Constitutively bound CTCF sites maintain 3D chromatin architecture and long-range epigenetically regulated domains

Khoury, Amanda; Achinger-Kawecka, Joanna; Bert, Saul A.; Smith, Grady C.; French, Hugh J.; Luu, Phuc-Loi; Peters, Timothy J.; Du, Qiyun; Parry, Aled; Valdés-Mora, Fátima; Taberlay, Phillippa C.; Stirzaker, Clare; Statham, Aaron L.; Clark, Susan J.

doi:10.1038/s41467-019-13753-7

Cited by 83 publications

(87 citation statements)

References 70 publications

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“…Indeed, regions that were globally accessible in all pig and cattle tissues were particularly enriched for CTCF recognition motifs, suggesting that these regions may delineate TAD boundaries, although direct profiling of chromatin interactions will be necessary to provide more definitive annotations of 3D chromatin structure. Interestingly, out of all accessible CTCF motifs, almost a third were only accessible in a single tissue, which is consistent with CTCF binding being highly variable in different cell types [37,38], even though TAD structure is largely consistent [32][33][34]. Only a fraction of CTCF binding sites (15%) actually localize to TAD boundaries [39], and most CTCF binding sites are interspersed with enhancers, stabilizing enhancer-promoter interactions [40], and forming cell type-specific chromatin loops linked to differential gene expression [40][41][42].…”

Section: Discussionsupporting

confidence: 63%

“…Although efforts are currently underway to further characterize these regulatory elements as enhancers, silencers, insulators, promoters, etc. [29,30], motif enrichment analysis highlighted some of their potential regulatory [31], which are largely invariable across cell types [32][33][34] and even across species [32,33,35,36]. Indeed, regions that were globally accessible in all pig and cattle tissues were particularly enriched for CTCF recognition motifs, suggesting that these regions may delineate TAD boundaries, although direct profiling of chromatin interactions will be necessary to provide more definitive annotations of 3D chromatin structure.…”

Section: Discussionmentioning

confidence: 99%

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A comparative analysis of chromatin accessibility in cattle, pig, and mouse tissues

et al. 2020

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Background Although considerable progress has been made towards annotating the noncoding portion of the human and mouse genomes, regulatory elements in other species, such as livestock, remain poorly characterized. This lack of functional annotation poses a substantial roadblock to agricultural research and diminishes the value of these species as model organisms. As active regulatory elements are typically characterized by chromatin accessibility, we implemented the Assay for Transposase Accessible Chromatin (ATAC-seq) to annotate and characterize regulatory elements in pigs and cattle, given a set of eight adult tissues. Results Overall, 306,304 and 273,594 active regulatory elements were identified in pig and cattle, respectively. 71,478 porcine and 47,454 bovine regulatory elements were highly tissue-specific and were correspondingly enriched for binding motifs of known tissue-specific transcription factors. However, in every tissue the most prevalent accessible motif corresponded to the insulator CTCF, suggesting pervasive involvement in 3-D chromatin organization. Taking advantage of a similar dataset in mouse, open chromatin in pig, cattle, and mice were compared, revealing that the conservation of regulatory elements, in terms of sequence identity and accessibility, was consistent with evolutionary distance; whereas pig and cattle shared about 20% of accessible sites, mice and ungulates only had about 10% of accessible sites in common. Furthermore, conservation of accessibility was more prevalent at promoters than at intergenic regions. Conclusions The lack of conserved accessibility at distal elements is consistent with rapid evolution of enhancers, and further emphasizes the need to annotate regulatory elements in individual species, rather than inferring elements based on homology. This atlas of chromatin accessibility in cattle and pig constitutes a substantial step towards annotating livestock genomes and dissecting the regulatory link between genome and phenome.

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Section: Discussionsupporting

confidence: 63%

Section: Discussionmentioning

confidence: 99%

A comparative analysis of chromatin accessibility in cattle, pig, and mouse tissues

et al. 2020

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“…Our ChIP-seq protocol was adapted from (Khoury, Achinger-Kawecka et al, 2020). Comma-Dβ cells were grown in 150 mm or 100 mm dishes (Corning) until 80-90% confluent.…”

Section: Methodsmentioning

confidence: 99%

Inhibitor of Differentiation 4 (ID4) represses myoepithelial differentiation of mammary stem cells through its interaction with HEB

Holliday¹,

Roden²,

Junankar³

et al. 2020

Preprint

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Differentiation of stem cells embedded within the mammary epithelium is orchestrated by lineage-specifying transcription factors. Unlike the well-defined luminal hierarchy, dissection of the basal lineage has been hindered by a lack of specific markers. Inhibitor of Differentiation 4 (ID4) is a basally-restricted helix-loop-helix (HLH) transcription factor essential for mammary development. Here we show that ID4 is highly expressed in basal stem cells and decreases during myoepithelial differentiation. By integrating transcriptomic, proteomic, and ChIP-sequencing data, we reveal that ID4 is required to suppress myoepithelial gene expression and cell fate. We identify the bHLH protein HEB as a direct binding partner of ID4, and describe a previously-unknown role for this regulator in mammary development. HEB binds to E-boxes in regulatory elements of developmental genes, negatively regulated by ID4, involved in extracellular matrix synthesis and cytoskeletal contraction. Together our findings support a model whereby ID4 binds to HEB and blocks it from promoting myoepithelial specialisation. These new insights expand our current understanding into control of myoepithelial differentiation and mammary gland morphogenesis.

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“…There is thus a distance bias to consider when comparing the elements separating different types of pairs. TAD boundaries are known to have insulator properties, limiting the effects of enhancers to nearby genes on the other side of the boundary (9,12,14,45). If true, the prevalence of TAD boundaries between genes having opposite behaviours following DEX induction should be higher.…”

Section: Co-expressed Genes Show Genomic Proximitymentioning

confidence: 99%

Genes on Different Strands Mark Boundaries Associated with Co-regulation Domains

Baguette

Bilodeau

Bourque

2020

Preprint

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Gene regulation is influenced by chromatin conformation. Current models suggest that topologically associating domains (TADs) act as regulatory units, which could also include distinct co-expression domains (CODs) favouring correlated gene expression. We integrated publicly available RNA-seq, ChIP-seq and Hi-C data from A549 cells stimulated with the glucocorticoid dexamethasone to explore how differentially expressed genes are co-regulated among TADs and CODs. Interestingly, we found that gene position and orientation also impact co-regulation. Indeed, divergent and convergent pairs of genes we enriched at sub-TAD boundaries, forming distinct CODs. We also found that genes at COD boundaries were less likely to be separated by structural proteins such as Cohesin and CTCF. A complementary analysis of lung expression quantitative trait loci (eQTL) demonstrated that genes affected by the same variant were more likely to be found on the same strand while lacking a TAD boundary. Taken together, these results suggest a model where gene orientation can provide a boundary between CODs, at the sub-TAD level, thus affecting their likelihood of co-regulation.

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Constitutively bound CTCF sites maintain 3D chromatin architecture and long-range epigenetically regulated domains

Cited by 83 publications

References 70 publications

A comparative analysis of chromatin accessibility in cattle, pig, and mouse tissues

A comparative analysis of chromatin accessibility in cattle, pig, and mouse tissues

Inhibitor of Differentiation 4 (ID4) represses myoepithelial differentiation of mammary stem cells through its interaction with HEB

Genes on Different Strands Mark Boundaries Associated with Co-regulation Domains

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