Cohesin regulates promoter-proximal pausing of RNA Polymerase II by limiting recruitment of super elongation complex

Cohesin is a ring-shaped complex, responsible for establishing sister chromatid cohesion and forming topologically associating domains (TADs) and chromatin loops. Loss-of-function mutations in cohesin subunits and its regulatory factors can cause Cornelia de Lange syndrome (CdLS). Because dysregulated gene expression was observed in CdLS, it has long been thought that cohesin plays a regulatory role in transcription. Here, we investigated the effect of acute cohesin depletion on transcription and observed that a small number of genes exhibited differential expression. Analysis of RNA polymerase II (Pol II) distribution revealed that the depletion reduced Pol II promoter binding and pausing simultaneously at the majority of genes. This implies that at most genes, the two decreases counterbalance each other, resulting in unchanged gene expression. Additionally, we find that cohesin loss increased promoter binding of super elongation complex (SEC), which mediates the release of Pol II from paused state. Moreover, the reduction in pausing caused by cohesin depletion was no longer observed when SEC was inhibited. These observations suggest that cohesin regulates Pol II pausing by restricting SEC recruitment to promoters. Together, our study demonstrates the involvement of cohesin in transcriptional regulation, particularly in Pol II pause and release.

[1]  A. S. Hansen,et al.  Enhancer selectivity in space and time: from enhancer-promoter interactions to promoter activation. , 2024, Nature reviews. Molecular cell biology.

[2]  Christopher Barrington,et al.  Cohesin chromatin loop formation by an extrinsic motor , 2023, bioRxiv.

[3]  A. Shilatifard,et al.  Transcriptional elongation control in developmental gene expression, aging, and disease. , 2023, Molecular cell.

[4]  I. Krantz,et al.  Genomic analyses in Cornelia de Lange Syndrome and related diagnoses: Novel candidate genes, genotype–phenotype correlations and common mechanisms , 2023, American journal of medical genetics. Part A.

[5]  Ilya M. Flyamer,et al.  Pairtools: from sequencing data to chromosome contacts , 2023, bioRxiv.

[6]  H. Einsele,et al.  Alterations of cohesin complex genes in acute myeloid leukemia: differential co-mutations, clinical presentation and impact on outcome , 2023, Blood Cancer Journal.

[7]  R. Tjian,et al.  Enhancer–promoter interactions and transcription are largely maintained upon acute loss of CTCF, cohesin, WAPL or YY1 , 2022, Nature Genetics.

[8]  Mingyi Xie,et al.  Enhancer-Mediated Formation of Nuclear Transcription Initiation Domains , 2022, International journal of molecular sciences.

[9]  Mariano Barbieri,et al.  Enhancer–promoter contact formation requires RNAPII and antagonizes loop extrusion , 2022, bioRxiv.

[10]  K. Shirahige,et al.  Cohesin-dependent chromosome loop extrusion is limited by transcription and stalled replication forks , 2022, Science advances.

[11]  J. Peters,et al.  Cohesin-Dependent and -Independent Mechanisms Mediate Chromosomal Contacts between Promoters and Enhancers , 2020, Cell reports.

[12]  M. Mannervik,et al.  Release of promoter–proximal paused Pol II in response to histone deacetylase inhibition , 2020, Nucleic acids research.

[13]  Ryuichiro Nakato,et al.  Methods for ChIP-seq analysis: A practical workflow and advanced applications. , 2020, Methods.

[14]  Cyril Matthey-Doret,et al.  Computer vision for pattern detection in chromosome contact maps , 2020, Nature Communications.

[15]  Stefano Lonardi,et al.  Mustache: multi-scale detection of chromatin loops from Hi-C and Micro-C maps using scale-space representation , 2020, Genome Biology.

[16]  Juan M. Vaquerizas,et al.  Cohesin Disrupts Polycomb-Dependent Chromosome Interactions in Embryonic Stem Cells , 2020, Cell reports.

[17]  Ilya J. Finkelstein,et al.  Human cohesin compacts DNA by loop extrusion , 2019, Science.

[18]  J. Peters,et al.  DNA loop extrusion by human cohesin , 2019, Science.

[19]  A. Sandelin,et al.  Determinants of enhancer and promoter activities of regulatory elements , 2019, Nature Reviews Genetics.

[20]  Neva C. Durand,et al.  Activity-by-Contact model of enhancer-promoter regulation from thousands of CRISPR perturbations , 2019, Nature Genetics.

[21]  Anders S. Hansen,et al.  Resolving the 3D landscape of transcription-linked mammalian chromatin folding , 2019, bioRxiv.

[22]  Leonid A. Mirny,et al.  Ultrastructural details of mammalian chromosome architecture , 2019, bioRxiv.

[23]  Ken-ichiro Hayashi,et al.  Generation of conditional auxin-inducible degron (AID) cells and tight control of degron-fused proteins using the degradation inhibitor auxinole , 2019, bioRxiv.

[24]  V. Corces,et al.  Organizational principles of 3D genome architecture , 2018, Nature Reviews Genetics.

[25]  Ashley R. Woodfin,et al.  Targeting Processive Transcription Elongation via SEC Disruption for MYC-Induced Cancer Therapy , 2018, Cell.

[26]  Neva C. Durand,et al.  The Energetics and Physiological Impact of Cohesin Extrusion , 2018, Cell.

[27]  Andrea J. Kriz,et al.  Transcriptional Pause Sites Delineate Stable Nucleosome-Associated Premature Polyadenylation Suppressed by U1 snRNP. , 2018, Molecular cell.

[28]  J. Ellenberg,et al.  Topologically associating domains and chromatin loops depend on cohesin and are regulated by CTCF, WAPL, and PDS5 proteins , 2017, The EMBO journal.

[29]  S. Cusack,et al.  Structural basis for mutually exclusive co-transcriptional nuclear cap-binding complexes with either NELF-E or ARS2 , 2017, Nature Communications.

[30]  Manolis Kellis,et al.  Chromatin-state discovery and genome annotation with ChromHMM , 2017, Nature Protocols.

[31]  Erez Lieberman Aiden,et al.  Cohesin Loss Eliminates All Loop Domains , 2017, Cell.

[32]  Michael Q. Zhang,et al.  PAF1 regulation of promoter-proximal pause release via enhancer activation , 2017, Science.

[33]  Ilya M Flyamer,et al.  A mechanism of cohesin‐dependent loop extrusion organizes zygotic genome architecture , 2017, bioRxiv.

[34]  Peter H. L. Krijger,et al.  The Cohesin Release Factor WAPL Restricts Chromatin Loop Extension , 2017, Cell.

[35]  Niels Galjart,et al.  Cohesin is positioned in mammalian genomes by transcription, CTCF and Wapl , 2017, Nature.

[36]  Kin Chung Lam,et al.  High-resolution TADs reveal DNA sequences underlying genome organization in flies , 2017, Nature Communications.

[37]  Neva C. Durand,et al.  Juicer Provides a One-Click System for Analyzing Loop-Resolution Hi-C Experiments. , 2016, Cell systems.

[38]  Fidel Ramírez,et al.  deepTools2: a next generation web server for deep-sequencing data analysis , 2016, Nucleic Acids Res..

[39]  Y. Saga,et al.  Rapid Protein Depletion in Human Cells by Auxin-Inducible Degron Tagging with Short Homology Donors. , 2016, Cell reports.

[40]  Sigal Shachar,et al.  3D Chromosome Regulatory Landscape of Human Pluripotent Cells. , 2016, Cell stem cell.

[41]  Neva C. Durand,et al.  Chromatin extrusion explains key features of loop and domain formation in wild-type and engineered genomes , 2015, Proceedings of the National Academy of Sciences.

[42]  A. Visel,et al.  Disruptions of Topological Chromatin Domains Cause Pathogenic Rewiring of Gene-Enhancer Interactions , 2015, Cell.

[43]  Christopher M. Vockley,et al.  Epigenome editing by a CRISPR/Cas9-based acetyltransferase activates genes from promoters and enhancers , 2015, Nature Biotechnology.

[44]  E. Zackai,et al.  Germline Gain-of-Function Mutations in AFF4 Cause a Developmental Syndrome Functionally Linking the Super Elongation Complex and Cohesin , 2015, Nature Genetics.

[45]  Neva C. Durand,et al.  A 3D Map of the Human Genome at Kilobase Resolution Reveals Principles of Chromatin Looping , 2014, Cell.

[46]  Jill M Dowen,et al.  Control of Cell Identity Genes Occurs in Insulated Neighborhoods in Mammalian Chromosomes , 2014, Cell.

[47]  T. Nagase,et al.  Regulation of RNA polymerase II activation by histone acetylation in single living cells , 2014, Nature.

[48]  H. Handa,et al.  DSIF and NELF interact with Integrator to specify the correct post-transcriptional fate of snRNA genes , 2014, Nature Communications.

[49]  Björn Usadel,et al.  Trimmomatic: a flexible trimmer for Illumina sequence data , 2014, Bioinform..

[50]  J. Lis,et al.  Control of transcriptional elongation. , 2013, Annual review of genetics.

[51]  Hiroshi Kimura,et al.  Histone modifications for human epigenome analysis , 2013, Journal of Human Genetics.

[52]  Masao Nagasaki,et al.  Recurrent mutations in multiple components of the cohesin complex in myeloid neoplasms , 2012, Nature Genetics.

[53]  D. Bentley,et al.  mRNA decapping factors and the exonuclease Xrn2 function in widespread premature termination of RNA polymerase II transcription. , 2012, Molecular cell.

[54]  Steven L Salzberg,et al.  Fast gapped-read alignment with Bowtie 2 , 2012, Nature Methods.

[55]  Manolis Kellis,et al.  ChromHMM: automating chromatin-state discovery and characterization , 2012, Nature Methods.

[56]  P. Scacheri,et al.  Epigenetic signatures distinguish multiple classes of enhancers with distinct cellular functions. , 2011, Genome research.

[57]  Ryan A. Flynn,et al.  A unique chromatin signature uncovers early developmental enhancers in humans , 2011, Nature.

[58]  R. Young,et al.  Histone H3K27ac separates active from poised enhancers and predicts developmental state , 2010, Proceedings of the National Academy of Sciences.

[59]  A. Shilatifard,et al.  AFF4, a component of the ELL/P-TEFb elongation complex and a shared subunit of MLL chimeras, can link transcription elongation to leukemia. , 2010, Molecular cell.

[60]  Dustin E. Schones,et al.  A clustering approach for identification of enriched domains from histone modification ChIP-Seq data , 2009, Bioinform..

[61]  Cole Trapnell,et al.  Ultrafast and memory-efficient alignment of short DNA sequences to the human genome , 2009, Genome Biology.

[62]  H. Handa,et al.  NELF interacts with CBC and participates in 3' end processing of replication-dependent histone mRNAs. , 2007, Molecular cell.

[63]  Kim Nasmyth,et al.  Molecular architecture of SMC proteins and the yeast cohesin complex. , 2002, Molecular cell.

[64]  K Nasmyth,et al.  Cohesin's binding to chromosomes depends on a separate complex consisting of Scc2 and Scc4 proteins. , 2000, Molecular cell.

[65]  V. Guacci,et al.  A Direct Link between Sister Chromatid Cohesion and Chromosome Condensation Revealed through the Analysis of MCD1 in S. cerevisiae , 1997, Cell.

[66]  K. Nasmyth,et al.  Cohesins: Chromosomal Proteins that Prevent Premature Separation of Sister Chromatids , 1997, Cell.

[67]  K. Shirahige,et al.  ChIP-seq Analysis of Condensin Complex in Cultured Mammalian Cells. , 2017, Methods in molecular biology.

[68]  L. Mirny,et al.  Formation of Chromosomal Domains by Loop Extrusion , 2016 .

[69]  Giovanni Manzini,et al.  Burrows-Wheeler Transform , 2016, Encyclopedia of Algorithms.

[70]  I. Amit,et al.  Comprehensive mapping of long range interactions reveals folding principles of the human genome , 2011 .