Crystal structure of an archaeal peroxiredoxin from the aerobic hyperthermophilic crenarchaeon Aeropyrum pernix K1

Peroxiredoxins (Prxs) are thiol-dependent peroxidases that catalyze the detoxification of various peroxide substrates such as H2O2, peroxinitrite, and hydroperoxides, and control some signal transduction in eukaryotic cells. Prxs are found in all cellular organisms and represent an enormous superfamily. Recent genome sequencing projects and biochemical studies have identified a novel subfamily, the archaeal Prxs. Their primary sequences are similar to those of the 1-Cys Prxs, which use only one cysteine residue in catalysis, while their catalytic properties resemble those of the typical 2-Cys Prxs, which utilize two cysteine residues from adjacent monomers within a dimer in catalysis. We present here the X-ray crystal structure of an archaeal Prx from the aerobic hyperthermophilic crenarchaeon, Aeropyrum pernix K1, determined at 2.3 A resolution (Rwork of 17.8% and Rfree of 23.0%). The overall subunit arrangement of the A.pernix archaeal Prx is a toroid-shaped pentamer of homodimers, or an (alpha2)5 decamer, as observed in the previously reported crystal structures of decameric Prxs. The basic folding topology and the peroxidatic active site structure are essentially the same as those of the 1-Cys Prx, hORF6, except that the C-terminal extension of the A.pernix archaeal Prx forms a unique helix with its flanking loops. The thiol group of the peroxidatic cysteine C50 is overoxidized to sulfonic acid. Notably, the resolving cysteine C213 forms the intra-monomer disulfide bond with the third cysteine, C207, which should be a unique structural characteristic in the many archaeal Prxs that retain two conserved cysteine residues in the C-terminal region. The conformational flexibility near the intra-monomer disulfide linkage might be necessary for the dramatic structural rearrangements that occur in the catalytic cycle.     

Insights into the Alkyl Peroxide Reduction Pathway of Xanthomonas campestris Bacterioferritin Comigratory Protein from the Trapped Intermediate-Ligand Complex Structures

Considerable insights into the oxidoreduction activity of the Xanthomonas campestris bacterioferritin comigratory protein (XcBCP) have been obtained from trapped intermediate/ligand complex structures determined by X-ray crystallography. Multiple sequence alignment and enzyme assay indicate that XcBCP belongs to a subfamily of atypical 2-Cys peroxiredoxins (Prxs), containing a strictly conserved peroxidatic cysteine (C_P48) and an unconserved resolving cysteine (C_R84). Crystals at different states, i.e. Free_SH state, Intra_SS state, and Inter_SS state, were obtained by screening the XcBCP proteins from a double C48S/C84S mutant, a wild type, and a C48A mutant, respectively. A formate or an alkyl analog with two water molecules that mimic an alkyl peroxide substrate was found close to the active site of the Free_SH or Inter_SS state, respectively. Their global structures were found to contain a novel substrate-binding pocket capable of accommodating an alkyl chain of no less than 16 carbons. In addition, in the Intra_SS or Inter_SS state, substantial local unfolding or complete unfolding of the C_R-helix was detected, with the C_P-helix remaining essentially unchanged. This is in contrast to the earlier observation that the C_P-helix exhibits local unfolding during disulfide bond formation in typical 2-Cys Prxs. These rich experimental data have enabled us to propose a pathway by which XcBCP carries out its oxidoreduction activity through the alternate opening and closing of the substrate entry channel and the disulfide-bond pocket.     

Crystal structure of Escherichia coli thiol peroxidase in the oxidized state: insights into intramolecular disulfide formation and substrate binding in atypical 2-Cys peroxiredoxins

Thioredoxin-dependent thiol peroxidase (Tpx) from Escherichia coli represents a group of antioxidant enzymes that are widely distributed in pathogenic bacterial species and which belong to the peroxiredoxin (Prx) family. Bacterial Tpxs are unique in that the location of the resolving cysteine (CR) is different from those of other Prxs. E. coli Tpx (EcTpx) shows substrate specificity toward alkyl hydroperoxides over H2O2 and is the most potent reductant of alkyl hydroperoxides surpassing AhpC and BCP, the other E. coli Prx members. Here, we present the crystal structure of EcTpx in the oxidized state determined at 2.2-A resolution. The structure revealed that Tpxs are the second type of atypical 2-Cys Prxs with an intramolecular disulfide bond formed between the peroxidatic (CP, Cys61) and resolving (Cys95) cysteine residues. The extraordinarily long N-terminal chain of EcTpx folds into a beta-hairpin making the overall structure very compact. Modeling suggests that, in atypical 2-Cys Prxs, the CR-loop as well as the CP-loop may alternately assume the fully folded or locally unfolded conformation depending on redox states, as does the CP-loop in typical 2-Cys Prxs. EcTpx exists as a dimer stabilized by hydrogen bonds. Its substrate binding site extends to the dimer interface. A modeled structure of the reduced EcTpx in complex with 15-hydroperoxyeicosatetraenoic acid suggests that the size and shape of the binding site are particularly suited for long fatty acid hydroperoxides consistent with its greater reactivity.     

Distinct Characteristics of Two 2-Cys Peroxiredoxins of Vibrio vulnificus Suggesting Differential Roles in Detoxifying Oxidative Stress

Peroxiredoxins (Prxs) are ubiquitous antioxidant enzymes reducing toxic peroxides. Two distinct 2-Cys Prxs, Prx1 and Prx2, were identified in Vibrio vulnificus, a facultative aerobic pathogen. Both Prxs have two conserved catalytic cysteines, C_P and C_R, but Prx2 is more homologous in amino acid sequences to eukaryotic Prx than to Prx1. Prx2 utilized thioredoxin A as a reductant, whereas Prx1 required AhpF. Prx2 contained GGIG and FL motifs similar to the motifs conserved in sensitive Prxs and exhibited sensitivity to overoxidation. MS analysis and C_P-SO₃H specific immunoblotting demonstrated overoxidation of C_P to C_P-SO₂H (or C_P-SO₃H) in vitro and in vivo, respectively. In contrast, Prx1 was robust and C_P was not overoxidized. Discrete expression of the Prxs implied that Prx2 is induced by trace amounts of H₂O₂ and thereby residential in cells grown aerobically. In contrast, Prx1 was occasionally expressed only in cells exposed to high levels of H₂O₂. A mutagenesis study indicated that lack of Prx2 accumulated sufficient H₂O₂ to induce Prx1. Kinetic properties indicated that Prx2 effectively scavenges low levels of peroxides because of its high affinity to H₂O₂, whereas Prx1 quickly degrades higher levels of peroxides because of its high turnover rate and more efficient reactivation. This study revealed that the two Prxs are differentially optimized for detoxifying distinct ranges of H₂O₂, and proposed that Prx2 is a residential scavenger of peroxides endogenously generated, whereas Prx1 is an occasional scavenger of peroxides exogenously encountered. Furthermore, genome sequence database search predicted widespread coexistence of the two Prxs among bacteria.     

Molecular Basis for the Resistance of Human Mitochondrial 2-Cys Peroxiredoxin 3 to Hyperoxidation

Peroxiredoxins (Prxs) detoxify peroxides and modulate H₂O₂-mediated cell signaling in normal and numerous pathophysiological contexts. The typical 2-Cys subclass of Prxs (human Prx1–4) utilizes a Cys sulfenic acid (Cys-SOH) intermediate and disulfide bond formation across two subunits during catalysis. During oxidative stress, however, the Cys-SOH moiety can react with H₂O₂ to form Cys sulfinic acid (Cys-SO₂H), resulting in inactivation. The propensity to hyperoxidize varies greatly among human Prxs. Mitochondrial Prx3 is the most resistant to inactivation, but the molecular basis for this property is unknown. A panel of chimeras and Cys variants of Prx2 and Prx3 were treated with H₂O₂ and analyzed by rapid chemical quench and time-resolved electrospray ionization-TOF mass spectrometry. The latter utilized an on-line rapid-mixing setup to collect data on the low seconds time scale. These approaches enabled the first direct observation of the Cys-SOH intermediate and a putative Cys sulfenamide (Cys-SN) for Prx2 and Prx3 during catalysis. The substitution of C-terminal residues in Prx3, residues adjacent to the resolving Cys residue, resulted in a Prx2-like protein with increased sensitivity to hyperoxidation and decreased ability to form the intermolecular disulfide bond between subunits. The corresponding Prx2 chimera became more resistant to hyperoxidation. Taken together, the results of this study support that the kinetics of the Cys-SOH intermediate is key to determine the probability of hyperoxidation or disulfide formation. Given the oxidizing environment of the mitochondrion, it makes sense that Prx3 would favor disulfide bond formation as a protection mechanism against hyperoxidation and inactivation.     

Novel Protective Mechanism against Irreversible Hyperoxidation of Peroxiredoxin: N��-TERMINAL ACETYLATION OF HUMAN PEROXIREDOXIN II*

Peroxiredoxins (Prxs) are a group of peroxidases containing a cysteine thiol at their catalytic site. During peroxidase catalysis, the catalytic cysteine, referred to as the peroxidatic cysteine (C_P), cycles between thiol (C_P-SH) and disulfide (–S–S–) states via a sulfenic (C_P-SOH) intermediate. Hyperoxidation of the C_P thiol to its sulfinic (C_P-SO₂H) derivative has been shown to be reversible, but its sulfonic (C_P-SO₃H) derivative is irreversible. Our comparative study of hyperoxidation and regeneration of Prx I and Prx II in HeLa cells revealed that Prx II is more susceptible than Prx I to hyperoxidation and that the majority of the hyperoxidized Prx II formation is reversible. However, the hyperoxidized Prx I showed much less reversibility because of the formation of its irreversible sulfonic derivative, as verified with C_P-SO₃H-specific antiserum. In an attempt to identify the multiple hyperoxidized spots of the Prx I on two-dimensional PAGE analysis, an N-acetylated Prx I was identified as part of the total Prx I using anti-acetylated Lys antibody. Using peptidyl-Asp metalloendopeptidase (EC 3.4.24.33) peptide fingerprints, we found that N^α-terminal acetylation (N^α-Ac) occurred exclusively on Prx II after demethionylation. N^α-Ac of Prx II blocks Prx II from irreversible hyperoxidation without altering its affinity for hydrogen peroxide. A comparative study of non-N^α-acetylated and N^α-terminal acetylated Prx II revealed that N^α-Ac of Prx II induces a significant shift in the circular dichroism spectrum and elevation of T_m from 59.6 to 70.9 °C. These findings suggest that the structural maintenance of Prx II by N^α-Ac may be responsible for preventing its hyperoxidation to form C_P-SO₃H.Peroxiredoxins (Prxs)⁴ are a family of peroxidases that possess a conserved cysteine residue at the catalytic site for the reduction of peroxide/peroxynitrite. Using thiol-based reducing equivalents, like thioredoxin, Prxs catalyze the reduction of hydrogen peroxide, alkylhydroperoxides, and peroxynitrite to water, corresponding alcohols, and nitrite, respectively (1–8). Based on the number and location of conserved cysteine residue(s) directly involved in peroxide reduction, the six isotypes of mammalian Prx can be grouped into three distinct subgroups as follows: 2-Cys Prx, atypical 2-Cys Prx, and 1-Cys Prx, (1–2, 5). Human Prx I (hPrx I) and Prx II (hPrx II) are members of the 2-Cys Prx subgroup and thus contain two conserved cysteine residues that are directly involved in peroxidase activity. Cys⁵² for hPrx I and Cys⁵¹ for hPrx II are designated the peroxidatic cysteines (C_P). These residues attack the O–O bond of the peroxide (ROOH) substrate to form the product (ROH) and the sulfenic derivative C_P-SOH. This sulfenic derivative then forms a disulfide bond with the other conserved cysteine residue, which is referred to as the resolving cysteine (C_R; Cys¹⁷³ in hPrx I and Cys¹⁷² in hPrx II). In the case of 2-Cys Prxs, the disulfide partners, C_P and C_R, reside within different subunits; therefore, the disulfide bond established between C_P and C_R (C_P-S–S-C_R) is intermolecular. The reduced thioredoxin molecule is responsible for reducing the C_P-S–S-C_R disulfide bond to generate sulfhydryls (1–3, 5, 9).The C_P of eukaryotic 2-Cys Prxs is vulnerable to hyperoxidation, which results in the loss of its peroxidase activity. This feature is referred to as the “floodgate” mechanism, by which Prxs function as a redox sensor for the regulation of cell signaling (10–11). Hyperoxidation of C_P does not occur when the disulfide bond (C_P-S–S-C_R) is formed. However, the thiol (C_P-SH) can be hyperoxidized via the sulfenic (C_P-SOH) derivative intermediate in the absence of C_P-S-S-C_R formation during catalysis (12). Two different hyperoxidation products of C_P, the reversible sulfinic (C_P-SO₂H) derivative and the irreversible sulfonic (C_P-SO₃H) derivative, have been identified. The irreversible C_P-SO₃H was reported in Tsa1p, a yeast 2-Cys Prx, based on in vivo and in vitro regeneration assay results, and a stronger reactivity to an anti-Tsa1p-SO₃H antibody, which exhibits high specificity toward Tsa1p-C_P-SO₃H relative to Tsa1p-C_P-SO₂H (13). Both forms of hyperoxidized Prxs, C_P-SO₂H and C_P-SO₃H, are superimposed on the acidic migrated spot instead of the Prx-SH spot on a two-dimensional polyacrylamide gel because of the introduction of one negative charge by hyperoxidation (12–16). The protein sulfinic acid reductase, sulfiredoxin, is responsible for reversing 2-Cys Prx-SO₂H to Prx-SH in the presence of ATP and thiol-reducing equivalents like thioredoxin or glutathione (17–24). Until now, an intracellular enzymatic regeneration system for Prx-SO₃H has not been reported.Because mammalian Prx I and Prx II have been studied independently in a number of different organisms and cultured cells, the comparative biochemical data supporting their distinctive functional identities is still very limited. Recombinant Prx I (rPrx I) showed a 2.6-fold higher specific activity as a peroxidase than the recombinant Prx II (rPrx II) without any obvious catalytic or mechanistic differences (25, 26). Recent competition kinetics studies of hPrx II revealed a rate constant of 1.3 × 10⁷ m^–1 s^–1, which is fast enough to favor an intracellular hydrogen peroxide target even in competition with catalase or glutathione peroxidase (27, 28). The kinetic parameters of the competition assay for hPrx I are still not available. Mammalian Prx I interacts with and regulates a broad spectrum of proteins, such as the Src homology domain 3 of c-Abl (29), the Myc box II (MBII) domain of c-Myc (30), the macrophage migration inhibitory factor (MIF, 31), the androgen receptor (32), and the apoptosis signal-regulating kinase-1 (ASK-1) (33). The suggested roles of Prx I in interactions with these molecules are those of a tumor repressor, a survival enhancer, and a growth regulator. Although these suggested functions are controversial (34), all of them can be attributed to the peroxide-scavenging capacity of Prx I (at least in part), except for the enhancement of androgen receptor transactivation (32). Prx II interacts with platelet-derived growth factor receptor and functions as a negative regulator for platelet-derived growth factor signaling (35). Prx II also binds to phospholipase D1 (PLD1) and functions as a hydrogen peroxide-stimulated PLD1 signal terminator (36). Both of these suggested Prx II roles are attributable to the peroxidase activity of Prx II. The major phenotypes of Prx I knock-out mice involve the development of a variety of age-related cancers, hemolytic anemia (37), and dramatic shifts in subcellular reactive oxygen species localization (38). Prx II knock-out mice exhibit splenomegaly and a lack of tumor development in any cell type or tissue (39). Until now, the protein molecule that interacts with Prx I and Prx II has not been characterized, and there is no indication of a heterodimer between Prx I and Prx II. Despite their similar peroxide-scavenging capacities, it is reasonable to conclude that the Prx I and Prx II are unable to compensate for each other in terms of physiological roles. There are several examples of tissue- or cell type-specific expression patterns, such as exclusive Prx I expression in astrocytes and Leydig cells and Prx II expression in neurons and Sertoli cells (40, 41); however, Prx I and Prx II are coexpressed in the majority of mammalian cells and tissues, suggesting distinguished biochemical characteristics of their cellular regulatory mechanisms. Recently, the unique presence of Cys⁸³ in hPrx I, which contributes to the stability of the dimer-dimer interface and suppresses local unfolding, has been claimed to be prone to overoxidation of Prx I (42). The contribution of the dimer-decamer interconversion to the regulation of Prx I activity has also been reported (43).In this study, we confirmed that hPrx II was more susceptible to hyperoxidation as well as more prone to regeneration than hPrx I in HeLa cells. We also found that the difficulty in regenerating hPrx I was caused by irreversible sulfonic (C_P-SO₃H) hyperoxidation. Using AspN (EC 3.4.24.33) peptide fingerprints, we identified the N^α-terminal acetylation exclusively on hPrx II. In addition, we provide evidence for the structural maintenance offered by N^α-terminal acetylation of hPrx II, which possibly contributes to preventing irreversible overoxidation of C_P-SO₃H.     

Structure,mechanism and regulation of peroxiredoxins

Peroxiredoxins (Prxs) are a ubiquitous family of antioxidant enzymes that also control cytokine-induced peroxide levels which mediate signal transduction in mammalian cells. Prxs can be regulated by changes to phosphorylation, redox and possibly oligomerization states. Prxs are divided into three classes: typical 2-Cys Prxs; atypical 2-Cys Prxs; and 1-Cys Prxs. All Prxs share the same basic catalytic mechanism, in which an active-site cysteine (the peroxidatic cysteine) is oxidized to a sulfenic acid by the peroxide substrate. The recycling of the sulfenic acid back to a thiol is what distinguishes the three enzyme classes. Using crystal structures, a detailed catalytic cycle has been derived for typical 2-Cys Prxs, including a model for the redox-regulated oligomeric state proposed to control enzyme activity.     

Crystal structure of reduced and of oxidized peroxiredoxin IV enzyme reveals a stable oxidized decamer and a non-disulfide-bonded intermediate in the catalytic cycle

Peroxiredoxin IV (PrxIV) is an endoplasmic reticulum-localized enzyme that metabolizes the hydrogen peroxide produced by endoplasmic reticulum oxidase 1 (Ero1). It has been shown to play a role in de novo disulfide formation, oxidizing members of the protein disulfide isomerase family of enzymes, and is a member of the typical 2-Cys peroxiredoxin family. We have determined the crystal structure of both reduced and disulfide-bonded, as well as a resolving cysteine mutant of human PrxIV. We show that PrxIV has a similar structure to other typical 2-Cys peroxiredoxins and undergoes a conformational change from a fully folded to a locally unfolded form following the formation of a disulfide between the peroxidatic and resolving cysteine residues. Unlike other mammalian typical 2-Cys peroxiredoxins, we show that human PrxIV forms a stable decameric structure even in its disulfide-bonded state. In addition, the structure of a resolving cysteine mutant reveals an intermediate in the reaction cycle that adopts the locally unfolded conformation. Interestingly the peroxidatic cysteine in the crystal structure is sulfenylated rather than sulfinylated or sulfonylated. In addition, the peroxidatic cysteine in the resolving cysteine mutant is resistant to hyper-oxidation following incubation with high concentrations of hydrogen peroxide. These results highlight some unique properties of PrxIV and suggest that the equilibrium between the fully folded and locally unfolded forms favors the locally unfolded conformation upon sulfenylation of the peroxidatic cysteine residue.     

Structural properties of the peroxiredoxin AhpC2 from the hyperthermophilic eubacterium Aquifex aeolicus

Peroxiredoxins (Prxs) are thiol peroxidases that scavenge various peroxide substrates such as hydrogen peroxide (H₂O₂), alkyl hydroperoxides and peroxinitrite. They also function as chaperones and are involved in signal transduction by H₂O₂ in eukaryotic cells. The genome of Aquifex aeolicus, a microaerophilic, hyperthermophilic eubacterium, encodes four Prxs, among them an alkyl hydroperoxide reductase AhpC2 which was found to be closely related to archaeal 1-Cys peroxiredoxins. We determined the crystal structure of AhpC2 at 1.8?Å resolution and investigated its oligomeric state in solution by electron microscopy. AhpC2 is arranged as a toroid-shaped dodecamer instead of the typically observed decamer. The basic folding topology and the active site structure are conserved and possess a high structural similarity to other 1-Cys Prxs. However, the C-terminal region adopts an opposite orientation. AhpC2 contains three cysteines, Cys⁴⁹, Cys²¹², and Cys²¹⁸. The peroxidatic cysteine C_P⁴⁹ was found to be hyperoxidized to the sulfonic acid (SO₃H) form, while Cys²¹² forms an intra-monomer disulfide bond with Cys²¹⁸. Mutagenesis experiments indicate that Cys²¹² and Cys²¹⁸ play important roles in the oligomerization of AhpC2. Based on these structural characteristics, we proposed the catalytic mechanism of AhpC2. This study provides novel insights into the structure and reaction mechanism of 1-Cys peroxiredoxins.     

Overoxidation of 2-Cys Peroxiredoxin in Prokaryotes: CYANOBACTERIAL 2-CYS PEROXIREDOXINS SENSITIVE TO OXIDATIVE STRESS*?

In eukaryotic organisms, hydrogen peroxide has a dual effect; it is potentially toxic for the cell but also has an important signaling activity. According to the previously proposed floodgate hypothesis, the signaling activity of hydrogen peroxide in eukaryotes requires a transient increase in its concentration, which is due to the inactivation by overoxidation of 2-Cys peroxiredoxin (2-Cys Prx). Sensitivity to overoxidation depends on the structural GGLG and YF motifs present in eukaryotic 2-Cys Prxs and is believed to be absent from prokaryotic enzymes, thus representing a paradoxical gain of function exclusive to eukaryotic organisms. Here we show that 2-Cys Prxs from several prokaryotic organisms, including cyanobacteria, contain the GG(L/V/I)G and YF motifs characteristic of sensitive enzymes. In search of the existence of overoxidation-sensitive 2-Cys Prxs in prokaryotes, we have analyzed the sensitivity to overoxidation of 2-Cys Prxs from two cyanobacterial strains, Anabaena sp. PCC7120 and Synechocystis sp. PCC6803. In vitro analysis of wild type and mutant variants of the Anabaena 2-Cys Prx showed that this enzyme is overoxidized at the peroxidatic cysteine residue, thus constituting an exception among prokaryotes. Moreover, the 2-Cys Prx from Anabaena is readily and reversibly overoxidized in vivo in response to high light and hydrogen peroxide, showing higher sensitivity to overoxidation than the Synechocystis enzyme. These cyanobacterial strains have different strategies to cope with hydrogen peroxide. While Synechocystis has low content of less sensitive 2-Cys Prx and high catalase activity, Anabaena contains abundant and sensitive 2-Cys Prx, but low catalase activity, which is remarkably similar to the chloroplast system.     

Dimers to doughnuts: redox-sensitive oligomerization of 2-cysteine peroxiredoxins

2-Cys peroxiredoxins (Prxs) are a large and diverse family of peroxidases which, in addition to their antioxidant functions, regulate cell signaling pathways, apoptosis, and differentiation. These enzymes are obligate homodimers (alpha(2)), utilizing a unique intermolecular redox-active disulfide center for the reduction of peroxides, and are known to form two oligomeric states: individual alpha(2) dimers or doughnut-shaped (alpha(2))(5) decamers. Here we characterize both the oligomerization properties and crystal structure of a bacterial 2-Cys Prx, Salmonella typhimurium AhpC. Analytical ultracentrifugation and dynamic light scattering show that AhpC's oligomeric state is redox linked, with oxidization favoring the dimeric state. The 2.5 A resolution crystal structure (R = 18.5%, R(free) = 23.9%) of oxidized, decameric AhpC reveals a metastable oligomerization intermediate, allowing us to identify a loop that adopts distinct conformations associated with decameric and dimeric states, with disulfide bond formation favoring the latter. This molecular switch contains the peroxidatic cysteine and acts to buttress the oligomerization interface in the reduced, decameric enzyme. A structurally detailed catalytic cycle incorporating these ideas and linking activity to oligomeric state is presented. Finally, on the basis of sequence comparisons, we suggest that the enzymatic and signaling activities of all 2-Cys Prxs are regulated by a redox-sensitive dimer to decamer transition.     

A colorimetric assay for sulfiredoxin activity using inorganic phosphate measurement

2-Cys peroxiredoxin (Prx) is the major subgroup of a family of Prx enzymes that reduce peroxide molecules such as hydrogen peroxide (H₂O₂). 2-Cys Prxs are inactivated when their active site cysteine residue is hyperoxidized to sulfinic acid. Sulfiredoxin (Srx) is an enzyme that catalyzes reduction of hyperoxidized 2-Cys Prxs in the presence of ATP, Mg²⁺, and thiol equivalent. Therefore, Srx activity is crucial for cellular function of 2-Cys Prxs. The method currently available for the determination of Srx activity relies on immunoblot detection using antibodies to hyperoxidized enzymes. Here we introduce a simple quantitative assay for Srx activity based on the colorimetric determination of inorganic phosphate released in Srx-dependent reduction of hyperoxidized Prx using the malachite green. The colorimetric assay was used for high-throughput screening of 25,000 chemicals to find Srx inhibitors.     

Cloning and characterization of a 2-Cys peroxiredoxin from Pisum sativum

A cDNA sequence coding for a pea (Pisum sativum L.) 2-Cys peroxiredoxin (2-Cys Prx) has been cloned. The deduced amino acid sequence showed a high sequence homology to the 2-Cys Prx enzymes of Phaseolus vulgaris (86%), Arabidopsis thaliana (75%), and Spinacia oleracea (75%), and contained a chloroplast target sequence at its N-terminus. The mature enzyme, without the transit peptide, has a molecular mass of 22 kDa as well as two cysteine residues (Cys-53 and Cys-175) which are well conserved among proteins of this group. The protein was expressed in a heterologous system using the expression vector pET3d, and was purified to homogeneity by three sequential chromatographic steps. The enzyme exhibits peroxidase activity on hydrogen peroxide (H(2)O(2)) and t-butyl hydroperoxide (TBHP) with DTT as reducing agent. Although both pea Trxs f and m reduce oxidized 2-Cys Prx, Trx m is more efficient. The precise conditions for oligomerization of 2-Cys Prx through extensive gel filtration studies are also reported. The transition dimer-decamer produced in vitro between pH 7.5 and 8.0 and the influence of DTT suggest that a great change in the enzyme quaternary structure of 2-Cys Prx may take place in the chloroplast during the dark-light transition. In addition, the cyclophilin-dependent reduction of chloroplast 2-Cys Prx is shown.     

Molecular characterization and expression analysis of a peroxiredoxin 1 cDNA from Korean rose bitterling (Rhodeus uyekii)

Peroxiredoxins (Prxs), also known as natural killer cell enhancing factors in fish, role as antioxidant proteins and participate in a variety of biological processes, including H₂O₂-mediated cell signaling, molecular chaperoning, and mitochondrial function. In this study, we isolated and characterized a Prx 1 cDNA from the Korean rose bitterling Rhodeus uyekii, and designated it RuPrx 1. The RuPrx 1 cDNA encodes a 197-amino-acid polypeptide that belongs to the class of typical 2-Cys Prxs that contain peroxidatic and resolving cysteines. The deduced RuPrx 1 protein shows strong homology (77.38–92.89 %) with Prx 1 proteins from other species, including fish, amphibians, and mammals, and it is most closely related to rainbow smelt Prx 1. RuPrx 1 mRNA was ubiquitously detected in all tested tissues and its expression was comparatively high in the brain, intestine, kidney, liver, ovary, stomach, and testis. Expression of RuPrx 1 mRNA in liver peaked 3 h post-infection with Aeromonas hydrophila and decreased 24 h post-infection while the expression in intestine decreased 24 h post-infection. These results suggest that RuPrx 1 is conserved through evolution and may play roles similar to its mammalian counterparts.     

Characterization of the yeast peroxiredoxin Ahp1 in its reduced active and overoxidized inactive forms using NMR

Peroxiredoxins (Prx's) are a superfamily of thiol-specific antioxidant proteins present in all organisms and involved in the hydroperoxide detoxification of the cell. The catalytic cysteine of Prx's reduces hydroperoxides and is transformed into a transient sulfenic acid (Cys-SOH). At high hydroperoxide concentration, the sulfenic acid can be overoxidized into a sulfinate, or even a sulfonate. We present here the first peroxiredoxin characterization by solution NMR of the Saccharomyces cerevisiae alkylhydroperoxide reductase (Ahp1) in its reduced and in vitro overoxidized forms. NMR (15)N relaxation data and ultracentrifugation experiments indicate that the protein behaves principally as a homodimer (2 x 19 kDa) in solution, regardless of the redox state. In vitro treatment of Ahp1 by a large excess of tBuOOH leads to an inactive form, with the catalytic cysteine overoxidized into sulfonate, as demonstrated by (13)C NMR. Depending on the amino acid sequence of their active site, Prx's are classified into five different families. In this classification, Ahp1 is a member of the scarcely studied D-type Prx's. Ahp1 is unique among the D-type Prx's in its ability to form an intermolecular disulfide. The peptidic sequence of Ahp1 was analyzed and compared to other D-type Prx sequences.     

Glutathionylation induces the dissociation of 1-Cys D-peroxiredoxin non-covalent homodimer

1-Cys peroxiredoxins (1-Cys Prxs) are antioxidant enzymes that catalyze the reduction of hydroperoxides into alcohols using a strictly conserved cysteine. 1-Cys B-Prxs, homologous to human PrxVI, were recently shown to be reactivated by glutathione S-transferase (GST) pi via the formation of a GST-Prx heterodimer and Prx glutathionylation. In contrast, 1-Cys D-Prxs, homologous to human PrxV, are reactivated by the glutaredoxin-glutathione system through an unknown mechanism. To investigate the mechanistic events that mediate the 1-Cys D-Prx regeneration, interaction of the Prx with glutathione was studied by mass spectrometry and NMR. This work reveals that the Prx can be glutathionylated on its active site cysteine. Evidences are reported that the glutathionylation of 1-Cys D-Prx induces the dissociation of the Prx non-covalent homodimer, which can be recovered by reduction with dithiothreitol. This work demonstrates for the first time the existence of a redox-dependent dimer-monomer switch in the Prx family, similar to the decamer-dimer switch for the 2-Cys Prxs.     

Interaction of adenanthin with glutathione and thiol enzymes: Selectivity for thioredoxin reductase and inhibition of peroxiredoxin recycling

The diterpenoid, adenanthin, represses tumor growth and prolongs survival in mouse promyelocytic leukemia models (Liu et al., Nat. Chem. Biol. 8, 486, 2012). It was proposed that this was done by inactivating peroxiredoxins (Prxs) 1 and 2 through the formation of an adduct specifically on the resolving Cys residue. We confirmed that adenanthin underwent Michael addition to isolated Prx2, thereby inhibiting oxidation to a disulfide-linked dimer. However, contrary to the original report, both the peroxidatic and the resolving Cys residues could be derivatized. Glutathione also formed an adenanthin adduct, reacting with a second-order rate constant of 25±5 M^–1 s^–1. With 50 µM adenanthin, the peroxidatic and resolving Cys of Prx2 reacted with half-times of 7 and 40 min, respectively, compared with 10 min for GSH. When erythrocytes or Jurkat T cells were treated with adenanthin, we saw no evidence for a reaction with Prxs 1 or 2. Instead, adenanthin caused time- and concentration-dependent loss of GSH followed by dimerization of the Prxs. Prxs undergo continuous oxidation in cells and are normally recycled by thioredoxin reductase and thioredoxin. Our results indicate that Prx reduction was inhibited. We observed rapid inhibition of purified thioredoxin reductase (half-time 5 min with 2 µM adenanthin) and in cells, thioredoxin reductase was much more sensitive than GSH and loss of both preceded accumulation of oxidized Prxs. Thus, adenanthin is not a specific Prx inhibitor, and its reported antitumor and anti-inflammatory effects are more likely to involve more general inhibition of thioredoxin and/or glutathione redox pathways.     

Structural and functional regulation of eukaryotic 2-Cys peroxiredoxins including the plant ones in cellular defense-signaling mechanisms against oxidative stress

The ubiquitously distributed peroxiredoxins (Prxs) have been shown to have diverse functions in cellular defense‐signaling pathways. They have been largely classified into three Prx classes, 2‐Cys Prx, atypical 2‐Cys Prx and 1‐Cys Prx, which can be distinguished by how many Cys residues they possess and by their catalytic mechanisms. Proteins belonging to the typical 2‐Cys Prx group containing the N‐terminal peroxidatic Cys residue undergo a cycle of peroxide‐dependent oxidation to sulfenic acid and thiol‐dependent reduction during H₂O₂ catalysis. However, in the presence of high concentrations of H₂O₂ and catalytic components, including thioredoxin (Trx), Trx reductase and NADPH, the sulfenic acid can be hyperoxidized to cysteine sulfinic acid. The overoxidized 2‐Cys Prxs are slowly reduced by the action of the adenosine 5′‐triphosphate‐dependent enzyme, sulfiredoxin. Upon exposure of cells to strong oxidative or heat‐shock stress conditions, 2‐Cys Prxs change their protein structures from low‐molecular weight to high‐molecular weight complexes, which trigger their functional switching from peroxidases to molecular chaperones. The C‐terminal region of 2‐Cys Prx also plays an essential role in this structural conversion. Thus, proteins with truncated C‐termini are resistant to overoxidation and cannot regulate their structures or functions. These reactions are primarily guided by the active site peroxidatic Cys residue, which serves as an ‘H₂O₂‐sensor’ in cells. The reversible structural and functional switching of 2‐Cys Prxs provides cells with a means to adapt to external stresses by presumably activating intracellular defense‐signaling systems. In particular, plant 2‐Cys Prxs localized in chloroplasts have dynamic protein structures that undergo major conformational changes during catalysis, forming super‐complexes and reversibly attaching to thylakoid membranes in a redox‐dependent manner.