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1 - Chaperone Function: The Orthodox View

Published online by Cambridge University Press:  10 August 2009

By
R. John Ellis
Edited by
Brian Henderson  and
A. Graham Pockley
R. John Ellis
Affiliation:
Department of Biological Sciences, University of Warwick, United Kingdom
Brian Henderson
Affiliation:
University College London
A. Graham Pockley
Affiliation:
University of Sheffield
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Summary

Introduction

The term molecular chaperone came into general use after the appearance of an article in Nature that suggested it was an appropriate phrase to describe a newly defined intracellular function – the ability of several unrelated protein families to assist the correct folding and assembly/disassembly of other proteins [1]. The identification of the chaperonin family of molecular chaperones in the following year [2] triggered a tidal wave of research in several laboratories aimed at unravelling how the GroEL/GroES chaperones, and later the DnaK/DnaJ chaperones, from Escherichia coli facilitate the folding of newly synthesised polypeptide chains and the refolding of denatured proteins. This wave continues to surge, with the result that much detailed information is available about the structure and function of those families of chaperone that assist protein folding [3].

It is now well established that a subset of proteins requires this chaperone function, not because chaperones provide steric information required for correct folding but because chaperones inhibit side reactions that would otherwise cause some of the chains to form non-functional aggregates. The number of different protein families described as chaperones is now more than 25 – some, but not all, of which are also stress proteins – and there is no slackening in the rate of discovery of new ones. The success of this wave of research has changed the paradigm of protein folding from the earlier view that it is a spontaneous self-assembly process to the current view that it is an assisted self-assembly process [4].

Type
Chapter
Information
Molecular Chaperones and Cell Signalling , pp. 3 - 21
Publisher: Cambridge University Press
Print publication year: 2005

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References

Ellis, R J. Proteins as molecular chaperones. Nature 1987, 328: 378–379Google Scholar
Hemmingsen, S M, Woolford, C, Vies, S M, Tilly, K, Dennis, D T, Georgopoulos, G C, Hendrix, R W and Ellis, R J. Homologous plant and bacterial proteins chaperone oligomeric protein assembly. Nature 1988, 333: 330–334Google Scholar
Hartl, F U and Hayer-Hartl, M. Molecular chaperones in the cytosol: from nascent chain to folded protein. Science 2002, 295: 1852–1858Google Scholar
Ellis, R J and Hartl, F U. Protein folding and chaperones. Nature Encyclopedia of the Human Genome. Macmillan Publishers Ltd 2003, pp 806–810
Laskey, R A, Honda, B M and Finch, J T. Nucleosomes are assembled by an acidic protein that binds histones and transfers them to DNA. Nature 1978, 275: 416–420Google Scholar
Ellis R J. The general concept of molecular chaperones. In Ellis, R. J., Laskey, R. A. and Lorimer, G. H. (Eds.) Molecular Chaperones. Chapman and Hall for The Royal Society, London 1993, pp 1–5
Musgrove, J E and Ellis, R J. The rubisco large subunit binding protein. Phil Trans R Soc Lond B 1986, 313: 419–428Google Scholar
Ellis, R J and Hemmingsen, S M. Molecular chaperones: proteins essential for the biogenesis of some macromolecular structures. Trends Biochem Sci 1989, 14: 339–342Google Scholar
Puig, A and Gilbert, H F. Protein disulfide isomerase exhibits chaperone and antichaperone activity in the oxidative folding of lysozyme. J Biol Chem 1994, 269: 7764–7771Google Scholar
Ellis, R J. Steric chaperones. Trends Biochem Sci 1998, 23: 43–45Google Scholar
Finley, D, Bartel, B and Varshavsky, A. The tails of ubiquitin precursors are ribosomal proteins whose fusion to ubiquitin facilitates ribosome biogenesis. Nature 1989, 338: 394–401Google Scholar
Welch, W J. Role of quality control pathways in human diseases involving protein misfolding. Semin Cell Devel Biol 2004, 15: 31–38Google Scholar
Ellis, R J. Macromolecular crowding: obvious but underappreciated. Trends Biochem Sci 2001, 26: 597–603Google Scholar
Hartl, F U. Molecular chaperones in cellular protein folding. Nature 1996, 381: 571–579Google Scholar
Ellis, R J and Hartl, F U. Principles of protein folding in the cellular environment. Cur Opin Struct Biol 1999, 9: 102–110Google Scholar
Schlieker, C, Bukau, B and Mogk, A. Prevention and reversion of protein aggregation by molecular chaperones in the E. coli cytosol; implications for their applicability in biotechnology. J Biotech 2002, 96: 13–21Google Scholar
Beatrix, B, Sakai, H and Wiedmann, M. The α and β subunits of the nascent polypeptide complex have distinct functions. J Biol Chem 2000, 275: 37838–37845Google Scholar
Deuerling, E, Schulze-Specking, A, Tomoyasu, A, Mogk, A and Bukau, B. Trigger factor and DnaK cooperate in folding of newly synthesized proteins. Nature 1999, 400: 693–696Google Scholar
Teter, S A, Houry, W A, Ang, D A, Tradler, T, Rockabrand, D, Fischer, G, Blum, P, Georgopoulos, C and Hartl, F U. Polypeptide flux through bacterial hsp70: DnaK cooperates with trigger factor in chaperoning nascent chains. Cell 1999, 97: 755–765Google Scholar
Bukau, B and Horwich, A L. The Hsp70 and Hsp60 chaperone machines. Cell 1998, 92: 351–366Google Scholar
Sondermann, H, Scheufler, C, Schneider, C, Hohfeld, J, Hartl, F U and Moarefi, I. Structure of a Bag/hsc70 complex: convergent functional evolution of hsp70 nucleotide exchange factors. Science 2001, 291: 1553–1557Google Scholar
Xu, Z, Horwich, A L and Sigler, P B. The crystal structure of the asymmetric GroEL-GroES- (ADP)7 chaperonin complex. Nature 1997, 388: 741–750Google Scholar
Ellis, R J. Protein folding: importance of the Anfinsen cage. Cur Biol 2003, 13: R881–R883Google Scholar
Martin, J and Hartl, F U. The effect of macromolecular crowding on chaperonin-mediated protein folding. Proc Natl Acad Sci USA 1997, 94: 1107–1112Google Scholar
Farr, G W, Fenton, W A, Rospert, S and Horwich, A L. Folding with and without encapsulation by cis and trans-only GroEL-GroES complexes. EMBO J 2001, 22: 3220–3230Google Scholar
Brinker, A, Pfeifer, G, Kerner, M J, Naylor, D J, Hartl, F U and Hayer-Hartl, M. Dual function of protein confinement in chaperonin-assisted protein folding. Cell 2001, 107: 223–233Google Scholar
Takagi, F, Koga, N and Takada, S. How protein thermodynamics and folding are altered by the chaperonin cage: molecular simulations. Proc Natl Acad Sci USA 2003, 100: 11367–11372Google Scholar
Thirumalai, D and Lorimer, G H. Chaperonin-mediated protein folding. Ann Rev Biophys Biomol Struct 2001, 30: 245–269Google Scholar
Young, J C, Moarefi, I and Hartl, F U. Hsp90: a specialized but essential protein-folding tool. J Cell Biol 2001, 154: 267–273Google Scholar
Smith, D F. Chaperones in progesterone receptor complexes. Semin Cell Devel Biol 2000, 11: 45–52Google Scholar
Csermley, P. Chaperone overload is a possible contributor to ‘civilization diseases’. Trends Genetics 2001, 17: 701–704Google Scholar
Soti, C and Csermley, P. Molecular chaperones and the aging process. Biogerontology 2000, 1: 225–233Google Scholar
Glover, J R and Tkach, J M. Crowbars and rachets: hsp100 chaperones as tools in reversing aggregation. Biochem Cell Biol 2001, 79: 557–568Google Scholar
Parsell, D A, Kowal, A S, Singer, M A and Lindquist, S. Protein disaggregation by heat shock protein hsp104. Nature 1994, 372: 475–477Google Scholar
Yoshida, N, Oeda, K, Watanabe, E, Mikami, T, Fukita, Y, Nishimura, K, Komai, K and Matsuda, K. Protein function. Chaperonin turned insect toxin. Nature 2001, 411: 44Google Scholar

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