Nonlinear control of transcription through enhancer–promoter interactions

Zuin, Jessica; Roth, Grégory; Zhan, Yinxiu; Cramard, Julie; Redolfi, Josef; Piskadlo, Ewa; Mach, Pia; Kryzhanovska, Mariya; Tihanyi, Gergely; Kohler, Hubertus; Eder, M; Leemans, C. René; Steensel, Bas van; Meister, Peter; Smallwood, Sébastien A.; Giorgetti, Luca

doi:10.1038/s41586-022-04570-y

Cited by 239 publications

(235 citation statements)

References 67 publications

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“…2b,c ) (see also below). Collectively these results support other recent data that the relationship between gene activity and E-P contact frequencies is non-linear and that subtle changes in contact frequencies can lead to large changes in expression 36 , 45 , 46 .…”

Section: Resultssupporting

confidence: 90%

“…We propose this is a consequence of concentrated loop extrusion activity. We, like others, find that transcriptional activity is controlled by more than just E-P contact frequencies 36 , 45 , 46 . Preformed contacts established prior to gene activation have been observed at, for example, the Hoxd locus, and such ‘permissive’ structures 58 may be reminiscent of the topologies that we detect here.…”

Section: Discussionsupporting

confidence: 75%

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Building regulatory landscapes reveals that an enhancer can recruit cohesin to create contact domains, engage CTCF sites and activate distant genes

Rinzema

Sofiadis

Tjalsma

et al. 2022

Nat Struct Mol Biol

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Developmental gene expression is often controlled by distal regulatory DNA elements called enhancers. Distant enhancer action is restricted to structural chromosomal domains that are flanked by CTCF-associated boundaries and formed through cohesin chromatin loop extrusion. To better understand how enhancers, genes and CTCF boundaries together form structural domains and control expression, we used a bottom-up approach, building series of active regulatory landscapes in inactive chromatin. We demonstrate here that gene transcription levels and activity over time reduce with increased enhancer distance. The enhancer recruits cohesin to stimulate domain formation and engage flanking CTCF sites in loop formation. It requires cohesin exclusively for the activation of distant genes, not of proximal genes, with nearby CTCF boundaries supporting efficient long-range enhancer action. Our work supports a dual activity model for enhancers: its classic role of stimulating transcription initiation and elongation from target gene promoters and a role of recruiting cohesin for the creation of chromosomal domains, the engagement of CTCF sites in chromatin looping and the activation of distal target genes.

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Section: Resultssupporting

confidence: 90%

Section: Discussionsupporting

confidence: 75%

Building regulatory landscapes reveals that an enhancer can recruit cohesin to create contact domains, engage CTCF sites and activate distant genes

Rinzema

Sofiadis

Tjalsma

et al. 2022

Nat Struct Mol Biol

View full text Add to dashboard Cite

show abstract

“…Besides boundary insulation, we observe that enhancer–promoter communication may be influenced by genomic distances. Indeed, analyses in mESCs demonstrated that the transcriptional output depends on the genomic distance between an enhancer and its promoter 44 . Moreover, reduced distances between the ZRS enhancer and the Shh gene, in inverted alleles, can overcome boundary insulation and cause gene activation 45 .…”

Section: Discussionmentioning

confidence: 99%

In vivo dissection of a clustered-CTCF domain boundary reveals developmental principles of regulatory insulation

et al. 2022

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Vertebrate genomes organize into topologically associating domains, delimited by boundaries that insulate regulatory elements from nontarget genes. However, how boundary function is established is not well understood. Here, we combine genome-wide analyses and transgenic mouse assays to dissect the regulatory logic of clustered-CCCTC-binding factor (CTCF) boundaries in vivo, interrogating their function at multiple levels: chromatin interactions, transcription and phenotypes. Individual CTCF binding site (CBS) deletions revealed that the characteristics of specific sites can outweigh other factors such as CBS number and orientation. Combined deletions demonstrated that CBSs cooperate redundantly and provide boundary robustness. We show that divergent CBS signatures are not strictly required for effective insulation and that chromatin loops formed by nonconvergently oriented sites could be mediated by a loop interference mechanism. Further, we observe that insulation strength constitutes a quantitative modulator of gene expression and phenotypes. Our results highlight the modular nature of boundaries and their control over developmental processes.

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“…A similar pattern is followed by the promoter's transcriptional output, where transcriptional levels decrease with increasing genomic distance and fall to promoter-only levels when the enhancer is located outside of the TAD and is not able to activate the promoter. Therefore, the authors built a mathematical model to explain transcriptional output in terms of contact probabilities: Transcription is described by a two-state (on–off) model where the frequency of transcriptional bursts depends on the enhancer-promoter contact probability through a Hill function [169] .…”

Section: Discussionmentioning

confidence: 99%