Literature DB >> 8876186

Interplay of structure and disorder in cochaperonin mobile loops.

S J Landry1, A Taher, C Georgopoulos, S M van der Vies.   

Abstract

Protein-protein interactions typically are characterized by highly specific interfaces that mediate binding with precisely tuned affinities. Binding of the Escherichia coli cochaperonin GroES to chaperonin GroEL is mediated, at least in part, by a mobile polypeptide loop in GroES that becomes immobilized in the GroEL/GroES/nucleotide complex. The bacteriophage T4 cochaperonin Gp31 possesses a similar highly flexible polypeptide loop in a region of the protein that shows low, but significant, amino acid similarity with GroES and other cochaperonins. When bound to GroEL, a synthetic peptide representing the mobile loop of either GroES or Gp31 adopts a characteristic bulged hairpin conformation as determined by transferred nuclear Overhauser effects in NMR spectra. Thermodynamic considerations suggest that flexible disorder in the cochaperonin mobile loops moderates their affinity for GroEL to facilitate cycles of chaperonin-mediated protein folding.

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Year:  1996        PMID: 8876186      PMCID: PMC38108          DOI: 10.1073/pnas.93.21.11622

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


  39 in total

Review 1.  The universally conserved GroE (Hsp60) chaperonins.

Authors:  J Zeilstra-Ryalls; O Fayet; C Georgopoulos
Journal:  Annu Rev Microbiol       Date:  1991       Impact factor: 15.500

2.  Conformation of beta hairpins in protein structures: classification and diversity in homologous structures.

Authors:  B L Sibanda; J M Thornton
Journal:  Methods Enzymol       Date:  1991       Impact factor: 1.600

3.  Tricine-sodium dodecyl sulfate-polyacrylamide gel electrophoresis for the separation of proteins in the range from 1 to 100 kDa.

Authors:  H Schägger; G von Jagow
Journal:  Anal Biochem       Date:  1987-11-01       Impact factor: 3.365

4.  How chaperones tell wrong from right.

Authors:  H R Saibil
Journal:  Nat Struct Biol       Date:  1994-12

5.  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

6.  Residues in chaperonin GroEL required for polypeptide binding and release.

Authors:  W A Fenton; Y Kashi; K Furtak; A L Horwich
Journal:  Nature       Date:  1994-10-13       Impact factor: 49.962

Review 7.  Dynamics of the chaperonin ATPase cycle: implications for facilitated protein folding.

Authors:  M J Todd; P V Viitanen; G H Lorimer
Journal:  Science       Date:  1994-07-29       Impact factor: 47.728

8.  Structure of the heat shock protein chaperonin-10 of Mycobacterium leprae.

Authors:  S C Mande; V Mehra; B R Bloom; W G Hol
Journal:  Science       Date:  1996-01-12       Impact factor: 47.728

9.  Bacteriophage T4 encodes a co-chaperonin that can substitute for Escherichia coli GroES in protein folding.

Authors:  S M van der Vies; A A Gatenby; C Georgopoulos
Journal:  Nature       Date:  1994-04-14       Impact factor: 49.962

10.  Chaperonin-mediated protein folding: GroES binds to one end of the GroEL cylinder, which accommodates the protein substrate within its central cavity.

Authors:  T Langer; G Pfeifer; J Martin; W Baumeister; F U Hartl
Journal:  EMBO J       Date:  1992-12       Impact factor: 11.598
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  23 in total

1.  Mycobacterium tuberculosis chaperonin 10 heptamers self-associate through their biologically active loops.

Authors:  Michael M Roberts; Alun R Coker; Gianluca Fossati; Paolo Mascagni; Anthony R M Coates; Steve P Wood
Journal:  J Bacteriol       Date:  2003-07       Impact factor: 3.490

2.  A mobile loop order-disorder transition modulates the speed of chaperonin cycling.

Authors:  Frank Shewmaker; Michael J Kerner; Manajit Hayer-Hartl; Gracjana Klein; Costa Georgopoulos; Samuel J Landry
Journal:  Protein Sci       Date:  2004-07-06       Impact factor: 6.725

3.  Topology and dynamics of the 10 kDa C-terminal domain of DnaK in solution.

Authors:  E B Bertelsen; H Zhou; D F Lowry; G C Flynn; F W Dahlquist
Journal:  Protein Sci       Date:  1999-02       Impact factor: 6.725

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

Authors:  Y Dubaquié; R Looser; S Rospert
Journal:  Proc Natl Acad Sci U S A       Date:  1997-08-19       Impact factor: 11.205

5.  Proton-proton Overhauser NMR spectroscopy with polypeptide chains in large structures.

Authors:  Reto Horst; Gerhard Wider; Jocelyne Fiaux; Eric B Bertelsen; Arthur L Horwich; Kurt Wüthrich
Journal:  Proc Natl Acad Sci U S A       Date:  2006-10-10       Impact factor: 11.205

6.  Differential effects of co-chaperonin homologs on cpn60 oligomers.

Authors:  Anat L Bonshtien; Avital Parnas; Rajach Sharkia; Adina Niv; Itzhak Mizrahi; Abdussalam Azem; Celeste Weiss
Journal:  Cell Stress Chaperones       Date:  2009-02-18       Impact factor: 3.667

7.  The MitCHAP-60 disease is due to entropic destabilization of the human mitochondrial Hsp60 oligomer.

Authors:  Avital Parnas; Michal Nadler; Shahar Nisemblat; Amnon Horovitz; Hanna Mandel; Abdussalam Azem
Journal:  J Biol Chem       Date:  2009-08-25       Impact factor: 5.157

Review 8.  A Review: Molecular Chaperone-mediated Folding, Unfolding and Disaggregation of Expressed Recombinant Proteins.

Authors:  Komal Fatima; Fatima Naqvi; Hooria Younas
Journal:  Cell Biochem Biophys       Date:  2021-02-25       Impact factor: 2.194

9.  Identifying natural substrates for chaperonins using a sequence-based approach.

Authors:  George Stan; Bernard R Brooks; George H Lorimer; D Thirumalai
Journal:  Protein Sci       Date:  2004-12-02       Impact factor: 6.725

10.  Structural characterization of the N-terminal autoregulatory sequence of phenylalanine hydroxylase.

Authors:  James Horne; Ian G Jennings; Trazel Teh; Paul R Gooley; Bostjan Kobe
Journal:  Protein Sci       Date:  2002-08       Impact factor: 6.725
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