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Literature DB >> 21757689

Stimulating the substrate folding activity of a single ring GroEL variant by modulating the cochaperonin GroES.

Melissa Illingworth¹, Andrew Ramsey, Zhida Zheng, Lingling Chen.

Abstract

In mediating protein folding, chaperonin GroEL and cochaperonin GroES form an enclosed chamber for substrate proteins in an ATP-dependent manner. The essential role of the double ring assembly of GroEL is demonstrated by the functional deficiency of the single ring GroEL(SR). The GroEL(SR)-GroES is highly stable with minimal ATPase activity. To restore the ATP cycle and the turnover of the folding chamber, we sought to weaken the GroEL(SR)-GroES interaction systematically by concatenating seven copies of groES to generate groES(7). GroES Ile-25, Val-26, and Leu-27, residues on the GroEL-GroES interface, were substituted with Asp on different groES modules of groES(7). GroES(7) variants activate ATP activity of GroEL(SR), but only some restore the substrate folding function of GroEL(SR), indicating a direct role of GroES in facilitating substrate folding through its dynamics with GroEL. Active GroEL(SR)-GroES(7) systems may resemble mammalian mitochondrial chaperonin systems.

Entities: Chemical Gene Species

Mesh：

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Year: 2011 PMID： 21757689 PMCID： PMC3162399 DOI： 10.1074/jbc.M111.255935

Source DB: PubMed Journal: J Biol Chem ISSN： 0021-9258 Impact factor: 5.157

57 in total

Review 1. GroEL-mediated protein folding: making the impossible, possible.

Authors: Zong Lin; Hays S Rye
Journal: Crit Rev Biochem Mol Biol Date: 2006 Jul-Aug Impact factor: 8.250

2. Elucidation of steps in the capture of a protein substrate for efficient encapsulation by GroE.

Authors: Matthew J Cliff; Claire Limpkin; Angus Cameron; Steven G Burston; Anthony R Clarke
Journal: J Biol Chem Date: 2006-05-09 Impact factor: 5.157

3. Characterisation of a GroEL single-ring mutant that supports growth of Escherichia coli and has GroES-dependent ATPase activity.

Authors: Eszter Kovács; Zhe Sun; Han Liu; David J Scott; Andreas I Karsisiotis; Anthony R Clarke; Steven G Burston; Peter A Lund
Journal: J Mol Biol Date: 2009-12-16 Impact factor: 5.469

4. Characterisation of mutations in GroES that allow GroEL to function as a single ring.

Authors: Han Liu; Eszter Kovács; Peter A Lund
Journal: FEBS Lett Date: 2009-06-21 Impact factor: 4.124

5. Determination of the number of active GroES subunits in the fused heptamer GroES required for interactions with GroEL.

Authors: Tatsuya Nojima; Shigeto Murayama; Masasuke Yoshida; Fumihiro Motojima
Journal: J Biol Chem Date: 2008-04-22 Impact factor: 5.157

6. Effect of the C-terminal truncation on the functional cycle of chaperonin GroEL: implication that the C-terminal region facilitates the transition from the folding-arrested to the folding-competent state.

Authors: Mihoko Suzuki; Taro Ueno; Ryo Iizuka; Takahiro Miura; Tamotsu Zako; Rena Akahori; Takeo Miyake; Naonobu Shimamoto; Mutsuko Aoki; Takashi Tanii; Iwao Ohdomari; Takashi Funatsu
Journal: J Biol Chem Date: 2008-06-26 Impact factor: 5.157

7. Analysis of peptides and proteins in their binding to GroEL.

Authors: Yali Li; Zhida Zheng; Andrew Ramsey; Lingling Chen
Journal: J Pept Sci Date: 2010-12 Impact factor: 1.905

8. Structural stability of covalently linked GroES heptamer: advantages in the formation of oligomeric structure.

Authors: Isao Sakane; Kunihiro Hongo; Fumihiro Motojima; Shigeto Murayama; Tomohiro Mizobata; Yasushi Kawata
Journal: J Mol Biol Date: 2007-01-20 Impact factor: 5.469

9. A single-ring mitochondrial chaperonin (Hsp60-Hsp10) can substitute for GroEL-GroES in vivo.

Authors: K L Nielsen; N McLennan; M Masters; N J Cowan
Journal: J Bacteriol Date: 1999-09 Impact factor: 3.490

10. GroEL-GroES cycling: ATP and nonnative polypeptide direct alternation of folding-active rings.

Authors: H S Rye; A M Roseman; S Chen; K Furtak; W A Fenton; H R Saibil; A L Horwich
Journal: Cell Date: 1999-04-30 Impact factor: 41.582

8 in total

1. Biochemical and Genetic Analysis of the Chlamydia GroEL Chaperonins.

Authors: Melissa Illingworth; Anna J Hooppaw; Lu Ruan; Derek J Fisher; Lingling Chen
Journal: J Bacteriol Date: 2017-05-25 Impact factor: 3.490

2. Allosteric differences dictate GroEL complementation of E. coli.

Authors: Jared Sivinski; Duc Ngo; Christopher J Zerio; Andrew J Ambrose; Edmond R Watson; Lynn K Kaneko; Marius M Kostelic; Mckayla Stevens; Anne-Marie Ray; Yangshin Park; Chunxiang Wu; Michael T Marty; Quyen Q Hoang; Donna D Zhang; Gabriel C Lander; Steven M Johnson; Eli Chapman
Journal: FASEB J Date: 2022-03 Impact factor: 5.191

3. Infection-driven activation of transglutaminase 2 boosts glucose uptake and hexosamine biosynthesis in epithelial cells.

Authors: Benoit Maffei; Marc Laverrière; Yongzheng Wu; Sébastien Triboulet; Stéphanie Perrinet; Magalie Duchateau; Mariette Matondo; Robert L Hollis; Charlie Gourley; Jan Rupp; Jeffrey W Keillor; Agathe Subtil
Journal: EMBO J Date: 2020-03-05 Impact factor: 11.598

4. Structural basis for the structural dynamics of human mitochondrial chaperonin mHsp60.

Authors: Joseph Che-Yen Wang; Lingling Chen
Journal: Sci Rep Date: 2021-07-20 Impact factor: 4.379

5. Nucleotide-induced conformational changes of tetradecameric GroEL mapped by H/D exchange monitored by FT-ICR mass spectrometry.

Authors: Qian Zhang; Jin Chen; Kunihiro Kuwajima; Hui-Min Zhang; Feng Xian; Nicolas L Young; Alan G Marshall
Journal: Sci Rep Date: 2013-02-13 Impact factor: 4.379