Abstract
Rice, an important food resource, is highly sensitive to salt stress, which is directly related to food security. Although many studies have identified physiological mechanisms that confer tolerance to the osmotic effects of salinity, the link between rice genotype and salt tolerance is not very clear yet. Association of gene co‐expression network and rice phenotypic data under stress has penitential to identify stress‐responsive genes, but there is no standard method to associate stress phenotype with gene co‐expression network. A novel method for integration of gene co‐expression network and stress phenotype data was developed to conduct a system analysis to link genotype to phenotype. We applied a LASSO‐based method to the gene co‐expression network of rice with salt stress to discover key genes and their interactions for salt tolerance‐related phenotypes. Submodules in gene modules identified from the co‐expression network were selected by the LASSO regression, which establishes a linear relationship between gene expression profiles and physiological responses, that is, sodium/potassium condenses under salt stress. Genes in these submodules have functions related to ion transport, osmotic adjustment, and oxidative tolerance. We argued that these genes in submodules are biologically meaningful and useful for studies on rice salt tolerance. This method can be applied to other studies to efficiently and reliably integrate co‐expression network and phenotypic data.
Highlights
Rice (Oryza sativa) is arguably the most important crop worldwide
After significant principal component (PC) selected by the linear regression, we developed a broken‐stick model to identify genes significantly associated with the selected PCs
The real PC matrix con‐ taining 51 PCs from 17 gene modules was used, and the same 8 PCs selected by least absolute shrinkage and selection operator (LASSO) with real data were assumed to be positives to contribute to the observed change in Na+/K+ ratio
Summary
Rice (Oryza sativa) is arguably the most important crop worldwide. Approximately 3.5 billion people globally rely on the cultivation and distribution of rice for food and economic security. Since many genes are involved in the regulation of salinity tolerance, traditional approaches that examine one or a few genes in response to salinity may fail to capture and characterize the complex responses at the molecular level For such quantitative traits, identifying functional gene clusters would be much more meaningful than searching for a single gene. LASSO‐based methods were applied to different biological research before It has been used GWAS analysis (Wu, Chen, Hastie, Sobel, & Lange, 2009), eQTL analysis (Cheng, Zhang, Guo, Shi, & Wang, 2014), transcriptome assembly (Li, Feng, & Jiang, 2011), and gene regulatory network analysis (Gustafsson, Hornquist, & Lombardi, 2005). It is the first application of LASSO method for the identification of submodules in gene co‐expression networks in plants
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