Functional and topological characteristics of mammalian regulatory domains

  1. Francois Spitz1,3
  1. 1 European Molecular Biology Laboratory;
  2. 2 University of Heidelberg
  1. * Corresponding author; email: spitz{at}embl.de

Abstract

Long-range regulatory interactions have an important role in shaping gene expression programs. However, the genomic features that organize these activities are still poorly characterized. We conducted a large operational analysis to chart the distribution of gene regulatory activities along the mouse genome, using hundreds of insertions of a regulatory sensor. We found that enhancers distribute their activities along broad regions and not in a gene-centric manner, defining large regulatory domains. Remarkably, these domains correlate strongly with the recently described TADs, which partition the genome into distinct self-interacting blocks. Different features, including specific repeats and CTCF-binding sites, correlate with the transition zones separating regulatory domains, and may help to further organize promiscuously distributed regulatory influences within large domains. These findings support a model of genomic organisation where TADs confine regulatory activities to specific but large regulatory domains, contributing to the establishment of specific gene expression profiles.

  • Received July 15, 2013.
  • Accepted December 19, 2013.

This article is distributed exclusively by Cold Spring Harbor Laboratory Press for the first six months after the full-issue publication date (see http://genome.cshlp.org/site/misc/terms.xhtml). After six months, it is available under a Creative Commons License (Attribution-NonCommercial 3.0 Unported), as described at http://creativecommons.org/licenses/by-nc/3.0/.

Articles citing this article

  • Loop Extrusion Accelerates Long-Range Enhancer-Promoter Searches in Living Embryos bioRxiv February 20, 2026 0: 2026.02.17.706355v1-2026.02.17.706355
  • H4K20me3 and CTCF act reciprocally at TAD boundaries to regulate cell state transitions bioRxiv February 3, 2026 0: 2026.01.29.702647v1-2026.01.29.702647
  • Heterotypic directional motifs contribute to TAD boundary function in Drosophila bioRxiv September 9, 2025 0: 2025.09.06.674533v1-2025.09.06.674533
  • The multiscale distribution of radiation-induced DNA damage and its impact on local genome structure bioRxiv September 2, 2025 0: 2025.08.25.672161v1-2025.08.25.672161
  • Bystander activation across a TAD boundary supports a cohesin-dependent transcription cluster model for enhancer function Genes Dev. September 1, 2025 39: 1012-1024
  • STARR-CRAAVT: A platform to design cell type-specific regulatory elements for next-generation gene therapy bioRxiv June 11, 2025 0: 2025.06.04.657008v1-2025.06.04.657008
  • Regulatory elements of pancreas development license the initiation of pancreatic ductal adenocarcinoma bioRxiv June 10, 2025 0: 2025.06.06.658264v1-2025.06.06.658264
  • Revisiting models of enhancer-promoter communication in gene regulation Genome Res June 1, 2025 35: 1277-1286
  • Prior epigenetic status predicts future susceptibility to seizures in mice bioRxiv March 26, 2025 0: 2025.03.20.644199v1-2025.03.20.644199
  • Transcriptional coregulation in cis around a contact insulation site revealed by single-molecule microscopy bioRxiv March 10, 2025 0: 2025.03.04.641491v1-2025.03.04.641491
  • CTCF depletion decouples enhancer-mediated gene activation from chromatin hub formation during cellular differentiation bioRxiv January 25, 2025 0: 2024.11.20.624447v2-2024.11.20.624447
  • Functional maps of a genomic locus reveal confinement of an enhancer by its target gene bioRxiv December 12, 2024 0: 2024.08.26.609360v2-2024.08.26.609360
  • A Cardiac Transcriptional Enhancer is Repurposed During Regeneration to Activate an Anti-proliferative Program bioRxiv November 15, 2024 0: 2023.06.30.547239v3-2023.06.30.547239
  • CTCF-anchored chromatin loop dynamics during human meiosis bioRxiv November 9, 2024 0: 2024.02.29.582729v2-2024.02.29.582729
  • Bystander activation across a TAD boundary supports a cohesin-dependent hub-model for enhancer function bioRxiv November 7, 2024 0: 2024.11.01.621524v1-2024.11.01.621524
  • Dissecting Regulatory Non-Coding Heart Disease GWAS Loci with High-Resolution 3D Chromatin Interactions Reveals Causal Genes with Pathophysiological Relevance to Heart Failure bioRxiv October 16, 2024 0: 2024.10.08.617295v1-2024.10.08.617295
  • Long range regulation of transcription scales with genomic distance in a gene specific manner bioRxiv July 23, 2024 0: 2024.07.19.604327v1-2024.07.19.604327
  • THE CELLS ARE ALL-RIGHT: Regulation of the Lefty genes by separate enhancers in mouse embryonic stem cells bioRxiv June 21, 2024 0: 2024.06.14.598870v1-2024.06.14.598870
  • HYENA detects oncogenes activated by distal enhancers in cancer bioRxiv April 15, 2024 0: 2023.01.09.523321v3-2023.01.09.523321
  • Genomic context sensitizes regulatory elements to genetic disruption bioRxiv March 15, 2024 0: 2023.07.02.547201v4-2023.07.02.547201
  • Putative Looping Factor ZNF143/ZFP143 is an Essential Transcriptional Regulator with No Looping Function bioRxiv March 15, 2024 0: 2024.03.08.583987v1-2024.03.08.583987
  • Long G4-rich enhancer physically interacts with EXOC3 promoter via a G4:G4 DNA-based mechanism bioRxiv February 2, 2024 0: 2024.01.29.577212v1-2024.01.29.577212
  • Activity-driven chromatin organization during interphase: compaction, segregation, and entanglement suppression bioRxiv January 29, 2024 0: 2024.01.22.576729v1-2024.01.22.576729
  • Evolutionary insights into 3D genome organization and epigenetic landscape of Vigna mungo LSA November 3, 2023 7: e202302074
  • Loop extrusion by cohesin plays a key role in enhancer-activated gene expression during differentiation bioRxiv September 12, 2023 0: 2023.09.07.556660v1-2023.09.07.556660
  • Ultra-long-range interactions between active regulatory elements Genome Res August 1, 2023 33: 1269-1283
  • Extrusion fountains are hallmarks of chromosome organization emerging upon zygotic genome activation bioRxiv July 19, 2023 0: 2023.07.15.549120v1-2023.07.15.549120
  • MAPT expression is mediated by long-range interactions with cis-regulatory elements bioRxiv April 13, 2023 0: 2023.03.07.531520v2-2023.03.07.531520
  • A multilayered post-GWAS analysis pipeline defines functional variants and target genes for systemic lupus erythematosus (SLE) medRxiv April 10, 2023 0: 2023.04.07.23288295v1-2023.04.07.23288295
  • MAPT expression is regulated by long-range interactions with cis-regulatory elements bioRxiv March 10, 2023 0: 2023.03.07.531520v1-2023.03.07.531520
  • Stochastic motion and transcriptional dynamics of pairs of distal DNA loci on a compacted chromosome bioRxiv February 15, 2023 0: 2023.01.18.524527v2-2023.01.18.524527
  • Loops and the activity of loop extrusion factors constrain chromatin dynamics bioRxiv January 20, 2023 0: 2020.02.29.969683v3-2020.02.29.969683
  • 3D chromatin interactions involving Drosophila insulators are infrequent but preferential and arise before TADs and transcription bioRxiv December 16, 2022 0: 2022.12.12.520036v1-2022.12.12.520036
  • Ultra-long-range interactions between active regulatory elements bioRxiv December 2, 2022 0: 2022.11.30.518557v1-2022.11.30.518557
  • Structural elements facilitate extreme long-range gene regulation at a human disease locus bioRxiv October 26, 2022 0: 2022.10.20.513057v1-2022.10.20.513057
  • Enhancer-promoter interactions form independently of genomic distance and are functional across TAD boundaries bioRxiv September 1, 2022 0: 2022.08.29.505755v1-2022.08.29.505755
  • DNA capture and loop extrusion dynamics by cohesin-NIPBL bioRxiv August 21, 2022 0: 2022.08.18.504320v1-2022.08.18.504320
  • CTCF, BEAF-32 and CP190 are not required for the initial establishment of TADs in early Drosophila embryos, but have locus specific roles bioRxiv July 30, 2022 0: 2022.07.27.501678v1-2022.07.27.501678
  • The Mediator complex regulates enhancer-promoter interactions bioRxiv June 17, 2022 0: 2022.06.15.496245v1-2022.06.15.496245
  • 3D or Not 3D: Shaping the Genome during Development Cold Spring Harb. Perspect. Biol. May 1, 2022 14: a040188
  • The Impact of Space and Time on the Functional Output of the Genome Cold Spring Harb. Perspect. Biol. April 1, 2022 14: a040378
  • A promoter-proximal silencer modifies the activity of a shared enhancer to mediate divergent expression of nub and pdm2 paralogs in wing development bioRxiv March 6, 2022 0: 2022.03.01.482523v1-2022.03.01.482523
  • Genomic context sensitivity of insulator function Genome Res March 1, 2022 32: 425-436
  • Multiple parameters shape the 3D chromatin structure of single nuclei bioRxiv January 18, 2022 0: 2022.01.16.476319v1-2022.01.16.476319
  • Dynamics of CTCF and cohesin mediated chromatin looping revealed by live-cell imaging bioRxiv December 15, 2021 0: 2021.12.12.472242v1-2021.12.12.472242
  • Deciphering the species-level structure of topologically associating domains bioRxiv November 1, 2021 0: 2021.10.28.466333v1-2021.10.28.466333
  • Promoter repression and 3D-restructuring resolves divergent developmental gene expression in TADs bioRxiv October 12, 2021 0: 2021.10.08.463672v1-2021.10.08.463672
  • The Stochastic Genome and Its Role in Gene Expression Cold Spring Harb. Perspect. Biol. October 1, 2021 13: a040386
  • Analysis of sub-kilobase chromatin topology reveals nano-scale regulatory interactions with variable dependence on cohesin and CTCF bioRxiv August 12, 2021 0: 2021.08.10.455796v1-2021.08.10.455796
  • Chromosomal neighbourhoods allowidentification of organ specific changesin gene expression bioRxiv August 11, 2021 0: 2020.11.20.390930v4-2020.11.20.390930
  • Live-cell 3D single-molecule tracking reveals how NuRD modulates enhancer dynamics bioRxiv July 21, 2021 0: 2020.04.03.003178v2-2020.04.03.003178
  • Systematic in vivo interrogation identifies novel enhancers and silencers associated to Atrial Fibrillation bioRxiv July 16, 2021 0: 2021.07.14.452222v1-2021.07.14.452222
  • Dynamic Runx1 chromatin boundaries affect gene expression in hematopoietic development bioRxiv May 25, 2021 0: 2021.05.14.444178v1-2021.05.14.444178
  • Insights into the molecular mechanisms of cell fate decision making processes from chromosome structural dynamics bioRxiv May 11, 2021 0: 2021.05.09.443292v1-2021.05.09.443292
  • Topologically Associating Domain Boundaries are Commonly Required for Normal Genome Function bioRxiv May 10, 2021 0: 2021.05.06.443037v1-2021.05.06.443037
  • Nonlinear control of transcription through enhancer-promoter interactions bioRxiv April 24, 2021 0: 2021.04.22.440891v1-2021.04.22.440891
  • In vivo dissection of a clustered-CTCF domain boundary reveals developmental principles of regulatory insulation bioRxiv April 16, 2021 0: 2021.04.14.439779v1-2021.04.14.439779
  • The giant axolotl genome uncovers the evolution, scaling, and transcriptional control of complex gene loci Proc. Natl. Acad. Sci. USA April 7, 2021 118: e2017176118
  • Seeing the forest through the trees: Identifying functional interactions from Hi-C bioRxiv December 1, 2020 0: 2020.11.29.402420v1-2020.11.29.402420
  • HOX13-MEDIATED DBX2 REGULATION IN LIMBS SUGGESTS INTER-TAD SHARING OF ENHANCERS bioRxiv November 19, 2020 0: 2020.11.16.379412v1-2020.11.16.379412
  • How subtle changes in 3D structure can create large changes in transcription bioRxiv October 26, 2020 0: 2020.10.22.351395v1-2020.10.22.351395
  • Topologically associating domain boundaries are enriched in early firing origins and restrict replication fork progression bioRxiv October 25, 2020 0: 2020.10.21.348946v1-2020.10.21.348946
  • Multiple stages of evolutionary change in anthrax toxin receptor expression in humans bioRxiv August 1, 2020 0: 2020.07.29.227660v1-2020.07.29.227660
  • Microscopic Chromosomal Structural and Dynamical Origin of Cell Differentiation and Reprogramming bioRxiv July 19, 2020 0: 2020.07.16.207662v1-2020.07.16.207662
  • Cis-regulatory chromatin loops arise before TADs and gene activation, and are independent of cell fate during development bioRxiv July 9, 2020 0: 2020.07.07.191015v1-2020.07.07.191015
  • Independence of 3D chromatin conformation and gene regulation during Drosophila dorsoventral patterning bioRxiv July 9, 2020 0: 2020.07.07.186791v1-2020.07.07.186791
  • 3D genome evolution and reorganization in the Drosophila melanogaster species group bioRxiv May 18, 2020 0: 2020.04.09.033753v2-2020.04.09.033753
  • Identifying regulatory and spatial genomic architectural elements using cell type independent machine and deep learning models bioRxiv May 10, 2020 0: 2020.04.19.049585v2-2020.04.19.049585
  • Splicing of enhancer-associated lincRNAs contributes to enhancer activity LSA February 21, 2020 3: e202000663
  • The regulatory landscapes of developmental genes Development February 3, 2020 147: dev171736
  • The impact of pro-inflammatory cytokines on the {beta}-cell regulatory landscape provides new insights into the genetics of type 1 diabetes bioRxiv December 26, 2019 0: 560193v1-560193
  • Controlling gene activation by enhancers through a drug-inducible topological insulator bioRxiv December 23, 2019 0: 534073v1-534073
  • Determining cellular CTCF and cohesin abundances to constrain 3D genome models bioRxiv December 18, 2019 0: 370650v2-370650
  • Chromatin topology, condensates and gene regulation: shifting paradigms or just a phase? Development September 25, 2019 146: dev182766
  • An unexpected contribution of lincRNA splicing to enhancer function bioRxiv July 30, 2019 0: 287706v1-287706
  • Enhancer-gene maps in the human and zebrafish genomes using evolutionary linkage conservation bioRxiv June 24, 2019 0: 244475v3-244475
  • Clustered CTCF binding is an evolutionary mechanism to maintain topologically associating domains bioRxiv June 14, 2019 0: 668855v1-668855
  • A revised model for promoter competition based on multi-way chromatin interactions bioRxiv April 19, 2019 0: 612275v1-612275
  • Principles of genome folding into topologically associating domains Sci Adv April 10, 2019 5: eaaw1668
  • Mapping Transgene Insertion Sites Reveals Complex Interactions Between Mouse Transgenes and Neighboring Endogenous Genes bioRxiv April 9, 2019 0: 389676v1-389676
  • Evolutionary stability of topologically associating domains is associated with conserved gene regulation bioRxiv March 30, 2019 0: 231431v2-231431
  • THE HOXD CLUSTER IS A DYNAMIC AND RESILIENT TAD BOUNDARY CONTROLLING THE SEGREGATION OF ANTAGONISTIC REGULATORY LANDSCAPES bioRxiv March 29, 2019 0: 193706v2-193706
  • Genetic drivers of repeat expansion disorders localize to 3-D chromatin domain boundaries bioRxiv March 26, 2019 0: 191213v1-191213
ACCEPTED MANUSCRIPT

This Article

  1. Published in Advance January 7, 2014, doi: 10.1101/gr.163519.113 Genome Res. gr.163519.113 Published by Cold Spring Harbor Laboratory Press

Article Category

Share

Preprint Server



Current Issue

  1. April 2026, 36 (4)
  1. Current Issue
  1. Alert me to new issues of Genome Research