Acceleration of disulfide-coupled protein folding using glutathione derivatives

Protein folding occurs simultaneously with disulfide bond formation. In general, the in vitro folding of proteins containing disulfide bond(s) is carried out in the presence of redox reagents, such as glutathione, to permit native disulfide pairing to occur. It is well known that the formation of a...

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Published inThe FEBS journal Vol. 278; no. 7; pp. 1137 - 1144
Main Authors Okumura, Masaki, Saiki, Masatoshi, Yamaguchi, Hiroshi, Hidaka, Yuji
Format Journal Article
LanguageEnglish
Published Oxford, UK Blackwell Publishing Ltd 01.04.2011
Subjects
amino acids
arginine
disulfide
disulfide bonds
Disulfides - chemistry
Disulfides - metabolism
folding
glutathione
Glutathione - chemistry
Glutathione - genetics
Glutathione - metabolism
Humans
lysozyme
Oligopeptides - chemistry
Oligopeptides - genetics
Oxidation-Reduction
Protein Folding
Protein Precursors - chemistry
Protein Precursors - genetics
Protein Precursors - metabolism
Proteins
Sulfide compounds
uroguanylin
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Summary:Protein folding occurs simultaneously with disulfide bond formation. In general, the in vitro folding of proteins containing disulfide bond(s) is carried out in the presence of redox reagents, such as glutathione, to permit native disulfide pairing to occur. It is well known that the formation of a disulfide bond and the correct tertiary structure of a target protein are strongly affected by the redox reagent used. However, little is known concerning the role of each amino acid residue of the redox reagent, such as glutathione. Therefore, we prepared glutathione derivatives - glutamyl-cysteinyl-arginine (ECR) and arginyl-cysteinyl-glycine (RCG) - and examined their ability to facilitate protein folding using lysozyme and prouroguanylin as model proteins. When the reduced and oxidized forms of RCG were used, folding recovery was greater than that for a typical glutathione redox system. This was particularly true when high protein concentrations were employed, whereas folding recovery using ECR was similar to that of the glutathione redox system. Kinetic analyses of the oxidative folding of prouroguanylin revealed that the folding velocity (KRCG = 3.69 × 10⁻³ s⁻¹) using reduced RCG/oxidized RCG was approximately threefold higher than that using reduced glutathione/oxidized glutathione. In addition, folding experiments using only the oxidized form of RCG or glutathione indicated that prouroguanylin was converted to the native conformation more efficiently in the case of RCG, compared with glutathione. The findings indicate that a positively charged redox molecule is preferred to accelerate disulfide-exchange reactions and that the RCG system is effective in mediating the formation of native disulfide bonds in proteins.
Bibliography:http://dx.doi.org/10.1111/j.1742-4658.2011.08039.x
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ISSN:1742-464X
1742-4658
DOI:10.1111/j.1742-4658.2011.08039.x