NPI-DCGNN: An Accurate Tool for Identifying ncRNA-Protein Interactions Using a Dual-Channel Graph Neural Network.

IF 1.4 4区 生物学 Q4 BIOCHEMICAL RESEARCH METHODS Journal of Computational Biology Pub Date : 2024-08-01 Epub Date: 2024-06-26 DOI:10.1089/cmb.2023.0449
Xin Zhang, Liangwei Zhao, Ziyi Chai, Hao Wu, Wei Yang, Chen Li, Yu Jiang, Quanzhong Liu
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Abstract

Noncoding RNA (NcRNA)-protein interactions (NPIs) play fundamentally important roles in carrying out cellular activities. Although various predictors based on molecular features and graphs have been published to boost the identification of NPIs, most of them often ignore the information between known NPIs or exhibit insufficient learning ability from graphs, posing a significant challenge in effectively identifying NPIs. To develop a more reliable and accurate predictor for NPIs, in this article, we propose NPI-DCGNN, an end-to-end NPI predictor based on a dual-channel graph neural network (DCGNN). NPI-DCGNN initially treats the known NPIs as an ncRNA-protein bipartite graph. Subsequently, for each ncRNA-protein pair, NPI-DCGNN extracts two local subgraphs centered around the ncRNA and protein, respectively, from the bipartite graph. After that, it utilizes a dual-channel graph representation learning layer based on GNN to generate high-level feature representations for the ncRNA-protein pair. Finally, it employs a fully connected network and output layer to predict whether an interaction exists between the pair of ncRNA and protein. Experimental results on four experimentally validated datasets demonstrate that NPI-DCGNN outperforms several state-of-the-art NPI predictors. Our case studies on the NPInter database further demonstrate the prediction power of NPI-DCGNN in predicting NPIs. With the availability of the source codes (https://github.com/zhangxin11111/NPI-DCGNN), we anticipate that NPI-DCGNN could facilitate the studies of ncRNA interactome by providing highly reliable NPI candidates for further experimental validation.

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NPI-DCGNN:利用双通道图神经网络识别 ncRNA 与蛋白质相互作用的精确工具
非编码 RNA(NcRNA)-蛋白质相互作用(NPIs)在细胞活动中发挥着极其重要的作用。虽然目前已有多种基于分子特征和图谱的预测方法来促进 NPIs 的鉴定,但大多数预测方法往往忽略了已知 NPIs 之间的信息,或者对图谱的学习能力不足,这给有效鉴定 NPIs 带来了巨大挑战。为了开发更可靠、更准确的 NPI 预测器,本文提出了基于双通道图神经网络(DCGNN)的端到端 NPI 预测器 NPI-DCGNN。NPI-DCGNN 最初将已知 NPI 视为 ncRNA 蛋白双向图。随后,对于每一对 ncRNA 蛋白,NPI-DCGNN 分别从双方图中提取以 ncRNA 和蛋白质为中心的两个局部子图。然后,它利用基于 GNN 的双通道图表示学习层为 ncRNA 蛋白对生成高级特征表示。最后,它利用全连接网络和输出层来预测 ncRNA 和蛋白质对之间是否存在相互作用。在四个经过实验验证的数据集上的实验结果表明,NPI-DCGNN 的性能优于几种最先进的 NPI 预测器。我们在 NPInter 数据库上进行的案例研究进一步证明了 NPI-DCGNN 在预测 NPI 方面的预测能力。随着源代码(https://github.com/zhangxin11111/NPI-DCGNN)的提供,我们预计 NPI-DCGNN 可以为进一步的实验验证提供高度可靠的 NPI 候选者,从而促进 ncRNA 相互作用组的研究。
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来源期刊
Journal of Computational Biology
Journal of Computational Biology 生物-计算机:跨学科应用
CiteScore
3.60
自引率
5.90%
发文量
113
审稿时长
6-12 weeks
期刊介绍: Journal of Computational Biology is the leading peer-reviewed journal in computational biology and bioinformatics, publishing in-depth statistical, mathematical, and computational analysis of methods, as well as their practical impact. Available only online, this is an essential journal for scientists and students who want to keep abreast of developments in bioinformatics. Journal of Computational Biology coverage includes: -Genomics -Mathematical modeling and simulation -Distributed and parallel biological computing -Designing biological databases -Pattern matching and pattern detection -Linking disparate databases and data -New tools for computational biology -Relational and object-oriented database technology for bioinformatics -Biological expert system design and use -Reasoning by analogy, hypothesis formation, and testing by machine -Management of biological databases
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