Investigation of changes in DNA methylation associated with alterations in gene expression resulting in differences between lean and obese adipogenesis.

DNA methylation (DNAm) is an important epigenetic regulator controlling various cellular activities, including cell proliferation and differentiation. In the present work, we examined alterations in DNAm associated with obesity using methylome and transcriptome data from 27 purified adipocytes (ACs) and 7 preadipocytes (preACs) in human visceral adipose tissue (VAT) samples. We identified differentially methylated probes (DMPs) using two methods: (i) DMPs that were obtained from a comparison of the DNAm levels between AC and preAC samples (AGDMPs) and (ii) DMPs that were obtained from a comparison of the DNAm levels between obese and lean AC samples (ACDMPs). These two classes of DMPs were obtained to identify a relationship between adipogenesis and obesity. We also investigated how hyper and hypomethylation of the promoter and/or gene body differentially affected changes in gene expression by estimating the odds ratios (ORs) of changes in gene expression without DMPs in the background. Interestingly, the magnitude of DNAm alterations during AC differentiation was greater under lean conditions than under obese conditions. In conclusion, several adipogenesis-related genes were affected by complicated methylation changes and ultimately cause differences in gene expression in ACs under lean and obese conditions.

Adipocyte differentiation between obese and lean conditions depends on changes in miRNA expression.

Adipogenesis is the process by which precursor cells, preadipocytes (preACs), differentiate into adipocytes (ACs). Here, we investigated differentially expressed miRNAs (DEMs) between the two conditions to understand the regulatory role of miRNAs in altering adipogenesis-related mRNAs. A total of 812 and 748 DEMs were obtained in lean and obese conditions, respectively. The up- and downregulated DEMs were highly concordant with each other in both lean and obese conditions; however, DEMs related to adipogenesis in obese conditions were more strongly downregulated than DEMs related to adipogenesis in lean conditions. There were more obese-specific downregulated DEMs than lean-specific downregulated DEMs; in contrast, there were more lean-specific upregulated DEMs than obese-specific upregulated DEMs. Approximately 45% of DEMs were mapped to the list of miRNA-target mRNA pairs when DEMs were matched to the experimentally validated list of miRNA-target mRNA information of miRTarBase. Many of the target mRNAs were differentially expressed genes (DEGs) with functions in processes such as inflammatory responses and fat metabolism. In particular, a total of 25 miRNAs that target three upregulated adipogenesis-associated inflammatory genes (IL-6, TNF-α, and IL-1ß) were commonly altered during adipogenesis. Taken together, our study reveals the types of adipogenesis-related miRNAs that are altered and the degree to which they influence healthy or pathogenic adipogenesis.