Whole-genome fingerprint of the DNA methylome during human B cell differentiation

Kulis, Marta; Merkel, Angelika; Heath, Simon; Queirós, Ana C.; Schuyler, Ronald P.; Castellano, Giancarlo; Beekman, Renée; Raineri, Emanuele; Esteve, Anna; Clot, Guillem; Verdaguer-Dot, Núria; Duran-Ferrer, Martí; Russiñol, Núria; Vilarrasa‐Blasi, Roser; Ecker, Simone; Pancaldi, Véra; Rico, Daniel; Águeda, Lídia; Blanc, Julie; Richardson, David; Clarke, Laura; Datta, Avik; Pascual, Marien; Agirre, Xabier; Prósper, Felipe; Alignani, Diego; Paiva, Bruno; Caron, Gersende; Fest, Thierry; Muench, Marcus O.; Fomin, Marina E.; Lee, Seung Tae; Wiemels, Joseph L.; Valencia, Alfonso; Gut, Marta; Flicek, Paul; Stunnenberg, Hendrik G.; Siebert, Reiner; Küppers, Ralf; Campo, Elı́as; Martín‐Subero, José I.

doi:10.1038/ng.3291

Cited by 281 publications

(338 citation statements)

References 71 publications

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“…PMD-associated genes generally showed low expression levels compared to FMR-associated genes and were fewer in number ( Figure S2C). We observed a similar segmented loss of global DNA-meth when re-examining DNA-meth profiles from B cells published by the BLUEPRINT consortium (Kulis et al, 2015). Here too, PMDs were the genomic segments that displayed progressive loss of DNA-meth with differentiation into memory B cells and antibody-secreting plasma cells ( Figure 1D), indicating that this phenomenon is shared during lymphocyte development.…”

Section: Progressive Segmented Loss Of Dna-meth Correlates With Tmemmentioning

confidence: 57%

Epigenomic Profiling of Human CD4+ T Cells Supports a Linear Differentiation Model and Highlights Molecular Regulators of Memory Development

Durek¹,

Nordström²,

Gasparoni³

et al. 2016

Immunity

178

192

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Section: Progressive Segmented Loss Of Dna-meth Correlates With Tmemmentioning

confidence: 57%

Epigenomic Profiling of Human CD4+ T Cells Supports a Linear Differentiation Model and Highlights Molecular Regulators of Memory Development

Durek¹,

Nordström²,

Gasparoni³

et al. 2016

Immunity

178

192

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“…Low-level de novo methylation of CpG islands is known to take place in normal tissues and has been shown to increase with age (6,11,12). In a similar manner, it has been shown that many of the general demethylation events observed in tumors also take place in normal cells (13), and this can even be seen in aging hematopoietic stem cells (HSC) and epidermal stem cells in vivo (14,15).…”

Section: When Do Methylation Changes Occur?mentioning

confidence: 75%

“…Interestingly, several studies have already established that hematopoietic stem cells from both mouse and man actually undergo a natural aging process whereby they increase in number while their lymphoid differentiation capacity is diminished, leading to a myeloid-dominant phenotype (34). Whole-genome bisulfite analysis indicates that this aging process is associated with typical de novo and demethylation events normally found in tumors (6,14), and there is a good possibility that these alterations in methylation actually play a role in promoting stem cell renewal and inhibiting differentiation. Strikingly, the changes in DNA methylation seen in aging stem cells are very similar to those detected in MDS (14), strongly suggesting that a large part of the "abnormal" methylation profile seen in this disease probably comes about as a natural result of aging even in the absence of genome mutations.…”

Section: Methylation and Tumorigenesismentioning

confidence: 99%

DNA Methylation in Cancer and Aging

et al. 2016

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DNA methylation is known to be abnormal in all forms of cancer, but it is not really understood how this occurs and what is its role in tumorigenesis. In this review, we take a wide view of this problem by analyzing the strategies involved in setting up normal DNA methylation patterns and understanding how this stable epigenetic mark works to prevent gene activation during development. Aberrant DNA methylation in cancer can be generated either prior to or following cell transformation through mutations. Increasing evidence suggests, however, that most methylation changes are generated in a programmed manner and occur in a subpopulation of tissue cells during normal aging, probably predisposing them for tumorigenesis. It is likely that this methylation contributes to the tumor state by inhibiting the plasticity of cell differentiation processes. Cancer Res; 76(12); 3446-50. Ó2016 AACR.

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“…However, some have attempted to measure only DNA methylation differences that are not due to cellular heterogeneity, by deriving samples with as pure a cell type as possible. For example, blood can be fractionated and DNA methylation investigated in specific cell types [32][33][34][35]. However, even relatively 'pure' populations of cells, such as CD4 + T cells, actually comprise many functionally and epigenetically distinct cell subpopulations (Th1, Th2, Th17, Treg, etc.).…”

Section: Partitioning the Relative Contributions Of Cellular MIX And Chmentioning

confidence: 99%

Is Cellular Heterogeneity Merely a Confounder to be Removed from Epigenome-Wide Association Studies?

et al. 2017

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Excitement about DNA methylation biomarkers has been tempered by a growing appreciation of the complex causal relations with cell fate. Intersample differences in DNA methylation can be partitioned into those that are independent of cellular heterogeneity and those that are caused by differential mixtures of cell types. Generally, the field has assumed that the former are more likely to be causative of disease. The latter has been considered a likely consequence of disease and a confounder to be removed. We argue that the conceptual separation of these signals is artificial and not necessarily informative about causation. DNA methylation is a very sensitive measure of cell fate mix and therefore reveals much about underlying disease etiology including aspects of causation. DNA methylation marks integrate genetic & environmental influences & hence have potential as prognostic & stratification biomarkers & also as read-outs of intervention efficacyLoci-specific DNA 5-methylcytosine levels at CpG sites are easily measured at scale in biological samples. They vary across individuals and this variation has been robustly associated with a range of disease phenotypes and environmental exposures [1][2][3][4][5][6]. As interindividual DNA methylation is specified by the interaction of both genotypic and environmental influences [7,8], it may be a more powerful prognostic biomarker than either genotypic or lifestyle factors alone [9]. DNA methylation is dynamic throughout the lifecourse and is potentially modifiable by therapeutic interventions. This raises the possibility of sensitive real-time biomarkers of disease status to track intervention efficacy [10].Locus-specific observations were first to demonstrate the role of early life environmental influence on interindividual variation in methylation. For instance, postnatal maternal care in rats or childhood trauma in humans, affects DNA methylation levels at the NR3C1 gene in blood and the hippocampus; methylation levels at this locus then predict adult psychopathology [11][12][13]. Observations such as this have inspired many epigenome wide association studies (EWAS) to determine the epigenetic consequences of early life influences. Although epigenetic programming was originally envisioned to pertain to very early life factors (i.e., fetal programming, see for example [14]), it could be generalized to account for environmental influences throughout the lifecourse. Some of the best evidence for the later life effect of the environment on DNA methylation is from Fasanelli and colleagues, who showed (by EWAS) that smoking reversibly caused hypomethylation of the AHRR and FR2L3 genes in adults and that

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Whole-genome fingerprint of the DNA methylome during human B cell differentiation

Cited by 281 publications

References 71 publications

Epigenomic Profiling of Human CD4+ T Cells Supports a Linear Differentiation Model and Highlights Molecular Regulators of Memory Development

Epigenomic Profiling of Human CD4+ T Cells Supports a Linear Differentiation Model and Highlights Molecular Regulators of Memory Development

DNA Methylation in Cancer and Aging

Is Cellular Heterogeneity Merely a Confounder to be Removed from Epigenome-Wide Association Studies?

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