Contrasting epigenetic states of heterochromatin in the different types of mouse pluripotent stem cells

Tosolini, Matteo; Brochard, Vincent; Adenot, Pierre; Chebrout, Martine; Grillo, Giacomo; Navia, Violette; Beaujean, Nathalie; Francastel, Claire; Bonnet-Garnier, Amélie; Jouneau, Alice

doi:10.1038/s41598-018-23822-4

Cited by 37 publications

(55 citation statements)

References 66 publications

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“…S3A). In the latter conditions, PCH shifts from H3K9me3 to H3K27me3 (Tosolini et al 2018), indicating that the PCH association of Oct4 is independent of the presence of specific heterochromatic marks. Remarkably, Oct4 staining is…”

Section: Resultsmentioning

confidence: 96%

Transcription factor activity and nucleosome organisation in mitosis

Festuccia

Owens

Papadopoulou

et al. 2018

Preprint

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Mitotic bookmarking transcription factors (BFs) maintain the capacity to bind to their targets during mitosis, despite major rearrangements of the chromatin. While they were thought to propagate gene regulatory information through mitosis by statically occupying their DNA targets, it has recently become clear that BFs are highly dynamic in mitotic cells. This represents both a technical and a conceptual challenge to study and understand the function of BFs: first, formaldehyde has been suggested to be unable to efficiently capture these transient interactions, leading to profound contradictions in the literature; second, if BFs are not permanently bound to their targets during mitosis, it becomes unclear how they convey regulatory information to daughter cells. Here, comparing formaldehyde to alternative fixatives we clarify the nature of the chromosomal association of previously proposed BFs in embryonic stem cells: while Esrrb can be considered as a canonical BF that binds at selected regulatory regions in mitosis, Sox2 and Oct4 establish DNA sequence independent interactions with the mitotic chromosomes, either throughout the chromosomal arms (Sox2) or at pericentromeric regions (Oct4). Moreover, we show that ordered nucleosomal arrays are retained during mitosis at Esrrb bookmarked sites, whereas regions losing transcription factor binding display a profound loss of order. By maintaining nucleosome positioning during mitosis, Esrrb might ensure the rapid postmitotic re-establishment of functional regulatory complexes at selected enhancers and promoters. Our results provide a mechanistic framework that reconciles dynamic mitotic binding with the transmission of gene regulatory information across cell division. mitotic bookmarking | mitosis | nucleosome | transcription factor | fixationCorrespondence: pnavarro@pasteur.fr

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Section: Resultsmentioning

confidence: 96%

Transcription factor activity and nucleosome organisation in mitosis

Festuccia

Owens

Papadopoulou

et al. 2018

Preprint

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“…The classical DAPI-dense condensed HP1-positive, H3K9me3 heterochromatin foci appear to be more diffuse in ESCs (Aoto et al, 2006;, and they increase in number and compaction during differentiation (Fussner et al, 2011;Kobayakawa et al, 2007;Meshorer, 2007; (Figure 3A), suggesting a global rearrangement of centromeres. A direct side-by-side comparison of 2i-grown, serum-grown, and primed EpiSCs shows an increase in H3K9me3 foci from 2i-to serum-grown to EpiSCs and, somewhat unexpectedly, H3K27me3-positive DAPI domains in 2i-grown cells (Tosolini et al, 2018). Especially visible is the redistribution of the heterochromatin protein HP1b from an almost completely diffuse pattern in nuclei of undifferentiated ESCs to the gradual accumulation in heterochromatin foci during differentiation (Mattout et al, 2015) ( Figure 3B).…”

Section: Developmental Cellmentioning

confidence: 92%

“…Interestingly, in the same study, H3K27me2 was found to display the opposite trend, suggesting that H3K27me2 is partially methylated into H3K27me3 during ESC differentiation. In 2i conditions, H3K27me3 is significantly depleted in developmentally regulated genes (Juan et al, 2016;Marks et al, 2012), but by contrast to the promiscuously transcribing serum-grown ESCs (Efroni et al, 2008;Lin et al, 2012;Nie et al, 2012;Percharde et al, 2017), ground-state ESCs do not show permissive transcription (Marks et al, 2012) and do not express satellite repeats (Tosolini et al, 2018) as serum-grown ESCs do (Efroni et al, 2008;Tosolini et al, 2018), suggesting that transcription in 2i-grown ESCs is blocked by means other than H3K27me3, H3K9me3, or DNA methylation.…”

Section: Chromatin Is Globally More Accessible In Pluripotent Cellsmentioning

confidence: 96%

“…Changing the Epigenome: 2i Reduces Global DNA Methylation and Local H3K27me3 Perhaps the two most prominent features of ground-state pluripotency, distinguishing it from serum-grown ESCs, are the global low-level DNA methylation and the reduced H3K27 methylation in developmentally regulated genes (Marks et al, 2012). Notwithstanding, a significant fraction (> 18%) of 2i-grown cells showed chromocenter accumulation of H3K27me3, a feature never observed in serum-grown cells (Tosolini et al, 2018). Recent reports added mechanistic insights into the erasure of DNA methylation when ESCs are switched from serum to 2i, identifying several key players in the process.…”

Section: Chromatin Is Globally More Accessible In Pluripotent Cellsmentioning

confidence: 99%

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Open Chromatin, Epigenetic Plasticity, and Nuclear Organization in Pluripotency

Schlesinger

Meshorer

2019

Developmental Cell

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“…Our data highlight the need for independent methods to measure chromatin compaction, as our observations challenge previous assumptions that lower levels of DNA methylation in 2i-treated ES cells (29) also results in less compaction. There have been some reports suggesting that the epigenetic marker H3K27me3 may be able to repress parts of the genome and counterbalance lower levels of DNA methylation, at least within some loci of 2i-treated cells (60,61).…”

Section: Resultsmentioning

confidence: 99%

Illuminating chromatin compaction in live cells and fixed tissues using SiR-DNA fluorescence lifetime

Hockings

Poudel

Feeney

et al. 2020

Preprint

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The global compaction state of chromatin in a nucleus is an important component of cell identity that has been difficult to measure. We have developed a quantitative method to measure the chromatin compaction state in both live and fixed cells, without the need for genetic modification, using the fluorescence lifetime of SiR-DNA dye. After optimising this method using live cancer cell lines treated to induce chromatin compaction or decompaction, we observed chromatin compaction in differentiating epithelial cells in fixed tissue sections, as well as local decompaction foci that may represent transcription factories. In addition, we shed new light on chromatin decompaction during embryonic stem cell transition out of their naïve pluripotent state. This method will be useful to studies of nuclear architecture, and may be easy, cheap, and accessible enough to serve as a general assay of ‘stem-ness’.

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Contrasting epigenetic states of heterochromatin in the different types of mouse pluripotent stem cells

Cited by 37 publications

References 66 publications

Transcription factor activity and nucleosome organisation in mitosis

Transcription factor activity and nucleosome organisation in mitosis

Open Chromatin, Epigenetic Plasticity, and Nuclear Organization in Pluripotency

Illuminating chromatin compaction in live cells and fixed tissues using SiR-DNA fluorescence lifetime

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