Literature DB >> 9256426

Significance of chaperonin 10-mediated inhibition of ATP hydrolysis by chaperonin 60.

Y Dubaquié1, R Looser, S Rospert.   

Abstract

Chaperonins are essential for the folding of proteins in bacteria, mitochondria, and chloroplasts. We have functionally characterized the yeast mitochondrial chaperonins hsp60 and hsp10. In the presence of ADP, one molecule of hsp10 binds to hsp60 with an apparent Kd of 0.9 nM and a second molecule of hsp10 binds with a Kd of 24 nM. In the presence of ATP, the purified yeast chaperonins mediate the refolding of mitochondrial malate dehydrogenase. Hsp10 inhibits the ATPase activity of hsp60 by about 40%. Hsp10(P36H) is a point mutant of hsp10 that confers temperature-sensitive growth to yeast. Consistent with the in vivo phenotype, refolding of mitochondrial malate dehydrogenase in the presence of purified hsp10(P36H) and hsp60 is reduced at 25 degrees C and abolished at 30 degrees C. The affinity of hsp10(P36H) to hsp60 as well as to Escherichia coli GroEL is reduced. However, this decrease in affinity does not correlate with the functional defect, because hsp10(P36H) fully assists the GroEL-mediated refolding of malate dehydrogenase at 30 degrees C. Refolding activity, rather, correlates with the ability of hsp10(P36H) to inhibit the ATPase of GroEL but not that of hsp60. Based on our findings, we propose that the inhibition of ATP hydrolysis is mechanistically coupled to chaperonin-mediated protein folding.

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Year:  1997        PMID: 9256426      PMCID: PMC23004          DOI: 10.1073/pnas.94.17.9011

Source DB:  PubMed          Journal:  Proc Natl Acad Sci U S A        ISSN: 0027-8424            Impact factor:   11.205


  47 in total

1.  The role of ATP hydrolysis in the function of the chaperonin GroEL: dynamic complex formation with GroES.

Authors:  Y Kawata; K Hongo; K Nosaka; Y Furutsu; T Mizobata; J Nagai
Journal:  FEBS Lett       Date:  1995-08-07       Impact factor: 4.124

2.  Symmetric GroEL-GroES complexes can contain substrate simultaneously in both GroEL rings.

Authors:  O Llorca; S Marco; J L Carrascosa; J M Valpuesta
Journal:  FEBS Lett       Date:  1997-03-24       Impact factor: 4.124

3.  The protein-folding activity of chaperonins correlates with the symmetric GroEL14(GroES7)2 heterooligomer.

Authors:  A Azem; S Diamant; M Kessel; C Weiss; P Goloubinoff
Journal:  Proc Natl Acad Sci U S A       Date:  1995-12-19       Impact factor: 11.205

4.  Protein folding in the central cavity of the GroEL-GroES chaperonin complex.

Authors:  M Mayhew; A C da Silva; J Martin; H Erdjument-Bromage; P Tempst; F U Hartl
Journal:  Nature       Date:  1996-02-01       Impact factor: 49.962

5.  Biochemical characterization of symmetric GroEL-GroES complexes. Evidence for a role in protein folding.

Authors:  O Llorca; J L Carrascosa; J M Valpuesta
Journal:  J Biol Chem       Date:  1996-01-05       Impact factor: 5.157

6.  The crystal structure of the GroES co-chaperonin at 2.8 A resolution.

Authors:  J F Hunt; A J Weaver; S J Landry; L Gierasch; J Deisenhofer
Journal:  Nature       Date:  1996-01-04       Impact factor: 49.962

7.  Substoichiometric amounts of the molecular chaperones GroEL and GroES prevent thermal denaturation and aggregation of mammalian mitochondrial malate dehydrogenase in vitro.

Authors:  D J Hartman; B P Surin; N E Dixon; N J Hoogenraad; P B Høj
Journal:  Proc Natl Acad Sci U S A       Date:  1993-03-15       Impact factor: 11.205

8.  Characterization of a functionally important mobile domain of GroES.

Authors:  S J Landry; J Zeilstra-Ryalls; O Fayet; C Georgopoulos; L M Gierasch
Journal:  Nature       Date:  1993-07-15       Impact factor: 49.962

9.  Escherichia coli chaperonins cpn60 (groEL) and cpn10 (groES) do not catalyse the refolding of mitochondrial malate dehydrogenase.

Authors:  A D Miller; K Maghlaoui; G Albanese; D A Kleinjan; C Smith
Journal:  Biochem J       Date:  1993-04-01       Impact factor: 3.857

10.  Characterization of the active intermediate of a GroEL-GroES-mediated protein folding reaction.

Authors:  J S Weissman; H S Rye; W A Fenton; J M Beechem; A L Horwich
Journal:  Cell       Date:  1996-02-09       Impact factor: 41.582
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  10 in total

1.  Identification of in vivo substrates of the yeast mitochondrial chaperonins reveals overlapping but non-identical requirement for hsp60 and hsp10.

Authors:  Y Dubaquié; R Looser; U Fünfschilling; P Jenö; S Rospert
Journal:  EMBO J       Date:  1998-10-15       Impact factor: 11.598

2.  Interaction of mitochondrial targeting signals with acidic receptor domains along the protein import pathway: evidence for the 'acid chain' hypothesis.

Authors:  T Komiya; S Rospert; C Koehler; R Looser; G Schatz; K Mihara
Journal:  EMBO J       Date:  1998-07-15       Impact factor: 11.598

3.  Mitochondrial heat shock protein (Hsp) 70 and Hsp10 cooperate in the formation of Hsp60 complexes.

Authors:  Lena Böttinger; Silke Oeljeklaus; Bernard Guiard; Sabine Rospert; Bettina Warscheid; Thomas Becker
Journal:  J Biol Chem       Date:  2015-03-18       Impact factor: 5.157

4.  Prolonged fasting identifies heat shock protein 10 as a Sirtuin 3 substrate: elucidating a new mechanism linking mitochondrial protein acetylation to fatty acid oxidation enzyme folding and function.

Authors:  Zhongping Lu; Yong Chen; Angel M Aponte; Valentina Battaglia; Marjan Gucek; Michael N Sack
Journal:  J Biol Chem       Date:  2014-12-12       Impact factor: 5.157

5.  Neuroproteomics: a biochemical means to discriminate the extent and modality of brain injury.

Authors:  Andrew K Ottens; Liliana Bustamante; Erin C Golden; Changping Yao; Ronald L Hayes; Kevin K W Wang; Frank C Tortella; Jitendra R Dave
Journal:  J Neurotrauma       Date:  2010-10-09       Impact factor: 5.269

6.  Glucose-modulated tyrosine nitration in beta cells: targets and consequences.

Authors:  Thomas Koeck; John A Corbett; John W Crabb; Dennis J Stuehr; Kulwant S Aulak
Journal:  Arch Biochem Biophys       Date:  2009-04-15       Impact factor: 4.013

7.  Systematic analysis of HSP gene expression and effects on cell growth and survival at high hydrostatic pressure in Saccharomyces cerevisiae.

Authors:  Takeshi Miura; Hiroaki Minegishi; Ron Usami; Fumiyoshi Abe
Journal:  Extremophiles       Date:  2006-02-18       Impact factor: 2.395

8.  The Golgi Ca2+-ATPase KlPmr1p function is required for oxidative stress response by controlling the expression of the heat-shock element HSP60 in Kluyveromyces lactis.

Authors:  Daniela Uccelletti; Francesca Farina; Paolo Pinton; Paola Goffrini; Patrizia Mancini; Claudio Talora; Rosario Rizzuto; Claudio Palleschi
Journal:  Mol Biol Cell       Date:  2005-07-19       Impact factor: 4.138

9.  Small but crucial: the novel small heat shock protein Hsp21 mediates stress adaptation and virulence in Candida albicans.

Authors:  François L Mayer; Duncan Wilson; Ilse D Jacobsen; Pedro Miramón; Silvia Slesiona; Iryna M Bohovych; Alistair J P Brown; Bernhard Hube
Journal:  PLoS One       Date:  2012-06-07       Impact factor: 3.240

Review 10.  Role of Heat-Shock Proteins in Cellular Function and in the Biology of Fungi.

Authors:  Shraddha Tiwari; Raman Thakur; Jata Shankar
Journal:  Biotechnol Res Int       Date:  2015-12-31
  10 in total

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