Molecular cloning of rabbit hyaluronic acid synthases and their expression patterns in synovial membrane and articular cartilage

Interaction of camel lens zeta-crystallin with the hydrophobic probe 1-anilinonaphthalene-8-sulfonic acid (ANS) enhanced the ANS fluorescence and quenched the protein fluorescence. Both of these events were concentration-dependent and showed typical saturation curves suggesting specific ANS-zeta-crystallin binding. Quantitative analysis indicated that 1 mole zeta-crystallin bound at most 1 mole ANS. NADPH but not 9,10-phenanthrenequinone (PQ) was able to displace zeta-crystallin-bound ANS. These results suggested the presence of a hydrophobic domain in zeta-crystallin, possibly at the NADPH binding site. alpha-Crystallin as well as NADPH protected zeta-crystallin against thermal inactivation suggesting the importance of this site for enzyme stability. The NADPH:quinone oxidoreductase activity of zeta-crystallin was inhibited by ANS with NADPH as electron donor and PQ as electron acceptor. Lineweaver-Burk plots indicated mixed-type inhibition with respect to NADPH, with a K(i) of 2.3 microM. Secondary plots of inhibition with respect to NADPH indicated a dissociation constant (K'I) of 12 microM for the zeta-crystallin-NADPH-ANS complex. The K(i) being smaller than K'I suggested that competitive inhibition at the NADPH binding site was predominant over non-competitive inhibition. Like ANS-zeta-crystallin binding, inhibition was dependent on ANS concentration but independent of incubation time.     

Identification and characterization of the enzymatic activity of zeta-crystallin from guinea pig lens. A novel NADPH:quinone oxidoreductase.

zeta-Crystallin is a major protein in the lens of certain mammals. In guinea pigs it comprises 10% of the total lens protein, and it has been shown that a mutation in the zeta-crystallin gene is associated with autosomal dominant congenital cataract. As with several other lens crystallins of limited phylogenetic distribution, zeta-crystallin has been characterized as an "enzyme/crystallin" based on its ability to reduce catalytically the electron acceptor 2,6-dichlorophenolindophenol. We report here that certain naturally occurring quinones are good substrates for the enzymatic activity of zeta-crystallin. Among the various quinones tested, the orthoquinones 1,2-naphthoquinone and 9,10-phenanthrenequinone were the best substrates whereas menadione, ubiquinone, 9,10-anthraquinone, vitamins K1 and K2 were inactive as substrates. This quinone reductase activity was NADPH specific and exhibited typical Michaelis-Menten kinetics. Activity was sensitive to heat and sulfhydryl reagents but was very stable on freezing. Dicumarol (Ki = 1.3 x 10(-5) M) and nitrofurantoin (Ki = 1.4 x 10(-5) M) inhibited the activity competitively with respect to the electron acceptor, quinone. NADPH protected the enzyme against inactivation caused by heat, N-ethylmaleimide, or H2O2. Electron paramagnetic resonance spectroscopy of the reaction products showed formation of a semiquinone radical. The enzyme activity was associated with O2 consumption, generation of O2- and H2O2, and reduction of ferricytochrome c. These properties indicate that the enzyme acts through a one-electron transfer process. The substrate specificity, reaction characteristics, and physicochemical properties of zeta-crystallin demonstrate that it is an active NADPH:quinone oxidoreductase distinct from quinone reductases described previously.     

Expression of recombinant zeta-crystallin in Escherichia coli with the help of GroEL/ES and its purification

zeta-Crystallin is a taxon-specific crystallin found in the eye lens of guinea pig and other hystricomorph rodents and camelids. It is an NADPH:quinone oxidoreductase and is also present in low amounts in other tissues where it might act as a detoxifying enzyme. A lens-specific promoter confers lens-specific expression of the gene in high amounts where it is speculated to play a structural role in maintaining the transparency of the lens ensemble. A deletion mutation leads to autosomal dominant congenital cataract and also results in the loss of NADPH binding. In order to perform structural studies with the protein with an aim to delineate the cause of cataract in these mutant guinea pigs, recombinant zeta-crystallin was cloned and expressed in Escherichia coli. The overexpression of the protein in E. coli resulted in a major fraction of it partitioning into inclusion bodies. The co-overexpression of the bacterial chaperone system GroEL/ES along with zeta-crystallin could significantly enhance the yield of soluble protein. Active zeta-crystallin could then be purified from the E. coli using Mono Q anion exchange FPLC and was found to be identical to the native zeta-crystallin isolated from the guinea pig lens with respect to size, spectral properties, and activity.     

Purification and characterization of zeta-crystallin/quinone reductase from guinea pig liver.

zeta-Crystallin, a major lens protein of certain mammalian species, has recently been characterized as a novel and active NADPH:quinone oxidoreductase. Here we report the purification of this protein from guinea pig liver by utilizing sequentially: ammonium sulphate precipitation, Blue Sepharose affinity, cation exchange and hydrophobic chromatography steps. This four-step isolation procedure yielded 118-fold purification and a specific activity of 6 U/mg protein when assayed in the presence of 9,10-phenanthrenequinone. Kinetic, immunological and physical properties of this protein have been found to be identical with those of guinea pig lens zeta-crystallin. Western blot analysis using antibodies raised against zeta-crystallin peptides demonstrated the presence of substantial amounts of this protein in human liver homogenates.     

Quinone induced stimulation of hexose monophosphate shunt activity in the guinea pig lens: role of zeta-crystallin.

The response of the hexose monophosphate shunt (HMS) in organ-cultured guinea pig lens to 1,2-naphthoquinone and 5-hydroxy-1,4-naphthoquinone (juglone) has been investigated. Both these compounds, which are substrates of guinea pig lens zeta-crystallin (NADPH:quinone oxidoreductase), were found to cause increases in the rate of 14CO2 production from 1-14C-labelled glucose. Exposure of lenses to 15 microM 1,2-naphthoquinone or 20 microM juglone yielded 5.9- and 7-fold stimulation of HMS activity, respectively. Unlike hydrogen peroxide-induced stimulation of HMS activity, these effects were not abolished by preincubation with the glutathione reductase inhibitor, 1,3-bis(2-chloroethyl)-1 nitrosourea (BCNU). While hydrogen peroxide produced substantial decrements in lens glutathione (GSH) levels, incubation with quinones was not associated with a similar reduction in GSH concentration. Protein-bound NADPH content in quinone-exposed guinea pig lenses was decreased, with a concomitant increase in the amounts of free NADP+. This finding supported the involvement of zeta-crystallin bound NADPH in the in vivo enzymic reduction of quinones. Hydrogen peroxide, on the other hand, caused decreases in the level of free NADPH alone, serving to confirm our earlier inference that quinone stimulated increases in the guinea pig lens HMS could be mediated through zeta-crystallin NADPH:quinone oxidoreductase activity.     

Taxon-specific zeta -crystallin in Japanese tree frog (Hyla japonica) lens

The present study demonstrated that the 38-kDa protein, instead of rho-crystallin (36 kDa), is expressed taxon specifically in the lens of Japanese tree frog (Hyla japonica). The 38-kDa protein was distinguished from rho-crystallin expressed in the lenses of bullfrog (Rana catesbeiana) and European common frog (Rana temporaria) immunochemically. Although the N terminus of the 38-kDa protein was blocked, the analyses of partial amino acid sequences showed that the protein was zeta-crystallin. Analysis of cDNA sequence encoding zeta-crystallin of the tree frog lens demonstrated that the deduced protein consisted of 329 amino acids including initial methionine and having 62.2 and 62.9% identity with zeta-crystallin of camel and guinea pig lenses, respectively. The molecular mass of the deduced structure was calculated to be 35,564 Da. zeta-Crystallin of the tree frog lens exhibited the intrinsic enzymatic activity of quinone reductase (EC, NADPH:quinone oxidoreductase). The crystallin specifically catalyzed the reduction of 9,10-phenanthrenequinone (Km, 42 microm) using NADPH (Km, 60 microm) as a cofactor. The enzymatic activity was inhibited by dicumarol, anti-coagulant drug, with IC50 of 4 microm. On gel filtration chromatography, the crystallin was recovered as 150-kDa molecular mass complex, indicating that the crystallin was homotetramer consisting of 38-kDa subunits. The crystallin gene was expressed specifically in the lens. These results show that taxon-specific crystallins such as zeta- and rho-crystallins may be available for the biochemical discrimination of Hyla- and Rana groups among frogs.     

Interaction of camel lens zeta-crystallin with quinones: portrait of a substrate by fluorescence spectroscopy.

Interaction of camel lens zeta-crystallin, an NADPH:quinone oxidoreductase, with several quinone derivatives was examined by fluorescence spectroscopy and activity measurements. Fluorescence of zeta-crystallin was quenched to different levels by the different quinones:juglone (5-OH, 1,4 naphthoquinone), 1,4 naphthoquinone (1,4-NQ), and 1,2 naphthoquinone (1,2-NQ) considerably quenched the fluorescence of zeta-crystallin, where as the commonly used substrate, 9,10-phenanthrenequinone (PQ) did not induce significant quenching. Activity measurements showed only PQ served as a substrate for camel lens zeta-crystallin, while juglone, 1,4-NQ, and 1,2-NQ were inhibitors. Thus quinones that interacted with zeta-crystallin directly inhibited the enzyme, whereas the substrate had very low affinity for the enzyme in the absence of NADPH. Another substrate, dichlorophenol indophenol (DCIP), conformed to the same pattern; DCIP did not quench the fluorescence of the enzyme significantly, but served as a substrate. This pattern is consistent with an ordered mechanism of catalysis with quinone being the second substrate. All three naphthoquinones were uncompetitive inhibitors with respect to NADPH and noncompetitive with respect to PQ. These kinetics are similar to those exhibited by cysteine- and/or lysine-modifying agents. Juglone, 1,4-NQ, and 1,2-NQ interacted with and quenched the fluorescence of camel lens alpha-crystallin, but to lesser extent than that of zeta-crystallin.     

High-affinity binding of NADPH to camel lens zeta-crystallin

Fluorescence spectrum of camel lens zeta-crystallin, a major protein in the lens of camelids and histicomorph rodents, showed maximum emission at 315 nm. This emission maximum is blue shifted compared to most proteins, including alpha-crystallin, and appeared to be due to tryptophan in highly hydrophobic environment. Interaction of NADPH with zeta-crystallin quenched the protein fluorescence and enhanced the fluorescence of bound NADPH. Analysis of fluorescence quenching suggested high-affinity interaction between NADPH and zeta-crystallin with an apparent Km<0.45 microM. This value is at least an order of magnitude lower than that suggested by activity measurements. Analysis of NADPH fluorescence showed a biphasic curve representing fluorescence of free- and bound-NADPH. The intersection between free- and bound-NADPH closely paralleled the enzyme concentration, suggesting one mole of NADPH was bound per subunit of the enzyme. Phenanthrenequinone (PQ), the substrate of zeta-crystallin, also was able to quench the fluorescence of zeta-crystallin, albeit weaker than NADPH. Quantitative analysis suggested that zeta-crystallin had low affinity for PQ in the absence of NADPH, and PQ binding induced significant conformational changes in zeta-crystallin.     

Purification and Characterization of a 1,4-Benzoquinone Reductase from the Basidiomycete Phanerochaete chrysosporium

An intracellular, soluble 1,4-benzoquinone reductase was purified from agitated cultures of Phanerochaete chrysosporium and characterized. The quinone reductase was expressed in cultures grown under both nitrogen-sufficient and nitrogen-limiting (12 and 1.2 mM ammonium tartrate) conditions. The protein was purified to homogeneity by using ammonium sulfate fractionation, hydrophobic interaction, and ion-exchange and blue-agarose affinity chromatographies. The native flavin mononucleotide-containing protein, pI 4.3, has a molecular mass of 44 kDa as determined by gel filtration. The protein has a subunit molecular mass of ^sim22 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The quinone reductase exhibits a broad pH optimum between 5.0 and 6.5 and a temperature optimum of 30(deg)C. The enzyme catalyzes the two-electron reduction of several quinones and other electron acceptors utilizing either NADH or NADPH as an electron donor. The apparent K(infm) for 2-methoxy-1,4-benzoquinone is 2.4 (mu)M, and the apparent k(infcat) is 4.4 x 10(sup5) s(sup-1). Enzyme activity is strongly inhibited by Cibacron blue 3GA and by dicumarol.     

Pyridine nucleotide specificity of barley nitrate reductase

NADPH nitrate reductase activity in higher plants has been attributed to the presence of NAD(P)H bispecific nitrate reductases and to the presence of phosphatases capable of hydrolyzing NADPH to NADH. To determine which of these conditions exist in barley (Hordeum vulgare L. cv. Steptoe), we characterized the NADH and NADPH nitrate reductase activities in crude and affinity-chromatography-purified enzyme preparations. The pH optima were 7.5 for NADH and 6 to 6.5 for the NADPH nitrate reductase activities. The ratio of NADPH to NADH nitrate reductase activities was much greater in crude extracts than it was in a purified enzyme preparation. However, this difference was eliminated when the NADPH assays were conducted in the presence of lactate dehydrogenase and pyruvate to eliminate NADH competitively. The addition of lactate dehydrogenase and pyruvate to NADPH nitrate reductase assay media eliminated 80 to 95% of the NADPH nitrate reductase activity in crude extracts. These results suggest that a substantial portion of the NADPH nitrate reductase activity in barley crude extracts results from enzyme(s) capable of converting NADPH to NADH. This conversion may be due to a phosphatase, since phosphate and fluoride inhibited NADPH nitrate reductase activity to a greater extent than the NADH activity. The NADPH activity of the purified nitrate reductase appears to be an inherent property of the barley enzyme, because it was not affected by lactate dehydrogenase and pyruvate. Furthermore, inorganic phosphate did not accumulate in the assay media, indicating that NADPH was not converted to NADH. The wild type barley nitrate reductase is a NADH-specific enzyme with a slight capacity to use NADPH.     

FQR1, a novel primary auxin-response gene, encodes a flavin mononucleotide-binding quinone reductase

FQR1 is a novel primary auxin-response gene that codes for a flavin mononucleotide-binding flavodoxin-like quinone reductase. Accumulation of FQR1 mRNA begins within 10 min of indole-3-acetic acid application and reaches a maximum of approximately 10-fold induction 30 min after treatment. This increase in FQR1 mRNA abundance is not diminished by the protein synthesis inhibitor cycloheximide, demonstrating that FQR1 is a primary auxin-response gene. Sequence analysis reveals that FQR1 belongs to a family of flavin mononucleotide-binding quinone reductases. Partially purified His-tagged FQR1 isolated from Escherichia coli catalyzes the transfer of electrons from NADH and NADPH to several substrates and exhibits in vitro quinone reductase activity. Overexpression of FQR1 in plants leads to increased levels of FQR1 protein and quinone reductase activity, indicating that FQR1 functions as a quinone reductase in vivo. In mammalian systems, glutathione S-transferases and quinone reductases are classified as phase II detoxification enzymes. We hypothesize that the auxin-inducible glutathione S-transferases and quinone reductases found in plants also act as detoxification enzymes, possibly to protect against auxin-induced oxidative stress.     

Purification by cibacron blue F3GA dye affinity chromatography and comparison of NAD(P)H:quinone reductase (E.C.1.6.99.2) from rat liver cytosol and microsomes

The dicoumarol-sensitive NAD(P)H:quinone reductase (E.C.1.6.99.2), often referred to as DT-diaphorase, has been purified from both the cytosolic and microsomal fractions from rat liver using a novel, highly efficient, two-step purification procedure utilizing immobilized Cibacron Blue F3GA dye affinity chromatography as the principal step. Under the conditions reported here, this dye affinity resin, generally recognized as preferentially binding nucleotide-dependent proteins, was highly selective in the recovery of up to 95% of the NAD(P)H:quinone reductase directly from the cytosol as a preparation which was often greater than 90% pure. Further purification by gel exclusion chromatography resulted in pure protein preparations with final recoveries approaching 80%. Similar results were obtained during the purification of this quinone reductase activity from microsomal extracts. Evidence is presented which suggests that the enzyme isolated from each cellular fraction are highly homologous, if not identical; data are consistent with genetic evidence.     

Purification and characterization of an intracellular NADH: quinone reductase from Trametes versicolor

Intracellular NADH:quinone reductase involved in degradation of aromatic compounds including lignin was purified and characterized from white rot fungus Trametes versicolor. The activity of quinone reductase was maximal after 3 days of incubation in fungal culture, and the enzyme was purified to homogeneity using ion-exchange, hydrophobic interaction, and gel filtration chromatographies. The purified enzyme has a molecular mass of 41 kDa as determined by SDS-PAGE, and exhibits a broad temperature optimum between 20-40 degrees C , with a pH optimum of 6.0. The enzyme preferred FAD as a cofactor and NADH rather than NADPH as an electron donor. Among quinone compounds tested as substrate, menadione showed the highest enzyme activity followed by 1,4-benzoquinone. The enzyme activity was inhibited by CuSO(4), HgCl(2), MgSO(4), MnSO(4), AgNO(3), dicumarol, KCN, NaN(3), and EDTA. Its Km and Vmax with NADH as an electron donor were 23 microM and 101 mM/mg per min, respectively, and showed a high substrate affinity. Purified quinone reductase could reduce 1,4-benzoquinone to hydroquinone, and induction of this enzyme was higher by 1,4-benzoquinone than those of other quinone compounds.     

Zeta-crystallin catalyzes the reductive activation of 2,4,6-trinitrotoluene to generate reactive oxygen species: a proposed mechanism for the induction of cataracts

Exposure to 2,4,6-trinitrotoluene (TNT) has been shown to cause induction of cataract in which oxidative stress plays a critical role. From bovine lens we purified to homogeneity and identified an enzyme that catalyzes the reduction of TNT, resulting in the production of reactive oxygen species. The final preparation of TNT reductase showed a single band with a subunit molecular weight of 38 kDa on SDS-PAGE. Sequence data from peptides obtained by digestion with lysylendopeptidase Achromobacter protease I (API) revealed that TNT reductase is identical to zeta-crystallin. Superoxide anions were formed during reduction of TNT by zeta-crystallin, though negligible enzyme activity or protein content for superoxide dismutase, a superoxide scavenging enzyme, was found in the lens. Thus, the present results suggest that the induction of cataracts by TNT may be associated with increased oxidative stress, as a result of reductive activation of TNT generating superoxide anions, there being minimal antioxidant enzyme activity for defense against reactive oxygen species exogenously produced in the lens.     

Cytosolic components to activate neutrophilic NADPH oxidase in a cell-free system

A soluble protein containing very weak NADPH-dependent nitroblue tetrazolium reductase activity was partially purified from the cytosol of dormant human neutrophils by DEAE-5PW ion exchange chromatography. This preparation of cytosolic reductase exhibited three nitroblue tetrazolium-reducing bands with approximate molecular masses of 95, 45, and 40 kDa on non-denaturing gel electrophoresis in the presence of 35 mM n-octyl-glucoside, and two major bands with apparent masses of 45 and 40 kDa along with a few variable minor bands on SDS-polyacrylamide gel electrophoresis. The 45 kDa protein is susceptible to endogenous proteases and is rapidly converted to proteolysis products at 36 degrees C. The partially purified cytosolic protein(s) provided a concentration-dependent activation of NADPH oxidase in the cell-free system composed of the membrane, arachidonate and magnesium ion. In addition, polyclonal antibodies raised against rabbit hepatic NADPH:cytochrome P-450 reductase [EC 1.6.99.1] showed positive immunological reactivity toward cytosolic 45 kDa protein and also caused 30 to 40% inhibition of superoxide anion production in the cell-free system.     

Oxysterol binding protein

A binding protein is described for certain oxygenated derivatives of cholesterol which suppress 3-hydroxy-3-methylglutaryl coenzyme A reductase and cholesterol synthesis in cultured mammalian cells. This protein is found in the cytosolic fraction of many cell types and is distinct from cytosolic proteins which bind cholesterol. The relative binding affinity of a wide variety of oxysterols correlates with their ability to suppress reductase and it is proposed that the binding protein functions as a receptor for endogenous regulatory oxysterols. The binding protein from cultured mouse fibroblasts (L cells) has been partially purified and characterized. Changes in its molecular form occur when a ligand is bound and further changes in form and binding kinetics occur at acid pH and in the presence of urea. Based on these changes a subunit model for the binding protein is presented.     

zeta-Crystallin is a major protein in the lens of Camelus dromedarius

Camel (Camelus dromedarius) lenses contain a protein with an apparent subunit Mr 38,000 that constitutes approximately 8-13% of the total protein. The protein has been purified and has a native Mr 140,000 as determined by gel filtration. This is consistent with its being a tetramer. The protein reacts with antibodies raised against both guinea pig zeta-crystallin and peptides corresponding to amino acids 1-10 and 295-308, but not to antibodies raised against amino acids 320-328 of zeta-crystallin. Based on these criteria it is concluded that this protein, which is a major constituent of camel lens, is zeta-crystallin. This may be the first example of a protein (enzyme) being independently utilized as a crystallin in the lens of species from two mammalian orders.     

Redox enzymes in the plant plasma membrane and their possible roles

Purified plasma membrane (PM) vesicles from higher plants contain redox proteins with low‐molecular‐mass prosthetic groups such as flavins (both FMN and FAD), hemes, metals (Cu, Fe and Mn), thiol groups and possibly naphthoquinone (vitamin K₁), all of which are likely to participate in redox processes. A few enzymes have already been identified: Monodehydroascorbate reductase (EC 1.6.5.4) is firmly bound to the cytosolic surface of the PM where it might be involved in keeping both cytosolic and, together with a b‐type cytochrome, apoplastic ascorbate reduced. A malate dehydrogenase (EC 1.1.1.37) is localized on the inner side of the PM. Several NAD(P)H‐quinone oxidoreductases have been purified from the cytocolic surface of the PM, but their function is still unknown. Different forms of nitrate reductase (EC 1.6.6.1–3) are found attached to, as well as anchored in, the PM where they may act as a nitrate sensor and/or contribute to blue‐light perception, although both functions are speculative. Ferric‐chelate‐reducing enzymes (EC 1.6.99.13) are localized and partially characterized on the inner surface of the PM but they may participate only in the reduction of ferric‐chelates in the cytosol. Very recently a ferric‐chelate‐reducing enzyme containing binding sites for FAD, NADPH and hemes has been identified and suggested to be a trans‐PM protein. This enzyme is involved in the reduction of apoplastic iron prior to uptake of Fe²⁺ and is induced by iron deficiency. The presence of an NADPH oxidase, similar to the so‐called respiratory burst oxidase in mammals, is still an open question. An auxin‐stimulated and cyanide‐insensitive NADH oxidase (possibly a protein disulphide reductase) has been characterized but its identity is still awaiting independent confirmation. Finally, the only trans‐PM redox protein which has been partially purified from plant PM so far is a high‐potential and ascorbate‐reducible b‐type cytochrome. In co‐operation with vitamin K₁ and an NAD(P)H‐quinone oxidoreductase, it may participate in trans‐PM electron transport.     

Heterologous expression and biochemical characterization of an NAD(P)H:quinone oxidoreductase from the hemiparasitic plant Triphysaria versicolor

Quinones are widespread secondary metabolites that function as signal molecules between organisms in the rhizosphere. Quinones are particularly important in the exchange of chemical signals between plant roots, a phenomenon classically termed allelopathy. The bioactivity of quinones is due in large part to radical intermediates formed during redox cycling between quinone and hydroquinone states. In order to investigate the role of quinone oxidoreductases in processing quinone signals exchanged between plant roots, we characterized an NAD(P)H-dependent quinone reductase expressed in roots of the parasitic plant Triphysaria versicolor (TvQR2). The predicted amino acid sequence encoded by TvQR2 shares homology with quinone reductases from Archaea, Eubacteria and Eukaryota organisms. The complete TvQR2 cDNA was cloned into the fungus Pichia pastoris and the heterologous protein purified. The recombinant protein reduced a variety of quinones and napthoquinones, including several of allelopathic significance, using either NADH or NADPH as electron donors. The protein had an absorption spectrum consistent with it being a flavoprotein and was inhibited by the quinone reductase inhibitor dicumarol. We propose that the TvQR2 protein functions as a quinone reductase in plant roots to mitigate the toxicity of exogenous quinones in the rhizosphere.     

A novel NADPH:diamide oxidoreductase activity in arabidopsis thaliana P1 zeta-crystallin.

The zeta-crystallin (ZCr) gene P1 of Arabidopsis thaliana, known to confer tolerance toward the oxidizing drug 1,1'-azobis(N, N-dimethylformamide) (diamide) to yeast [Babiychuk, E., Kushnir, S., Belles-Boix, E., Van Montagu, M. & Inzé, D. (1995) J. Biol. Chem. 270, 26224], was expressed in Escherichia coli to characterize biochemical properties of the P1-zeta-crystallin (P1-ZCr). Recombinant P1-ZCr, a noncovalent dimer, showed NADPH:quinone oxidoreductase activity with specificity to quinones similar to that of guinea-pig ZCr. P1-ZCr also catalyzed the divalent reduction of diamide to 1,2-bis(N,N-dimethylcarbamoyl)hydrazine, with a kcat comparable with that for quinones. Two other azodicarbonyl compounds also served as substrates of P1-ZCr. Guinea-pig ZCr, however, did not catalyze the azodicarbonyl reduction. Hence, plant ZCr is distinct from mammalian ZCr, and can be referred to as NADPH:azodicarbonyl/quinone reductase. The quinone-reducing reaction was accompanied by radical chain reactions to produce superoxide radicals, while the azodicarbonyl-reducing reaction was not. Specificity to NADPH, as judged by kcat/Km, was > 1000-fold higher than that to NADH both for quinones and diamide. N-Ethylmaleimide and p-chloromercuribenzoic acid inhibited both quinone-reducing and diamide-reducing activities. Both NADPH and NADP+ suppressed the inhibition, but NADH did not, suggesting that sulfhydryl groups reside in the binding site for the phosphate group on the adenosine moiety of NADPH. The diamide-reducing activity of P1-ZCr accounts for the tolerance of P1-overexpressing yeast to diamide. Other possible physiological functions of P1-ZCr in plants are discussed.