Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 The LRS and SIN domains: two structurally equivalent but functionally distinct nucleosomal surfaces required for transcriptional silencing.

Literature DB >> 17015465

The LRS and SIN domains: two structurally equivalent but functionally distinct nucleosomal surfaces required for transcriptional silencing.

Christopher J Fry¹, Anne Norris, Michael Cosgrove, Jef D Boeke, Craig L Peterson.

Abstract

Genetic experiments have identified two structurally similar nucleosomal domains, SIN and LRS, required for transcriptional repression at genes regulated by the SWI/SNF chromatin remodeling complex or for heterochromatic gene silencing, respectively. Each of these domains consists of histone H3 and H4 L1 and L2 loops that form a DNA-binding surface at either superhelical location (SHL) +/-2.5 (LRS) or SHL +/-0.5 (SIN). Here we show that alterations in the LRS domain do not result in Sin(-) phenotypes, nor does disruption of the SIN domain lead to loss of ribosomal DNA heterochromatic gene silencing (Lrs(-) phenotype). Furthermore, whereas disruption of the SIN domain eliminates intramolecular folding of nucleosomal arrays in vitro, alterations in the LRS domain have no effect on chromatin folding in vitro. In contrast to these dissimilarities, we find that the SIN and LRS domains are both required for recruitment of Sir2p and Sir4p to telomeric and silent mating type loci, suggesting that both surfaces can contribute to heterochromatin formation. Our study shows that structurally similar nucleosomal surfaces provide distinct functionalities in vivo and in vitro.

Entities: Gene Species

Mesh：

Substances：

Year: 2006 PMID： 17015465 PMCID： PMC1636829 DOI： 10.1128/MCB.00248-06

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

36 in total

Review 1. In vivo cross-linking and immunoprecipitation for studying dynamic Protein:DNA associations in a chromatin environment.

Authors: M H Kuo; C D Allis
Journal: Methods Date: 1999-11 Impact factor: 3.608

2. The SIN domain of the histone octamer is essential for intramolecular folding of nucleosomal arrays.

Authors: Peter J Horn; Kimberly A Crowley; Lenny M Carruthers; Jeffrey C Hansen; Craig L Peterson
Journal: Nat Struct Biol Date: 2002-03

3. Identification of a functional domain within the essential core of histone H3 that is required for telomeric and HM silencing in Saccharomyces cerevisiae.

Authors: Jeffrey S Thompson; Marilyn L Snow; Summer Giles; Leslie E McPherson; Michael Grunstein
Journal: Genetics Date: 2003-01 Impact factor: 4.562

4. Ordered nucleation and spreading of silenced chromatin in Saccharomyces cerevisiae.

Authors: Laura N Rusché; Ann L Kirchmaier; Jasper Rine
Journal: Mol Biol Cell Date: 2002-07 Impact factor: 4.138

5. RNA polymerase I propagates unidirectional spreading of rDNA silent chromatin.

Authors: Stephen W Buck; Joseph J Sandmeier; Jeffrey S Smith
Journal: Cell Date: 2002-12-27 Impact factor: 41.582

6. A core nucleosome surface crucial for transcriptional silencing.

Authors: Jeong-Hyun Park; Michael S Cosgrove; Elaine Youngman; Cynthia Wolberger; Jef D Boeke
Journal: Nat Genet Date: 2002-09-16 Impact factor: 38.330

7. Three new dominant drug resistance cassettes for gene disruption in Saccharomyces cerevisiae.

Authors: A L Goldstein; J H McCusker
Journal: Yeast Date: 1999-10 Impact factor: 3.239

8. Dot1p modulates silencing in yeast by methylation of the nucleosome core.

Authors: Fred van Leeuwen; Philip R Gafken; Daniel E Gottschling
Journal: Cell Date: 2002-06-14 Impact factor: 41.582

9. Lysine methylation within the globular domain of histone H3 by Dot1 is important for telomeric silencing and Sir protein association.

Authors: Huck Hui Ng; Qin Feng; Hengbin Wang; Hediye Erdjument-Bromage; Paul Tempst; Yi Zhang; Kevin Struhl
Journal: Genes Dev Date: 2002-06-15 Impact factor: 11.361

10. Rap1-Sir4 binding independent of other Sir, yKu, or histone interactions initiates the assembly of telomeric heterochromatin in yeast.

Authors: Kunheng Luo; Miguel A Vega-Palas; Michael Grunstein
Journal: Genes Dev Date: 2002-06-15 Impact factor: 11.361

21 in total

1. Interplay of chromatin modifiers on a short basic patch of histone H4 tail defines the boundary of telomeric heterochromatin.

Authors: Mohammed Altaf; Rhea T Utley; Nicolas Lacoste; Song Tan; Scott D Briggs; Jacques Côté
Journal: Mol Cell Date: 2007-12-28 Impact factor: 17.970

2. Histone H3 K36 methylation is mediated by a trans-histone methylation pathway involving an interaction between Set2 and histone H4.

Authors: Hai-Ning Du; Ian M Fingerman; Scott D Briggs
Journal: Genes Dev Date: 2008-10-15 Impact factor: 11.361

3. Novel functional residues in the core domain of histone H2B regulate yeast gene expression and silencing and affect the response to DNA damage.

Authors: McKenna N M Kyriss; Yi Jin; Isaura J Gallegos; James A Sanford; John J Wyrick
Journal: Mol Cell Biol Date: 2010-05-17 Impact factor: 4.272

4. Differential contributions of histone H3 and H4 residues to heterochromatin structure.

Authors: Qun Yu; Lars Olsen; Xinmin Zhang; Jef D Boeke; Xin Bi
Journal: Genetics Date: 2011-03-24 Impact factor: 4.562

5. Histone fold modifications control nucleosome unwrapping and disassembly.

Authors: Marek Simon; Justin A North; John C Shimko; Robert A Forties; Michelle B Ferdinand; Mridula Manohar; Meng Zhang; Richard Fishel; Jennifer J Ottesen; Michael G Poirier
Journal: Proc Natl Acad Sci U S A Date: 2011-07-18 Impact factor: 11.205

6. Histone Sprocket Arginine Residues Are Important for Gene Expression, DNA Repair, and Cell Viability in Saccharomyces cerevisiae.

Authors: Amelia J Hodges; Isaura J Gallegos; Marian F Laughery; Rithy Meas; Linh Tran; John J Wyrick
Journal: Genetics Date: 2015-05-12 Impact factor: 4.562