DNA methylation trajectories during innate and adaptive immune responses of human B lymphocytes.

B lymphocytes can engage in either a rapid T cell-independent pathway (TI) or a delayed long-lasting T cell-independent (TD) response through highly ordered transcriptional programs, yet the detailed underlying mechanisms are unclear. Since DNA methylation plays a key role in controlling gene expression and lineage specification, we explored the dynamics of whole-genome cytosine modifications during the ex vivo response of human B cells isolated from normal individuals by negative selection. We found that B cell differentiation following TI and TD signaling is accompanied by extensive remodeling of the epigenome, including global gain and loss of DNA methylation. The epigenetic changes map to different regions of the B cell genome, including non-CpG islands, indicating that modifications of distal regulatory elements likely regulate specific gene transcription in B cells. Non-CpG methylation also occurs in differentiating human B cells, suggesting that this DNA modification is involved in transcriptional regulation of B cell genes with promoters exhibiting a low-density methylation, possibly by changing the chromatin shape that could have an impact on gene expression. Most strikingly, compared to TD activation, stimulation of B cells through an innate pathway induced higher levels of DNA methylation modifications at CpG, CHG, and CGG contexts, supporting the view that DNA methylation modifications are used in distinct trajectories to specify the TI and TD B lymphocyte responses. This article is protected by copyright. All rights reserved.