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A flexible data-free framework for structure-based <i>de novo</i> drug design with reinforcement learning

Hongyan Du, Dejun Jiang, Odin Zhang, Zhenhua Wu, Junbo Gao, Xujun Zhang, Xiaorui Wang, Yafeng Deng, Yu Kang, Dan Li, Peichen Pan, Chang‐Yu Hsieh, Tingjun Hou

2023Chemical Science20 citationsDOIOpen Access PDF

Abstract

drug design. Distinct from prevailing atom-centric methods, 3D-MCTS employs a fragment-based molecular editing strategy. The fragments decomposed from small-molecule drugs are recombined under predefined retrosynthetic rules, offering improved drug-likeness and synthesizability, overcoming the inherent limitations of atom-based approaches. Leveraging multi-threaded parallel simulations combined with a real-time energy constraint-based pruning strategy, 3D-MCTS achieves remarkable efficiency. At a fixed computational cost, it outperforms other state-of-the-art (SOTA) methods by producing molecules with enhanced binding affinity. Furthermore, its fragment-based approach ensures the generation of more dependable binding conformations, exhibiting a success rate 43.6% higher than that of other SOTAs. This advantage becomes even more pronounced when handling targets that significantly deviate from the training dataset. 3D-MCTS is capable of achieving thirty times more hits with high binding affinity than traditional virtual screening methods, which demonstrates the superior ability of 3D-MCTS to explore chemical space. Moreover, the flexibility of our framework makes it easy to incorporate domain knowledge during the process, thereby enabling the generation of molecules with desirable pharmacophores and enhanced binding affinity. The adaptability of 3D-MCTS is further showcased in metalloprotein applications, highlighting its potential across various drug design scenarios.

Topics & Concepts

Reinforcement learningDrugReinforcementComputer scienceArtificial intelligencePsychologyPharmacologyMedicineSocial psychologyComputational Drug Discovery MethodsReceptor Mechanisms and SignalingProtein Structure and Dynamics
A flexible data-free framework for structure-based <i>de novo</i> drug design with reinforcement learning | Litcius