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Interpretable Deep-Learning p <i>K</i> <sub>a</sub> Prediction for Small Molecule Drugs via Atomic Sensitivity Analysis

Joseph A. DeCorte, Benjamin P. Brown, R. Brooke Jeffrey, Jens Meiler

2024Journal of Chemical Information and Modeling6 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Machine learning (ML) models now play a crucial role in predicting properties essential to drug development, such as a drug’s logscale acid-dissociation constant (p K a ). Despite recent architectural advances, these models often generalize poorly to novel compounds due to a scarcity of ground-truth data. Further, these models lack interpretability. To this end, with deliberate molecular embeddings, atomic-resolution information is accessible in chemical structures by observing the model response to atomic perturbations of an input molecule. Here, we present BCL-XpKa, a deep neural network (DNN)-based multitask classifier for p K a prediction that encodes local atomic environments through Mol2D descriptors. BCL-XpKa outputs a discrete distribution for each molecule, which stores the p K a prediction and the model’s uncertainty for that molecule. BCL-XpKa generalizes well to novel small molecules. BCL-XpKa performs competitively with modern ML p K a predictors, outperforms several models in generalization tasks, and accurately models the effects of common molecular modifications on a molecule’s ionizability. We then leverage BCL-XpKa’s granular descriptor set and distribution-centered output through atomic sensitivity analysis (ASA), which decomposes a molecule’s predicted p K a value into its respective atomic contributions without model retraining. ASA reveals that BCL-XpKa has implicitly learned high-resolution information about molecular substructures. We further demonstrate ASA’s utility in structure preparation for protein–ligand docking by identifying ionization sites in 93.2% and 87.8% of complex small molecule acids and bases. We then applied ASA with BCL-XpKa to identify and optimize the physicochemical liabilities of a recently published KRAS-degrading PROTAC.

Topics & Concepts

InterpretabilityVirtual screeningLeverage (statistics)Test setComputer scienceQuantitative structure–activity relationshipMolecular descriptorArtificial intelligenceMoleculeArtificial neural networkMachine learningClassifier (UML)Small moleculeBiological systemChemistryComputational chemistryMolecular dynamicsBiologyBiochemistryOrganic chemistryComputational Drug Discovery MethodsMachine Learning in Materials ScienceProtein Structure and Dynamics
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