AI Article Synopsis
- - The study focuses on thymocyte differentiation, outlining the DNA methylation and gene expression changes that occur during the development of mature T-cells in humans.
- - DNA demethylation was found to be more common than de novo methylation, significantly influencing gene expression, particularly in regions lacking CpG sites, and correlating with T-cell differentiation and TCR function.
- - A total of 88 genes related to transcriptional regulation showed differential methylation during differentiation, with most changes being irreversible, providing insights into the molecular mechanisms driving T-cell development.
Article Abstract
Thymocyte differentiation is a complex process involving well-defined sequential developmental stages that ultimately result in the generation of mature T-cells. In this study, we analyzed DNA methylation and gene expression profiles at successive human thymus developmental stages. Gain and loss of methylation occurred during thymocyte differentiation, but DNA demethylation was much more frequent than de novo methylation and more strongly correlated with gene expression. These changes took place in CpG-poor regions and were closely associated with T-cell differentiation and TCR function. Up to 88 genes that encode transcriptional regulators, some of whose functions in T-cell development are as yet unknown, were differentially methylated during differentiation. Interestingly, no reversion of accumulated DNA methylation changes was observed as differentiation progressed, except in a very small subset of key genes (RAG1, RAG2, CD8A, PTCRA, etc.), indicating that methylation changes are mostly unique and irreversible events. Our study explores the contribution of DNA methylation to T-cell lymphopoiesis and provides a fine-scale map of differentially methylated regions associated with gene expression changes. These can lay the molecular foundations for a better interpretation of the regulatory networks driving human thymopoiesis.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4333391 | PMC |
| http://dx.doi.org/10.1093/nar/gku1340 | DOI Listing |
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