Literature DB >> 32513732

H1 linker histones silence repetitive elements by promoting both histone H3K9 methylation and chromatin compaction.

Sean E Healton1, Hugo D Pinto2, Laxmi N Mishra2, Gregory A Hamilton2,3, Justin C Wheat2, Kalina Swist-Rosowska4, Nicholas Shukeir4, Yali Dou5, Ulrich Steidl2, Thomas Jenuwein4, Matthew J Gamble2,3, Arthur I Skoultchi1.   

Abstract

Nearly 50% of mouse and human genomes are composed of repetitive sequences. Transcription of these sequences is tightly controlled during development to prevent genomic instability, inappropriate gene activation and other maladaptive processes. Here, we demonstrate an integral role for H1 linker histones in silencing repetitive elements in mouse embryonic stem cells. Strong H1 depletion causes a profound de-repression of several classes of repetitive sequences, including major satellite, LINE-1, and ERV. Activation of repetitive sequence transcription is accompanied by decreased H3K9 trimethylation of repetitive sequence chromatin. H1 linker histones interact directly with Suv39h1, Suv39h2, and SETDB1, the histone methyltransferases responsible for H3K9 trimethylation of chromatin within these regions, and stimulate their activity toward chromatin in vitro. However, we also implicate chromatin compaction mediated by H1 as an additional, dominant repressive mechanism for silencing of repetitive major satellite sequences. Our findings elucidate two distinct, H1-mediated pathways for silencing heterochromatin.

Entities:  

Keywords:  chromatin; epigenetics; linker histones; repetitive elements

Mesh:

Substances:

Year:  2020        PMID: 32513732      PMCID: PMC7322038          DOI: 10.1073/pnas.1920725117

Source DB:  PubMed          Journal:  Proc Natl Acad Sci U S A        ISSN: 0027-8424            Impact factor:   11.205


  61 in total

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Journal:  Cell       Date:  2007-02-23       Impact factor: 41.582

2.  Linker histones stabilize the intrinsic salt-dependent folding of nucleosomal arrays: mechanistic ramifications for higher-order chromatin folding.

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Journal:  Biochemistry       Date:  1998-10-20       Impact factor: 3.162

3.  Chromatin fibers are formed by heterogeneous groups of nucleosomes in vivo.

Authors:  Maria Aurelia Ricci; Carlo Manzo; María Filomena García-Parajo; Melike Lakadamyali; Maria Pia Cosma
Journal:  Cell       Date:  2015-03-12       Impact factor: 41.582

4.  STAR: ultrafast universal RNA-seq aligner.

Authors:  Alexander Dobin; Carrie A Davis; Felix Schlesinger; Jorg Drenkow; Chris Zaleski; Sonali Jha; Philippe Batut; Mark Chaisson; Thomas R Gingeras
Journal:  Bioinformatics       Date:  2012-10-25       Impact factor: 6.937

5.  Proviral silencing in embryonic stem cells requires the histone methyltransferase ESET.

Authors:  Toshiyuki Matsui; Danny Leung; Hiroki Miyashita; Irina A Maksakova; Hitoshi Miyachi; Hiroshi Kimura; Makoto Tachibana; Matthew C Lorincz; Yoichi Shinkai
Journal:  Nature       Date:  2010-02-17       Impact factor: 49.962

6.  Transposable elements drive widespread expression of oncogenes in human cancers.

Authors:  Hyo Sik Jang; Nakul M Shah; Alan Y Du; Zea Z Dailey; Erica C Pehrsson; Paula M Godoy; David Zhang; Daofeng Li; Xiaoyun Xing; Sungsu Kim; David O'Donnell; Jeffrey I Gordon; Ting Wang
Journal:  Nat Genet       Date:  2019-03-29       Impact factor: 38.330

7.  Mouse Heterochromatin Adopts Digital Compaction States without Showing Hallmarks of HP1-Driven Liquid-Liquid Phase Separation.

Authors:  Fabian Erdel; Anne Rademacher; Rifka Vlijm; Jana Tünnermann; Lukas Frank; Robin Weinmann; Elisabeth Schweigert; Klaus Yserentant; Johan Hummert; Caroline Bauer; Sabrina Schumacher; Ahmad Al Alwash; Christophe Normand; Dirk-Peter Herten; Johann Engelhardt; Karsten Rippe
Journal:  Mol Cell       Date:  2020-02-25       Impact factor: 17.970

8.  High-resolution mapping of h1 linker histone variants in embryonic stem cells.

Authors:  Kaixiang Cao; Nathalie Lailler; Yunzhe Zhang; Ashwath Kumar; Karan Uppal; Zheng Liu; Eva K Lee; Hongwei Wu; Magdalena Medrzycki; Chenyi Pan; Po-Yi Ho; Guy P Cooper; Xiao Dong; Christoph Bock; Eric E Bouhassira; Yuhong Fan
Journal:  PLoS Genet       Date:  2013-04-25       Impact factor: 5.917

9.  MacroH2A1.1 and PARP-1 cooperate to regulate transcription by promoting CBP-mediated H2B acetylation.

Authors:  Hongshan Chen; Penelope D Ruiz; Leonid Novikov; Alyssa D Casill; Jong Woo Park; Matthew J Gamble
Journal:  Nat Struct Mol Biol       Date:  2014-10-12       Impact factor: 15.369

10.  A two-state activation mechanism controls the histone methyltransferase Suv39h1.

Authors:  Manuel M Müller; Beat Fierz; Lenka Bittova; Glen Liszczak; Tom W Muir
Journal:  Nat Chem Biol       Date:  2016-01-25       Impact factor: 15.040
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  20 in total

1.  Silencing the genome with linker histones.

Authors:  Jeffrey C Hansen
Journal:  Proc Natl Acad Sci U S A       Date:  2020-06-19       Impact factor: 11.205

2.  Hinfp is a guardian of the somatic genome by repressing transposable elements.

Authors:  Niraj K Nirala; Qi Li; Prachi N Ghule; Hsi-Ju Chen; Rui Li; Lihua Julie Zhu; Ruijia Wang; Nicholas P Rice; Junhao Mao; Janet L Stein; Gary S Stein; Andre J van Wijnen; Y Tony Ip
Journal:  Proc Natl Acad Sci U S A       Date:  2021-10-12       Impact factor: 11.205

Review 3.  Generating specificity in genome regulation through transcription factor sensitivity to chromatin.

Authors:  Luke Isbel; Ralph S Grand; Dirk Schübeler
Journal:  Nat Rev Genet       Date:  2022-07-12       Impact factor: 59.581

4.  Nucleosome Clutches are Regulated by Chromatin Internal Parameters.

Authors:  Stephanie Portillo-Ledesma; Lucille H Tsao; Meghna Wagley; Melike Lakadamyali; Maria Pia Cosma; Tamar Schlick
Journal:  J Mol Biol       Date:  2020-11-09       Impact factor: 5.469

Review 5.  Unraveling linker histone interactions in nucleosomes.

Authors:  Fanfan Hao; Seyit Kale; Stefan Dimitrov; Jeffrey J Hayes
Journal:  Curr Opin Struct Biol       Date:  2021-07-08       Impact factor: 6.809

6.  The Dynamic Influence of Linker Histone Saturation within the Poly-Nucleosome Array.

Authors:  Dustin C Woods; Francisco Rodríguez-Ropero; Jeff Wereszczynski
Journal:  J Mol Biol       Date:  2021-03-02       Impact factor: 5.469

7.  H1 histones control the epigenetic landscape by local chromatin compaction.

Authors:  Michael A Willcockson; Sean E Healton; Cary N Weiss; Boris A Bartholdy; Yair Botbol; Laxmi N Mishra; Dhruv S Sidhwani; Tommy J Wilson; Hugo B Pinto; Maxim I Maron; Karin A Skalina; Laura Norwood Toro; Jie Zhao; Chul-Hwan Lee; Harry Hou; Nevin Yusufova; Cem Meydan; Adewola Osunsade; Yael David; Ethel Cesarman; Ari M Melnick; Simone Sidoli; Benjamin A Garcia; Winfried Edelmann; Fernando Macian; Arthur I Skoultchi
Journal:  Nature       Date:  2020-12-09       Impact factor: 49.962

8.  Spreading and epigenetic inheritance of heterochromatin require a critical density of histone H3 lysine 9 tri-methylation.

Authors:  Amber R Cutter DiPiazza; Nitika Taneja; Jothy Dhakshnamoorthy; David Wheeler; Sahana Holla; Shiv I S Grewal
Journal:  Proc Natl Acad Sci U S A       Date:  2021-06-01       Impact factor: 11.205

9.  Site-specific ubiquitylation acts as a regulator of linker histone H1.

Authors:  Eva Höllmüller; Simon Geigges; Marie L Niedermeier; Kai-Michael Kammer; Simon M Kienle; Daniel Rösner; Martin Scheffner; Andreas Marx; Florian Stengel
Journal:  Nat Commun       Date:  2021-06-09       Impact factor: 14.919

Review 10.  Interplay between chromatin marks in development and disease.

Authors:  Sanne M Janssen; Matthew C Lorincz
Journal:  Nat Rev Genet       Date:  2021-10-04       Impact factor: 53.242
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