Comprehensive methylome map of lineage commitment from haematopoietic progenitors

Ji, Hong; Ehrlich, Lauren I.R.; Seita, Jun; Murakami, Peter; Doi, Akiko; Lindau, Paul; Lee, Hwajin; Aryee, Martin J.; Irizarry, Rafael A.; Kim, Kitai; Rossi, Derrick J.; Inlay, Matthew A.; Serwold, Thomas; Karsunky, Holger; Ho, Lena; Daley, George Q.; Weissman, Irving L.; Feinberg, Andrew P.

doi:10.1038/nature09367

Cited by 563 publications

(523 citation statements)

References 30 publications

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“…3). These results contrast to other differentiation models, where divergent cell fates derived from a multipotent/pluripotent progenitor adopt different epigenetic patterns (Mikkelsen et al 2007;Ji et al 2010). It is possible that a common methylation signature between memory and PCs partially explains the more rapid PC differentiation from memory B cells upon subsequent rechallenge with the same antigen.…”

Section: Discussioncontrasting

confidence: 78%

“…One such epigenetic modification, DNA methylation, occurs on cytosine residues primarily at CpG dinucleotides in mammals. The role of DNA methylation in regulating cellular differentiation from pluripotent and multipotent progenitors has been demonstrated through functional analysis of animals deficient in DNA methyltransferases (DNMTs) (Li et al 1992;Okano et al 1999;Tadokoro et al 2007;Broske et al 2009;, as well as from recent genome-wide studies comparing the DNA methylome of various differentiated cell types and their precursors Lister et al 2009;Ji et al 2010;Hodges et al 2011;Bock et al 2012). In the context of the immune system, mutations in the DNMT3B gene are causal for the development of ICF syndrome (immunodeficiency, centromere instability, and facial anomalies syndrome), a rare autosomal recessive immune disorder (Hansen et al 1999;Xu et al 1999).…”

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confidence: 99%

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DNA methylation profiling in human B cells reveals immune regulatory elements and epigenetic plasticity at Alu elements during B-cell activation

et al. 2013

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Memory is a hallmark of adaptive immunity, wherein lymphocytes mount a superior response to a previously encountered antigen. It has been speculated that epigenetic alterations in memory lymphocytes contribute to their functional distinction from their naive counterparts. However, the nature and extent of epigenetic alterations in memory compartments remain poorly characterized. Here we profile the DNA methylome and the transcriptome of B-lymphocyte subsets representing stages of the humoral immune response before and after antigen exposure in vivo from multiple humans. A significant percentage of activation-induced losses of DNA methylation mapped to transcription factor binding sites. An additional class of demethylated loci mapped to Alu elements across the genome and accompanied repression of DNA methyltransferase 3A. The activation-dependent DNA methylation changes were largely retained in the progeny of activated B cells, generating a similar epigenetic signature in downstream memory B cells and plasma cells with distinct transcriptional programs. These findings provide insights into the methylation dynamics of the genome during cellular differentiation in an immune response.

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Section: Discussioncontrasting

confidence: 78%

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confidence: 99%

DNA methylation profiling in human B cells reveals immune regulatory elements and epigenetic plasticity at Alu elements during B-cell activation

et al. 2013

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“…For example, differentiation-associated genes are methylated in mouse and human hematopoietic progenitor cells and become demethylated during differentiation (Ji et al, 2010;Bocker et al, 2011). A functional role of DNA methylation in the differentiation of adult progenitor cells is further supported by the observation that hematopoietic stem cells from mice with reduced DNA methyltransferase 1 activity failed to suppress key differentiation genes and lost their ability to differentiate into lymphoid progeny (Broske et al, 2009).…”

Section: Epigenetic Side Effects Of Global Dna Demethylationmentioning

confidence: 99%

Epigenetic cancer therapy: rationales, targets and drugs

2011

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The fundamental role of altered epigenetic modification patterns in tumorigenesis establishes epigenetic regulatory enzymes as important targets for cancer therapy. Over the past few years, several drugs with an epigenetic activity have received approval for the treatment of cancer patients, which has led to a detailed characterization of their modes of action. The results showed that both established drug classes, the histone deacetylase (HDAC) inhibitors and the DNA methyltransferase inhibitors, show substantial limitations in their epigenetic specificity. HDAC inhibitors are highly specific drugs, but the enzymes have a broad substrate specificity and deacetylate numerous proteins that are not associated with epigenetic regulation. Similarly, the induction of global DNA demethylation by non-specific inhibition of DNA methyltransferases shows pleiotropic effects on epigenetic regulation with no apparent tumor-specificity. Second-generation azanucleoside drugs have integrated the knowledge about the cellular uptake and metabolization pathways, but do not show any increased specificity for cancer epigenotypes. As such, the traditional rationale of epigenetic cancer therapy appears to be in need of refinement, as we move from the global inhibition of epigenetic modifications toward the identification and targeting of tumor-specific epigenetic programs. Recent studies have identified epigenetic mechanisms that promote self-renewal and developmental plasticity in cancer cells. Druggable somatic mutations in the corresponding epigenetic regulators are beginning to be identified and should facilitate the development of epigenetic therapy approaches with improved tumor specificity.

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“…8 Although hypermethylation of CpG islands within gene promoters has been the main focus of studies on malignant cells, the role of differential DNA methylation in other regions is gaining favor. 9,10 One such region harbors transcriptional enhancers, which reside within noncoding regions of the genome and are known to work over long distances to promote cell/tissue type specific gene expression. Active enhancers are often accompanied by DNA demethylation, 11 and alterations in enhancer methylation are seen in malignant transformation.…”

Section: Introductionmentioning

confidence: 99%

Integrated methylome and transcriptome analysis reveals novel regulatory elements in pediatric acute lymphoblastic leukemia

et al. 2015

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Acute lymphoblastic leukemia (ALL) is the most common cancer diagnosed in children under the age of 15. In addition to genetic aberrations, epigenetic modifications such as DNA methylation are altered in cancer and impact gene expression. To identify epigenetic alterations in ALL, genome-wide methylation profiles were generated using the methylated CpG island recovery assay followed by next-generation sequencing. More than 25,000 differentially methylated regions (DMR) were observed in ALL patients with »90% present within intronic or intergenic regions. To determine the regulatory potential of the DMR, whole-transcriptome analysis was performed and integrated with methylation data. Aberrant promoter methylation was associated with the altered expression of genes involved in transcriptional regulation, apoptosis, and proliferation. Novel enhancer-like sequences were identified within intronic and intergenic DMR. Aberrant methylation in these regions was associated with the altered expression of neighboring genes involved in cell cycle processes, lymphocyte activation and apoptosis. These genes include potential epi-driver genes, such as SYNE1, PTPRS, PAWR, HDAC9, RGCC, MCOLN2, LYN, TRAF3, FLT1, and MELK, which may provide a selective advantage to leukemic cells. In addition, the differential expression of epigenetic modifier genes, pseudogenes, and non-coding RNAs was also observed accentuating the role of erroneous epigenetic gene regulation in ALL.

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Comprehensive methylome map of lineage commitment from haematopoietic progenitors

Cited by 563 publications

References 30 publications

DNA methylation profiling in human B cells reveals immune regulatory elements and epigenetic plasticity at Alu elements during B-cell activation

DNA methylation profiling in human B cells reveals immune regulatory elements and epigenetic plasticity at Alu elements during B-cell activation

Epigenetic cancer therapy: rationales, targets and drugs

Integrated methylome and transcriptome analysis reveals novel regulatory elements in pediatric acute lymphoblastic leukemia

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