Literature DB >> 18381894

DNA methylation of retrotransposon genes is regulated by Piwi family members MILI and MIWI2 in murine fetal testes.

Satomi Kuramochi-Miyagawa1, Toshiaki Watanabe, Kengo Gotoh, Yasushi Totoki, Atsushi Toyoda, Masahito Ikawa, Noriko Asada, Kanako Kojima, Yuka Yamaguchi, Takashi W Ijiri, Kenichiro Hata, En Li, Yoichi Matsuda, Tohru Kimura, Masaru Okabe, Yoshiyuki Sakaki, Hiroyuki Sasaki, Toru Nakano.   

Abstract

Silencing of transposable elements occurs during fetal gametogenesis in males via de novo DNA methylation of their regulatory regions. The loss of MILI (miwi-like) and MIWI2 (mouse piwi 2), two mouse homologs of Drosophila Piwi, activates retrotransposon gene expression by impairing DNA methylation in the regulatory regions of the retrotransposons. However, as it is unclear whether the defective DNA methylation in the mutants is due to the impairment of de novo DNA methylation, we analyze DNA methylation and Piwi-interacting small RNA (piRNA) expression in wild-type, MILI-null, and MIWI2-null male fetal germ cells. We reveal that defective DNA methylation of the regulatory regions of the Line-1 (long interspersed nuclear elements) and IAP (intracisternal A particle) retrotransposons in the MILI-null and MIWI2-null male germ cells takes place at the level of de novo methylation. Comprehensive analysis shows that the piRNAs of fetal germ cells are distinct from those previously identified in neonatal and adult germ cells. The expression of piRNAs is reduced under MILI- and MIWI2-null conditions in fetal germ cells, although the extent of the reduction differs significantly between the two mutants. Our data strongly suggest that MILI and MIWI2 play essential roles in establishing de novo DNA methylation of retrotransposons in fetal male germ cells.

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Year:  2008        PMID: 18381894      PMCID: PMC2279202          DOI: 10.1101/gad.1640708

Source DB:  PubMed          Journal:  Genes Dev        ISSN: 0890-9369            Impact factor:   11.361


  34 in total

1.  Initial sequencing and analysis of the human genome.

Authors:  E S Lander; L M Linton; B Birren; C Nusbaum; M C Zody; J Baldwin; K Devon; K Dewar; M Doyle; W FitzHugh; R Funke; D Gage; K Harris; A Heaford; J Howland; L Kann; J Lehoczky; R LeVine; P McEwan; K McKernan; J Meldrim; J P Mesirov; C Miranda; W Morris; J Naylor; C Raymond; M Rosetti; R Santos; A Sheridan; C Sougnez; Y Stange-Thomann; N Stojanovic; A Subramanian; D Wyman; J Rogers; J Sulston; R Ainscough; S Beck; D Bentley; J Burton; C Clee; N Carter; A Coulson; R Deadman; P Deloukas; A Dunham; I Dunham; R Durbin; L French; D Grafham; S Gregory; T Hubbard; S Humphray; A Hunt; M Jones; C Lloyd; A McMurray; L Matthews; S Mercer; S Milne; J C Mullikin; A Mungall; R Plumb; M Ross; R Shownkeen; S Sims; R H Waterston; R K Wilson; L W Hillier; J D McPherson; M A Marra; E R Mardis; L A Fulton; A T Chinwalla; K H Pepin; W R Gish; S L Chissoe; M C Wendl; K D Delehaunty; T L Miner; A Delehaunty; J B Kramer; L L Cook; R S Fulton; D L Johnson; P J Minx; S W Clifton; T Hawkins; E Branscomb; P Predki; P Richardson; S Wenning; T Slezak; N Doggett; J F Cheng; A Olsen; S Lucas; C Elkin; E Uberbacher; M Frazier; R A Gibbs; D M Muzny; S E Scherer; J B Bouck; E J Sodergren; K C Worley; C M Rives; J H Gorrell; M L Metzker; S L Naylor; R S Kucherlapati; D L Nelson; G M Weinstock; Y Sakaki; A Fujiyama; M Hattori; T Yada; A Toyoda; T Itoh; C Kawagoe; H Watanabe; Y Totoki; T Taylor; J Weissenbach; R Heilig; W Saurin; F Artiguenave; P Brottier; T Bruls; E Pelletier; C Robert; P Wincker; D R Smith; L Doucette-Stamm; M Rubenfield; K Weinstock; H M Lee; J Dubois; A Rosenthal; M Platzer; G Nyakatura; S Taudien; A Rump; H Yang; J Yu; J Wang; G Huang; J Gu; L Hood; L Rowen; A Madan; S Qin; R W Davis; N A Federspiel; A P Abola; M J Proctor; R M Myers; J Schmutz; M Dickson; J Grimwood; D R Cox; M V Olson; R Kaul; C Raymond; N Shimizu; K Kawasaki; S Minoshima; G A Evans; M Athanasiou; R Schultz; B A Roe; F Chen; H Pan; J Ramser; H Lehrach; R Reinhardt; W R McCombie; M de la Bastide; N Dedhia; H Blöcker; K Hornischer; G Nordsiek; R Agarwala; L Aravind; J A Bailey; A Bateman; S Batzoglou; E Birney; P Bork; D G Brown; C B Burge; L Cerutti; H C Chen; D Church; M Clamp; R R Copley; T Doerks; S R Eddy; E E Eichler; T S Furey; J Galagan; J G Gilbert; C Harmon; Y Hayashizaki; D Haussler; H Hermjakob; K Hokamp; W Jang; L S Johnson; T A Jones; S Kasif; A Kaspryzk; S Kennedy; W J Kent; P Kitts; E V Koonin; I Korf; D Kulp; D Lancet; T M Lowe; A McLysaght; T Mikkelsen; J V Moran; N Mulder; V J Pollara; C P Ponting; G Schuler; J Schultz; G Slater; A F Smit; E Stupka; J Szustakowki; D Thierry-Mieg; J Thierry-Mieg; L Wagner; J Wallis; R Wheeler; A Williams; Y I Wolf; K H Wolfe; S P Yang; R F Yeh; F Collins; M S Guyer; J Peterson; A Felsenfeld; K A Wetterstrand; A Patrinos; M J Morgan; P de Jong; J J Catanese; K Osoegawa; H Shizuya; S Choi; Y J Chen; J Szustakowki
Journal:  Nature       Date:  2001-02-15       Impact factor: 49.962

2.  Resistance of IAPs to methylation reprogramming may provide a mechanism for epigenetic inheritance in the mouse.

Authors:  Natasha Lane; Wendy Dean; Sylvia Erhardt; Petra Hajkova; Azim Surani; Jörn Walter; Wolf Reik
Journal:  Genesis       Date:  2003-02       Impact factor: 2.487

3.  Germline-specific expression of the Oct-4/green fluorescent protein (GFP) transgene in mice.

Authors:  T Yoshimizu; N Sugiyama; M De Felice; Y I Yeom; K Ohbo; K Masuko; M Obinata; K Abe; H R Schöler; Y Matsui
Journal:  Dev Growth Differ       Date:  1999-12       Impact factor: 2.053

4.  Two mouse piwi-related genes: miwi and mili.

Authors:  S Kuramochi-Miyagawa; T Kimura; K Yomogida; A Kuroiwa; Y Tadokoro; Y Fujita; M Sato; Y Matsuda; T Nakano
Journal:  Mech Dev       Date:  2001-10       Impact factor: 1.882

5.  The mouse homolog of Drosophila Vasa is required for the development of male germ cells.

Authors:  S S Tanaka; Y Toyooka; R Akasu; Y Katoh-Fukui; Y Nakahara; R Suzuki; M Yokoyama; T Noce
Journal:  Genes Dev       Date:  2000-04-01       Impact factor: 11.361

6.  Evidence for a piwi-dependent RNA silencing of the gypsy endogenous retrovirus by the Drosophila melanogaster flamenco gene.

Authors:  Emeline Sarot; Geneviève Payen-Groschêne; Alain Bucheton; Alain Pélisson
Journal:  Genetics       Date:  2004-03       Impact factor: 4.562

7.  Meiotic catastrophe and retrotransposon reactivation in male germ cells lacking Dnmt3L.

Authors:  Déborah Bourc'his; Timothy H Bestor
Journal:  Nature       Date:  2004-08-18       Impact factor: 49.962

8.  Mili, a mammalian member of piwi family gene, is essential for spermatogenesis.

Authors:  Satomi Kuramochi-Miyagawa; Tohru Kimura; Takashi W Ijiri; Taku Isobe; Noriko Asada; Yukiko Fujita; Masahito Ikawa; Naomi Iwai; Masaru Okabe; Wei Deng; Haifan Lin; Yoichi Matsuda; Toru Nakano
Journal:  Development       Date:  2004-01-21       Impact factor: 6.868

9.  Retrotransposition of limited deletion type of intracisternal A-particle elements in the myeloid leukemia Clls of C3H/He mice.

Authors:  Hiroshi Ishihara; Izumi Tanaka; Hong Wan; Kumie Nojima; Kazuko Yoshida
Journal:  J Radiat Res       Date:  2004-03       Impact factor: 2.724

10.  Role of the Dnmt3 family in de novo methylation of imprinted and repetitive sequences during male germ cell development in the mouse.

Authors:  Yuzuru Kato; Masahiro Kaneda; Kenichiro Hata; Kenji Kumaki; Mizue Hisano; Yuji Kohara; Masaki Okano; En Li; Masami Nozaki; Hiroyuki Sasaki
Journal:  Hum Mol Genet       Date:  2007-07-06       Impact factor: 6.150
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  388 in total

1.  Mouse MOV10L1 associates with Piwi proteins and is an essential component of the Piwi-interacting RNA (piRNA) pathway.

Authors:  Ke Zheng; Jordi Xiol; Michael Reuter; Sigrid Eckardt; N Adrian Leu; K John McLaughlin; Alexander Stark; Ravi Sachidanandam; Ramesh S Pillai; Peijing Jeremy Wang
Journal:  Proc Natl Acad Sci U S A       Date:  2010-06-01       Impact factor: 11.205

Review 2.  Active human retrotransposons: variation and disease.

Authors:  Dustin C Hancks; Haig H Kazazian
Journal:  Curr Opin Genet Dev       Date:  2012-03-08       Impact factor: 5.578

3.  Locus- and domain-dependent control of DNA methylation at mouse B1 retrotransposons during male germ cell development.

Authors:  Kenji Ichiyanagi; Yufeng Li; Yungfeng Li; Toshiaki Watanabe; Tomoko Ichiyanagi; Kei Fukuda; Junko Kitayama; Yasuhiro Yamamoto; Satomi Kuramochi-Miyagawa; Toru Nakano; Yukihiro Yabuta; Yoshiyuki Seki; Mitinori Saitou; Hiroyuki Sasaki
Journal:  Genome Res       Date:  2011-10-31       Impact factor: 9.043

Review 4.  Argonaute and the nuclear RNAs: new pathways for RNA-mediated control of gene expression.

Authors:  Keith T Gagnon; David R Corey
Journal:  Nucleic Acid Ther       Date:  2012-01-27       Impact factor: 5.486

Review 5.  Male germline control of transposable elements.

Authors:  Jianqiang Bao; Wei Yan
Journal:  Biol Reprod       Date:  2012-05-31       Impact factor: 4.285

Review 6.  Regulation of small RNA stability: methylation and beyond.

Authors:  Lijuan Ji; Xuemei Chen
Journal:  Cell Res       Date:  2012-03-13       Impact factor: 25.617

Review 7.  Small RNAs as guardians of the genome.

Authors:  Colin D Malone; Gregory J Hannon
Journal:  Cell       Date:  2009-02-20       Impact factor: 41.582

Review 8.  Post-transcriptional regulation of LINE-1 retrotransposition by AID/APOBEC and ADAR deaminases.

Authors:  Elisa Orecchini; Loredana Frassinelli; Silvia Galardi; Silvia Anna Ciafrè; Alessandro Michienzi
Journal:  Chromosome Res       Date:  2018-02-02       Impact factor: 5.239

Review 9.  The rise of regulatory RNA.

Authors:  Kevin V Morris; John S Mattick
Journal:  Nat Rev Genet       Date:  2014-04-29       Impact factor: 53.242

10.  Meiosis arrest female 1 (MARF1) has nuage-like function in mammalian oocytes.

Authors:  You-Qiang Su; Fengyun Sun; Mary Ann Handel; John C Schimenti; John J Eppig
Journal:  Proc Natl Acad Sci U S A       Date:  2012-10-22       Impact factor: 11.205
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