Literature DB >> 10930581

Evidence for an active role of the DnaK chaperone system in the degradation of sigma(32).

T Tatsuta1, D M Joob, R Calendar, Y Akiyama, T Ogura.   

Abstract

Under non-stressed conditions in Escherichia coli, the heat shock transcription factor sigma(32) is rapidly degraded by the AAA protease FtsH. The DnaK chaperone system is also required for the rapid turnover of sigma(32) in the cell. It has been hypothesized that the DnaK chaperone system facilitates the degradation of sigma(32) by sequestering it from RNA polymerase core. This hypothesis predicts that mutant sigma(32) proteins, which are deficient in binding to RNA polymerase core, will be degraded independently of the DnaK chaperone system. We examined the in vivo stability of such mutant sigma(32) proteins. Results indicated that the mutant sigma(32) proteins as similar as authentic sigma(32) were stabilized in DeltadnaK and DeltadnaJ/DeltacbpA cells. The interaction between sigma(32) and DnaK/DnaJ/GrpE was not affected by these mutations. These results strongly suggest that the degradation of sigma(32) requires an unidentified active role of the DnaK chaperone system.

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Year:  2000        PMID: 10930581     DOI: 10.1016/s0014-5793(00)01869-x

Source DB:  PubMed          Journal:  FEBS Lett        ISSN: 0014-5793            Impact factor:   4.124


  9 in total

1.  The C terminus of sigma(32) is not essential for degradation by FtsH.

Authors:  T Tomoyasu; F Arsène; T Ogura; B Bukau
Journal:  J Bacteriol       Date:  2001-10       Impact factor: 3.490

2.  Gene structure and transcriptional regulation of dnaK and dnaJ genes from a psychrophilic bacterium, Colwellia maris.

Authors:  Seiji Yamauchi; Hidetoshi Okuyama; Yoshitaka Nishiyama; Hidenori Hayashi
Journal:  Extremophiles       Date:  2004-04-15       Impact factor: 2.395

Review 3.  Regulated proteolysis in Gram-negative bacteria--how and when?

Authors:  Eyal Gur; Dvora Biran; Eliora Z Ron
Journal:  Nat Rev Microbiol       Date:  2011-10-24       Impact factor: 60.633

4.  Surviving heat shock: control strategies for robustness and performance.

Authors:  H El-Samad; H Kurata; J C Doyle; C A Gross; M Khammash
Journal:  Proc Natl Acad Sci U S A       Date:  2005-01-24       Impact factor: 11.205

5.  Conserved region 2.1 of Escherichia coli heat shock transcription factor sigma32 is required for modulating both metabolic stability and transcriptional activity.

Authors:  Mina Horikoshi; Takashi Yura; Sachie Tsuchimoto; Yoshihiro Fukumori; Masaaki Kanemori
Journal:  J Bacteriol       Date:  2004-11       Impact factor: 3.490

6.  The rpoH gene encoding heat shock sigma factor sigma32 of psychrophilic bacterium Colwellia maris.

Authors:  Seiji Yamauchi; Hidetoshi Okuyama; Yoshitaka Nishiyama; Hidenori Hayashi
Journal:  Extremophiles       Date:  2005-12-17       Impact factor: 2.395

7.  Nonnative disulfide bond formation activates the σ32-dependent heat shock response in Escherichia coli.

Authors:  Alexandra Müller; Jörg H Hoffmann; Helmut E Meyer; Franz Narberhaus; Ursula Jakob; Lars I Leichert
Journal:  J Bacteriol       Date:  2013-04-12       Impact factor: 3.490

Review 8.  Convergence of molecular, modeling, and systems approaches for an understanding of the Escherichia coli heat shock response.

Authors:  Eric Guisbert; Takashi Yura; Virgil A Rhodius; Carol A Gross
Journal:  Microbiol Mol Biol Rev       Date:  2008-09       Impact factor: 11.056

9.  Network-Based Methods for Identifying Key Active Proteins in the Extracellular Electron Transfer Process in Shewanella oneidensis MR-1.

Authors:  Dewu Ding; Xiao Sun
Journal:  Genes (Basel)       Date:  2018-01-16       Impact factor: 4.096
  9 in total

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