Literature DB >> 28535375

MORC-1 Integrates Nuclear RNAi and Transgenerational Chromatin Architecture to Promote Germline Immortality.

Natasha E Weiser1, Danny X Yang2, Suhua Feng3, Natallia Kalinava4, Kristen C Brown5, Jayshree Khanikar6, Mallory A Freeberg7, Martha J Snyder8, Györgyi Csankovszki8, Raymond C Chan6, Sam G Gu4, Taiowa A Montgomery5, Steven E Jacobsen9, John K Kim10.   

Abstract

Germline-expressed endogenous small interfering RNAs (endo-siRNAs) transmit multigenerational epigenetic information to ensure fertility in subsequent generations. In Caenorhabditis elegans, nuclear RNAi ensures robust inheritance of endo-siRNAs and deposition of repressive H3K9me3 marks at target loci. How target silencing is maintained in subsequent generations is poorly understood. We discovered that morc-1 is essential for transgenerational fertility and acts as an effector of endo-siRNAs. Unexpectedly, morc-1 is dispensable for siRNA inheritance but is required for target silencing and maintenance of siRNA-dependent chromatin organization. A forward genetic screen identified mutations in met-1, which encodes an H3K36 methyltransferase, as potent suppressors of morc-1(-) and nuclear RNAi mutant phenotypes. Further analysis of nuclear RNAi and morc-1(-) mutants revealed a progressive, met-1-dependent enrichment of H3K36me3, suggesting that robust fertility requires repression of MET-1 activity at nuclear RNAi targets. Without MORC-1 and nuclear RNAi, MET-1-mediated encroachment of euchromatin leads to detrimental decondensation of germline chromatin and germline mortality.
Copyright © 2017 Elsevier Inc. All rights reserved.

Entities:  

Keywords:  epigenetic inheritance; germline; heterochromatin; histone modification; microrchidia; nuclear RNAi; small RNA

Mesh:

Substances:

Year:  2017        PMID: 28535375      PMCID: PMC5527976          DOI: 10.1016/j.devcel.2017.04.023

Source DB:  PubMed          Journal:  Dev Cell        ISSN: 1534-5807            Impact factor:   12.270


  72 in total

1.  Maternal piRNAs Are Essential for Germline Development following De Novo Establishment of Endo-siRNAs in Caenorhabditis elegans.

Authors:  Bruno F M de Albuquerque; Maria Placentino; René F Ketting
Journal:  Dev Cell       Date:  2015-08-13       Impact factor: 12.270

2.  Computational and analytical framework for small RNA profiling by high-throughput sequencing.

Authors:  Noah Fahlgren; Christopher M Sullivan; Kristin D Kasschau; Elisabeth J Chapman; Jason S Cumbie; Taiowa A Montgomery; Sunny D Gilbert; Mark Dasenko; Tyler W H Backman; Scott A Givan; James C Carrington
Journal:  RNA       Date:  2009-03-23       Impact factor: 4.942

3.  The MRT-1 nuclease is required for DNA crosslink repair and telomerase activity in vivo in Caenorhabditis elegans.

Authors:  Bettina Meier; Louise J Barber; Yan Liu; Ludmila Shtessel; Simon J Boulton; Anton Gartner; Shawn Ahmed
Journal:  EMBO J       Date:  2009-09-24       Impact factor: 11.598

4.  Fast gapped-read alignment with Bowtie 2.

Authors:  Ben Langmead; Steven L Salzberg
Journal:  Nat Methods       Date:  2012-03-04       Impact factor: 28.547

5.  xol-1: a gene that controls the male modes of both sex determination and X chromosome dosage compensation in C. elegans.

Authors:  L M Miller; J D Plenefisch; L P Casson; B J Meyer
Journal:  Cell       Date:  1988-10-07       Impact factor: 41.582

6.  New gene family defined by MORC, a nuclear protein required for mouse spermatogenesis.

Authors:  N Inoue; K D Hess; R W Moreadith; L L Richardson; M A Handel; M L Watson; A R Zinn
Journal:  Hum Mol Genet       Date:  1999-07       Impact factor: 6.150

7.  Epigenetic reprogramming in mouse primordial germ cells.

Authors:  Petra Hajkova; Sylvia Erhardt; Natasha Lane; Thomas Haaf; Osman El-Maarri; Wolf Reik; Jörn Walter; M Azim Surani
Journal:  Mech Dev       Date:  2002-09       Impact factor: 1.882

8.  MORC family ATPases required for heterochromatin condensation and gene silencing.

Authors:  Guillaume Moissiard; Shawn J Cokus; Joshua Cary; Suhua Feng; Allison C Billi; Hume Stroud; Dylan Husmann; Ye Zhan; Bryan R Lajoie; Rachel Patton McCord; Christopher J Hale; Wei Feng; Scott D Michaels; Alison R Frand; Matteo Pellegrini; Job Dekker; John K Kim; Steven E Jacobsen
Journal:  Science       Date:  2012-05-03       Impact factor: 47.728

9.  A nuclear Argonaute promotes multigenerational epigenetic inheritance and germline immortality.

Authors:  Bethany A Buckley; Kirk B Burkhart; Sam Guoping Gu; George Spracklin; Aaron Kershner; Heidi Fritz; Judith Kimble; Andrew Fire; Scott Kennedy
Journal:  Nature       Date:  2012-07-18       Impact factor: 49.962

10.  Trans-generational epigenetic regulation of C. elegans primordial germ cells.

Authors:  Hirofumi Furuhashi; Teruaki Takasaki; Andreas Rechtsteiner; Tengguo Li; Hiroshi Kimura; Paula M Checchi; Susan Strome; William G Kelly
Journal:  Epigenetics Chromatin       Date:  2010-08-12       Impact factor: 4.954
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  21 in total

1.  Natural Genetic Variation in a Multigenerational Phenotype in C. elegans.

Authors:  Lise Frézal; Emilie Demoinet; Christian Braendle; Eric Miska; Marie-Anne Félix
Journal:  Curr Biol       Date:  2018-08-02       Impact factor: 10.834

2.  Dual roles for nuclear RNAi Argonautes in Caenorhabditis elegans dosage compensation.

Authors:  Michael B Davis; Eshna Jash; Bahaar Chawla; Rebecca A Haines; Lillian E Tushman; Ryan Troll; Györgyi Csankovszki
Journal:  Genetics       Date:  2022-05-05       Impact factor: 4.402

3.  Multiple Histone Methyl-Lysine Readers Ensure Robust Development and Germline Immortality in Caenorhabditis elegans.

Authors:  Arneet L Saltzman; Mark W Soo; Reta Aram; Jeannie T Lee
Journal:  Genetics       Date:  2018-09-05       Impact factor: 4.562

4.  SNPC-1.3 is a sex-specific transcription factor that drives male piRNA expression in C. elegans.

Authors:  Charlotte P Choi; Rebecca J Tay; Margaret R Starostik; Suhua Feng; James J Moresco; Brooke E Montgomery; Emily Xu; Maya A Hammonds; Michael C Schatz; Taiowa A Montgomery; John R Yates; Steven E Jacobsen; John K Kim
Journal:  Elife       Date:  2021-02-15       Impact factor: 8.713

5.  Neuropathic MORC2 mutations perturb GHKL ATPase dimerization dynamics and epigenetic silencing by multiple structural mechanisms.

Authors:  Christopher H Douse; Stuart Bloor; Yangci Liu; Maria Shamin; Iva A Tchasovnikarova; Richard T Timms; Paul J Lehner; Yorgo Modis
Journal:  Nat Commun       Date:  2018-02-13       Impact factor: 14.919

Review 6.  MORC Proteins: Novel Players in Plant and Animal Health.

Authors:  Aline Koch; Hong-Gu Kang; Jens Steinbrenner; D'Maris A Dempsey; Daniel F Klessig; Karl-Heinz Kogel
Journal:  Front Plant Sci       Date:  2017-10-18       Impact factor: 5.753

7.  Arabidopsis MORC proteins function in the efficient establishment of RNA directed DNA methylation.

Authors:  Yan Xue; Zhenhui Zhong; C Jake Harris; Javier Gallego-Bartolomé; Ming Wang; Colette Picard; Xueshi Cao; Shan Hua; Ivy Kwok; Suhua Feng; Yasaman Jami-Alahmadi; Jihui Sha; Jason Gardiner; James Wohlschlegel; Steven E Jacobsen
Journal:  Nat Commun       Date:  2021-07-13       Impact factor: 14.919

8.  DAF-18/PTEN inhibits germline zygotic gene activation during primordial germ cell quiescence.

Authors:  Amanda L Fry; Amy K Webster; Julia Burnett; Rojin Chitrakar; L Ryan Baugh; E Jane Albert Hubbard
Journal:  PLoS Genet       Date:  2021-07-21       Impact factor: 5.917

Review 9.  Host sensing and signal transduction during Toxoplasma stage conversion.

Authors:  Leonardo Augusto; Ronald C Wek; William J Sullivan
Journal:  Mol Microbiol       Date:  2020-11-21       Impact factor: 3.979

Review 10.  Repressive Chromatin in Caenorhabditis elegans: Establishment, Composition, and Function.

Authors:  Julie Ahringer; Susan M Gasser
Journal:  Genetics       Date:  2018-02       Impact factor: 4.562
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