Heterochromatin establishment during early mammalian development is regulated by pericentromeric RNA and characterized by non-repressive H3K9me3

Burton, Adam; Brochard, Vincent; Galán, Carmen; Ruiz-Morales, Elias R.; Rovira, Quirze; Rodriguez-Terrones, Diego; Kruse, Kai; Gras, Stéphanie Le; Udayakumar, Vishnu S.; Chin, Hang Gyeong; Eid, André; Liu, Xiaoyu; Wang, Chenfei; Gao, Shaorong; Pradhan, Sriharsa; Vaquerizas, Juan M.; Beaujean, Nathalie; Jenuwein, Thomas; Torres-Padilla, Maria-Elena

doi:10.1038/s41556-020-0536-6

Cited by 79 publications

(72 citation statements)

References 74 publications

(42 reference statements)

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“…Expression of exogenous gene does not require enhancers in 1-cell mouse embryos but does so at the 2-cell stage when ZGA occurs, supporting permissive chromatin in 1-cell embryos but more repressed chromatin at the 2-cell stage ( Schultz, 2002 ). In line with the notion that heterochromatin is extensively remodeled after fertilization, many repressive epigenetic marks, including DNA methylation, H3K27me3, and H3K9me3, are either missing or in the “immature state” in pre-implantation embryos ( Burton et al., 2020 ; Lee et al., 2014 ; Liu et al., 2016b ; Smith and Meissner, 2013 ; Wang et al., 2018 ; Xia et al., 2019 ; Zheng et al., 2016 ). For example, SUV39H1 is not expressed in 1-cell mouse embryos, coinciding with the absence of constitutive heterochromatin including chromocenters ( Burton et al., 2020 ).…”

Section: Main Textmentioning

confidence: 71%

“…In mouse, unlike H3K4me3 and H3K27me3, H3K9me3 appears to undergo global resetting on both alleles after fertilization ( Wang et al., 2018 ). The de novo H3K9me3 deposited in 1-cell embryos shows distinct distributions between the two parental alleles, with the paternal, but not the maternal, H3K9me3 being deposited by SUV39H2 ( Burton et al., 2020 ; Wang et al., 2018 ). The allele asymmetry lasts as late as the blastocyst stage ( Wang et al., 2018 ).…”

Section: Main Textmentioning

confidence: 99%

“…However, such de novo H3K9me3 is non-repressive but instead bookmarks promoters for future compaction. Forced expression of SUV39H1 induced chromocenter formation at the 2-cell stage and compromised pre-implantation development, suggesting that the precocious restoration of constitutive heterochromatin is detrimental to embryo development ( Burton et al., 2020 ). Besides, by using DamID, LADs are shown to be de novo established after fertilization but exhibit atypical genome distribution on the maternal allele in zygotes and on both alleles at the 2-cell stage ( Borsos et al., 2019 ).…”

Section: Main Textmentioning

confidence: 99%

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Rebooting the Epigenomes during Mammalian Early Embryogenesis

Xia

Xie

2020

Stem Cell Reports

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Summary Upon fertilization, terminally differentiated gametes are transformed to a totipotent zygote, which gives rise to an embryo. How parental epigenetic memories are inherited and reprogrammed to accommodate parental-to-zygotic transition remains a fundamental question in developmental biology, epigenetics, and stem cell biology. With the rapid advancement of ultra-sensitive or single-cell epigenome analysis methods, unusual principles of epigenetic reprogramming begin to be unveiled. Emerging data reveal that in many species, the parental epigenome undergoes dramatic reprogramming followed by subsequent re-establishment of the embryo epigenome, leading to epigenetic “rebooting.” Here, we discuss recent progress in understanding epigenetic reprogramming and their functions during mammalian early development. We also highlight the conserved and species-specific principles underlying diverse regulation of the epigenome in early embryos during evolution.

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Section: Main Textmentioning

confidence: 71%

Section: Main Textmentioning

confidence: 99%

Section: Main Textmentioning

confidence: 99%

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Rebooting the Epigenomes during Mammalian Early Embryogenesis

Xia

Xie

2020

Stem Cell Reports

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“…In fission yeast, the importance of pericentromeric transcription for heterochromatin formation has been extensively studied (reviewed here [ 86 ]). Beyond fission yeast, only a few studies have addressed directly whether centromeric transcription plays an important role in pericentromeric heterochromatin formation [ 23 , 43 , 141 ]. Why are CENP-A nucleosomes deposited where they are and not somewhere else on the chromosome?…”

Section: Functions Of Centromeric Transcriptionmentioning

confidence: 99%

Centromeric Transcription: A Conserved Swiss-Army Knife

Arunkumar

Melters

2020

Genes

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In most species, the centromere is comprised of repetitive DNA sequences, which rapidly evolve. Paradoxically, centromeres fulfill an essential function during mitosis, as they are the chromosomal sites wherein, through the kinetochore, the mitotic spindles bind. It is now generally accepted that centromeres are transcribed, and that such transcription is associated with a broad range of functions. More than a decade of work on this topic has shown that centromeric transcripts are found across the eukaryotic tree and associate with heterochromatin formation, chromatin structure, kinetochore structure, centromeric protein loading, and inner centromere signaling. In this review, we discuss the conservation of small and long non-coding centromeric RNAs, their associations with various centromeric functions, and their potential roles in disease.

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“…Considering the profound influence of heterochromatin on genome stability and cell fate transitions, much effort has been devoted to understanding how heterochromatin domains are established during development and maintained through cell divisions 9,14 . One of the most persistent challenges to heterochromatin maintenance is the response to DNA damage, which can arise at any time, anywhere in the genome 15,16 and poses a major threat to epigenome stability 17,18 .…”

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confidence: 99%

Imaging the response to DNA damage in heterochromatin domains reveals core principles of heterochromatin maintenance

Fortuny

Chansard

Caron

et al. 2019

Preprint

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Heterochromatin is a critical chromatin compartment, whose integrity governs genome stability and cell fate transitions. How heterochromatin features, including higher-order chromatin folding and histone modifications associated with transcriptional silencing, are maintained following a genotoxic stress challenge is unknown. Here, we establish a system for targeting UV damage to pericentric heterochromatin in mammalian cells and for tracking the heterochromatin response to UV in real time. We uncover profound heterochromatin compaction changes during repair, orchestrated by the UV damage sensor DDB2.Importantly, the restoration of heterochromatin folding is uncoupled from the maintenance of heterochromatin-specific histone modifications. We also unveil a central role for the methyltransferase SETDB1 in the maintenance of heterochromatic histone marks after UV, SETDB1 coordinating H3 methylation with new histone deposition by histone H3 chaperones in damaged heterochromatin. Our data thus shed light on fundamental molecular mechanisms safeguarding higher-order chromatin integrity following DNA damage.

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Heterochromatin establishment during early mammalian development is regulated by pericentromeric RNA and characterized by non-repressive H3K9me3

Cited by 79 publications

References 74 publications

Rebooting the Epigenomes during Mammalian Early Embryogenesis

Rebooting the Epigenomes during Mammalian Early Embryogenesis

Centromeric Transcription: A Conserved Swiss-Army Knife

Imaging the response to DNA damage in heterochromatin domains reveals core principles of heterochromatin maintenance

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