Three-Dimensional Convolutional Neural Networks and a Cross-Docked Data Set for Structure-Based Drug Design

One of the main challenges in drug discovery is predicting protein–ligand binding affinity. Recently, machine learning approaches have made substantial progress on this task. However, current methods of model evaluation are overly optimistic in measuring generalization to new targets, and there does...

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Bibliographic Details
Published in:Journal of chemical information and modeling 2020-09, Vol.60 (9), p.4200-4215
Main Authors: Francoeur, Paul G, Masuda, Tomohide, Sunseri, Jocelyn, Jia, Andrew, Iovanisci, Richard B, Snyder, Ian, Koes, David R
Format: Article
Language:English
Subjects:
Affinity
Artificial neural networks
Binding
Databases, Protein
Datasets
Drug Design
Ligands
Logistics
Machine learning
Machine Learning and Deep Learning
Neural networks
Neural Networks, Computer
Protein Binding
Proteins
Standard data
Target recognition
Training
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Summary:One of the main challenges in drug discovery is predicting protein–ligand binding affinity. Recently, machine learning approaches have made substantial progress on this task. However, current methods of model evaluation are overly optimistic in measuring generalization to new targets, and there does not exist a standard data set of sufficient size to compare performance between models. We present a new data set for structure-based machine learning, the CrossDocked2020 set, with 22.5 million poses of ligands docked into multiple similar binding pockets across the Protein Data Bank, and perform a comprehensive evaluation of grid-based convolutional neural network (CNN) models on this data set. We also demonstrate how the partitioning of the training data and test data can impact the results of models trained with the PDBbind data set, how performance improves by adding more lower-quality training data, and how training with docked poses imparts pose sensitivity to the predicted affinity of a complex. Our best performing model, an ensemble of five densely connected CNNs, achieves a root mean squared error of 1.42 and Pearson R of 0.612 on the affinity prediction task, an AUC of 0.956 at binding pose classification, and a 68.4% accuracy at pose selection on the CrossDocked2020 set. By providing data splits for clustered cross-validation and the raw data for the CrossDocked2020 set, we establish the first standardized data set for training machine learning models to recognize ligands in noncognate target structures while also greatly expanding the number of poses available for training. In order to facilitate community adoption of this data set for benchmarking protein–ligand binding affinity prediction, we provide our models, weights, and the CrossDocked2020 set at https://github.com/gnina/models.
ISSN:1549-9596
1549-960X
1549-960X
DOI:10.1021/acs.jcim.0c00411