Combinations of protein-disulfide isomerase domains show that there is little correlation between isomerase activity and wild-type growth.

Protein-disulfide isomerase (PDI) has five domains: a, b, b', a' and c, all of which except c have a thioredoxin fold. A single catalytic domain (a or a') is effective in catalyzing oxidation of a reduced protein but not isomerization of disulfides (Darby, N. J., and Creighton, T. E. (1995) Biochemistry 34, 11725-11735). To examine the structural basis for this oxidase and isomerase activity of PDI, shuffled domain mutants were generated using a method that should be generally applicable to multidomain proteins. Domains a and a' along with constructs ab, aa', aba', ab'a' display low disulfide isomerase activity, but all show significant reactivity with mammalian thioredoxin reductase, suggesting that the structure is not seriously compromised. The only domain order that retains significant isomerase activity has the b' domain coupled to the N terminus of the a' domain. This b'a'c has 38% of the isomerase activity of wild-type PDI, equivalent to the activity of full-length PDI with one of the active sites inactivated by mutation (Walker, K. W., Lyles, M. M., and Gilbert, H. F. (1996) Biochemistry 35, 1972-1980). Individual a and a' domains, despite their very low isomerase activities in vitro, support wild-type growth of a pdi1Delta Saccharomyces cerevisiae strain yeast. Thus, most of the PDI structure is dispensable for its essential function in yeast, and high-level isomerase activity appears not required for viability or rapid growth.

Reactivity of glutaredoxins 1, 2 and 3 from Escherichia coli and protein disulfide isomerase towards glutathionyl-mixed disulfides in ribonuclease A.

We have examined the activity of protein disulfide isomerase (PDI) and glutaredoxin (Grx) 1, 2 and 3 from Escherichia coli to catalyze the cleavage of glutathionylated ribonuclease A (RNase-SG) by 1 mM GSH to yield reduced RNase. Apparent Km values for RNase-SG were similar, 2-10 microM, for Grx 1, 3 and PDI but Grx I and Grx 3 showed 500-fold higher turnover numbers than PDI. The atypical Grx 2 also catalyzed deglutathionylation by GSH, but had higher Km and apparent turnover number values compared to the two classical Grx. Refolding of RNase in a glutathione redox buffer was catalyzed by PDI. However, it could be measured only after a characteristic lag phase that was shortened by all three E. coli Grxs in a concentration-dependent manner. A role of the glutaredoxin mechanism in the endoplasmic reticulum is suggested.

Insulin-like growth factors I and II are unable to form and maintain their native disulfides under in vivo redox conditions.

Insulin-like growth factor (IGF) I does not quantitatively form its three native disulfide bonds in the presence of 10 mM reduced and 1 mM oxidized glutathione in vitro [Hober, S. et al. (1992) Biochemistry 31, 1749-1756]. In this paper, we show (i) that both IGF-I and IGF-II are unable to form and maintain their native disulfide bonds at redox conditions that are similar to the situation in the secretory vesicles in vivo and (ii) that the presence of protein disulfide isomerase does not overcome this problem. The results indicate that the previously described thermodynamic disulfide exchange folding problem of IGF-I in vitro is also present in vivo. Speculatively, we suggest that the thermodynamic disulfide exchange properties of IGF-I and II are biologically significant for inactivation of the unbound growth factors by disulfide exchange reactions to generate variants destined for rapid clearance.

Effect of glutaredoxin and protein disulfide isomerase on the glutathione-dependent folding of ribonuclease A.

Protein folding, associated with oxidation and isomerization of disulfide bonds, was studied using reduced and denatured RNase A (rd-RNase A) and mixed disulfide between glutathione and reduced RNase A derivative (GS-RNase A) as starting materials. Folding was initiated by addition of free glutathione (GSH + GSSG) and was monitored by electrospray mass spectrometry (ESMS) time-course analysis and recovery of the native catalytic activity. The ESMS analysis permitted both the identification and quantitation of the population of intermediates present during the refolding process. Refolding of rd-RNase A and GS-RNase A was also performed in the presence of glutaredoxin (Grx) and/or protein disulfide isomerase (PDI). All the analyses indicate a pathway of sequential reactions in the formation of native RNase A. First, the reduced protein reacts with a single glutathione molecule to form a mixed disulfide which then evolves to an intramolecular S-S bond via thiol-disulfide exchange. Only at this stage, the intermediate containing one intramolecular S-S reacts with a further glutathione molecule, reiterating the process. An analogous mechanism occurs in the refolding of GS-RNase A. The structural analysis of the intermediates formed during the refolding of RNase A showed for the first time that Grx is actually able to catalyze both formation and reduction of mixed disulfides involving glutatione. In both refolding processes, starting from either rd-RNase A or GS-RNase A, Grx displays a significant catalysis at the early stages of the process. Addition of PDI led to a net catalysis of the entire process without appearing to alter the refolding pathway. In the presence of both Grx and PDI, the two enzymes showed a synergistic activity either starting from rd-RNase A, as previously reported [Lundström, J., and Holmgren, A. (1995) J. Biol. Chem. 270, 7822-7828], or starting from GS-RNase A. Present data suggest that the synergistic effect can be explained assuming that Grx actually facilitates PDI action by catalyzing formation or reduction of mixed disulfides. The mixed disulfides are then rapidly converted into intramolecular disulfides in the presence of PDI. These steps are repeated sequentially throughout the whole refolding, resulting in an immediate formation of fully oxidized species even at the very beginning of the reaction. Finally, a Grx mutant, C14S Grx, in which one of the active site cysteine residues (Cys14) had been replaced by serine, had a similar effect on the distribution of folding intermediates, compared to the wild-type protein, thus demonstrating that Grx acts by a monothiol mechanism either in the reduction or in the oxidation step.

Glutaredoxin accelerates glutathione-dependent folding of reduced ribonuclease A together with protein disulfide-isomerase.

Glutaredoxin (Grx) contains a redox-active disulfide and catalyzes thiol-disulfide interchange reactions with specificity for GSH. The dithiol form of Grx reduces mixed disulfides involving GSH or protein disulfides. During oxidative refolding of 8 microM reduced and denatured ribonuclease RNase-(SH)8 in a redox buffer of 1 mM GSH and 0.2 mM GSSG to yield native RNase-(S2)4, a large number of GSH-mixed disulfide species are formed. A lag phase that precedes formation of folded active RNase at a steady-state rate was shortened or eliminated by the presence of a catalytic concentration (0.5 microM) of Escherichia coli Grx together with protein disulfide-isomerase (PDI), its procaryotic equivalent E. coli DsbA, or the PDI analogue the E. coli thioredoxin mutant protein P34H. A mutant Grx in which one of the active site cysteine residues (Cys-11 and Cys-14) had been replaced by serine, C14S Grx, had similar effect compared with its wild-type counterpart. This demonstrated that Grx acted by a monothiol mechanism involving only Cys-11 and that RNase-S-SG-mixed disulfides were the substrates. Grx displayed synergistic activity together with PDI only in GSH/GSSG redox buffers with sufficiently low redox potential (E'0 of -208 or -181 mV) to allow reduction of the active site of Grx. In refolding systems that do not depend on glutathione, like cystamine/cysteamine or in the presence of selenite (SeO3(2-)), no synergistic activity of Grx was observed with PDI. We conclude that Grx acts by reducing mixed disulfides between GSH and RNase that are rate-limiting in enzyme-catalyzed refolding.

Two resident ER-proteins, CaBP1 and CaBP2, with thioredoxin domains, are substrates for thioredoxin reductase: comparison with protein disulfide isomerase.

Protein disulfide-isomerase (PDI) is the best known representative of a growing family of enzymes with thioredoxin domains. Two such proteins with thioredoxin (Trx) domains, CaBP1 and CaBP2 (ERp72), have previously been isolated from rat liver microsomes. Here we report that they, like PDI are substrates for thioredoxin reductase and will catalyze NADPH-dependent insulin disulfide reduction. The activity of CaBP1 and CaBP2 in this assay was higher than that of PDI but lower than that of E. coli Trx. Furthermore, as isolated the thioredoxin domains of CaBP1 and CaBP2 were in disulfide form as judged by stoichiometric oxidation of 2 and 3 mol of NADPH in CaBP1 and CaBP2, respectively. The redox potential of the active site disulfide/dithiol was estimated from the equilibrium with a mutant E. coli Trx, P34H Trx, with a known redox potential (-235 mV). This showed that CaBP1 and CaBP2, like PDI, have a much higher redox potential than wild type thioredoxin (-270 mV) in agreement with a role in formation of protein disulfide bonds. In conclusion, in vitro CaBP1 and CaBP2 share catalytic properties in thiol disulfide-interchange reactions with PDI. Thus, the well known activity of PDI is not unique in the endoplasmic reticulum and CaBP1 and CaBP2 may be regarded as functional equivalents.