Literature DB >> 7739554

Dynamic protein-DNA architecture of a yeast heat shock promoter.

C Giardina1, J T Lis.   

Abstract

Here we present an in vivo footprinting analysis of the Saccharomyces cerevisiae HSP82 promoter. Consistent with current models, we find that yeast heat shock factor (HSF) binds to strong heat shock elements (HSEs) in non-heat-shocked cells. Upon heat shock, however, additional binding of HSF becomes apparent at weak HSEs of the promoter as well. Recovery from heat shock results in a dramatic reduction in HSF binding at both strong and weak HSEs, consistent with a model in which HSF binding is subject to a negative feedback regulation by heat shock proteins. In vivo KMnO4 footprinting reveals that the interaction of the TATA-binding protein (TBP) with this promoter is also modulated: heat shock slightly increases TBP binding to the promoter and this binding is reduced upon recovery from heat shock. KMnO4 footprinting does not reveal a high density of polymerase at the promoter prior to heat shock, but a large open complex between the transcriptional start site and the TATA box is formed rapidly upon activation, similar to that observed in other yeast genes.

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Year:  1995        PMID: 7739554      PMCID: PMC230504          DOI: 10.1128/MCB.15.5.2737

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


  48 in total

1.  Transcriptional regulation of SSA3, an HSP70 gene from Saccharomyces cerevisiae.

Authors:  W R Boorstein; E A Craig
Journal:  Mol Cell Biol       Date:  1990-06       Impact factor: 4.272

2.  Genomic footprinting of the yeast HSP82 promoter reveals marked distortion of the DNA helix and constitutive occupancy of heat shock and TATA elements.

Authors:  D S Gross; K E English; K W Collins; S W Lee
Journal:  J Mol Biol       Date:  1990-12-05       Impact factor: 5.469

3.  Drosophila nuclear proteins bind to regions of alternating C and T residues in gene promoters.

Authors:  D S Gilmour; G H Thomas; S C Elgin
Journal:  Science       Date:  1989-09-29       Impact factor: 47.728

4.  Constitutive binding of yeast heat shock factor to DNA in vivo.

Authors:  B K Jakobsen; H R Pelham
Journal:  Mol Cell Biol       Date:  1988-11       Impact factor: 4.272

5.  Heat shock factor is regulated differently in yeast and HeLa cells.

Authors:  P K Sorger; M J Lewis; H R Pelham
Journal:  Nature       Date:  1987 Sep 3-9       Impact factor: 49.962

6.  Postinitiation transcriptional control in Drosophila melanogaster.

Authors:  A E Rougvie; J T Lis
Journal:  Mol Cell Biol       Date:  1990-11       Impact factor: 4.272

7.  Stable binding of Drosophila heat shock factor to head-to-head and tail-to-tail repeats of a conserved 5 bp recognition unit.

Authors:  O Perisic; H Xiao; J T Lis
Journal:  Cell       Date:  1989-12-01       Impact factor: 41.582

8.  The RNA polymerase II molecule at the 5' end of the uninduced hsp70 gene of D. melanogaster is transcriptionally engaged.

Authors:  A E Rougvie; J T Lis
Journal:  Cell       Date:  1988-09-09       Impact factor: 41.582

9.  Protein/DNA architecture of the DNase I hypersensitive region of the Drosophila hsp26 promoter.

Authors:  G H Thomas; S C Elgin
Journal:  EMBO J       Date:  1988-07       Impact factor: 11.598

10.  Purification and characterization of a heat-shock element binding protein from yeast.

Authors:  P K Sorger; H R Pelham
Journal:  EMBO J       Date:  1987-10       Impact factor: 11.598
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  44 in total

1.  Cell cycle-dependent binding of yeast heat shock factor to nucleosomes.

Authors:  C B Venturi; A M Erkine; D S Gross
Journal:  Mol Cell Biol       Date:  2000-09       Impact factor: 4.272

2.  Displacement of histones at promoters of Saccharomyces cerevisiae heat shock genes is differentially associated with histone H3 acetylation.

Authors:  T Y Erkina; A M Erkine
Journal:  Mol Cell Biol       Date:  2006-10       Impact factor: 4.272

3.  Combination of two regulatory elements in the Tetrahymena thermophila HSP70-1 gene controls heat shock activation.

Authors:  Sabrina Barchetta; Antonietta La Terza; Patrizia Ballarini; Sandra Pucciarelli; Cristina Miceli
Journal:  Eukaryot Cell       Date:  2007-11-30

Review 4.  The transition from transcriptional initiation to elongation.

Authors:  Joseph T Wade; Kevin Struhl
Journal:  Curr Opin Genet Dev       Date:  2008-02-20       Impact factor: 5.578

5.  Regulation of thermotolerance by stress-induced transcription factors in Saccharomyces cerevisiae.

Authors:  Noritaka Yamamoto; Yuka Maeda; Aya Ikeda; Hiroshi Sakurai
Journal:  Eukaryot Cell       Date:  2008-03-21

6.  SAGA and Rpd3 chromatin modification complexes dynamically regulate heat shock gene structure and expression.

Authors:  Selena B Kremer; David S Gross
Journal:  J Biol Chem       Date:  2009-09-15       Impact factor: 5.157

7.  Multiple single-stranded cis elements are associated with activated chromatin of the human c-myc gene in vivo.

Authors:  G A Michelotti; E F Michelotti; A Pullner; R C Duncan; D Eick; D Levens
Journal:  Mol Cell Biol       Date:  1996-06       Impact factor: 4.272

Review 8.  Mechanisms of heat shock response in mammals.

Authors:  Artem K Velichko; Elena N Markova; Nadezhda V Petrova; Sergey V Razin; Omar L Kantidze
Journal:  Cell Mol Life Sci       Date:  2013-04-30       Impact factor: 9.261

9.  Phosphorylation of the yeast heat shock transcription factor is implicated in gene-specific activation dependent on the architecture of the heat shock element.

Authors:  Naoya Hashikawa; Hiroshi Sakurai
Journal:  Mol Cell Biol       Date:  2004-05       Impact factor: 4.272

10.  Functional interplay between chromatin remodeling complexes RSC, SWI/SNF and ISWI in regulation of yeast heat shock genes.

Authors:  T Y Erkina; Y Zou; S Freeling; V I Vorobyev; A M Erkine
Journal:  Nucleic Acids Res       Date:  2009-12-16       Impact factor: 16.971
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