Abstract
Understanding the genetic contributions behind skeletal muscle composition and metabolism is of great interest in medicine and agriculture. Attempts to dissect these complex traits combine genome-wide genotyping, expression data analyses and network analyses. Weighted gene co-expression network analysis (WGCNA) groups genes into modules based on patterns of co-expression, which can be linked to phenotypes by correlation analysis of trait values and the module eigengenes, i.e. the first principal component of a given module. Network hub genes and regulators of the genes in the modules are likely to play an important role in the emergence of respective traits. In order to detect common regulators of genes in modules showing association with meat quality traits, we identified eQTL for each of these genes, including the highly connected hub genes. Additionally, the module eigengene values were used for association analyses in order to derive a joint eQTL for the respective module. Thereby major sites of orchestrated regulation of genes within trait-associated modules were detected as hotspots of eQTL of many genes of a module and of its eigengene. These sites harbor likely common regulators of genes in the modules. We exemplarily showed the consistent impact of candidate common regulators on the expression of members of respective modules by RNAi knockdown experiments. In fact, Cxcr7 was identified and validated as a regulator of genes in a module, which is involved in the function of defense response in muscle cells. Zfp36l2 was confirmed as a regulator of genes of a module related to cell death or apoptosis pathways. The integration of eQTL in module networks enabled to interpret the differentially-regulated genes from a systems perspective. By integrating genome-wide genomic and transcriptomic data, employing co-expression and eQTL analyses, the study revealed likely regulators that are involved in the fine-tuning and synchronization of genes with trait-associated expression.
Highlights
Muscle is the major energy consumption and storage organ in animals
Weighted gene co-expression network analysis (WGCNA) groups genes into modules based on patterns of co-expression, which can be linked to phenotypes by correlation analysis of trait values and the module eigengenes, i.e. the first principal component of a given module
Network hub genes and regulators of the genes in the modules are likely to play an important role in the emergence of respective traits
Summary
Muscle is the major energy consumption and storage organ in animals. An imbalance in the supply and demand of nutrients, energy, and oxygen in muscle cells is evident in many diseases. Termination of nutrient and energy supply and anoxia in muscle cell occurs postmortem. Physiological processes occurring to change from muscle to meat involve a gene expression pattern associated with both muscle structural and metabolic processes [1, 2]. Studies have begun to identify co-expression networks of genes involved in the functionality of muscles (contractile, metabolic, and structural properties) and their potential relationships to differences in muscle plasticity, size and shape, fibers as well as meat quality [3,4,5]. More work is needed to better understand the contribution of genetics to muscle-related phenotypes
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