EDC-DTI: An end-to-end deep collaborative learning model based on multiple information for drug-target interactions prediction

计算机科学 人工智能 特征(语言学) 编码器 分类器(UML) 端到端原则 深度学习 机器学习 稳健性(进化) 数据挖掘 哲学 语言学 生物化学 化学 基因 操作系统
作者
Yongna Yuan,Yuhao Zhang,Xiangbo Meng,Zhenyu Liu,Bohan Wang,Ruidong Miao,Ruisheng Zhang,Wei Su,Lei Liu
出处
期刊:Journal of Molecular Graphics & Modelling [Elsevier BV]
卷期号:122: 108498-108498 被引量:11
标识
DOI:10.1016/j.jmgm.2023.108498
摘要

Innovations in drug-target interactions (DTIs) prediction accelerate the progression of drug development. The introduction of deep learning models has a dramatic impact on DTIs prediction, with a distinct influence on saving time and money in drug discovery. This study develops an end-to-end deep collaborative learning model for DTIs prediction, called EDC-DTI, to identify new targets for existing drugs based on multiple drug-target-related information including homogeneous information and heterogeneous information by the way of deep learning. Our end-to-end model is composed of a feature builder and a classifier. Feature builder consists of two collaborative feature construction algorithms that extract the molecular properties and the topology property of networks, and the classifier consists of a feature encoder and a feature decoder which are designed for feature integration and DTIs prediction, respectively. The feature encoder, mainly based on the improved graph attention network, incorporates heterogeneous information into drug features and target features separately. The feature decoder is composed of multiple neural networks for predictions. Compared with six popular baseline models, EDC-DTI achieves highest predictive performance in the case of low computational costs. Robustness tests demonstrate that EDC-DTI is able to maintain strong predictive performance on sparse datasets. As well, we use the model to predict the most likely targets to interact with Simvastatin (DB00641), Nifedipine (DB01115) and Afatinib (DB08916) as examples. Results show that most of the predictions can be confirmed by literature with clear evidence.
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