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MTMol-GPT: De novo multi-target molecular generation with transformer-based generative adversarial imitation learning

计算机科学 药效团 药物发现 人工智能 药物靶点 概化理论 生成语法 强化学习 鉴别器 机器学习 计算生物学 生物信息学 生物 药理学 统计 探测器 电信 数学
作者
Chengwei Ai,Hongpeng Yang,Xiaoyi Liu,Ruihan Dong,Yijie Ding,Fei Guo
出处
期刊:PLOS Computational Biology [Public Library of Science]
卷期号:20 (6): e1012229-e1012229 被引量:35
标识
DOI:10.1371/journal.pcbi.1012229
摘要

De novo drug design is crucial in advancing drug discovery, which aims to generate new drugs with specific pharmacological properties. Recently, deep generative models have achieved inspiring progress in generating drug-like compounds. However, the models prioritize a single target drug generation for pharmacological intervention, neglecting the complicated inherent mechanisms of diseases, and influenced by multiple factors. Consequently, developing novel multi-target drugs that simultaneously target specific targets can enhance anti-tumor efficacy and address issues related to resistance mechanisms. To address this issue and inspired by Generative Pre-trained Transformers (GPT) models, we propose an upgraded GPT model with generative adversarial imitation learning for multi-target molecular generation called MTMol-GPT. The multi-target molecular generator employs a dual discriminator model using the Inverse Reinforcement Learning (IRL) method for a concurrently multi-target molecular generation. Extensive results show that MTMol-GPT generates various valid, novel, and effective multi-target molecules for various complex diseases, demonstrating robustness and generalization capability. In addition, molecular docking and pharmacophore mapping experiments demonstrate the drug-likeness properties and effectiveness of generated molecules potentially improve neuropsychiatric interventions. Furthermore, our model’s generalizability is exemplified by a case study focusing on the multi-targeted drug design for breast cancer. As a broadly applicable solution for multiple targets, MTMol-GPT provides new insight into future directions to enhance potential complex disease therapeutics by generating high-quality multi-target molecules in drug discovery.
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