Chromatin remodelling at promoters suppresses antisense transcription

Whitehouse, Iestyn; Rando, Oliver J.; Delrow, Jeffery J.; Tsukiyama, Toshio

doi:10.1038/nature06391

Cited by 383 publications

(494 citation statements)

References 48 publications

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“…This is consistent with the fact that chromatin regulators may control the interbarrier distance L and in turn the distance L (; L À188 bp) via the statistical ordering imposed by nucleosome excluding barriers. Note that in the precise case of Iswi2 remodeling (Whitehouse et al 2007), we did not obtain conclusive results concerning the crystal/bi-stable nature of the target genes (data not shown). When compared to crystal genes, bi-stable genes are thus highly plastic, with a wide dynamic range of expression level as the signature of a more dynamic and regulated chromatin structure.…”

Section: Proof Onlymentioning

confidence: 44%

Thermodynamics of Intragenic Nucleosome Ordering

et al. 2009

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Numerous AU2studies of chromatin structure showed that nucleosome free regions (NFRs) located at 59 gene ends contribute to transcription initiation regulation. Here, we determine the role of intragenic chromatin structure on gene expression regulation. We show that, along Saccharomyces cerevisiae genes, nucleosomes are highly organized following two types of architecture that depend only on the distance between the NFRs located at the 59 and 39 gene ends. In the first type, this distance constrains in vivo the positioning of n nucleosomes regularly organized in a ''crystal-like'' array. In the second type, this distance is such that the corresponding genes can accommodate either n or (n + 1) nucleosomes, thereby displaying two possible crystal-like arrays of n weakly compacted or n + 1 highly compacted nucleosomes. This adaptability confers ''bistable'' properties to chromatin and is a key to its dynamics. Compared to crystal-like genes, bi-stable genes present higher transcriptional plasticity, higher sensitivity to chromatin regulators, higher H3 turnover rate, and lower H2A.Z enrichment. The results strongly suggest that transcription elongation is facilitated by higher chromatin compaction. The data allow us to propose a new paradigm of transcriptional control mediated by the stability and the level of compaction of the intragenic chromatin architecture and open new ways for investigating eukaryotic gene expression regulation.

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Section: Proof Onlymentioning

confidence: 44%

Thermodynamics of Intragenic Nucleosome Ordering

et al. 2009

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“…Genome-wide chromatin remodeling by ISW2 near promoters and in coding regions increases nucleosome density and enforces the accuracy of transcription (Yadon et al 2010). More specifically, the isw2 and isw1 complexes contribute to the positioning of nucleosomes in intergenic regions or in the middle of genes, respectively, which suppresses cryptic, antisense transcription that would otherwise pose a risk of interfering with sense transcription (Whitehouse et al 2007;Tirosh et al 2010). The positioning and phasing of nucleosomes around transcription start sites in yeast, which frequently carry information in the form of histone variants and specific modifications, are brought about by the RSC complex in S. cerevisiae Zhang et al 2011).…”

Section: Nucleosome Remodeling In Chromatin Assembly and Organizationmentioning

confidence: 99%

Nucleosome Remodeling and Epigenetics

Becker

Workman

2013

Cold Spring Harbor Perspectives in Biology

262

203

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“…Conceivably, under energy-rich growth conditions, nucleosomes may be actively placed in thermodynamically less favorable positions at carbon-responsive genes, a concept whose mechanism has been developed elsewhere (Whitehouse et al 2007). Under comparatively lower energy states in carbon-depleted media, this Figure 6.…”

Section: Regulation Of Transcription Initiation By +1 Nucleosome Repomentioning

confidence: 99%

Stable and dynamic nucleosome states during a meiotic developmental process

Zhang

Mā²,

Pugh³

2011

Genome Res.

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The plasticity of chromatin organization as chromosomes undergo a full compendium of transactions including DNA replication, recombination, chromatin compaction, and changes in transcription during a developmental program is unknown. We generated genome-wide maps of individual nucleosome organizational states, including positions and occupancy of all nucleosomes, and H3K9 acetylation and H3K4, K36, K79 tri-methylation, during meiotic spore development (gametogenesis) in Saccharomyces. Nucleosome organization was remarkably constant as the genome underwent compaction. However, during an acute meiotic starvation response, nucleosomes were repositioned to alter the accessibility of select transcriptional start sites. Surprisingly, the majority of the meiotic programs did not use this nucleosome repositioning, but was dominated by antisense control. Histone modification states were also remarkably stable, being abundant at specific nucleosome positions at three-quarters of all genes, despite most genes being rarely transcribed. Our findings suggest that, during meiosis, the basic features of genomic chromatin organization are essentially a fixed property of chromosomes, but tweaked in a restricted and program-specific manner.

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Chromatin remodelling at promoters suppresses antisense transcription

Cited by 383 publications

References 48 publications

Thermodynamics of Intragenic Nucleosome Ordering

Thermodynamics of Intragenic Nucleosome Ordering

Nucleosome Remodeling and Epigenetics

Stable and dynamic nucleosome states during a meiotic developmental process

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