Literature DB >> 19273607

Nucleosome remodeling and transcriptional repression are distinct functions of Isw1 in Saccharomyces cerevisiae.

Marina Pinskaya1, Anitha Nair, David Clynes, Antonin Morillon, Jane Mellor.   

Abstract

The SANT domain is a nucleosome recognition module found in transcriptional regulatory proteins, including chromatin-modifying enzymes. It shows high functional degeneracy between species, varying in sequence and copy number. Here, we investigate functions in vivo associated with two SANT motifs, SANT and SLIDE, in the Saccharomyces cerevisiae Isw1 chromatin-remodeling ATPase. We show that differences in the primary structures of the SANT and SLIDE domains in yeast and Drosophila melanogaster reflect their different functions. In yeast, the SLIDE domain is required for histone interactions, while this is a function of the SANT domain in flies. In yeast, both motifs are required for optimal association with chromatin and for formation of the Isw1b complex (Isw1, Ioc2, and Ioc4). Moreover, nucleosome remodeling at the MET16 locus is defective in strains lacking the SANT or SLIDE domain. In contrast, the SANT domain is dispensable for the interaction between Isw1 and Ioc3 in the Isw1a complex. We show that, although defective in nucleosome remodeling, Isw1 lacking the SANT domain is able to repress transcription initiation at the MET16 promoter. Thus, chromatin remodeling and transcriptional repression are distinct activities of Isw1.

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Year:  2009        PMID: 19273607      PMCID: PMC2668368          DOI: 10.1128/MCB.01050-08

Source DB:  PubMed          Journal:  Mol Cell Biol        ISSN: 0270-7306            Impact factor:   4.272


  60 in total

1.  Critical role for the histone H4 N terminus in nucleosome remodeling by ISWI.

Authors:  C R Clapier; G Längst; D F Corona; P B Becker; K P Nightingale
Journal:  Mol Cell Biol       Date:  2001-02       Impact factor: 4.272

2.  In vivo chromatin remodeling by yeast ISWI homologs Isw1p and Isw2p.

Authors:  N A Kent; N Karabetsou; P K Politis; J Mellor
Journal:  Genes Dev       Date:  2001-03-01       Impact factor: 11.361

3.  Regulation of NuA4 histone acetyltransferase activity in transcription and DNA repair by phosphorylation of histone H4.

Authors:  Rhea T Utley; Nicolas Lacoste; Olivier Jobin-Robitaille; Stéphane Allard; Jacques Côté
Journal:  Mol Cell Biol       Date:  2005-09       Impact factor: 4.272

4.  Proteome survey reveals modularity of the yeast cell machinery.

Authors:  Anne-Claude Gavin; Patrick Aloy; Paola Grandi; Roland Krause; Markus Boesche; Martina Marzioch; Christina Rau; Lars Juhl Jensen; Sonja Bastuck; Birgit Dümpelfeld; Angela Edelmann; Marie-Anne Heurtier; Verena Hoffman; Christian Hoefert; Karin Klein; Manuela Hudak; Anne-Marie Michon; Malgorzata Schelder; Markus Schirle; Marita Remor; Tatjana Rudi; Sean Hooper; Andreas Bauer; Tewis Bouwmeester; Georg Casari; Gerard Drewes; Gitte Neubauer; Jens M Rick; Bernhard Kuster; Peer Bork; Robert B Russell; Giulio Superti-Furga
Journal:  Nature       Date:  2006-01-22       Impact factor: 49.962

5.  Double chromodomains cooperate to recognize the methylated histone H3 tail.

Authors:  John F Flanagan; Li-Zhi Mi; Maksymilian Chruszcz; Marcin Cymborowski; Katrina L Clines; Youngchang Kim; Wladek Minor; Fraydoon Rastinejad; Sepideh Khorasanizadeh
Journal:  Nature       Date:  2005-12-22       Impact factor: 49.962

6.  Modulation of ISWI function by site-specific histone acetylation.

Authors:  Davide F V Corona; Cedric R Clapier; Peter B Becker; John W Tamkun
Journal:  EMBO Rep       Date:  2002-03       Impact factor: 8.807

7.  Histone H3 tail positioning and acetylation by the c-Myb but not the v-Myb DNA-binding SANT domain.

Authors:  Xianming Mo; Elisabeth Kowenz-Leutz; Yves Laumonnier; Hong Xu; Achim Leutz
Journal:  Genes Dev       Date:  2005-09-29       Impact factor: 11.361

8.  Phosphorylation of histone H4 serine 1 during DNA damage requires casein kinase II in S. cerevisiae.

Authors:  Wang L Cheung; Fiona B Turner; Thanuja Krishnamoorthy; Branden Wolner; Sung-Hee Ahn; Melissa Foley; Jean A Dorsey; Craig L Peterson; Shelley L Berger; C David Allis
Journal:  Curr Biol       Date:  2005-04-12       Impact factor: 10.834

9.  Recognition of histone H3 lysine-4 methylation by the double tudor domain of JMJD2A.

Authors:  Ying Huang; Jia Fang; Mark T Bedford; Yi Zhang; Rui-Ming Xu
Journal:  Science       Date:  2006-04-06       Impact factor: 47.728

10.  The ISWI and CHD1 chromatin remodelling activities influence ADH2 expression and chromatin organization.

Authors:  Barbara Xella; Colin Goding; Eleonora Agricola; Ernesto Di Mauro; Micaela Caserta
Journal:  Mol Microbiol       Date:  2006-03       Impact factor: 3.501
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  13 in total

Review 1.  Nucleosome sliding mechanisms: new twists in a looped history.

Authors:  Felix Mueller-Planitz; Henrike Klinker; Peter B Becker
Journal:  Nat Struct Mol Biol       Date:  2013-09       Impact factor: 15.369

2.  Identification and characterization of ToRC, a novel ISWI-containing ATP-dependent chromatin assembly complex.

Authors:  Alexander V Emelyanov; Elena Vershilova; Maria A Ignatyeva; Daniil K Pokrovsky; Xingwu Lu; Alexander Y Konev; Dmitry V Fyodorov
Journal:  Genes Dev       Date:  2012-03-15       Impact factor: 11.361

3.  Structure and mechanism of the chromatin remodelling factor ISW1a.

Authors:  Kazuhiro Yamada; Timothy D Frouws; Brigitte Angst; Daniel J Fitzgerald; Carl DeLuca; Kyoko Schimmele; David F Sargent; Timothy J Richmond
Journal:  Nature       Date:  2011-04-28       Impact factor: 49.962

4.  Widespread remodeling of mid-coding sequence nucleosomes by Isw1.

Authors:  Itay Tirosh; Nadejda Sigal; Naama Barkai
Journal:  Genome Biol       Date:  2010-05-10       Impact factor: 13.583

5.  Functional antagonism between Sas3 and Gcn5 acetyltransferases and ISWI chromatin remodelers.

Authors:  Anne Lafon; Emily Petty; Lorraine Pillus
Journal:  PLoS Genet       Date:  2012-10-04       Impact factor: 5.917

6.  The DNA-binding domain of the Chd1 chromatin-remodelling enzyme contains SANT and SLIDE domains.

Authors:  Daniel P Ryan; Ramasubramanian Sundaramoorthy; David Martin; Vijender Singh; Tom Owen-Hughes
Journal:  EMBO J       Date:  2011-05-27       Impact factor: 11.598

7.  ATP-independent cooperative binding of yeast Isw1a to bare and nucleosomal DNA.

Authors:  Anne De Cian; Elise Praly; Fangyuan Ding; Vijender Singh; Christophe Lavelle; Eric Le Cam; Vincent Croquette; Olivier Piétrement; David Bensimon
Journal:  PLoS One       Date:  2012-02-16       Impact factor: 3.240

8.  The SNF2-family member Fun30 promotes gene silencing in heterochromatic loci.

Authors:  Ana Neves-Costa; W Ryan Will; Anna T Vetter; J Ross Miller; Patrick Varga-Weisz
Journal:  PLoS One       Date:  2009-12-01       Impact factor: 3.240

9.  Nucleosome mobilization by ISW2 requires the concerted action of the ATPase and SLIDE domains.

Authors:  Swetansu K Hota; Saurabh K Bhardwaj; Sebastian Deindl; Yuan-chi Lin; Xiaowei Zhuang; Blaine Bartholomew
Journal:  Nat Struct Mol Biol       Date:  2013-01-20       Impact factor: 15.369

10.  Chromatin remodelers Isw1 and Chd1 maintain chromatin structure during transcription by preventing histone exchange.

Authors:  Michaela Smolle; Swaminathan Venkatesh; Madelaine M Gogol; Hua Li; Ying Zhang; Laurence Florens; Michael P Washburn; Jerry L Workman
Journal:  Nat Struct Mol Biol       Date:  2012-08-26       Impact factor: 15.369
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