Abstract
Underlying a cancer phenotype is a specific gene regulatory network that represents the complex regulatory relationships between genes. However, it remains a challenge to find cancer-related gene regulatory network because of insufficient sample sizes and complex regulatory mechanisms in which gene is influenced by not only other genes but also other biological factors. With the development of high-throughput technologies and the unprecedented wealth of multi-omics data give us a new opportunity to design machine learning method to investigate underlying gene regulatory network. In this paper, we propose an approach, which use biweight midcorrelation to measure the correlation between factors and make use of nonconvex penalty based sparse regression for gene regulatory network inference (BMNPGRN). BMNCGRN incorporates multi-omics data (including DNA methylation and copy number variation) and their interactions in gene regulatory network model. The experimental results on synthetic datasets show that BMNPGRN outperforms popular and state-of-the-art methods (including DCGRN, ARACNE and CLR) under false positive control. Furthermore, we applied BMNPGRN on breast cancer (BRCA) data from The Cancer Genome Atlas database and provided gene regulatory network.
Highlights
GENE regulatory network (GRN) is a biological process that represents the complex regulatory relationships between genes
DCGRN is a method using Least Absolute Shrinkage and Selection Operator (LASSO) with DNA methylation site and copy number variation (CNV) [22], ARACNE is an algorithm for reverse engineering of gene regulatory network [30]
In order to demonstrate the superiority of BMNPGRN over three state-of-the-art methods in naive synthetic dataset used by three state-of-the-art methods, a naive experiment is designed to compare BMNPGRN with three methods
Summary
GENE regulatory network (GRN) is a biological process that represents the complex regulatory relationships between genes. Research on the structures and dynamics of GRNs provides an important insights into the mechanisms of complex diseases (e.g., breast cancer or brain tumors). Huang are with the Institute of Machine Learning and Systems Biology, School of Electronics and Information Engineering, Tongji University, Caoan Road 4800, Shanghai 201804, China.
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More From: IEEE/ACM Transactions on Computational Biology and Bioinformatics
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