Prediction of small molecule drug-miRNA associations based on GNNs and CNNs

Zheyu Niu; Xin Gao; Zhaozhi Xia; Shuchao Zhao; Hongrui Sun; Heng Wang; Meng Liu; Xiaohan Kong; Chaoqun Ma; Huaqiang Zhu; Hengjun Gao; Qinggong Liu; Faji Yang; Xie Song; Jun Lu; Xu Zhou

doi:10.3389/fgene.2023.1201934

Prediction of small molecule drug-miRNA associations based on GNNs and CNNs

Front Genet. 2023 May 30:14:1201934. doi: 10.3389/fgene.2023.1201934. eCollection 2023.

Authors

Zheyu Niu¹, Xin Gao¹, Zhaozhi Xia¹, Shuchao Zhao¹, Hongrui Sun¹, Heng Wang¹, Meng Liu¹, Xiaohan Kong¹, Chaoqun Ma¹, Huaqiang Zhu¹, Hengjun Gao¹, Qinggong Liu¹, Faji Yang¹, Xie Song¹, Jun Lu¹, Xu Zhou¹

Affiliation

¹ Department of Hepatobiliary Surgery, Shandong Provincial Hospital Affiliated to Shandong First Medical University, Jinan, China.

Abstract

MicroRNAs (miRNAs) play a crucial role in various biological processes and human diseases, and are considered as therapeutic targets for small molecules (SMs). Due to the time-consuming and expensive biological experiments required to validate SM-miRNA associations, there is an urgent need to develop new computational models to predict novel SM-miRNA associations. The rapid development of end-to-end deep learning models and the introduction of ensemble learning ideas provide us with new solutions. Based on the idea of ensemble learning, we integrate graph neural networks (GNNs) and convolutional neural networks (CNNs) to propose a miRNA and small molecule association prediction model (GCNNMMA). Firstly, we use GNNs to effectively learn the molecular structure graph data of small molecule drugs, while using CNNs to learn the sequence data of miRNAs. Secondly, since the black-box effect of deep learning models makes them difficult to analyze and interpret, we introduce attention mechanisms to address this issue. Finally, the neural attention mechanism allows the CNNs model to learn the sequence data of miRNAs to determine the weight of sub-sequences in miRNAs, and then predict the association between miRNAs and small molecule drugs. To evaluate the effectiveness of GCNNMMA, we implement two different cross-validation (CV) methods based on two different datasets. Experimental results show that the cross-validation results of GCNNMMA on both datasets are better than those of other comparison models. In a case study, Fluorouracil was found to be associated with five different miRNAs in the top 10 predicted associations, and published experimental literature confirmed that Fluorouracil is a metabolic inhibitor used to treat liver cancer, breast cancer, and other tumors. Therefore, GCNNMMA is an effective tool for mining the relationship between small molecule drugs and miRNAs relevant to diseases.

Keywords: CNN; convolutional neural networks; graph neural networks; liver cancer; miRNAs; small molecule drug.

Grants and funding

This study is supported by Natural Science Foundation of Shandong Province, China (Grant Nos ZR2020MH259, ZR2016HB40), Natural Science Foundation of China Youth Project (Grant No. 81802379).