Deep Docking: A Deep Learning Platform for Augmentation of Structure Based Drug Discovery

Overview

Journal ACS Cent Sci

Specialty Chemistry

Date 2020 Jul 2

PMID 32607441

Citations 105

Authors

Francesco Gentile

Vibudh Agrawal

Michael Hsing

Anh-Tien Ton

Fuqiang Ban

Ulf Norinder

Martin E Gleave

Artem Cherkasov

Affiliations

Soon will be listed here.

Abstract

Drug discovery is a rigorous process that requires billion dollars of investments and decades of research to bring a molecule "from bench to a bedside". While virtual docking can significantly accelerate the process of drug discovery, it ultimately lags the current rate of expansion of chemical databases that already exceed billions of molecular records. This recent surge of small molecules availability presents great drug discovery opportunities, but also demands much faster screening protocols. In order to address this challenge, we herein introduce Deep Docking (), a novel deep learning platform that is suitable for docking billions of molecular structures in a rapid, yet accurate fashion. The approach utilizes quantitative structure-activity relationship (QSAR) deep models trained on docking scores of subsets of a chemical library to approximate the docking outcome for yet unprocessed entries and, therefore, to remove unfavorable molecules in an iterative manner. The use of methodology in conjunction with the FRED docking program allowed rapid and accurate calculation of docking scores for 1.36 billion molecules from the ZINC15 library against 12 prominent target proteins and demonstrated up to 100-fold data reduction and 6000-fold enrichment of high scoring molecules (without notable loss of favorably docked entities). The protocol can readily be used in conjunction with any docking program and was made publicly available.

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