Orientation-dependent<i>Dxz4</i>contacts shape the 3D structure of the inactive X chromosome

Bonora, Giancarlo; Deng, Xinxian; He, Fang; Ramani, Vijay; Qui, Ruolan; Berletch, Joel B.; Filippova, Gala N; Duan, Zhijun; Schendure, Jay; Noble, William Stafford

doi:10.1101/165340

“…In general, longer paired-end reads can increase mapping efficiency. Moreover, longer reads (e.g., 150 bp) are required for efficiently identifying allelespecific chromatin interactions based on single nucleotide polymorphisms (SNPs) [46,48].…”

Section: Sequencingmentioning

confidence: 99%

Using DNase Hi-C techniques to map global and local three-dimensional genome architecture at high resolution

Ma

¹

,

Ay

²

,

Lee

³

et al. 2017

Preprint

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The folding and three-dimensional (3D) organization of chromatin in the nucleus critically impacts genome function. The past decade has witnessed rapid advances in genomic tools for delineating 3D genome architecture. Among them, chromosome conformation capture (3C)-based methods such as Hi-C are the most widely used techniques for mapping chromatin interactions. However, traditional Hi-C protocols rely on restriction enzymes (REs) to fragment chromatin and are therefore limited in resolution. We recently developed DNase Hi-C for mapping 3D genome organization, which uses DNase I for chromatin fragmentation. DNase Hi-C overcomes RE-related limitations associated with traditional Hi-C methods, leading to improved methodological resolution. Furthermore, combining this method with DNA capture technology provides a high-throughput approach (targeted DNase Hi-C) that allows for mapping fine-scale chromatin architecture at exceptionally high resolution. Hence, targeted DNase Hi-C will be valuable for delineating the physical landscapes of cis-regulatory networks that control gene expression and for characterizing phenotype-associated chromatin 3D signatures. Here, we provide a detailed description of method design and step-by-step working protocols for these two methods.

show abstract

Using DNase Hi-C techniques to map global and local three-dimensional genome architecture at high resolution

Ma

¹

,

Ay

²

,

Lee

³

et al. 2018

Methods

View full text Add to dashboard Cite

The folding and three-dimensional (3D) organization of chromatin in the nucleus critically impacts genome function. The past decade has witnessed rapid advances in genomic tools for delineating 3D genome architecture. Among them, chromosome conformation capture (3C)-based methods such as Hi-C are the most widely used techniques for mapping chromatin interactions. However, traditional Hi-C protocols rely on restriction enzymes (REs) to fragment chromatin and are therefore limited in resolution. We recently developed DNase Hi-C for mapping 3D genome organization, which uses DNase I for chromatin fragmentation. DNase Hi-C overcomes RE-related limitations associated with traditional Hi-C methods, leading to improved methodological resolution. Furthermore, combining this method with DNA capture technology provides a high-throughput approach (targeted DNase Hi-C) that allows for mapping fine-scale chromatin architecture at exceptionally high resolution. Hence, targeted DNase Hi-C will be valuable for delineating the physical landscapes of cis-regulatory networks that control gene expression and for characterizing phenotype-associated chromatin 3D signatures. Here, we provide a detailed description of method design and step-by-step working protocols for these two methods.

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A TAD boundary is preserved upon deletion of the CTCF-rich Firre locus

Barutcu

¹

,

Maass

²

,

Lewandowski

³

et al. 2018

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The binding of the transcriptional regulator CTCF to the genome has been implicated in the formation of topologically associated domains (TADs). However, the general mechanisms of folding the genome into TADs are not fully understood. Here we test the effects of deleting a CTCF-rich locus on TAD boundary formation. Using genome-wide chromosome conformation capture (Hi-C), we focus on one TAD boundary on chromosome X harboring ~ 15 CTCF binding sites and located at the long non-coding RNA (lncRNA) locus Firre. Specifically, this TAD boundary is invariant across evolution, tissues, and temporal dynamics of X-chromosome inactivation. We demonstrate that neither the deletion of this locus nor the ectopic insertion of Firre cDNA or its ectopic expression are sufficient to alter TADs in a sex-specific or allele-specific manner. In contrast, Firre’s deletion disrupts the chromatin super-loop formation of the inactive X-chromosome. Collectively, our findings suggest that apart from CTCF binding, additional mechanisms may play roles in establishing TAD boundary formation.

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Orientation-dependentDxz4contacts shape the 3D structure of the inactive X chromosome

Cited by 5 publications

References 62 publications

Using DNase Hi-C techniques to map global and local three-dimensional genome architecture at high resolution

Using DNase Hi-C techniques to map global and local three-dimensional genome architecture at high resolution

Using DNase Hi-C techniques to map global and local three-dimensional genome architecture at high resolution

A TAD boundary is preserved upon deletion of the CTCF-rich Firre locus

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