Abstract
BackgroundDNA methylation, an epigenetic modification, can be affected by environmental factors and thus regulate gene expression levels that can lead to alterations of certain phenotypes. Network analysis has been used successfully to discover gene sets that are expressed differently across multiple disease states and suggest possible pathways of disease progression. We applied this framework to compare DNA methylation levels before and after lipid-lowering medication and to identify modules that differ topologically between the two time points, revealing the association between lipid medication and these triglyceride-related methylation sites.MethodsWe performed quality control using beta-mixture quantile normalization on 463,995 cytosine-phosphate-guanine (CpG) sites and deleted problematic sites, resulting in 423,004 probes. We identified 14,850 probes that were nominally associated with triglycerides prior to treatment and performed weighted gene correlation network analysis (WGCNA) to construct pre- and posttreatment methylation networks of these probes. We then applied both WGCNA module preservation and generalized Hamming distance (GHD) to identify modules with topological differences between the pre- and posttreatment. For modules with structural changes between 2 time points, we performed pathway-enrichment analysis to gain further insight into the biological function of the genes from these modules.ResultsSix triglyceride-associated modules were identified using pretreatment methylation probes. The same 3 modules were not preserved in posttreatment data using both the module-preservation and the GHD methods. Top-enriched pathways for the 3 differentially methylated modules are sphingolipid signaling pathway, proteoglycans in cancer, and metabolic pathways (p values < 0.005). One module in particular included an enrichment of lipid-related pathways among the top results.ConclusionsThe same 3 modules, which were differentially methylated between pre- and posttreatment, were identified using both WGCNA module-preservation and GHD methods. Pathway analysis revealed that triglyceride-associated modules contain groups of genes that are involved in lipid signaling and metabolism. These 3 modules may provide insight into the effect of fenofibrate on changes in triglyceride levels and these methylation sites.
Highlights
DNA methylation, an epigenetic modification, can be affected by environmental factors and regulate gene expression levels that can lead to alterations of certain phenotypes
Null: pre- and posttreatment modules are dependent; alternative: pre- and posttreatment modules are independent made up of more genes that are involved in lipid signaling and metabolism, which points to overrepresentation in the gene list in the red module
By performing network analyses on triglyceride-associated DNA methylation, we found 2 modules that are differentially methylated between pre- and posttreatment based on the results of both 2 statistics (Zsummary and medianRank) in the weighted gene correlation network analysis (WGCNA) module-preservation method and the generalized Hamming distance (GHD) method
Summary
DNA methylation, an epigenetic modification, can be affected by environmental factors and regulate gene expression levels that can lead to alterations of certain phenotypes. Network analysis has been used successfully to discover gene sets that are expressed differently across multiple disease states and suggest possible pathways of disease progression. We applied this framework to compare DNA methylation levels before and after lipid-lowering medication and to identify modules that differ topologically between the two time points, revealing the association between lipid medication and these triglyceride-related methylation sites. It is known to regulate gene expression levels by changing the chromatin structure, thereby preventing transcription factors from binding to the gene promoter, which can lead to alterations of phenotypes [2]. Epigenetic information is considered to be fundamental in understanding the interaction between the human genome and the environment
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