Activation of <i>Saccharomyces cerevisiae HIS3</i> Results in Gcn4p-Dependent, SWI/SNF-Dependent Mobilization of Nucleosomes over the Entire Gene

Kim, Yeonjung; McLaughlin, Neil; Lindstrom, Kim; Tsukiyama, Toshio; Clark, David

doi:10.1128/mcb.00678-06

Cited by 54 publications

(75 citation statements)

References 47 publications

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“…The INO1 ORF and its promoter are organized into a set of well-positioned overlapping nucleosomes during repressing conditions. Such overlapping chromatin structures were also observed in other genes such as CUP1 (28,35) and HIS3 (36). It is interesting to observe overlapping positions under repressing conditions.…”

Section: Discussionmentioning

confidence: 61%

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A SWI/SNF- and INO80-dependent nucleosome movement at the INO1 promoter

Ford

Odeyale

Eskandar

et al. 2007

Biochemical and Biophysical Research Communications

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Transcriptional activation in yeast INO1 chromatin was studied using the indirect end-labeling technique. INO1 chromatin is organized into an ordered, overlapping nucleosomal array under repressing conditions. Nucleosome positions were only disrupted at the promoter region under inducing conditions in the presence of SWI/SNF and INO80. Mutants lacking either remodeler demonstrated identical positioning patterns as the wild type under repressing conditions. This indicates that these two remodelers are responsible and essential for local nucleosomal mobilization at the INO1 promoter. The area of local nucleosome movement is consistent with the previously identified region of histone deacetylation activity. In light of these findings, we suggest that nucleosomes subject to local mobilization are also targets for local histone modifications.

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Section: Discussionmentioning

confidence: 61%

“…This differs from previous observations in other genes. For example, in HIS3, both SWI/SNF and ISW1 act synergistically in induction (36). The ISW1 complex plays a more subtle role in nucleosome mobilization over HIS3, favoring positions different from those preferred by SWI/SNF.…”

Section: Discussionmentioning

confidence: 99%

A SWI/SNF- and INO80-dependent nucleosome movement at the INO1 promoter

Ford

Odeyale

Eskandar

et al. 2007

Biochemical and Biophysical Research Communications

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Section: Introductionmentioning

confidence: 99%

“…Consistent with this notion, several examples have been reported in which gene induction involves recruitment to a promoter of chromatin remodeling factors and histone modifying activities designed to remove or reposition a nucleosome to allow access to an otherwise masked transcription factor binding site (Li et al, 2007;Williams and Tyler, 2007). For example, remodeling factors act at the above-mentioned promoters for PHO5, GAL1, CUP1, and SUC2 to facilitate nucleosome loss on transcriptional activation and conversely to assemble or stabilize nucleosomes on the gene promoter during transcriptional repression (Almer et al, 1986;Fedor and Kornberg, 1989;Shen et al, 2001;Kim et al, 2006).Chromatin can also play a more passive role in gene regulation by simply controlling which transcription factor binding sites are available for participation in gene regulation. Recent genome-wide studies of nucleosome positioning found that most yeast promoters contain an extended nucleosome-depleted region (NDR) that is enriched for transcription factor binding sites (Lee et al, 2004;Yuan et al, 2005;Lee et al, 2007;Mavrich et al, 2008;Shivaswamy et al, 2008).…”

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confidence: 99%

Chromatin-dependent Transcription Factor Accessibility Rather than Nucleosome Remodeling Predominates during Global Transcriptional Restructuring in Saccharomyces cerevisiae

Zawadzki

Morozov

Broach

2009

MBoC

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Several well-studied promoters in yeast lose nucleosomes upon transcriptional activation and gain them upon repression, an observation that has prompted the model that transcriptional activation and repression requires nucleosome remodeling of regulated promoters. We have examined global nucleosome positioning before and after glucose-induced transcriptional reprogramming, a condition under which more than half of all yeast genes significantly change expression. The majority of induced and repressed genes exhibit no change in promoter nucleosome arrangement, although promoters that do undergo nucleosome remodeling tend to contain a TATA box. Rather, we found multiple examples where the pre-existing accessibility of putative transcription factor binding sites before glucose addition determined whether the corresponding gene would change expression in response to glucose addition. These results suggest that selection of appropriate transcription factor binding sites may be dictated to a large extent by nucleosome prepositioning but that regulation of expression through these sites is dictated not by nucleosome repositioning but by changes in transcription factor activity. INTRODUCTIONChromatin, whose basic unit is a nucleosome that consists of 147 base pairs of DNA wrapped twice around a histone octamer, plays a central role in the regulation of genes. Several experiments in yeast have shown that nucleosome depletion causes derepression of PHO5, GAL1, CUP1, SUC2, and HIS3 in the absence of their transcriptional activators Durrin et al., 1992;Hirschhorn et al., 1992). These observations suggested that nucleosomes in promoters can function as nonspecific repressors, consistent with the concept that DNA sequences incorporated into nucleosomes are less accessible to DNA binding proteins such as transcription factors (Morse, 2003(Morse, , 2007. Subsequent observations have demonstrated that chromatin structure can participate actively in gene regulation through repositioning of nucleosomes so as to block access of a transcription factor to its cognate binding sites or to remove a barrier to such access. Consistent with this notion, several examples have been reported in which gene induction involves recruitment to a promoter of chromatin remodeling factors and histone modifying activities designed to remove or reposition a nucleosome to allow access to an otherwise masked transcription factor binding site (Li et al., 2007;Williams and Tyler, 2007). For example, remodeling factors act at the above-mentioned promoters for PHO5, GAL1, CUP1, and SUC2 to facilitate nucleosome loss on transcriptional activation and conversely to assemble or stabilize nucleosomes on the gene promoter during transcriptional repression (Almer et al., 1986;Fedor and Kornberg, 1989;Shen et al., 2001;Kim et al., 2006).Chromatin can also play a more passive role in gene regulation by simply controlling which transcription factor binding sites are available for participation in gene regulation. Recent genome-wide studies of nucleosome positioning fo...

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“…These remodelers hydrolyze ATP to alter the contacts between histone octamers and DNA, resulting in nucleosome movement. The effects of individual remodelers on certain genes have been extensively characterized [5][6][7][8]. However, it is becoming clear that the regulation of some, if not all yeast genes, including HIS3 [7] and INO1 [8], requires more than one remodeler.…”

Section: Introductionmentioning

confidence: 99%

Activator-dependent recruitment of SWI/SNF and INO80 during INO1 activation

Ford¹,

Odeyale²,

Shen³

2008

Biochemical and Biophysical Research Communications

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Transcriptional activation of yeast INO1 requires SWI/SNF and INO80 for nucleosome disruption at the promoter. However, the cooperative interplay among remodelers and their recruitment dynamics in activation have thus far been vague. Here, we showed, using chromatin immunoprecipitation, that both SWI/SNF and INO80 are present at the promoter and are restricted to the promoter, indicating that they directly participate in localized INO1 chromatin remodeling. Furthermore, both SWI/SNF and INO80 are absent at the INO1 promoter in ino2Δ cells, suggesting that these are activator-dependent remodelers. We have also found that the presence of INO80 is required for SWI/SNF recruitment, indicating that INO80 arrives first at the promoter followed by SWI/SNF. In light of these findings, we proposed a model which describes the order of events in INO1 activation.

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Activation of Saccharomyces cerevisiae HIS3 Results in Gcn4p-Dependent, SWI/SNF-Dependent Mobilization of Nucleosomes over the Entire Gene

Cited by 54 publications

References 47 publications

A SWI/SNF- and INO80-dependent nucleosome movement at the INO1 promoter

A SWI/SNF- and INO80-dependent nucleosome movement at the INO1 promoter

Chromatin-dependent Transcription Factor Accessibility Rather than Nucleosome Remodeling Predominates during Global Transcriptional Restructuring in Saccharomyces cerevisiae

Activator-dependent recruitment of SWI/SNF and INO80 during INO1 activation

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