Laura S. Itzhaki scite author profile

The importance of chaperonin-protein interactions has been investigated by analyzing the refolding of the barley chymotrypsin inhibitor 2 in the presence of GroEL. The chaperonin retards the rate of refolding of wild type and 32 representative point mutants. The retardation of the rate drops to a finite level at saturating concentrations of GroEL, being lowered by a factor of 3-100, depending on the mutation. It is seen qualitatively that truncation of large hydrophobic side chains to smaller side chains weakens binding. Analysis of the magnitude of the rates of retardation shows further that hydrophobic and positively charged side chains tend to interact favorably with GroEL whereas negatively charged side chains tend to repel. There is an inverse correlation between the strength of hydrophobic interactions and the rate constant for refolding of the GroEL-complexed protein: the better the binding, the slower the folding. This shows directly that hydrophobic (and other favorable) interactions between the chaperonin and substrate are weakened during the refolding process and implies that unfolding can be catalyzed by the gain of such interactions.

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The Unfolding Story of Three-Dimensional Domain Swapping

Rousseau

2003

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Three-dimensional domain swapping is the event by which a monomer exchanges part of its structure with identical monomers to form an oligomer where each subunit has a similar structure to the monomer. The accumulating number of observations of this phenomenon in crystal structures has prompted speculation as to its biological relevance. Domain swapping was originally proposed to be a mechanism for the emergence of oligomeric proteins and as a means for functional regulation, but also to be a potentially harmful process leading to misfolding and aggregation. We highlight experimental studies carried out within the last few years that have led to a much greater understanding of the mechanism of domain swapping and of the residue- and structure-specific features that facilitate the process. We discuss the potential biological implications of domain swapping in light of these findings.

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Structure of the Transition State for Folding of a Protein Derived from Experiment and Simulation

Daggett

Itzhaki

et al. 1996

Journal of Molecular Biology

222

218

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Three-dimensional domain swapping in p13suc1 occurs in the unfolded state and is controlled by conserved proline residues

Rousseau¹,

Schymkowitz

Wilkinson

et al. 2001

Proc. Natl. Acad. Sci. U.S.A.

192

216

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CorrectionsBIOCHEMISTRY. For the article ''Differential effects of a centrally acting fatty acid synthase inhibitor in lean and obese mice,'' by Monica V. Kumar, Teruhiko Shimokawa, Tim R. Nagy, and M. Daniel Lane, which appeared in number 4, February 19, 2002, of Proc. Natl. Acad. Sci. USA (99, 1921-1925, the authors note the following. ''Under a licensing agreement between FASgen, Inc., and The Johns Hopkins University, Dr. Lane is entitled to a share of royalty received by the University on sales of products that embody the technology described in this article. (98, 10687-10691; First Published August 28, 2001; 10.1073͞pnas.181354398), the authors note the following. In the Introduction and Discussion of our paper, we failed to reference a recent article by Rousseau et al.(1), which demonstrated that single point mutations can significantly perturb the equilibrium between monomeric and domain-swapped dimeric p13suc1. Rational methods were used to redesign p13suc1 from a fully monomeric protein (dissociation constant of Ϸ900 mM) to a fully dimeric protein (dissociation constant of Ϸ100 nM). Fig. 3 appeared incorrectly. The correct version of the figure and its legend appear below.

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Functionalised staple linkages for modulating the cellular activity of stapled peptides

et al. 2014

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Structure of the transition state for the folding/unfolding of the barley chymotrypsin inhibitor 2 and its implications for mechanisms of protein folding.

Otzen

Itzhaki

elMasry

et al. 1994

Proc. Natl. Acad. Sci. U.S.A.

216

181

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Tertiary Interactions in the Folding Pathway of Hen Lysozyme: Kinetic Studies Using Fluorescent Probes

Itzhaki¹,

Evans²,

Dobson³

et al. 1994

Biochemistry

148

164

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The refolding kinetics of hen lysozyme have been studied using a range of fluorescent probes. These experiments have provided new insight into the nature of intermediates detected in our recent hydrogen-exchange labeling studies [Radford, S.E., et al. (1992) Nature 358, 302-307], which were performed under the same conditions. Protection from exchange results primarily from the development of stabilizing side-chain interactions, and the fluorescence studies reported here have provided a new perspective on this aspect of the refolding process. The intrinsic fluorescence of the six tryptophan residues and its susceptibility to quenching by iodide have been used to monitor the development of hydrophobic structure, and these studies have been complemented by experiments involving binding to a fluorescent hydrophobic dye 1-anilino-naphthalenesulfonic acid (ANS). Formation of fixed tertiary interactions of aromatic residues has been monitored by near-UV circular dichorism, while development of a competent active site has been probed by binding to a competitive inhibitor bearing a fluorescent label, 4-methylumbelliferyl-N,N'-diacetyl-beta-chitobiose. The combination of these techniques has enabled us to monitor the development both of the hydrophobic core of the protein and of interactions between the two folding domains. If the behavior of the tryptophans is representative of the hydrophobic residues of the protein in general, it seems that collapse is already substantial in species formed within the first few milliseconds of refolding and is highly developed in later intermediates which nonetheless appear to lack many fixed tertiary interactions.(ABSTRACT TRUNCATED AT 250 WORDS)

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Laura S. Itzhaki

The Structure of the Transition State for Folding of Chymotrypsin Inhibitor 2 Analysed by Protein Engineering Methods: Evidence for a Nucleation-condensation Mechanism for Protein Folding

Nature and Consequences of GroEL-Protein Interactions

The Unfolding Story of Three-Dimensional Domain Swapping

Structure of the Transition State for Folding of a Protein Derived from Experiment and Simulation

Three-dimensional domain swapping in p13suc1 occurs in the unfolded state and is controlled by conserved proline residues

Functionalised staple linkages for modulating the cellular activity of stapled peptides

Structure of the transition state for the folding/unfolding of the barley chymotrypsin inhibitor 2 and its implications for mechanisms of protein folding.

Tertiary Interactions in the Folding Pathway of Hen Lysozyme: Kinetic Studies Using Fluorescent Probes

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