scispace - formally typeset
Search or ask a question
Author

Elphège P. Nora

Bio: Elphège P. Nora is an academic researcher from University of California, San Francisco. The author has contributed to research in topics: CTCF & Chromatin. The author has an hindex of 23, co-authored 44 publications receiving 6133 citations. Previous affiliations of Elphège P. Nora include Cold Spring Harbor Laboratory & Curie Institute.
Topics: CTCF, Chromatin, X-inactivation, XIST, Cohesin


Papers
More filters
Journal ArticleDOI
17 May 2012-Nature
TL;DR: In addition to uncovering a new principle of cis-regulatory architecture of mammalian chromosomes, this study sets the stage for the full genetic dissection of the mouse X-inactivation centre.
Abstract: High-order chromatin folding in topologically associating domains has a critical role in proper long-range transcriptional control around the Xist locus, and presumably throughout the genome. The spatial organization of the genome is linked to biological function, and advances in genomic technologies are allowing the conformation of chromosomes to be assessed genome wide. Two groups present complementary papers on the subject. Bing Ren and colleagues use Hi-C, an adaption of the chromosome conformation capture (3C) technique, to investigate the three-dimensional organization of the human and mouse genomes in embryonic stem cells and terminally differentiated cell types. Large, megabase-sized chromatin interaction domains, termed topological domains, are found to be a pervasive and conserved feature of genome organization. Edith Heard and colleagues use chromosome conformation capture carbon-copy (5C) technology and high-resolution microscopy to obtain a high-resolution map of the chromosomal interactions over a large region of the mouse X chromosome, including the X-inactivation centre. A series of discrete topologically associating domains is revealed, as is a previously unknown long intergenic RNA with a potential regulatory role. In eukaryotes transcriptional regulation often involves multiple long-range elements and is influenced by the genomic environment1. A prime example of this concerns the mouse X-inactivation centre (Xic), which orchestrates the initiation of X-chromosome inactivation (XCI) by controlling the expression of the non-protein-coding Xist transcript. The extent of Xic sequences required for the proper regulation of Xist remains unknown. Here we use chromosome conformation capture carbon-copy (5C)2 and super-resolution microscopy to analyse the spatial organization of a 4.5-megabases (Mb) region including Xist. We discover a series of discrete 200-kilobase to 1 Mb topologically associating domains (TADs), present both before and after cell differentiation and on the active and inactive X. TADs align with, but do not rely on, several domain-wide features of the epigenome, such as H3K27me3 or H3K9me2 blocks and lamina-associated domains. TADs also align with coordinately regulated gene clusters. Disruption of a TAD boundary causes ectopic chromosomal contacts and long-range transcriptional misregulation. The Xist/Tsix sense/antisense unit illustrates how TADs enable the spatial segregation of oppositely regulated chromosomal neighbourhoods, with the respective promoters of Xist and Tsix lying in adjacent TADs, each containing their known positive regulators. We identify a novel distal regulatory region of Tsix within its TAD, which produces a long intervening RNA, Linx. In addition to uncovering a new principle of cis-regulatory architecture of mammalian chromosomes, our study sets the stage for the full genetic dissection of the X-inactivation centre.

2,627 citations

Journal ArticleDOI
18 May 2017-Cell
TL;DR: The data support that CTCF mediates transcriptional insulator function through enhancer blocking but not as a direct barrier to heterochromatin spreading, and provides new fundamental insights into the rules governing mammalian genome organization.

1,259 citations

Journal ArticleDOI
08 May 2014-Cell
TL;DR: It is demonstrated that contacts between potential regulatory elements occur in the context of fluctuating structures rather than stable loops and proposed that such fluctuations may contribute to asymmetric expression in the Xic during X inactivation.

444 citations

Journal ArticleDOI
TL;DR: Recent high-resolution chromosome conformation capture and functional studies that have informed models of the spatial and regulatory compartmentalization of mammalian genomes are reviewed, and mechanistic models for how CTCF and cohesin control the functional architecture of mammalian chromosomes are discussed.
Abstract: Genome function, replication, integrity, and propagation rely on the dynamic structural organization of chromosomes during the cell cycle. Genome folding in interphase provides regulatory segmentation for appropriate transcriptional control, facilitates ordered genome replication, and contributes to genome integrity by limiting illegitimate recombination. Here, we review recent high-resolution chromosome conformation capture and functional studies that have informed models of the spatial and regulatory compartmentalization of mammalian genomes, and discuss mechanistic models for how CTCF and cohesin control the functional architecture of mammalian chromosomes.

431 citations

Journal ArticleDOI
TL;DR: The recent discovery of the plasticity of the inactive state during early development, or during cloning, and induced pluripotency have contributed to the X chromosome becoming a gold standard in reprogramming studies.
Abstract: X-chromosome inactivation (XCI) ensures dosage compensation in mammals and is a paradigm for allele-specific gene expression on a chromosome-wide scale. Important insights have been made into the developmental dynamics of this process. Recent studies have identified several cis- and trans-acting factors that regulate the initiation of XCI via the X-inactivation centre. Such studies have shed light on the relationship between XCI and pluripotency. They have also revealed the existence of dosage-dependent activators that trigger XCI when more than one X chromosome is present, as well as possible mechanisms underlying the monoallelic regulation of this process. The recent discovery of the plasticity of the inactive state during early development, or during cloning, and induced pluripotency have also contributed to the X chromosome becoming a gold standard in reprogramming studies.

330 citations


Cited by
More filters
Journal ArticleDOI
18 Dec 2014-Cell
TL;DR: In situ Hi-C is used to probe the 3D architecture of genomes, constructing haploid and diploid maps of nine cell types, identifying ∼10,000 loops that frequently link promoters and enhancers, correlate with gene activation, and show conservation across cell types and species.

5,945 citations

Journal ArticleDOI
17 May 2012-Nature
TL;DR: It is found that the boundaries of topological domains are enriched for the insulator binding protein CTCF, housekeeping genes, transfer RNAs and short interspersed element (SINE) retrotransposons, indicating that these factors may have a role in establishing the topological domain structure of the genome.
Abstract: The spatial organization of the genome is intimately linked to its biological function, yet our understanding of higher order genomic structure is coarse, fragmented and incomplete. In the nucleus of eukaryotic cells, interphase chromosomes occupy distinct chromosome territories, and numerous models have been proposed for how chromosomes fold within chromosome territories. These models, however, provide only few mechanistic details about the relationship between higher order chromatin structure and genome function. Recent advances in genomic technologies have led to rapid advances in the study of three-dimensional genome organization. In particular, Hi-C has been introduced as a method for identifying higher order chromatin interactions genome wide. Here we investigate the three-dimensional organization of the human and mouse genomes in embryonic stem cells and terminally differentiated cell types at unprecedented resolution. We identify large, megabase-sized local chromatin interaction domains, which we term 'topological domains', as a pervasive structural feature of the genome organization. These domains correlate with regions of the genome that constrain the spread of heterochromatin. The domains are stable across different cell types and highly conserved across species, indicating that topological domains are an inherent property of mammalian genomes. Finally, we find that the boundaries of topological domains are enriched for the insulator binding protein CTCF, housekeeping genes, transfer RNAs and short interspersed element (SINE) retrotransposons, indicating that these factors may have a role in establishing the topological domain structure of the genome.

5,774 citations

Journal ArticleDOI
17 May 2012-Nature
TL;DR: In addition to uncovering a new principle of cis-regulatory architecture of mammalian chromosomes, this study sets the stage for the full genetic dissection of the mouse X-inactivation centre.
Abstract: High-order chromatin folding in topologically associating domains has a critical role in proper long-range transcriptional control around the Xist locus, and presumably throughout the genome. The spatial organization of the genome is linked to biological function, and advances in genomic technologies are allowing the conformation of chromosomes to be assessed genome wide. Two groups present complementary papers on the subject. Bing Ren and colleagues use Hi-C, an adaption of the chromosome conformation capture (3C) technique, to investigate the three-dimensional organization of the human and mouse genomes in embryonic stem cells and terminally differentiated cell types. Large, megabase-sized chromatin interaction domains, termed topological domains, are found to be a pervasive and conserved feature of genome organization. Edith Heard and colleagues use chromosome conformation capture carbon-copy (5C) technology and high-resolution microscopy to obtain a high-resolution map of the chromosomal interactions over a large region of the mouse X chromosome, including the X-inactivation centre. A series of discrete topologically associating domains is revealed, as is a previously unknown long intergenic RNA with a potential regulatory role. In eukaryotes transcriptional regulation often involves multiple long-range elements and is influenced by the genomic environment1. A prime example of this concerns the mouse X-inactivation centre (Xic), which orchestrates the initiation of X-chromosome inactivation (XCI) by controlling the expression of the non-protein-coding Xist transcript. The extent of Xic sequences required for the proper regulation of Xist remains unknown. Here we use chromosome conformation capture carbon-copy (5C)2 and super-resolution microscopy to analyse the spatial organization of a 4.5-megabases (Mb) region including Xist. We discover a series of discrete 200-kilobase to 1 Mb topologically associating domains (TADs), present both before and after cell differentiation and on the active and inactive X. TADs align with, but do not rely on, several domain-wide features of the epigenome, such as H3K27me3 or H3K9me2 blocks and lamina-associated domains. TADs also align with coordinately regulated gene clusters. Disruption of a TAD boundary causes ectopic chromosomal contacts and long-range transcriptional misregulation. The Xist/Tsix sense/antisense unit illustrates how TADs enable the spatial segregation of oppositely regulated chromosomal neighbourhoods, with the respective promoters of Xist and Tsix lying in adjacent TADs, each containing their known positive regulators. We identify a novel distal regulatory region of Tsix within its TAD, which produces a long intervening RNA, Linx. In addition to uncovering a new principle of cis-regulatory architecture of mammalian chromosomes, our study sets the stage for the full genetic dissection of the X-inactivation centre.

2,627 citations

Journal ArticleDOI
TL;DR: Key concepts in the function of DNA methylation in mammals are discussed, stemming from more than two decades of research, including many recent studies that have elucidated when and whereDNA methylation has a regulatory role in the genome.
Abstract: DNA methylation is among the best studied epigenetic modifications and is essential to mammalian development. Although the methylation status of most CpG dinucleotides in the genome is stably propagated through mitosis, improvements to methods for measuring methylation have identified numerous regions in which it is dynamically regulated. In this Review, we discuss key concepts in the function of DNA methylation in mammals, stemming from more than two decades of research, including many recent studies that have elucidated when and where DNA methylation has a regulatory role in the genome. We include insights from early development, embryonic stem cells and adult lineages, particularly haematopoiesis, to highlight the general features of this modification as it participates in both global and localized epigenetic regulation.

2,550 citations

Journal ArticleDOI
03 Jul 2013-Cell
TL;DR: This Review outlines the emerging understanding of lincRNAs in vertebrate animals, with emphases on how they are being identified and current conclusions and questions regarding their genomics, evolution and mechanisms of action.

2,213 citations