Literature DB >> 25733687

Nucleosome spacing generated by ISWI and CHD1 remodelers is constant regardless of nucleosome density.

Corinna Lieleg1, Philip Ketterer2, Johannes Nuebler3, Johanna Ludwigsen1, Ulrich Gerland3, Hendrik Dietz2, Felix Mueller-Planitz4, Philipp Korber4.   

Abstract

Arrays of regularly spaced nucleosomes are a hallmark of chromatin, but it remains unclear how they are generated. Recent genome-wide studies, in vitro and in vivo, showed constant nucleosome spacing even if the histone concentration was experimentally reduced. This counters the long-held assumption that nucleosome density determines spacing and calls for factors keeping spacing constant regardless of nucleosome density. We call this a clamping activity. Here, we show in a purified system that ISWI- and CHD1-type nucleosome remodelers have a clamping activity such that they not only generate regularly spaced nucleosome arrays but also generate constant spacing regardless of nucleosome density. This points to a functionally attractive nucleosome interaction that could be mediated either directly by nucleosome-nucleosome contacts or indirectly through the remodelers. Mutant Drosophila melanogaster ISWI without the Hand-Sant-Slide (HSS) domain had no detectable spacing activity even though it is known to remodel and slide nucleosomes. This suggests that the role of ISWI remodelers in generating constant spacing is not just to mediate nucleosome sliding; they actively contribute to the attractive interaction. Additional factors are necessary to set physiological spacing in absolute terms.
Copyright © 2015, American Society for Microbiology. All Rights Reserved.

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Year:  2015        PMID: 25733687      PMCID: PMC4387221          DOI: 10.1128/MCB.01070-14

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


  75 in total

1.  Chromatin-remodelling factor CHRAC contains the ATPases ISWI and topoisomerase II.

Authors:  P D Varga-Weisz; M Wilm; E Bonte; K Dumas; M Mann; P B Becker
Journal:  Nature       Date:  1997-08-07       Impact factor: 49.962

Review 2.  Intra- and inter-nucleosome interactions of the core histone tail domains in higher-order chromatin structure.

Authors:  Sharon Pepenella; Kevin J Murphy; Jeffrey J Hayes
Journal:  Chromosoma       Date:  2013-08-31       Impact factor: 4.316

3.  Cell-free system for assembly of transcriptionally repressed chromatin from Drosophila embryos.

Authors:  P B Becker; C Wu
Journal:  Mol Cell Biol       Date:  1992-05       Impact factor: 4.272

4.  New DNA sequence rules for high affinity binding to histone octamer and sequence-directed nucleosome positioning.

Authors:  P T Lowary; J Widom
Journal:  J Mol Biol       Date:  1998-02-13       Impact factor: 5.469

5.  ACF, an ISWI-containing and ATP-utilizing chromatin assembly and remodeling factor.

Authors:  T Ito; M Bulger; M J Pazin; R Kobayashi; J T Kadonaga
Journal:  Cell       Date:  1997-07-11       Impact factor: 41.582

6.  Cryo-EM study of the chromatin fiber reveals a double helix twisted by tetranucleosomal units.

Authors:  Feng Song; Ping Chen; Dapeng Sun; Mingzhu Wang; Liping Dong; Dan Liang; Rui-Ming Xu; Ping Zhu; Guohong Li
Journal:  Science       Date:  2014-04-25       Impact factor: 47.728

7.  Statistical distributions of nucleosomes: nonrandom locations by a stochastic mechanism.

Authors:  R D Kornberg; L Stryer
Journal:  Nucleic Acids Res       Date:  1988-07-25       Impact factor: 16.971

8.  Electrostatic mechanism of nucleosome spacing.

Authors:  T A Blank; P B Becker
Journal:  J Mol Biol       Date:  1995-09-22       Impact factor: 5.469

9.  Negative supercoiling and nucleosome cores. II. The effect of negative supercoiling on the positioning of nucleosome cores in vitro.

Authors:  H G Patterton; C von Holt
Journal:  J Mol Biol       Date:  1993-02-05       Impact factor: 5.469

10.  Unusual chromosome structure of fission yeast DNA in mouse cells.

Authors:  J McManus; P Perry; A T Sumner; D M Wright; E J Thomson; R C Allshire; N D Hastie; W A Bickmore
Journal:  J Cell Sci       Date:  1994-03       Impact factor: 5.285
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  23 in total

1.  Identification of a DNA N6-Adenine Methyltransferase Complex and Its Impact on Chromatin Organization.

Authors:  Leslie Y Beh; Galia T Debelouchina; Derek M Clay; Robert E Thompson; Kelsi A Lindblad; Elizabeth R Hutton; John R Bracht; Robert P Sebra; Tom W Muir; Laura F Landweber
Journal:  Cell       Date:  2019-05-16       Impact factor: 41.582

Review 2.  Beads on a string-nucleosome array arrangements and folding of the chromatin fiber.

Authors:  Sandro Baldi; Philipp Korber; Peter B Becker
Journal:  Nat Struct Mol Biol       Date:  2020-02-10       Impact factor: 15.369

3.  Genomic Nucleosome Organization Reconstituted with Pure Proteins.

Authors:  Nils Krietenstein; Megha Wal; Shinya Watanabe; Bongsoo Park; Craig L Peterson; B Franklin Pugh; Philipp Korber
Journal:  Cell       Date:  2016-10-20       Impact factor: 41.582

4.  Differences in nanoscale organization of regulatory active and inactive human chromatin.

Authors:  Katharina Brandstetter; Tilo Zülske; Tobias Ragoczy; David Hörl; Miguel Guirao-Ortiz; Clemens Steinek; Toby Barnes; Gabriela Stumberger; Jonathan Schwach; Eric Haugen; Eric Rynes; Philipp Korber; John A Stamatoyannopoulos; Heinrich Leonhardt; Gero Wedemann; Hartmann Harz
Journal:  Biophys J       Date:  2022-02-10       Impact factor: 4.033

5.  A chromodomain protein mediates heterochromatin-directed piRNA expression.

Authors:  Xinya Huang; Peng Cheng; Chenchun Weng; Zongxiu Xu; Chenming Zeng; Zheng Xu; Xiangyang Chen; Chengming Zhu; Shouhong Guang; Xuezhu Feng
Journal:  Proc Natl Acad Sci U S A       Date:  2021-07-06       Impact factor: 11.205

6.  Genome information processing by the INO80 chromatin remodeler positions nucleosomes.

Authors:  Elisa Oberbeckmann; Nils Krietenstein; Vanessa Niebauer; Yingfei Wang; Kevin Schall; Manuela Moldt; Tobias Straub; Remo Rohs; Karl-Peter Hopfner; Philipp Korber; Sebastian Eustermann
Journal:  Nat Commun       Date:  2021-05-28       Impact factor: 14.919

7.  Ruler elements in chromatin remodelers set nucleosome array spacing and phasing.

Authors:  Elisa Oberbeckmann; Vanessa Niebauer; Shinya Watanabe; Lucas Farnung; Manuela Moldt; Andrea Schmid; Patrick Cramer; Craig L Peterson; Sebastian Eustermann; Karl-Peter Hopfner; Philipp Korber
Journal:  Nat Commun       Date:  2021-05-28       Impact factor: 17.694

Review 8.  Mechanisms of ATP-Dependent Chromatin Remodeling Motors.

Authors:  Coral Y Zhou; Stephanie L Johnson; Nathan I Gamarra; Geeta J Narlikar
Journal:  Annu Rev Biophys       Date:  2016-07-05       Impact factor: 19.763

9.  The ISW1 and CHD1 ATP-dependent chromatin remodelers compete to set nucleosome spacing in vivo.

Authors:  Josefina Ocampo; Răzvan V Chereji; Peter R Eriksson; David J Clark
Journal:  Nucleic Acids Res       Date:  2016-02-09       Impact factor: 16.971

10.  Establishment of a promoter-based chromatin architecture on recently replicated DNA can accommodate variable inter-nucleosome spacing.

Authors:  Ross T Fennessy; Tom Owen-Hughes
Journal:  Nucleic Acids Res       Date:  2016-04-22       Impact factor: 16.971
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