Literature DB >> 11189448

RSK2 represses HSF1 activation during heat shock.

X Wang1, A Asea, Y Xie, E Kabingu, M A Stevenson, S K Calderwood.   

Abstract

Heat shock transcription factor 1(HSF1) activation is a multistep process. The conversion of a latent cytoplasmic form to a nuclear, DNA binding state appears to be activated by nonsteroidal anti-inflammatory drugs. In previous studies, we showed that HSF 1 is phosphorylated by the protein kinase RSK2 in vitro and that this effect is inhibited by nonsteroidal anti-inflammatory drugs at the concentration that leads to the activation of HSF1 in vivo (Stevenson et al 1999). In the present study, using cells from a patient with Coffin-Lowry syndrome (deficient in RSK2), we demonstrate that RSK2 slightly represses activation of HSF1 in vivo at 37 degrees C. In Coffin-Lowry syndrome cells, HSF1-HSE DNA binding activity after treatment with sodium salicylate was slightly higher than that in untreated cells, indicating that although RSK2 is involved in HSF1 regulation, it is not the unique protein kinase that suppresses HSF1-HSE binding activity at 37 degrees C. However, heat shock treatment resulted in significantly higher HSF1-HSE binding activity in Coffin-Lowry syndrome cells as compared with normal controls, suggesting that RSK2 represses HSF1-HSE binding activity during heat shock.

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Year:  2000        PMID: 11189448      PMCID: PMC312873          DOI: 10.1379/1466-1268(2000)005<0432:rrhadh>2.0.co;2

Source DB:  PubMed          Journal:  Cell Stress Chaperones        ISSN: 1355-8145            Impact factor:   3.667


  28 in total

1.  Ca2+ is essential for multistep activation of the heat shock factor in permeabilized cells.

Authors:  B D Price; S K Calderwood
Journal:  Mol Cell Biol       Date:  1991-06       Impact factor: 4.272

2.  Rapid detection of octamer binding proteins with 'mini-extracts', prepared from a small number of cells.

Authors:  E Schreiber; P Matthias; M M Müller; W Schaffner
Journal:  Nucleic Acids Res       Date:  1989-08-11       Impact factor: 16.971

3.  Probable localisation of the Coffin-Lowry locus in Xp22.2-p22.1 by multipoint linkage analysis.

Authors:  A Hanauer; Y Alembik; S Gilgenkrantz; P Mujica; A Nivelon-Chevallier; M E Pembrey; I D Young; J L Mandel
Journal:  Am J Med Genet       Date:  1988 May-Jun

Review 4.  The Coffin-Lowry syndrome.

Authors:  I D Young
Journal:  J Med Genet       Date:  1988-05       Impact factor: 6.318

Review 5.  The heat-shock proteins.

Authors:  S Lindquist; E A Craig
Journal:  Annu Rev Genet       Date:  1988       Impact factor: 16.830

6.  Salicylic acid and aspirin inhibit the activity of RSK2 kinase and repress RSK2-dependent transcription of cyclic AMP response element binding protein- and NF-kappa B-responsive genes.

Authors:  M A Stevenson; M J Zhao; A Asea; C N Coleman; S K Calderwood
Journal:  J Immunol       Date:  1999-11-15       Impact factor: 5.422

7.  Non-steroidal anti-inflammatory drugs inhibit the expression of cytokines and induce HSP70 in human monocytes.

Authors:  J N Housby; C M Cahill; B Chu; R Prevelige; K Bickford; M A Stevenson; S K Calderwood
Journal:  Cytokine       Date:  1999-05       Impact factor: 3.861

8.  Stress-induced oligomerization and chromosomal relocalization of heat-shock factor.

Authors:  J T Westwood; J Clos; C Wu
Journal:  Nature       Date:  1991-10-31       Impact factor: 49.962

9.  Nuclear protein phosphatase 2A dephosphorylates protein kinase A-phosphorylated CREB and regulates CREB transcriptional stimulation.

Authors:  B E Wadzinski; W H Wheat; S Jaspers; L F Peruski; R L Lickteig; G L Johnson; D J Klemm
Journal:  Mol Cell Biol       Date:  1993-05       Impact factor: 4.272

10.  DNA binding of heat shock factor to the heat shock element is insufficient for transcriptional activation in murine erythroleukemia cells.

Authors:  J O Hensold; C R Hunt; S K Calderwood; D E Housman; R E Kingston
Journal:  Mol Cell Biol       Date:  1990-04       Impact factor: 4.272
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  6 in total

1.  Role of Heat Shock Factors in Stress-Induced Transcription.

Authors:  Ayesha Murshid; Thomas L Prince; Ben Lang; Stuart K Calderwood
Journal:  Methods Mol Biol       Date:  2018

2.  Signal Transduction Pathways Leading to Heat Shock Transcription.

Authors:  S K Calderwood; Y Xie; X Wang; M A Khaleque; S D Chou; A Murshid; T Prince; Y Zhang
Journal:  Sign Transduct Insights       Date:  2010

3.  Transformation of eEF1Bδ into heat-shock response transcription factor by alternative splicing.

Authors:  Taku Kaitsuka; Kazuhito Tomizawa; Masayuki Matsushita
Journal:  EMBO Rep       Date:  2011-07-01       Impact factor: 8.807

4.  The role of heat shock factors in stress-induced transcription.

Authors:  Yue Zhang; Shiuh-Dih Chou; Ayesha Murshid; Thomas L Prince; Sheila Schreiner; Mary Ann Stevenson; Stuart K Calderwood
Journal:  Methods Mol Biol       Date:  2011

5.  A transcription cofactor required for the heat-shock response.

Authors:  Danmei Xu; L Panagiotis Zalmas; Nicholas B La Thangue
Journal:  EMBO Rep       Date:  2008-05-02       Impact factor: 8.807

6.  Regulation of molecular chaperone gene transcription involves the serine phosphorylation, 14-3-3 epsilon binding, and cytoplasmic sequestration of heat shock factor 1.

Authors:  XiaoZhe Wang; Nicholas Grammatikakis; Aliki Siganou; Stuart K Calderwood
Journal:  Mol Cell Biol       Date:  2003-09       Impact factor: 4.272
  6 in total

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