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Polycomb-lamina antagonism partitions heterochromatin at the nuclear periphery

Author

Listed:
  • Allison P. Siegenfeld

    (Harvard University
    Broad Institute of Harvard and MIT)

  • Shelby A. Roseman

    (Harvard University
    Broad Institute of Harvard and MIT)

  • Heejin Roh

    (Harvard University
    Broad Institute of Harvard and MIT)

  • Nicholas Z. Lue

    (Harvard University
    Broad Institute of Harvard and MIT)

  • Corin C. Wagen

    (Harvard University)

  • Eric Zhou

    (Harvard University)

  • Sarah E. Johnstone

    (Broad Institute of Harvard and MIT
    Dana-Farber Cancer Institute)

  • Martin J. Aryee

    (Broad Institute of Harvard and MIT
    Dana-Farber Cancer Institute)

  • Brian B. Liau

    (Harvard University
    Broad Institute of Harvard and MIT)

Abstract

The genome can be divided into two spatially segregated compartments, A and B, which partition active and inactive chromatin states. While constitutive heterochromatin is predominantly located within the B compartment near the nuclear lamina, facultative heterochromatin marked by H3K27me3 spans both compartments. How epigenetic modifications, compartmentalization, and lamina association collectively maintain heterochromatin architecture remains unclear. Here we develop Lamina-Inducible Methylation and Hi-C (LIMe-Hi-C) to jointly measure chromosome conformation, DNA methylation, and lamina positioning. Through LIMe-Hi-C, we identify topologically distinct sub-compartments with high levels of H3K27me3 and differing degrees of lamina association. Inhibition of Polycomb repressive complex 2 (PRC2) reveals that H3K27me3 is essential for sub-compartment segregation. Unexpectedly, PRC2 inhibition promotes lamina association and constitutive heterochromatin spreading into H3K27me3-marked B sub-compartment regions. Consistent with this repositioning, genes originally marked with H3K27me3 in the B compartment, but not the A compartment, remain largely repressed, suggesting that constitutive heterochromatin spreading can compensate for H3K27me3 loss at a transcriptional level. These findings demonstrate that Polycomb sub-compartments and their antagonism with lamina association are fundamental features of genome structure. More broadly, by jointly measuring nuclear position and Hi-C contacts, our study demonstrates how compartmentalization and lamina association represent distinct but interdependent modes of heterochromatin regulation.

Suggested Citation

  • Allison P. Siegenfeld & Shelby A. Roseman & Heejin Roh & Nicholas Z. Lue & Corin C. Wagen & Eric Zhou & Sarah E. Johnstone & Martin J. Aryee & Brian B. Liau, 2022. "Polycomb-lamina antagonism partitions heterochromatin at the nuclear periphery," Nature Communications, Nature, vol. 13(1), pages 1-16, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-31857-5
    DOI: 10.1038/s41467-022-31857-5
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    1. Yichao Cai & Ying Zhang & Yan Ping Loh & Jia Qi Tng & Mei Chee Lim & Zhendong Cao & Anandhkumar Raju & Erez Lieberman Aiden & Shang Li & Lakshmanan Manikandan & Vinay Tergaonkar & Greg Tucker-Kellogg , 2021. "H3K27me3-rich genomic regions can function as silencers to repress gene expression via chromatin interactions," Nature Communications, Nature, vol. 12(1), pages 1-22, December.
    2. Wibke Schwarzer & Nezar Abdennur & Anton Goloborodko & Aleksandra Pekowska & Geoffrey Fudenberg & Yann Loe-Mie & Nuno A Fonseca & Wolfgang Huber & Christian H. Haering & Leonid Mirny & Francois Spitz, 2017. "Two independent modes of chromatin organization revealed by cohesin removal," Nature, Nature, vol. 551(7678), pages 51-56, November.
    3. Kyle Xiong & Jian Ma, 2019. "Revealing Hi-C subcompartments by imputing inter-chromosomal chromatin interactions," Nature Communications, Nature, vol. 10(1), pages 1-12, December.
    4. Lars Guelen & Ludo Pagie & Emilie Brasset & Wouter Meuleman & Marius B. Faza & Wendy Talhout & Bert H. Eussen & Annelies de Klein & Lodewyk Wessels & Wouter de Laat & Bas van Steensel, 2008. "Domain organization of human chromosomes revealed by mapping of nuclear lamina interactions," Nature, Nature, vol. 453(7197), pages 948-951, June.
    5. Tamer T. Onder & Nergis Kara & Anne Cherry & Amit U. Sinha & Nan Zhu & Kathrin M. Bernt & Patrick Cahan & B. Ogan Mancarci & Juli Unternaehrer & Piyush B. Gupta & Eric S. Lander & Scott A. Armstrong &, 2012. "Chromatin-modifying enzymes as modulators of reprogramming," Nature, Nature, vol. 483(7391), pages 598-602, March.
    6. Raphael Margueron & Neil Justin & Katsuhito Ohno & Miriam L. Sharpe & Jinsook Son & William J. Drury III & Philipp Voigt & Stephen R. Martin & William R. Taylor & Valeria De Marco & Vincenzo Pirrotta , 2009. "Role of the polycomb protein EED in the propagation of repressive histone marks," Nature, Nature, vol. 461(7265), pages 762-767, October.
    7. Alistair N. Boettiger & Bogdan Bintu & Jeffrey R. Moffitt & Siyuan Wang & Brian J. Beliveau & Geoffrey Fudenberg & Maxim Imakaev & Leonid A. Mirny & Chao-ting Wu & Xiaowei Zhuang, 2016. "Super-resolution imaging reveals distinct chromatin folding for different epigenetic states," Nature, Nature, vol. 529(7586), pages 418-422, January.
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