Genome-wide DNA methylation drives human embryonic stem cell erythropoiesis by remodeling gene expression dynamics

Aim: To investigate the role of DNA methylation during erythrocyte production by human embryonic stem cells (hESCs). Methods: We employed an erythroid differentiation model from hESCs, and then tracked the genome-wide DNA methylation maps and gene expression patterns through an Infinium Human-Methylation450K BeadChip and an Ilumina Human HT-12 v4 Expression Beadchip, respectively. Results: A negative correlation between DNA methylation and gene expression was substantially enriched during the later differentiation stage and was present in both the promoter and the gene body. Moreover, erythropoietic genes with differentially methylated CpG sites that were primarily enriched in nonisland regions were upregulated, and demethylation of their gene bodies was associated with the presence of enhancers and DNase I hypersensitive sites. Finally, the components of JAK-STAT-NF-kappa B signaling were DNA hypomethylated and upregulated, which targets the key genes for erythropoiesis. Conclusion: Erythroid lineage commitment by hESCs requires genome-wide DNA methylation modifications to remodel gene expression dynamics.