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DeepMPF:基于多模态表示和元路径语义分析的深度学习框架,用于预测药物-靶标相互作用。

DeepMPF: deep learning framework for predicting drug-target interactions based on multi-modal representation with meta-path semantic analysis.

机构信息

School of Information Engineering, Xijing University, Xi'an, 710100, China.

School of Computer Science, Northwestern Polytechnical University, Xi'an, 710129, China.

出版信息

J Transl Med. 2023 Jan 25;21(1):48. doi: 10.1186/s12967-023-03876-3.

DOI:10.1186/s12967-023-03876-3
PMID:36698208
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9876420/
Abstract

BACKGROUND

Drug-target interaction (DTI) prediction has become a crucial prerequisite in drug design and drug discovery. However, the traditional biological experiment is time-consuming and expensive, as there are abundant complex interactions present in the large size of genomic and chemical spaces. For alleviating this phenomenon, plenty of computational methods are conducted to effectively complement biological experiments and narrow the search spaces into a preferred candidate domain. Whereas, most of the previous approaches cannot fully consider association behavior semantic information based on several schemas to represent complex the structure of heterogeneous biological networks. Additionally, the prediction of DTI based on single modalities cannot satisfy the demand for prediction accuracy.

METHODS

We propose a multi-modal representation framework of 'DeepMPF' based on meta-path semantic analysis, which effectively utilizes heterogeneous information to predict DTI. Specifically, we first construct protein-drug-disease heterogeneous networks composed of three entities. Then the feature information is obtained under three views, containing sequence modality, heterogeneous structure modality and similarity modality. We proposed six representative schemas of meta-path to preserve the high-order nonlinear structure and catch hidden structural information of the heterogeneous network. Finally, DeepMPF generates highly representative comprehensive feature descriptors and calculates the probability of interaction through joint learning.

RESULTS

To evaluate the predictive performance of DeepMPF, comparison experiments are conducted on four gold datasets. Our method can obtain competitive performance in all datasets. We also explore the influence of the different feature embedding dimensions, learning strategies and classification methods. Meaningfully, the drug repositioning experiments on COVID-19 and HIV demonstrate DeepMPF can be applied to solve problems in reality and help drug discovery. The further analysis of molecular docking experiments enhances the credibility of the drug candidates predicted by DeepMPF.

CONCLUSIONS

All the results demonstrate the effectively predictive capability of DeepMPF for drug-target interactions. It can be utilized as a useful tool to prescreen the most potential drug candidates for the protein. The web server of the DeepMPF predictor is freely available at http://120.77.11.78/DeepMPF/ , which can help relevant researchers to further study.

摘要

背景

药物-靶标相互作用(DTI)预测已成为药物设计和药物发现的关键前提。然而,传统的生物学实验既耗时又昂贵,因为在基因组和化学空间的大尺寸中存在丰富的复杂相互作用。为了缓解这种现象,大量的计算方法被用于有效地补充生物学实验,并将搜索空间缩小到首选候选域。然而,以前的大多数方法都不能充分考虑基于几个模式的关联行为语义信息来表示异构生物网络的复杂结构。此外,基于单一模态的 DTI 预测不能满足预测精度的要求。

方法

我们提出了一种基于元路径语义分析的“DeepMPF”多模态表示框架,该框架有效地利用异构信息来预测 DTI。具体来说,我们首先构建了由三个实体组成的蛋白质-药物-疾病异构网络。然后,在三个视图下获取特征信息,包括序列模态、异构结构模态和相似性模态。我们提出了六个具有代表性的元路径模式,以保留异构网络的高阶非线性结构并捕获隐藏的结构信息。最后,DeepMPF 生成高度代表性的综合特征描述符,并通过联合学习计算相互作用的概率。

结果

为了评估 DeepMPF 的预测性能,我们在四个金数据集上进行了对比实验。在所有数据集上,我们的方法都能获得有竞争力的性能。我们还探讨了不同特征嵌入维度、学习策略和分类方法的影响。有意义的是,COVID-19 和 HIV 的药物重定位实验表明,DeepMPF 可用于解决实际问题并帮助药物发现。分子对接实验的进一步分析增强了 DeepMPF 预测的药物候选物的可信度。

结论

所有结果都证明了 DeepMPF 对药物-靶标相互作用的有效预测能力。它可以作为一种有用的工具,用于对蛋白质的最有潜力的药物候选物进行预筛选。DeepMPF 预测器的网络服务器可在 http://120.77.11.78/DeepMPF/ 免费获得,可供相关研究人员进一步研究。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/83188b461f24/12967_2023_3876_Fig9_HTML.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/6a05fa4c534b/12967_2023_3876_Fig6_HTML.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/3b7b46c3cb6d/12967_2023_3876_Fig8_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/83188b461f24/12967_2023_3876_Fig9_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/1dd6ecb53d47/12967_2023_3876_Fig1_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/30cd4c495b7c/12967_2023_3876_Fig2_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/81147841a416/12967_2023_3876_Fig3_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/e289b0c5fa3d/12967_2023_3876_Fig4_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/06f4dfe0a3f4/12967_2023_3876_Fig5_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/6a05fa4c534b/12967_2023_3876_Fig6_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/b211233e7a7e/12967_2023_3876_Fig7_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/3b7b46c3cb6d/12967_2023_3876_Fig8_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cdb1/9878862/83188b461f24/12967_2023_3876_Fig9_HTML.jpg

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