The origami of thioredoxin-like folds

doi:10.1110/ps.062268106

REVIEW

The origami of thioredoxin-like folds

Jonathan L. Pan¹ and James C.A. Bardwell¹^,2

¹ Program in Cellular and Molecular Biology, University of Michigan, Ann Arbor, Michigan 48109, USA
² Department of Molecular, Cellular & Developmental Biology, University of Michigan, Ann Arbor, Michigan 48109, USA

Abstract

TOP
Abstract
Introduction
Thioredoxin
Glutaredoxins
The Dsb disulfide...
Alkyl hydroperoxidases
Glutathione S-transferases
Conclusions and laboratory...
Acknowledgments
References

Origami is the Japanese art of folding a piece of paper intocomplex shapes and forms. Much like origami of paper, Naturehas used conserved protein folds to engineer proteins for aparticular task. An example of a protein family, which has beenused by Nature numerous times, is the thioredoxin superfamily.Proteins in the thioredoxin superfamily are all structured witha $beta$ -sheet core surrounded with ${alpha}$ -helices, and most contain a canonicalCXXC motif. The remarkable feature of these proteins is thatthe link between them is the fold; however, their reactivityis different for each member due to small variations in thisgeneral fold as well as their active site. This review attemptsto unravel the minute differences within this protein family,and it also demonstrates the ingenuity of Nature to use a conservedfold to generate a diverse collection of proteins to performa number of different biochemical tasks.

Keywords: thioredoxin; protein folds; glutaredoxin; glutathione S-transferase; Dsb; alkylhydroperoxidase; protein engineering

Introduction

TOP
Abstract
Introduction
Thioredoxin
Glutaredoxins
The Dsb disulfide...
Alkyl hydroperoxidases
Glutathione S-transferases
Conclusions and laboratory...
Acknowledgments
References

Origami is the ancient Japanese art of paper folding—thesimple movement of paper into various shapes and forms someof startling complexity (see Fig. 1). Nature has taken polypeptidesand also folded them into very complicated structures. Unlikefolded paper, proteins are capable of performing countless numbersof reactions, essential to life. Also, unlike paper origami,protein origami does not necessarily engineer completely newfolds, but rather usually alters existing folds slightly tomake that protein adopt new roles. Nature currently uses numerousfolds. Extrapolating back to the origin of life, it seems likelythat all proteins were derived from one or a very limited numberof primordial protein folds. These folds then diverged fromeach other so much that there is often no detectable resemblancethat can be found between protein families. However, by closeexamination of one protein family, we can see how Nature hasadapted one particular fold to perform various functions. Wewill focus on the protein thioredoxin and its adaptable fold.

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Figure 1. Japanese origami. Paper is carefully folded into complex angles using different parts of the paper incorporated with delicate creases. Manipulation of the paper results in a functional representation of an object of shape. In this case, paper was folded to create a replica of a dinosaur. Proteins are also folded with careful creases, creating a functionally active biomolecule.

Thioredoxin is a small ubiquitous protein that reduces proteindisulfides, protects cells from oxidative damage, and is importantfor maintaining the cytoplasm in a reducing state. Thioredoxinremains folded at temperatures up to 80°C. The high degreeof stability conferred by the thioredoxin scaffold may explainwhy it has been adopted by so many proteins for their function.In Escherichia coli, proteins related to thioredoxin includethe glutaredoxins, the disulfide bond oxidoreductases, glutathioneS-transferases, and alkylhydroperoxidases. One important characteristicof the fold is the presence of a Cys-X-X-Cys motif at the activesite, where X is any amino acid. The cysteines can reversiblyform a disulfide bond, allowing thioredoxin-related moleculesto participate in disulfide exchange reactions. Here we attemptto provide a glimpse at the art of protein structure and functionand how it relates to the prototypical protein, thioredoxin.The evolution of thioredoxin via gene duplication events andmutation has altered the function of many members in the thioredoxinsuperfamily. Although the function may have changed, many thioredoxinsand thioredoxin-like proteins have retained key structural featuresthat make them similar. In this review, we will explore thechanges each thioredoxin-like protein has changed by manipulatingits active site, changing its oligomeric state, and adding newdomains to accommodate a particular reactivity. There is vastliterature on thioredoxin-related proteins, and to limit thescope of this review, we have chosen to focus on the analysisof the thioredoxin superfamily in the model organism E. coli.Though limited, this focus has the advantage of detailed analysesand experimentation of many thioredoxin-related proteins havingbeen performed in this organism, and E. coli possesses at leastone member of all major families of thioredoxin-like proteins.

Thioredoxin

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Abstract
Introduction
Thioredoxin
Glutaredoxins
The Dsb disulfide...
Alkyl hydroperoxidases
Glutathione S-transferases
Conclusions and laboratory...
Acknowledgments
References

Thioredoxin is the founding member of the thioredoxin family.It is a 12-kDa protein that is involved in many reactions includingreducing improper disulfides that have formed in the cytosol,donating reductive equivalents to ribonucleotide reductase,and being an indicator of the intracellular redox status. Thioredoxinis reduced by thioredoxin reductase, a flavoenzyme that transfersreducing equivalents from pyridine nucleotide NADPH to thioredoxin(Holmgren 1985, 1989, 2000).

The function of thioredoxin has been implicated in numerouspathways; principally, it provides a protective role againstmany different types of damaging stresses. In most organisms,thioredoxin participates as a hydrogen donor to ribonucleotidereductase, a key enzyme in the generation of deoxyribonucleotidesfor DNA synthesis (Holmgren 1976). Thioredoxin also maintainsreductive homeostasis in the cytosol by reducing incorrect disulfidesthat have formed in proteins, thus returning these proteinsto their native state. Many antioxidant proteins such as theperoxiredoxins, another group in the thioredoxin superfamily,require the reductive action of thioredoxin to remove potentiallydamaging peroxides (Cha et al. 1995).

The structures of thioredoxin of both the oxidized and reducedprotein were solved by NMR (Jeng et al. 1994). The structureof thioredoxin is comprised of five $beta$ -strands located in thecore of the protein, which are encircled by four ${alpha}$ -helices (Holmgren et al. 1975)(see Fig. 2). The active-site motif in thioredoxin includesa conserved four amino acid motif C-P-G-C, which is locatedat the C terminus of $beta$ 2 and starts in the beginning of an ${alpha}$ -helix(Holmgren et al. 1975). These two cysteines reversibly forma disulfide as part of thioredoxin's catalytic mechanism.

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Figure 2. Structure of oxidized thioredoxin. The thioredoxin fold, named for the founding member of the family thioredoxin, is a protein fold consisting of four $beta$ -sheets surrounded by three ${alpha}$ -helices. The thioredoxin family of protein is typically involved in redox active reactions and usually contains a C-X-X-C motif, where X is any amino acid.

The standard redox protein of thioredoxin is E°' = –270mV, indicating that this protein prefers to be in the oxidized,disulfide bonded state (Aslund et al. 1997). The N-terminalcysteine in the thioredoxin motif has a pK_a value of $~$ 7.5, andthe C-terminal cysteine has a pK_a of $~$ 9.2. The N-terminal cysteine'spK_a of thioredoxin is significantly lower than that of freecysteine due to the hydrogen bonding network created by Asp26and Lys57, thereby allowing the C-terminal cysteine to havea lower pK_a (Kallis and Holmgren 1980; Holmgren and Fagerstedt 1982;Dyson et al. 1991, 1997; Chivers et al. 1997). This low pK_aenables thioredoxin to act as a nucleophile and attack disulfidebonds within proteins. The nucleophilic attack on a proteindisulfide results in a mixed disulfide between thioredoxin andits target protein. The resolution of this disulfide iscarried out by the C-terminal cysteine, resulting in a reducedprotein substrate and an oxidized thioredoxin (Holmgren 1995).Thioredoxin thus acts to reduce proteins. The cycle is keptcatalytic via thioredoxin reductase and the pyridine nucleotideNADPH (Lennon and Williams 1996). The NMR structures for bothreduced and oxidized forms of thioredoxin share similar overallstructure with small variations, particularly around the active-sitemotif (Dyson et al. 1988, 1989, 1991; Katti et al. 1990).

Thioredoxin itself has been very well studied and is the subjectof a number of reviews (Holmgren 1985, 1995; Nakamura 2005),and it will not be further discussed here.

Glutaredoxins

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Abstract
Introduction
Thioredoxin
Glutaredoxins
The Dsb disulfide...
Alkyl hydroperoxidases
Glutathione S-transferases
Conclusions and laboratory...
Acknowledgments
References

The glutaredoxins are distantly related to thioredoxin, andoperate via a similar mechanism. They also assist in maintainingthe reductive nature of the cytoplasm. The active site of glutaredoxinsis nearly always a conserved C-P-Y-C motif (Shi et al. 1999).Glutaredoxins provide hydrogens to the protein ribonucleotidereductase (RNR), which is an essential protein in the synthesisof deoxyribonucleotides. Glutaredoxins also participate in thereduction of dehydroascorbate to ascorbate, the reactivationof DNA binding for some transcription factors, and in themaintenance of HIV-1 protease (Kelley and Bushweller 1998).Maintenance of glutaredoxin in its reduced state is facilitatedby reduced glutathione in the cytoplasm. The reduced glutathioneis recycled from the oxidized state to the reduced state viaglutathione reductase (gor), which in turn is reduced by pyridinenucleotide.

Glutaredoxins were first discovered in 1976 by Arne Holmgren(Holmgren 1976). Glutaredoxin in E. coli has four orthologs:Grx1, Grx2, Grx3, and Grx4. These proteins share the classicthioredoxin/glutaredoxin fold, which is characterized by four $beta$ -sheets surrounded by three ${alpha}$ -helices (Eklund et al. 1992) (Figs. 3,4). These proteins participate in a variety of reactions inE. coli by providing hydrogens to ribonucleotide reductase andPAPS reductase as well as the detoxification of many toxic organicmolecules.

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Figure 3. Ribbon structures of representative members for the thioredoxin family. Members of the thioredoxin family have a characteristic fold with $beta$ -sheets surrounded by ${alpha}$ -helices.

Glutaredoxins have been generalized into three different isoforms.The first isoform characteristic of Grx1 and Grx3 from E. colihas a typical thioredoxin fold as well as a CXXC motif. Grx1and Grx3 are functionally similar because they both functionas reductive enzymes and provide reducing equivalents to proteins(Bushweller et al. 1994; Aslund et al. 1996). The secondisoform of glutaredoxins is the glutathione S-transferase-likeproteins. These are much larger, $~$ 24 kDa; in E. coli, the representativeis Grx2. Grx2 has an N-terminal glutaredoxin domain with a catalyticallyactive CXXC motif and a C-terminal ${alpha}$ -helical domain (Vlamis-Gardikas et al. 1997).These proteins are involved in cellular detoxification of manytoxic compounds. Grx4, a very recently discovered E. coli memberof the last group of glutaredoxins, are monothiol glutaredoxinsthat contain a CXFX motif (Fernandes et al. 2005). In eukaryotesthey are principally involved in iron–sulfur cluster assembly,oxidative stress response, and other cellular processes (Rodriguez-Manzaneque et al. 1999).

Grx1 was first discovered as a GSH-dependent hydrogen donorto the enzyme ribonucleotide reductase (Holmgren 1976). In vivoit was shown to be 10-fold less in concentration than its counterpartthioredoxin, but also had a 10-fold less K _m for ribonucleotidereductase (RNR) (Holmgren 1979b). Grx1 has been shown to bethe primary reductant to RNR, and is also an alternate reductantto methionine sulfoxide reductase (Holmgren 1979a,b). Grx1 alsois a stress induced protein (Stewart et al. 1998). Grx1is under the control of OxyR, a potent transcription factorthat senses oxidative stress induced by chemicals such as hydrogenperoxide (Tao 1997). OxyR must be glutathionylated to be activein inducing the transcriptions of target genes. Grx1 functionsto deglutathionylate OxyR. This system is autoregulatory whereGrx1 regulates OxyR activity, and OxyR regulates expressionof the gene for Grx1, grxA (Tao 1997). Grx1 is not essentialfor cell viability in E. coli, suggesting the existence of alternatereducing agents (Zheng et al. 1998).

One such alternative reductant, Grx2, was discovered by lookingfor suppressors in a ${Delta}$ grxA strain. Grx2 is much larger in sizethan the other three orthologs of glutaredoxin in E. coli, andits structure more closely resembles glutathione S-transferasethan glutaredoxin 1, 2, and 4. However, Grx2 does have an N-terminalglutaredoxin domain whose structure is similar to the otherglutaredoxins, including a C-P-Y-C active site. Grx2 also containsa C-terminal ${alpha}$ -helical domain. Grx2 does not reduce ribonucleotidereductase, and is not a reductant for PAPS reductase, but hasan extremely high catalytic activity in resolving the mixeddisulfide between $beta$ -hydroxyethyl disulfide (HED) and GSH. Thissuggests that Grx2 participates mainly in monothiol reactionsthat remove glutathionylation from proteins. Grx2 is regulatedby the stationary phase sigma factor (RpoS) and guanosine-3',5'-tetraphosphate (ppGpp). These two factors control the regulationof genes in stationary phase of growth, and the expression ofGrx2 under these conditions might contribute to the overalldefense of organic peroxides and hydrogen peroxides (Aslund et al. 1994;Vlamis-Gardikas et al. 1997; Lillig et al. 1999).

Grx3 was also discovered in a suppressor screen using a ${Delta}$ grxAstrain. It resembles Grx1 both in size and in structure. Grx3has $~$ 33% sequence identity to Grx1, contains a glutaredoxin-likefold, and has the C-P-Y-C redox active motif. Grx3 has $~$ 5% thecatalytic rate of Grx1 for ribonucleotide reductase, and Grx3cannot reduce PAPS reductase. Deletion of this gene caused increasedsensitivity to oxidizing agents such as menadione and cumenehydroperoxide, but it is still unclear what the in vivo roleof Grx3 is and how it is regulated (Aslund et al. 1994, 1996;Lillig et al. 1999).

Grx4 is the only monothiol glutaredoxin in E. coli, and wasshown to be essential (Gerdes et al. 2003). Grx4 differs fromthe other orthologs in that it lacks activity toward classicglutaredoxin substrates such as HED, insulin, and others (Fernandes et al. 2005).It was also shown that Grx4 can be a substrate for thioredoxinreductase, and its glutathionylation status is dependent onGrx1 (Fernandes et al. 2005). Recently, Fladvad et al. (2005)solved the NMR solution structure of Grx4 and detailed its monothiolmechanism.

The catalytic mechanism of the glutaredoxins can be classifiedas being dithiol or monothiol reduction (see Fig. 5 below).In the dithiol mechanism, the N-terminal cysteine in the CXXChas an extremely low pK_a and is deprotonated, exposing a thiolateanion. The manipulation of the pK_a of the N-terminal cysteineis a common theme in thioredoxin-like proteins including glutaredoxins.An intricate network of hydrogen bonds secures the thiolateand allows it to be catalytically active. A common theme inglutaredoxins is the incorporation of a proline in the firstposition of the CXXC motif and an aromatic residue at the secondposition; Grx4 also contains the aromatic residue phenyalaninein a conserved CXFX motif, which also participates in hydrogenbonding to lower the pK_a of the N-terminal cysteine (Foloppe et al. 2001;Fladvad et al. 2005). The proline incorporation results in akink that displaces the N-terminal cysteine into a positionthat can be hydrogen bonded by the amide proton from the aromaticresidue (Foloppe et al. 2001; Fladvad et al. 2005). These modificationscontrast the active site with thioredoxin.

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Figure 4. Typical architecture of thioredoxin-like proteins. The figure displays the two-dimensional representation of the thioredoxin fold in representative proteins in the thioredoxin super family. $beta$ -Sheets are drawn as arrows and ${alpha}$ -helices are drawn in boxes. A typical thioredoxin fold is shown where two parallel $beta$ -sheets are intervened by an ${alpha}$ -helix. In addition, between the N-terminal and C-terminal portion is an ${alpha}$ -helix that connects these two domains. Helices that are not part of the thioredoxin fold are drawn colored in white.

The resulting stabilized thiolate anion can then initiate anucleophilic attack on a sulfur atom of a target disulfide bridge.The glutaredoxin has now formed a mixed disulfide with a targetprotein; this causes the second cysteine in the CXXC motif tobecome deprotonated and attack the N-terminal cysteine to resolvethe mixed disulfide. This dithiol reaction results in a reducedtarget protein and an oxidized glutaredoxin (see Fig. 5A). Thedithiol reaction is very similar to the one carried outby thioredoxin; however, glutaredoxin can also participate inmonothiol reductions in concert with GSH. The principal purposeof the monothiol reaction is to deglutathionylate proteins.This release of the GSH from proteins is first initiated bythe N-terminal cysteine of the CXXC motif, which attacks theprotein–GSH complex. In addition, the N-terminal cysteineof the CXXC also has a low pKa, which allows the sulfur to serveas a good leaving group in a monothiol reaction. Furthermore,Glutaredoxin has a high affinity site that only interactswith the GSH moiety and not the protein. GSH binding grooveis formed in part by Lys8 and Asp67, which provide favorableionic interactions between GSH and glutaredoxin (Foloppe and Nilsson 2004).The addition of this site to the thioredoxin scaffold is oneof the key things that allows glutaredoxins to specificallyreact with glutaredoxin. These residues are conserved in theglutaredoxins, but are not present in the rest of the thioredoxinsuperfamily, which explains why proteins such as thioredoxinand DsbA cannot efficiently participate in monothiol reactionsinvolving GSH.

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Figure 5. Mechanism of dithiol and monothiol reactivities of glutaredoxin. (A) (1) Reduced glutaredoxin first seeks a substrate that has a disulfide bond; (2) with a reduced cysteine, glutaredoxin attacks the disulfide in the target protein resulting in a mixed disulfide; (3–4) with a deprotonated C-terminal cysteine, glutaredoxin attacks the mixed disulfide, which results in a reduced substrate protein and a completely oxidized glutaredoxin; (5) Glutaredoxin is then reduced to return back into its active form. (B) (1) Glutaredoxin starts off as a reduced species and attacks a protein that is glutathionylated on a cysteine. (2) Glutaredoxin becomes glutathionylated and the substrate protein becomes reduced with a free cystine. (3) A reduced glutathione molecule then attacks the mixed disulfide in glutaredoxin. (4) Glutaredoxin returns back into its reduced conformation and oxidized glutathione disulfide is formed.

Glutaredoxin catalyzes the movement of GSH from the target proteinto the glutaredoxin, creating a glutaredoxin–GSH conjugate.The conjugate is later displaced by another GSH (Bushweller et al. 1994).The resulting reaction results in the deglutathionylation ofproteins, the formation of oxidized glutathione, and the releaseof glutaredoxin in its reduced state (see Fig. 5B).

The Dsb disulfide oxidoreductases

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Abstract
Introduction
Thioredoxin
Glutaredoxins
The Dsb disulfide...
Alkyl hydroperoxidases
Glutathione S-transferases
Conclusions and laboratory...
Acknowledgments
References

The conditions faced in the extracellular world are harsh, imposinga need for proteins to have extra stability. Disulfide bondsare one modification proteins utilize to retain their tertiarystructure even in harsh environments. The disulfide oxidoreductases(Dsb) are proteins that catalyze disulfide bond formation insecreted proteins. In addition, if incorrect disulfide bondsform within a protein, another thioredoxin-like oxidoreductasecalled DsbC can isomerize the incorrect disulfides to the correctform (Kadokura et al. 2003).

DsbA
DsbA, a 21-kDa thioredoxin-like oxidoreductase, acts as thedirect donor of disulfide bonds to secreted proteins (Bardwell et al. 1991).DsbA is the primary oxidant in the E. coli periplasm. Deletionof this gene results in the failure to oxidize a variety ofsecreted proteins, their instability, and degradation (Hiniker and Bardwell 2004).The resulting phenotypes include sensitivity to the reductantdithiothreitol, loss of motility due to a misfolded flagellarmotor protein, FlgI, metal sensitivity, and an increased susceptibilityto M13 phage due to incorrect F pilus formation (Dailey and Berg 1993;Missiakas et al. 1993; Stafford et al. 1999). While the ${Delta}$ dsbmutant is not lethal, the activities associated with DsbA areimportant to the viability of the cell.

The molecular mechanism of DsbA is well studied (see Fig. 6).DsbA is composed of two domains, a thioredoxin-like domain andan all ${alpha}$ -helical domain missing in thioredoxin. Thioredoxin sharesonly about 10% sequence identity with the thioredoxin-like domainof DsbA. The active site of DsbA is a conserved CPHC motif locatedin the thioredoxin domain (Martin et al. 1993) (Fig. 2). Thesetwo cysteines form a highly oxidizing disulfide bond, whichis donated to substrate proteins. The standard redox potentialof DsbA is –122 mV, which makes DsbA one of the most oxidizingdisulfide oxidoreductases known, a key requirement for DsbAfunction (Zapun et al. 1993).

The strongly oxidizing nature of DsbA is in part due to thestabilization of the Cys30 thiolate anion by the partial positivecharge on the helix dipole of helix ${alpha}$ 1, hydrogen bond contactsto His32, and stabilization by hydrogen bonding to either Sor H^N of Cys33 (Grauschopf et al. 1995). These interactionsmost likely provide a hydrogen bond network that lowers thepK_a of Cys30 to $~$ 3.5. This is much lower than both the pK_a offree cysteine and the pK_a or thioredoxin. Thus, Cys30 almostalways exists as a thiolate in vivo (Grauschopf et al. 1995;Guddat et al. 1998).

Once DsbA transfers its disulfide to proteins, in order to becatalytic it needs to be reoxidized. DsbB acts to reoxidizeDsbA; it removes electrons from DsbA and transfers them to therespiratory chain. In aerobic conditions, DsbB reduces ubiquinone,and ultimately reduces oxygen. In anaerobic conditions, theelectron acceptor is menaquinone, which transfers the electronsto nitrate, nitrite, and fumarate (Kobayashi et al. 1997; Bader et al. 1999,2000; Xie et al. 2002) (see Fig. 6).

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Figure 6. Mechanism of disulfide formation and isomerization in the bacterial periplasm. (A) Disulfide bonds are generated by the Dsb family of proteins in the bacterial periplasm. First, DsbA, a thioredoxin-like protein, has a catalytic disulfide and seeks to donate its disulfide to newly translocated proteins, resulting in a reduced DsbA and oxidized substrate protein. For the system to be catalytic, a membrane protein DsbB oxidizes DsbA. DsbB gains its oxidizing equivalents from the electron transport chain with the final electron acceptor oxygen. (B) DsbA is a potent disulfide oxidase and has the potential to incorporate incorrect disulfides. Another pathway exists to correct incorrect disulfides formed by DsbA or another exogenous disulfide source. DsbC is a thioredoxin-like protein that has reduced cysteines. These reduced cysteines accept a disulfide from a substrate protein. Maintaining DsbC in the reduced form is accomplished by the membrane protein DsbD. DsbD gains its reducing equivalents from the cytosolic protein thioredoxin, which ultimately gains its reduced equivalents from NADPH.

DsbC
DsbA is a very powerful oxidant. If a protein has more thantwo cysteine residues, then DsbA has the potential to form incorrectdisulfide bonds. DsbC acts to isomerize incorrectly oxidizedproteins. DsbC is a 23.5-kDa protein with two domains, a C-terminalthioredoxin-like domain and an N-terminal dimerization domain(McCarthy et al. 2000). The protein forms a V-shaped dimer withan uncharged cleft that is thought to be involved in peptidebinding (McCarthy et al. 2000; Bader et al. 2001; Collet et al. 2002).It is thought that DsbC functions by detecting hydrophobic patcheson misfolded proteins via its uncharged cleft, once bound; DsbC'sreduced cysteines probe for disulfides in the misfolded protein.Cys98, the nucleophilic cysteine in DsbC, attacks a substratedisulfide and forms a mixed disulfide between DsbC and the substrateprotein. The mixed disulfide can be resolved in one of two ways.The mixed disulfide could be resolved when the substrate protein'sreduced cysteine attacks the mixed disulfide, creating a newdisulfide bond in the target protein and returning DsbC backinto its reduced state. Alternatively, the second active sitecysteine from DsbC could attack the mixed disulfide, formingan oxidized DsbC and a reduced substrate protein (see Fig. 5).This process would cause the target substrate protein to becomereduced, and could allow DsbA to reoxidize that protein to thecorrect conformation. Both forms of DsbC action require thatDsbC be maintained in the reduced state, and this requires DsbD(Walker and Gilbert 1997; Darby et al. 1998a,b) (see Fig. 6).

In contrast, in order to function as an oxidase in vivo, DsbAneeds to be kept oxidized. This means that there needs to bea barrier that separates the isomerase pathway from the oxidasepathway. Otherwise, DsbA would oxidize and therefore inactivateDsbC, and DsbC would reduce and therefore inactivate DsbA. Bader et al. (2001)probed the nature of this barrier by the selection of DsbC mutantsthat could rescue DsbA function in a ${Delta}$ dsbA strain. The mutationsin DsbC that allowed DsbC to function as an oxidase disrupteddimerization and resulted in DsbC monomers. These DsbCmutations allowed DsbC to be oxidized by DsbB, suggesting thatthe dimeric form of DsbC cannot be oxidized by DsbB. DsbC canthus function as a disulfide oxidase when the dimerization domainis mutated to form monomers. In addition, Sergatori et al. (2006)has also shown that a deletion in the ${alpha}$ -helical linker betweenthe N-terminal dimerization domain and the C-terminal thioredoxindomain also causes the dimeric DsbC to function as asubstrate for DsbB. This illustrates how simply the overallfunction of a thioredoxin related protein can be changed bymutagenesis, from that of an isomerase to an oxidase. It alsopoints out the important role of the conjugant reoxidants andreductases have in dictating the overall function of thioredoxinrelated proteins. Closely related to DsbC in both sequence andstructure is the DsbG protein, which is also thought tofunction as a disulfide isomerase (Andersen et al. 1997).

DsbD is a 59-kDa membrane protein found in E. coli that reducesboth DsbC and DsbG. DsbD is composed of three domains:DsbD ${alpha}$ is a thioredoxin-like domain, DsbD ${gamma}$ resembles an immunoglobulin-likefold, and DsbD $beta$ is a membrane-bound domain that contains eighttransmembrane segments (Goulding et al. 2002). Each domain containsa pair of cysteines postulated to be involved in the reductionof DsbC and DsbG. The mechanism of moving reducing equivalentsfrom the cytoplasm to the periplasm has been shown to work inconcert with the thioredoxin system. The proposed mechanismstarts with reduced thioredoxin docking to the $beta$ -domain and reducingthe cysteine pair located in that subunit. This subunit subsequentlyreduces the ${gamma}$ -domain, which then reduces the ${alpha}$ -domain. The ${alpha}$ -domainthen reduces oxidized DsbC and DsbG in a disulfide cascade reactionthat involves multiple thiol–disulfide exchange reactions.This achieves a net flow of reducing equivalents from the cytoplasmto the periplasm (Rietsch et al. 1996, 1997; Collet et al. 2002).Since thioredoxin-like proteins function primarily as thiol–disulfideoxidoreductases, it is not surprising that a thioredoxin-likeprotein be involved in this cascade, but it is remarkable thatthe disulfide isomerization pathway consists of no less thanfour thioredoxin related proteins: thioredoxin itself, DsbD,DsbC, and DsbG. The disulfide cascade within this pathway appearsto be controlled by ever increasing redox potentials that allowthe disulfides to fall down an energy gradient.

Alkyl hydroperoxidases

TOP
Abstract
Introduction
Thioredoxin
Glutaredoxins
The Dsb disulfide...
Alkyl hydroperoxidases
Glutathione S-transferases
Conclusions and laboratory...
Acknowledgments
References

Reactive oxygen species (ROS, ROOH, H₂O₂, O₂ ^–, and OH^· ) are generated in the cell by a variety of cellularprocesses that include incomplete reduction of molecular oxygenby the respiration chain, phagocytosis, and redox cycling ofxenobiotics (Cha et al. 1995). These reactive oxygen speciescan be extremely detrimental by oxidizing, thereby criticallydamaging many cellular components. They can oxidize proteinsresulting in denaturation, and can cause oxidation of nucleotidesin DNA and thus mutagenesis. A class of thioredoxin-like proteinscalled the peroxiredoxins (PRX) or the alkylhydroperoxidases(AHP) provide a line of defense against inorganic and organicperoxides. In E. coli, examples of these proteins are the thiol-dependentperoxidase and alkylhydroperoxide reductase (Bieger and Essen 2001).In general, these proteins reduce hydroperoxides by having acysteine react with a peroxide moiety. The peroxide moiety isreduced to a less harmful alcohol and the cysteine is oxidizedto form a sulfenic acid intermediate. The sulfenic acidintermediate is then resolved by another protein to reform thethiol. Alternatively, the sulfenic acid intermediate reactswith another cysteine in the protein causing the formation of adisulfide bond and water. The disulfide bond is then reducedby a thiol reductase such as thioredoxin, returning theperoxiredoxin or alklhydroperoxidase back into its reduced catalyticallyactive thiol form (Cha et al. 1995; Poole 1996; Wood et al. 2003)(see Fig. 7).

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Figure 7. Generalized mechanisms of atypical 2-Cys, typical 2-Cys, and 1-Cys peroxiredoxins. (A) In the typical 2-Cys peroxiredoxins, a homodimer, where one monomer has the active peroxidatic site cysteine and the other having the resolving cysteine. The peroxidatic becomes oxidized to a sulfenic acid, thereby reducing hydrogen peroxide to water. The resolving cysteine now attacks the peroxidatic cysteine to form an intersubunit disulfide bond. The disulfide is reduced from cytosolic reductants such as thioredoxin. (B) In the atypical 2-Cys peroxiredoxins, the mechanism of action is very similar to the typical 2-Cys peroxiredoxins except that both the peroxidatic and the resolving cysteines are both on the same monomer, thereby eliminating the need for two protein monomers. (C) The 1-Cys peroxiredoxins function differently than the 2-Cys peroxiredoxins. These peroxiredoxins interact with the peroxide directly and form a sulfenic acid intermediate on the peroxidatic cysteine. The 2-Cys peroxiredoxins then interact with a thiol reducing source such as thioredoxin or glutaredoxin and become reduced, releasing water and regenerating the reduced 1-Cys peroxiredoxin. (Derived from Wood et al. 2003.)

Tpx is a 20-kDa peroxiredoxin found in the E. coli periplasmand other pathogenic bacterial species and has been implicatedin the reduction of hydrogen peroxide. It was discovered in1995 by its thiol-dependent antioxidant activity (Cha et al. 1995).Tpx contains two catalytically active cysteines that participatein the reduction of hydrogen peroxide and other organic hydroperoxides.Tpx can efficiently suppress the inactivation of glutamine synthetasevia metal catalyzed oxidation, a standard assay in measuringperoxidase activity (Cha et al. 1995). Tpx is reduced by thioredoxinin vivo.

Tpx contains a thioredoxin-like fold consisting of a seven-strandedtwisted $beta$ -sheet surrounded by four ${alpha}$ -helices (Choi et al. 2003).It shares $~$ 16% sequence identity with thioredoxin. Thr58, Cys61,and Arg133 form a catalytic triad. Thr58 and Arg133 act to lowerthe pK_a of Cys61’s active site sulfur, thus allowing theresulting thiolate to participate in nucleophilic attack ofthe target hydroperoxide. A lower than normal pK_a of the activesite cysteine is a common mechanism that thioredoxin-likeproteins including thioredoxin, glutaredoxin, DsbA, DsbC, DsbG,and Tpx use to increase their reactivity. The pyrrolidine ringon Pro54 of Tpx acts to limits solvent accessibility as wellas peroxide accessibility of Cys61. This may prevent overoxidationof that cysteine from a sulfenic acid intermediate to speciessuch as sulfinic and sulfonic acid. Also observed in the crystalstructure was an L-shaped hydrophobic cleft that is formed bythe N-terminal $beta$ -hairpin, which seems to be able to accommodatelong fatty acid hydroperoxides. This N-terminal $beta$ -hairpin isabsent in other peroxiredoxins, a possible reason why Tpxhas high specificity toward alkylhydroperoxides. The structurewith the extra N-terminal $beta$ -hairpin is uniquely present in Gram-negativebacteria, particularly in pathogenic bacteria (Choi et al. 2003).

AhpR is a multimeric protein composed of AhpC and AhpF, whichcombine to form a potent alkylhydroperoxidase complex. AhpCis a 21-kDa thioredoxin-like protein that has two cysteine residues.AhpC forms an intersubunit disulfide with another AhpC monomerresulting in a homodimer. This intersubunit disulfide seemsto be undergoing reversible reduction during catalysis and the additionof N-ethylmaleimide can irreversibly inhibit AhpC, evidencethat this intersubunit disulfide is part of a disulfide exchangemechanism (Wood et al. 2003).

AhpF forms the other component of the AhpR complex. AhpF isa 57-kDa protein that contains an FAD moiety as well as sixtotal cysteines, with one pair forming a disulfide and the otherfour existing in the reduced form. AhpF has an N-terminal thioredoxin-foldwith two cysteines that are involved in thiol–disulfideexchange. It also contains a C terminus that is highly homologousto thioredoxin reductase and is responsible for binding theflavin moiety. Thus, the AhpF enzyme could be thought of asbeing derived from a fusion of the two main components of thethioredoxin–thioredoxin reductase pathway. The completeAhpF enzyme contains two disulfides, Cys129–Cys132 andCys345–Cys 348, as well as two thiols in the C terminus(Cys476 and Cys489). The Cys129 and Cys132 in the thioredoxindomain of AhpF are the cysteine pair that directly reduces AhpCas part of AhpC's catalytic cycle. Removal of this domain causesa dramatic decrease in NADH consumption as well as decreasedreduction rate of AhpC by AhpF (Poole et al. 2000; Reynolds and Poole 2000;Bieger and Essen 2001; Wood et al. 2001).

Glutathione S-transferases

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Abstract
Introduction
Thioredoxin
Glutaredoxins
The Dsb disulfide...
Alkyl hydroperoxidases
Glutathione S-transferases
Conclusions and laboratory...
Acknowledgments
References

The glutathione S-transferases are a class of proteins thatparticipate in the addition of glutathione to electrophilicgroups of many hydrophobic compounds including organic halides,epoxides, ${alpha}$ - and $beta$ -unsaturated carbonyls, organic nitrate esters,and organic thiocyanates (Mannervik and Danielson 1988; Coles and Ketterer 1990).The addition of glutathione to these xenobiotic compounds allowsthe compounds to become more hydrophilic, and tends to makethe compounds less reactive to cellular components. GlutathioneS-transferases also participate in concert with GSH to detoxifyintracellular organic hydroperoxides. In addition, bacterialspecies including E. coli use glutathionylation as a meansto promote degradation of antibiotics, and glutathione S-transferaseshave also been shown to bind to the antibiotics themselves(Vuilleumier 1997). These examples show that glutathione S-transferasesparticipate in the degradation of toxic compounds importedinto the cell. They do so by making them more water solubleand deactivating reactive groups that could potentially causedamage.

Most glutathione S-transferases are homodimers, with each monomerfolding into two domains connected via hydrogen bonds. Eachmonomer in the dimer has two distinct domains, an N-terminalthioredoxin-like domain (amino acids $~$ 1–80) and a C-terminaldomain (amino acids $~$ 89–201) (using E. coli numbering).The N-terminal domain participates in binding the glutathionemoiety via its thioredoxin-like domain while the C-terminaldomain contains several hydrophobic ${alpha}$ -helices that specificallybind hydrophobic substrates. Thus, similar to DsbC, DsbD, andAhpF, the function of the thioredoxin-like domain has becomemodified by the covalent addition on another domain. Anotherexample of a thioredoxin-like protein that has an additionaldomain fused onto it is YbbN, a 33-kDa heat-shock inducibleprotein of unknown function. This protein consists of an N-terminalthioredoxin domain and a C-terminal glcnac transferase-likedomain. In thioredoxin-like proteins the N-terminal cysteineof the CXXC motif is exposed and reactive, but intriguingly,YbbN lacks the N-terminal cysteine of this motif. The proteinhas no activity in the reduction of insulin's disulfide bonds,nor does it show any chaperone activity when using citrate synthaseas a model substrate (J.L. Pan and J.C. Bardwell, unpubl.).YbbN may be an example of a thioredoxin-like fold that is inthe process of evolving away from a redox-related function.

The E. coli glutathione S-transferase structure was solved at2.1 Å bound to glutathione sulfonate, a glutathione analog.The overall topology and structure show that the protein hasa similar shape to many other glutathione S-transferases structures.E. coli glutathione S-transferase shares $~$ 26%–80% sequenceidentity with other bacterial glutathione S-transferases and<20% sequence identity to the eukaryotic glutathione S-transferases.Mechanistically, the reaction scheme for eukaryotic glutathioneS-transferases involves either Tyr5 or Ser11 in the positioningof the glutathione molecule within the N-terminal domain (Nishida et al. 1998).In E. coli glutathione S-transferase, these two residues areunable to participate in hydrogen bonding with glutathione dueto spatial constraints. In E. coli, Tyr5, instead, has its sidechain directed into the solvent region and Ser11 is almost 7.1Å away, placing the amino acid far away from the sulfurof the glutathione analog. Thus, Ser11 and Try5 in E. coli arenot playing a part in stabilizing the glutathione; instead,Cys10 and His106 are involved. This is an example of how differentorganisms have used different residues but maintained acertain activity (Nishida et al. 1998).

Glutathione S-transferases are extremely specific in their abilityto detoxify aromatic and other hydrophobic compounds. In Burkholderia,bphK is a glutathione S-transferase thought to be involved specificallyin the degradation of biphenyls (Vuilleumier 1997). In Sphingomonaspaucimobilis the glutathione S-transferases ligE and ligF canactually distinguish between the two different enantiomers ofa $beta$ -aryl ether model compound, allowing for selective degradationof one product over another (Masai et al. 2003).

Conclusions and laboratory evolution of thioredoxin-like proteins

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Abstract
Introduction
Thioredoxin
Glutaredoxins
The Dsb disulfide...
Alkyl hydroperoxidases
Glutathione S-transferases
Conclusions and laboratory...
Acknowledgments
References

The thioredoxin-like fold is found in numerous proteins in themodel genetic organism E. coli and in other species. This particularfold is seen in predominantly redox active proteins that participatein the reduction or oxidation of disulfide bonds, electron donation,and detoxification. These examples show that enzymatic evolutionhas used the thioredoxin fold as a scaffold for a number ofdifferent purposes. Nature has been seen to maintain catalyticallyactive protein folds and alter them so that they broaden theirability to catalyze a new substrate. These changes occurredas a selection to new substrates, and have led to the evolutionof thioredoxin into more specialized proteins that maintaincell homeostasis.

Laboratory evolution of the thioredoxin-like fold further emphasizesthe flexibility of the fold and helps illustrate how variousfunctions can be acquired by individual members that did notpossess these functions prior to the imposed selection. Forexample, substitution of thioredoxin's active site CGPC to DsbA'sactive site CPHC can result in a protein that functions verysimilarly to DsbA. The CXXC sequence can even be thought ofas a signature motif that defines the function of the family.Another example of in vitro evolution is the selection of thioredoxinmutants that can compensate for the whole DsbA–DsbB pathway.A mutation from CGPC to CACC in exported versions of thioredoxinwas capable of complementing null mutations in the DsbA–DsbBpathway. They did so by acquiring a 2Fe–2S iron–sulfurcluster, and presumably a whole new mechanism of action. Thisshows that thioredoxin is extremely amenable to mutation, conferringthe protein with new catalytic properties and the abilityto participate in new redox reactions (Masip et al. 2004).

Ritz et al. (2001) deleted thioredoxin reductase and glutathioneoxidoreductase; both of these proteins are required forthe maintenance of a reducing cytosol. However, it was discoveredthat an insertion of a single TCT insertion in the gene ahpCallowed the AhpC protein product to function as a disulfidereductase as opposed to the peroxiredoxin role that it normallyparticipates in within the cell. AhpC has lost its peroxidaseactivity while gaining a disulfide reductase activity.

These examples show that thioredoxin and thioredoxin-like proteinscan evolve, both in function and substrate specificity, withonly few amino acid changes in the protein. Although the functionand specificity has changed, the thioredoxin fold is still conserved.The observed pliability and adaptation of thioredoxin makesthis protein extremely suitable for the construction of novelredox reactions that participate in numerous processes, ranging fromprotein folding, detoxification, and metabolite synthesis.

Footnotes

Reprint requests to: James C.A. Bardwell, 830 North University,Rm. 4007, Ann Arbor, MI 48109, USA; e-mail: jbardwel{at}umich.edu;fax: (313) 647-0884.

Article and publication are at http://www.proteinscience.org/cgi/doi/10.1110/ps.062268106.

Acknowledgments

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Abstract
Introduction
Thioredoxin
Glutaredoxins
The Dsb disulfide...
Alkyl hydroperoxidases
Glutathione S-transferases
Conclusions and laboratory...
Acknowledgments
References

We thank Jimmy Regeimbal, Stefan Gleiter, and Annie Hinikerfor reading over this article. We also thank Arne Holgren forproviding his helpful comments. Funding was made available fromNIH and HHMI to J.C.A.B. J.L.P. is a Ruth L. Kirchenstein Fellow.

References

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Thioredoxin
Glutaredoxins
The Dsb disulfide...
Alkyl hydroperoxidases
Glutathione S-transferases
Conclusions and laboratory...
Acknowledgments
References

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