Abstract
Cytosine methylation is widespread among organisms and essential for mammalian development. In line with early postulations of an epigenetic role in gene regulation, symmetric CpG methylation can be mitotically propagated over many generations with extraordinarily high fidelity. Here, we combine BrdU labeling and immunoprecipitation with genome-wide bisulfite sequencing to explore the inheritance of cytosine methylation onto newly replicated DNA in human cells. Globally, we observe a pronounced lag between the copying of genetic and epigenetic information in embryonic stem cells that is reconsolidated within hours to accomplish faithful mitotic transmission. Populations of arrested cells show a global reduction of lag-induced intermediate CpG methylation when compared to proliferating cells, whereas sites of transcription factor engagement appear cell-cycle invariant. Alternatively, the cancer cell line HCT116 preserves global epigenetic heterogeneity independently of cell-cycle arrest. Taken together, our data suggest that heterogeneous methylation largely reflects asynchronous proliferation, but is intrinsic to actively engaged cis-regulatory elements and cancer.
Original language | English (US) |
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Pages (from-to) | 327-332 |
Number of pages | 6 |
Journal | Nature Structural and Molecular Biology |
Volume | 25 |
Issue number | 4 |
DOIs | |
State | Published - Apr 1 2018 |
Funding
We thank all members of the Meissner laboratory and in particular R. Karnik. We also thank A. Jeltsch for providing thoughtful feedback on the manuscript. T.L.D. was supported in part by postdoctoral fellowships from the Ford Foundation, UNCF/Merck Science Initiative, Harvard Medical School, and the Broad Institute Diversity Initiative. The Kiskinis lab gratefully acknowledges financial support from the Les Turner ALS Foundation, Muscular Dystrophy Association and the Feinberg School of Medicine. A.M. is a New York Stem Cell Foundation – Robertson Investigator. The Max Planck Society, the New York Stem Cell Foundation, the Broad Institute (SPARC funding to develop single cell RRBS) and NIH grants (1P50HG006193, P01GM099117, R01DA036898) supported this work.
ASJC Scopus subject areas
- Structural Biology
- Molecular Biology