LPI-HyADBS: a hybrid framework for lncRNA-protein interaction prediction integrating feature selection and classification

Liqian Zhou; Qi Duan; Xiongfei Tian; He Xu; Jianxin Tang; Lihong Peng

doi:10.1186/s12859-021-04485-x

LPI-HyADBS: a hybrid framework for lncRNA-protein interaction prediction integrating feature selection and classification

BMC Bioinformatics. 2021 Nov 26;22(1):568. doi: 10.1186/s12859-021-04485-x.

Authors

Liqian Zhou¹, Qi Duan¹, Xiongfei Tian¹, He Xu¹, Jianxin Tang², Lihong Peng^{3

4}

Affiliations

¹ School of Computer, Hunan University of Technology, Zhuzhou, China.
² College of Life Sciences and Chemistry, Hunan University of Technology, Zhuzhou, China. jxtang0733@163.com.
³ School of Computer, Hunan University of Technology, Zhuzhou, China. plhhnu@163.com.
⁴ College of Life Sciences and Chemistry, Hunan University of Technology, Zhuzhou, China. plhhnu@163.com.

Abstract

Background: Long noncoding RNAs (lncRNAs) have dense linkages with a plethora of important cellular activities. lncRNAs exert functions by linking with corresponding RNA-binding proteins. Since experimental techniques to detect lncRNA-protein interactions (LPIs) are laborious and time-consuming, a few computational methods have been reported for LPI prediction. However, computation-based LPI identification methods have the following limitations: (1) Most methods were evaluated on a single dataset, and researchers may thus fail to measure their generalization ability. (2) The majority of methods were validated under cross validation on lncRNA-protein pairs, did not investigate the performance under other cross validations, especially for cross validation on independent lncRNAs and independent proteins. (3) lncRNAs and proteins have abundant biological information, how to select informative features need to further investigate.

Results: Under a hybrid framework (LPI-HyADBS) integrating feature selection based on AdaBoost, and classification models including deep neural network (DNN), extreme gradient Boost (XGBoost), and SVM with a penalty Coefficient of misclassification (C-SVM), this work focuses on finding new LPIs. First, five datasets are arranged. Each dataset contains lncRNA sequences, protein sequences, and an LPI network. Second, biological features of lncRNAs and proteins are acquired based on Pyfeat. Third, the obtained features of lncRNAs and proteins are selected based on AdaBoost and concatenated to depict each LPI sample. Fourth, DNN, XGBoost, and C-SVM are used to classify lncRNA-protein pairs based on the concatenated features. Finally, a hybrid framework is developed to integrate the classification results from the above three classifiers. LPI-HyADBS is compared to six classical LPI prediction approaches (LPI-SKF, LPI-NRLMF, Capsule-LPI, LPI-CNNCP, LPLNP, and LPBNI) on five datasets under 5-fold cross validations on lncRNAs, proteins, lncRNA-protein pairs, and independent lncRNAs and independent proteins. The results show LPI-HyADBS has the best LPI prediction performance under four different cross validations. In particular, LPI-HyADBS obtains better classification ability than other six approaches under the constructed independent dataset. Case analyses suggest that there is relevance between ZNF667-AS1 and Q15717.

Conclusions: Integrating feature selection approach based on AdaBoost, three classification techniques including DNN, XGBoost, and C-SVM, this work develops a hybrid framework to identify new linkages between lncRNAs and proteins.

Keywords: C-SVM; Deep neural network; Ensemble learning; Feature selection; XGBoost; lncRNA-protein interaction.

MeSH terms

Amino Acid Sequence
Computational Biology
Neural Networks, Computer
RNA, Long Noncoding* / genetics
RNA-Binding Proteins / metabolism

Substances

RNA, Long Noncoding
RNA-Binding Proteins