Graph-DTI: A New Model for Drug-target Interaction Prediction Based on Heterogenous Network Graph Embedding.

IF 1.5 4区 医学 Q4 CHEMISTRY, MEDICINAL
Xiaohan Qu, Guoxia Du, Jing Hu, Yongming Cai
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引用次数: 0

Abstract

Background: In this study, we aimed to develop a new end-to-end learning model called Graph-Drug-Target Interaction (DTI), which integrates various types of information in the heterogeneous network data, and to explore automatic learning of the topology-maintaining representations of drugs and targets, thereby effectively contributing to the prediction of DTI. Precise predictions of DTI can guide drug discovery and development. Most machine learning algorithms integrate multiple data sources and combine them with common embedding methods. However, the relationship between the drugs and target proteins is not well reported. Although some existing studies have used heterogeneous network graphs for DTI prediction, there are many limitations in the neighborhood information between the nodes in the heterogeneous network graphs. We studied the drug-drug interaction (DDI) and DTI from DrugBank Version 3.0, protein-protein interaction (PPI) from the human protein reference database Release 9, drug structure similarity from Morgan fingerprints of radius 2 and calculated by RDKit, and protein sequence similarity from Smith-Waterman score.

Methods: Our study consists of three major components. First, various drugs and target proteins were integrated, and a heterogeneous network was established based on a series of data sets. Second, the graph neural networks-inspired graph auto-encoding method was used to extract high-order structural information from the heterogeneous networks, thereby revealing the description of nodes (drugs and proteins) and their topological neighbors. Finally, potential DTI prediction was made, and the obtained samples were sent to the classifier for secondary classification.

Results: The performance of Graph-DTI and all baseline methods was evaluated using the sums of the area under the precision-recall curve (AUPR) and the area under the receiver operating characteristic curve (AUC). The results indicated that Graph-DTI outperformed the baseline methods in both performance results.

Conclusion: Compared with other baseline DTI prediction methods, the results showed that Graph-DTI had better prediction performance. Additionally, in this study, we effectively classified drugs corresponding to different targets and vice versa. The above findings showed that Graph-DTI provided a powerful tool for drug research, development, and repositioning. Graph- DTI can serve as a drug development and repositioning tool more effectively than previous studies that did not use heterogeneous network graph embedding.

Graph-DTI:基于异质网络图嵌入的药物靶点相互作用预测新模型。
研究背景本研究旨在开发一种新的端到端学习模型--"图-药物-靶点相互作用(DTI)",该模型整合了异构网络数据中的各类信息,并探索自动学习药物和靶点的拓扑保持表征,从而有效促进 DTI 的预测。对 DTI 的精确预测可以指导药物发现和开发。大多数机器学习算法都会整合多个数据源,并结合常用的嵌入方法。然而,有关药物与靶蛋白之间关系的报道并不多。虽然已有研究利用异构网络图进行 DTI 预测,但异构网络图中节点之间的邻域信息存在很多局限性。我们研究了DrugBank 3.0版中的药物相互作用(DDI)和DTI、人类蛋白质参考数据库第9版中的蛋白质相互作用(PPI)、RDKit计算的半径为2的摩根指纹中的药物结构相似性以及Smith-Waterman评分中的蛋白质序列相似性:我们的研究包括三个主要部分。首先,整合了各种药物和靶蛋白,并基于一系列数据集建立了异构网络。其次,利用图神经网络启发的图自动编码方法从异构网络中提取高阶结构信息,从而揭示节点(药物和蛋白质)及其拓扑邻域的描述。最后,进行潜在的 DTI 预测,并将获得的样本发送给分类器进行二次分类:使用精确度-召回曲线下面积(AUPR)和接收者工作特征曲线下面积(AUC)的总和评估了 Graph-DTI 和所有基线方法的性能。结果表明,Graph-DTI 在这两项性能结果上都优于基线方法:结论:与其他基线 DTI 预测方法相比,结果表明 Graph-DTI 具有更好的预测性能。此外,在这项研究中,我们有效地对不同目标对应的药物进行了分类,反之亦然。上述研究结果表明,Graph-DTI 为药物研究、开发和重新定位提供了强有力的工具。与之前没有使用异构网络图嵌入的研究相比,Graph- DTI 可以更有效地作为药物研发和重新定位的工具。
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来源期刊
Current computer-aided drug design
Current computer-aided drug design 医学-计算机:跨学科应用
CiteScore
3.70
自引率
5.90%
发文量
46
审稿时长
>12 weeks
期刊介绍: Aims & Scope Current Computer-Aided Drug Design aims to publish all the latest developments in drug design based on computational techniques. The field of computer-aided drug design has had extensive impact in the area of drug design. Current Computer-Aided Drug Design is an essential journal for all medicinal chemists who wish to be kept informed and up-to-date with all the latest and important developments in computer-aided methodologies and their applications in drug discovery. Each issue contains a series of timely, in-depth reviews, original research articles and letter articles written by leaders in the field, covering a range of computational techniques for drug design, screening, ADME studies, theoretical chemistry; computational chemistry; computer and molecular graphics; molecular modeling; protein engineering; drug design; expert systems; general structure-property relationships; molecular dynamics; chemical database development and usage etc., providing excellent rationales for drug development.
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