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Machine learning accelerates pharmacophore-based virtual screening of MAO inhibitors

Marcin Cieślak, Tomasz Danel, Olga Krzysztyńska‐Kuleta, Justyna Kalinowska‐Tłuścik

2024Scientific Reports15 citationsDOIOpen Access PDF

Abstract

Nowadays, an efficient and robust virtual screening procedure is crucial in the drug discovery process, especially when performed on large and chemically diverse databases. Virtual screening methods, like molecular docking and classic QSAR models, are limited in their ability to handle vast numbers of compounds and to learn from scarce data, respectively. In this study, we introduce a universal methodology that uses a machine learning-based approach to predict docking scores without the need for time-consuming molecular docking procedures. The developed protocol yielded 1000 times faster binding energy predictions than classical docking-based screening. The proposed predictive model learns from docking results, allowing users to choose their preferred docking software without relying on insufficient and incoherent experimental activity data. The methodology described employs multiple types of molecular fingerprints and descriptors to construct an ensemble model that further reduces prediction errors and is capable of delivering highly precise docking score values for monoamine oxidase ligands, enabling faster identification of promising compounds. An extensive pharmacophore-constrained screening of the ZINC database resulted in a selection of 24 compounds that were synthesized and evaluated for their biological activity. A preliminary screen discovered weak inhibitors of MAO-A with a percentage efficiency index close to a known drug at the lowest tested concentration. The approach presented here can be successfully applied to other biological targets as target-specific knowledge is not incorporated at the screening phase.

Topics & Concepts

PharmacophoreVirtual screeningComputer scienceDocking (animal)Machine learningChemical databaseDrug discoveryQuantitative structure–activity relationshipArtificial intelligenceProtein–ligand dockingComputational biologyData miningChemistryBioinformaticsStereochemistryBiologyMedicineNursingComputational Drug Discovery MethodsAdvanced Biosensing Techniques and ApplicationsMachine Learning in Materials Science