DNA Methylation Profiles of Blood Cells Are Distinct between Early-Onset Obese and Control Individuals.
- Author:
Je Keun RHEE
1
;
Jin Hee LEE
;
Hae Kyung YANG
;
Tae Min KIM
;
Kun Ho YOON
Author Information
- Publication Type:Original Article
- Keywords: DNA methylation; genome-wide DNA methylation profiling; genome-wide gene expression profiling; obese children
- MeSH: Adolescent; Biomarkers; Blood Cells*; CpG Islands; DNA Methylation*; DNA*; Epigenomics; Gene Expression; Gene Expression Profiling; Humans; Incidence; Leukocytes; Mass Screening; Obesity; Pilot Projects
- From:Genomics & Informatics 2017;15(1):28-37
- CountryRepublic of Korea
- Language:English
- Abstract: Obesity is a highly prevalent, chronic disorder that has been increasing in incidence in young patients. Both epigenetic and genetic aberrations may play a role in the pathogenesis of obesity. Therefore, in-depth epigenomic and genomic analyses will advance our understanding of the detailed molecular mechanisms underlying obesity and aid in the selection of potential biomarkers for obesity in youth. Here, we performed microarray-based DNA methylation and gene expression profiling of peripheral white blood cells obtained from six young, obese individuals and six healthy controls. We observed that the hierarchical clustering of DNA methylation, but not gene expression, clearly segregates the obese individuals from the controls, suggesting that the metabolic disturbance that occurs as a result of obesity at a young age may affect the DNA methylation of peripheral blood cells without accompanying transcriptional changes. To examine the genome-wide differences in the DNA methylation profiles of young obese and control individuals, we identified differentially methylated CpG sites and investigated their genomic and epigenomic contexts. The aberrant DNA methylation patterns in obese individuals can be summarized as relative gains and losses of DNA methylation in gene promoters and gene bodies, respectively. We also observed that the CpG islands of obese individuals are more susceptible to DNA methylation compared to controls. Our pilot study suggests that the genome-wide aberrant DNA methylation patterns of obese individuals may advance not only our understanding of the epigenomic pathogenesis but also early screening of obesity in youth.
