Bacterial infection remodels the DNA methylation landscape of human dendritic cells

• Main Authors: Pacis, Alain (Author), Tailleux, Ludovic (Author), Morin, Alexander M. (Author), Lambourne, John (Author), MacIsaac, Julia L. (Author), Yotova, Vania (Author), Dumaine, Anne (Author), Danckaert, Anne (Author), Luca, Francesca (Author), Grenier, Jean-Christophe (Author), Hansen, Kasper D. (Author), Gicquel, Brigitte (Author), He, Chuan (Author), Tung, Jenny (Author), Pastinen, Tomi (Author), Kobor, Michael S. (Author), Pique-Regi, Roger (Author), Gilad, Yoav (Author), Barreiro, Luis B. (Author), Pai, Athma A. (Contributor), Yu, Miao, Ph. D. Massachusetts Institute of Technology (Author)
• Other Authors: Massachusetts Institute of Technology. Department of Biology (Contributor)
• Format: Article
• Language: English
• Published: Cold Spring Harbor Laboratory Press, 2016-04-19T15:24:40Z.
• Subjects: Article
• Online Access: Get fulltext

 DNA methylation is an epigenetic mark thought to be robust to environmental perturbations on a short time scale. Here, we challenge that view by demonstrating that the infection of human dendritic cells (DCs) with a live pathogenic bacteria is associated with rapid and active demethylation at thousands of loci, independent of cell division. We performed an integrated analysis of data on genome-wide DNA methylation, histone mark patterns, chromatin accessibility, and gene expression, before and after infection. We found that infection-induced demethylation rarely occurs at promoter regions and instead localizes to distal enhancer elements, including those that regulate the activation of key immune transcription factors. Active demethylation is associated with extensive epigenetic remodeling, including the gain of histone activation marks and increased chromatin accessibility, and is strongly predictive of changes in the expression levels of nearby genes. Collectively, our observations show that active, rapid changes in DNA methylation in enhancers play a previously unappreciated role in regulating the transcriptional response to infection, even in nonproliferating cells.