

Derivation of structure-kinetics relationships can help rational design and development of new small-molecule drug candidates with desired residence times. Efforts are now being directed toward the development of efficient computational methods. Currently, there is a lack of solid, high-throughput binding kinetics prediction approaches on bigger datasets. We present a prediction method for binding kinetics based on the machine learning analysis of protein-ligand structural features, which can serve as a baseline for more sophisticated methods utilizing molecular dynamics (MD). We showed that the random forest algorithm is capable of learning the protein binding site secondary structure and backbone/side-chain features to predict the binding kinetics of protein-ligand complexes but still with inferior performance to that of MD-based descriptor analysis. MD simulations had been applied to a limited number of targets and a series of ligands in terms of kinetics analysis, and we believe that the developed approach may guide new studies. The method was trained on a newly curated database of 501 protein-ligand unbinding rate constants, which can also be used for testing and training the binding kinetics prediction models.

Topics & Concepts

KineticsReceptor–ligand kineticsLigand (biochemistry)Computer scienceMolecular dynamicsBiological systemQuantitative structure–activity relationshipChemistryArtificial intelligenceMachine learningComputational chemistryPhysicsBiologyBiochemistryReceptorQuantum mechanicsComputational Drug Discovery MethodsProtein Structure and DynamicsRNA and protein synthesis mechanisms