Class Of Oxidoreductases Research Articles

Bioinformatic studies of the wheat glutaredoxin gene family and functional analysis of the ROXY1 orthologues.

CC-type glutaredoxins comprise a large land plant-specific class of oxidoreductases. Previous research shows roles for two such proteins in developmental processes in Arabidopsis; ROXY1 mediates petal initiation and morphogenesis, and ROXY1 and ROXY2 are required for normal anther development. In the present work, the broader glutaredoxin family was investigated in hexaploid wheat with bioinformatic methods, revealing a large and multifunctional gene family. With a PCR based method, three wheat ROXY homeoalleles were isolated. Complementation analyses show that these three isoforms fully complemented the roxy1 mutation in Arabidopsis. Further, yeast two-hybrid experiments demonstrate that one such wheat ROXY protein interacts strongly with TGA3, an Arabidopsis TGA transcription factor previously shown to associate with ROXY1. Deletion analyses show that TaROXY-α3 docks to a glutamine rich region of TGA3, a putative transcriptional activation domain. These results suggest a conserved molecular role of Arabidopsis and wheat ROXY proteins in inflorescence/spike development, most likely in the post-translational regulation of TGA proteins including HBP-1b (the wheat PERIANTHIA orthologue), which likely exerts also a developmental function by activating histone gene transcription in highly proliferating tissues such as the SAM and root tip.

1-Naphthol 2-hydroxylase from Pseudomonas sp. strain C6: purification, characterization and chemical modification studies

1-Naphthol 2-hydroxylase (1-NH) which catalyzes the conversion of 1-naphthol to 1,2-dihydroxynaphthalene was purified to homogeneity from carbaryl-degrading Pseudomonas sp. strain C6. The enzyme was found to be a homodimer with subunit molecular weight of 66 kDa. UV, visible and fluorescence spectral properties, identification of flavin moiety by HPLC as FAD, and reconstitution of apoenzyme by FAD suggest that enzyme is FAD-dependent. 1-NH accepts electron from NADH as well as NADPH. Besides 1-naphthol (K(m), 9.1 μM), the enzyme also accepts 5-amino 1-naphthol (K(m), 6.4 μM) and 4-chloro 1-naphthol (K(m), 2.3 μM) as substrates. Enzyme showed substrate inhibition phenomenon at high concentration of 1-naphthol (K(i), 283 μM). Stoichiometric consumption of oxygen and NADH, and biochemical properties suggest that 1-NH belongs to FAD containing external flavomonooxygenase group of oxido-reductase class of enzymes. Based on biochemical and kinetic properties, 1-NH from Pseudomonas sp. strain C6 appears to be different than that reported earlier from Pseudomonas sp. strain C4. Chemical modification and protection by 1-naphthol and NADH suggest that His, Arg, Cys, Tyr and Trp are at or near the active site of 1-NH.

A new family of enzymes catalyzing the first committed step of the methylerythritol 4-phosphate (MEP) pathway for isoprenoid biosynthesis in bacteria

Isoprenoids are a large family of compounds with essential functions in all domains of life. Most eubacteria synthesize their isoprenoids using the methylerythritol 4-phosphate (MEP) pathway, whereas a minority uses the unrelated mevalonate pathway and only a few have both. Interestingly, Brucella abortus and some other bacteria that only use the MEP pathway lack deoxyxylulose 5-phosphate (DXP) reductoisomerase (DXR), the enzyme catalyzing the NADPH-dependent production of MEP from DXP in the first committed step of the pathway. Fosmidomycin, a specific competitive inhibitor of DXR, inhibited growth of B. abortus cells expressing the Escherichia coli GlpT transporter (required for fosmidomycin uptake), confirming that a DXR-like (DRL) activity exists in these bacteria. The B. abortus DRL protein was found to belong to a family of uncharacterized proteins similar to homoserine dehydrogenase. Subsequent experiments confirmed that DRL and DXR catalyze the same biochemical reaction. DRL homologues shown to complement a DXR-deficient E. coli strain grouped within the same phylogenetic clade. The scattered taxonomic distribution of sequences from the DRL clade and the occurrence of several paralogues in some bacterial strains might be the result of lateral gene transfer and lineage-specific gene duplications and/or losses, similar to that described for typical mevalonate and MEP pathway genes. These results reveal the existence of a novel class of oxidoreductases catalyzing the conversion of DXP into MEP in prokaryotic cells, underscoring the biochemical and genetic plasticity achieved by bacteria to synthesize essential compounds such as isoprenoids.

A promiscuous dicopper(II) system promoting the hydrolysis of bis(2,4‐dinitrophenyl)phosphate: Gaining mechanistic insight by means of structural and spectroscopic DFT studies

AbstractCatechol oxidases (COs) are plant enzymes that belong to the oxidoreductases class. They contain a dinuclear copper center in their active site. In this article, we have investigated the dicopper(II) model complex [Cu2(μ‐OH)(C21H33ON6)]2+ (Complex‐A) under a computational perspective, using the DFT method, since this approach has been very useful in the treatment of bimetallic copper systems. The structural and spectroscopic study of Complex‐A as well as the structural analysis of the BDNPP/Complex‐A (Complex‐B) adduct have been carried out. The calculated parameters for Complex‐A are in good accordance with the experimental X‐ray data. Some remarkable points can be observed from the calculated UV–vis relative excitations. The Complex‐B computed structure verifies its identity as a key intermediate species in the BDNPP hydrolysis mechanism. The CuII···CuII calculated distance in Complex‐B (3.026 Å) is shorter than the calculated for Complex‐A (3.080 Å); one copper atom is bonded to the oxygen of phosphate [Cu (2)···O64–P] at 2.511 Å. These arguments clearly suggest a monodentate interaction and lead to a new mechanism involving terminal substrate coordination and subsequent intramolecular nucleophilic attack by a bridging hydroxide. Such a hypothesis is completely new in terms of homobimetallic copper systems, and may have important implications regarding the chemistry of several biological dinuclear catalytic sites. © 2009 Wiley Periodicals, Inc. Int J Quantum Chem, 2010

New Potential Biocatalysts by Laccase Immobilization in PVA Cryogel Type Carrier

Laccases are enzymes belonging to the Oxidoreductases class. These enzymes may be good biocatalysts for different processes, at laboratory and industrial levels. A successful use at industrial scale demands a higher stability of the enzyme. As an easy way to obtain longer life biocatalysts, the immobilization process is recommended. Thus, the paper presents different ways of obtaining new biocatalysts by a laccase covalent immobilization on a macroporous carrier based on poly(vinyl alcohol) cryogel. Different procedures of covalent immobilization are described, the newly obtained biocatalysts being characterized. According to the experimental data, the stability of the immobilized enzyme increased and the pH profile changed, compared with those of the free enzyme.

Characterization of a gene encoding alcohol dehydrogenase in benznidazole-susceptible and -resistant populations of Trypanosoma cruzi

Alcohol dehydrogenases (ADH) are a class of oxidoreductases that catalyse the reversible oxidation of ethanol to acetaldehyde. In the human parasite Trypanosoma cruzi the TcADH gene was identified through microarray analysis as having reduced transcription in an in vitro induced benznidazole (BZ)-resistant population. In the present study, we have extended these results by characterizing the TcADH gene from 11 strains of T. cruzi that were either susceptible or naturally resistant to benznidazole and nifurtimox or had in vivo selected or in vitro induced resistance to BZ. Sequence comparisons showed that TcADH was more similar to prokaryotic ADHs than to orthologs identified Leishmania spp. Immunolocalisation using confocal microscopy revealed that TcADH is present in the kinetoplast region and along the parasite body, consistent with the mitochondrial localization predicted by sequence analysis. Northern blots showed a 1.9 kb transcript with similar signal intensity in all T. cruzi samples analysed, except for the in vitro selected resistant population, where transcript levels were 2-fold lower. These findings were confirmed by quantitative real-time PCR. In Western blot analysis, anti-TcADH polyclonal antisera recognised a 42 kDa protein in all T. cruzi strains tested. The level of expression of this polypeptide was approximately 2-fold lower in the in vitro induced benznidazole-resistant strain, than in the susceptible parental strain. The chromosomal location of the TcADH gene was variable, but was not associated with the zymodeme or with the drug resistance phenotype. The data presented here show that the TcADH enzyme has a decreased level of expression in the in vitro induced BZ-resistant T. cruzi population, a situation that has not been observed in the in vivo selected BZ-resistant and naturally resistant strains.

Purification and Characterization of 1-Naphthol-2-Hydroxylase from Carbaryl-Degrading Pseudomonas Strain C4

Pseudomonas sp. strain C4 metabolizes carbaryl (1-naphthyl-N-methylcarbamate) as the sole source of carbon and energy via 1-naphthol, 1,2-dihydroxynaphthalene, and gentisate. 1-Naphthol-2-hydroxylase (1-NH) was purified 9.1-fold to homogeneity from Pseudomonas sp. strain C4. Gel filtration and sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that the enzyme is a homodimer with a native molecular mass of 130 kDa and a subunit molecular mass of 66 kDa. The enzyme was yellow, with absorption maxima at 274, 375, and 445 nm, indicating a flavoprotein. High-performance liquid chromatography analysis of the flavin moiety extracted from 1-NH suggested the presence of flavin adenine dinucleotide (FAD). Based on the spectral properties and the molar extinction coefficient, it was determined that the enzyme contained 1.07 mol of FAD per mol of enzyme. Although the enzyme accepts electrons from NADH, it showed maximum activity with NADPH and had a pH optimum of 8.0. The kinetic constants K(m) and V(max) for 1-naphthol and NADPH were determined to be 9.6 and 34.2 microM and 9.5 and 5.1 micromol min(-1) mg(-1), respectively. At a higher concentration of 1-naphthol, the enzyme showed less activity, indicating substrate inhibition. The K(i) for 1-naphthol was determined to be 79.8 microM. The enzyme showed maximum activity with 1-naphthol compared to 4-chloro-1-naphthol (62%) and 5-amino-1-naphthol (54%). However, it failed to act on 2-naphthol, substituted naphthalenes, and phenol derivatives. The enzyme utilized one mole of oxygen per mole of NADPH. Thin-layer chromatographic analysis showed the conversion of 1-naphthol to 1,2-dihydroxynaphthalene under aerobic conditions, but under anaerobic conditions, the enzyme failed to hydroxylate 1-naphthol. These results suggest that 1-NH belongs to the FAD-containing external flavin mono-oxygenase group of the oxidoreductase class of proteins.

Heme-thiolate haloperoxidases: versatile biocatalysts with biotechnological and environmental significance

Heme-thiolate haloperoxidases are undoubtedly the most versatile biocatalysts of the hemeprotein family and share catalytic properties with at least three further classes of heme-containing oxidoreductases, namely, classic plant and fungal peroxidases, cytochrome P450 monooxygenases, and catalases. For a long time, only one enzyme of this type--the chloroperoxidase (CPO) of the ascomycete Caldariomyces fumago--has been known. The enzyme is commercially available as a fine chemical and catalyzes the unspecific chlorination, bromination, and iodation (but no fluorination) of a variety of electrophilic organic substrates via hypohalous acid as actual halogenating agent. In the absence of halide, CPO resembles cytochrome P450s and epoxidizes and hydroxylates activated substrates such as organic sulfides and olefins; aromatic rings, however, are not susceptible to CPO-catalyzed oxygen-transfer. Recently, a second fungal haloperoxidase of the heme-thiolate type has been discovered in the agaric mushroom Agrocybe aegerita. The UV-Vis adsorption spectrum of the isolated enzyme shows little similarity to that of CPO but is almost identical to a resting-state P450. The Agrocybe aegerita peroxidase (AaP) has strong brominating as well as weak chlorinating and iodating activities, and catalyzes both benzylic and aromatic hydroxylations (e.g., of toluene and naphthalene). AaP and related fungal peroxidases could become promising biocatalysts in biotechnological applications because they seemingly fill the gap between CPO and P450 enzymes and act as "self-sufficient" peroxygenases. From the environmental point of view, the existence of a halogenating mushroom enzyme is interesting because it could be linked to the multitude of halogenated compounds known from these organisms.

Kinetic Modeling of Amino Acid Oxidation Catalyzed by a New D‐Amino Acid Oxidase from Arthrobacter protophormiae

AbstractAmino acid oxidases, which enantiospecifically catalyze the oxidative deamination of either D‐ or L‐amino acids, belong to the class of oxidoreductases functioning with a tightly bound cofactor. This cofactor favors industrial applications of D‐amino acid oxidases (D‐AAO). Hence, the enzyme is very important for the industrial application in the purification and determination of certain amino acids. In developing the enzyme‐catalyzed reaction for large‐scale production, modeling of the reaction kinetics plays an important role. Therefore, the subject of this study was the kinetics of the oxidative deamination, a very complex reaction system, which is catalyzed by D‐AAO from Arthrobacter protophormiae using its natural substrate D‐methionine and the aromatic amino acid 3,4‐dihydroxyphenyl‐D‐alanine (D‐DOPA). The kinetic parameters determined by the measurement of the initial rate and nonlinear regression were verified in batch reactor experiments by comparing calculated and experimental concentration‐time curves. It was found that the enzyme is highly specific towards D‐methionine (Km = 0.24 mM) and not as specific to D‐DOPA as a substrate (Km = 9.33 mM). The enzyme activity towards D‐methionine ($ V_m^{D-{\rm Met}}$ = 3.01 U/mL) was approx. seven times higher than towards D‐DOPA ($ V_m^{D-{\rm DOPA}} $= 20.01 U/mL). The enzyme exhibited no activity towards L‐methionine and L‐DOPA. Batch and repetitive batch experiments were performed with both substrates in the presence and in the absence of catalase for hydrogen peroxide decomposition. Their comparison made it possible to conclude that hydrogen peroxide has no negative influence on the enzyme activity.

DSD--an integrated, web-accessible database of Dehydrogenase Enzyme Stereospecificities.

BackgroundDehydrogenase enzymes belong to the oxidoreductase class and utilise the coenzymes NAD and NADP. Stereo-selectivity is focused on the C4 hydrogen atoms of the nicotinamide ring of NAD(P). Depending upon which hydrogen is transferred at the C4 location, the enzyme is designated as A or B stereospecific.DescriptionThe Dehydrogenase Stereospecificity Database v1.0 (DSD) provides a compilation of enzyme stereochemical data, as sourced from the primary literature, in the form of a web-accessible database. There are two search engines, a menu driven search and a BLAST search. The entries are also linked to several external databases, including the NCBI and the Protein Data Bank, providing wide background information. The database is freely available online at: ConclusionDSD is a unique compilation available on-line for the first time which provides a key resource for the comparative analysis of reductase hydrogen transfer stereospecificity. As databases increasingly form the backbone of science, largely complete databases such as DSD, are a vital addition.

The 1.3 Å Crystal Structure of the Flavoprotein YqjM Reveals a Novel Class of Old Yellow Enzymes

Here we report the crystal structure of YqjM, a homolog of Old Yellow Enzyme (OYE) that is involved in the oxidative stress response of Bacillus subtilis. In addition to the oxidized and reduced enzyme form, the structures of complexes with p-hydroxybenzaldehyde and p-nitrophenol, respectively, were solved. As for other OYE family members, YqjM folds into a (alpha/beta)8-barrel and has one molecule of flavin mononucleotide bound non-covalently at the COOH termini of the beta-sheet. Most of the interactions that control the electronic properties of the flavin mononucleotide cofactor are conserved within the OYE family. However, in contrast to all members of the OYE family characterized to date, YqjM exhibits several unique structural features. For example, the enzyme exists as a homotetramer that is assembled as a dimer of catalytically dependent dimers. Moreover, the protein displays a shared active site architecture where an arginine finger (Arg336) at the COOH terminus of one monomer extends into the active site of the adjacent monomer and is directly involved in substrate recognition. Another remarkable difference in the binding of the ligand in YqjM is represented by the contribution of the NH2-terminal Tyr28 instead of a COOH-terminal tyrosine in OYE and its homologs. The structural information led to a specific data base search from which a new class of OYE oxidoreductases was identified that exhibits a strict conservation of active site residues, which are critical for this subfamily, most notably Cys26, Tyr28, Lys109, and Arg336. Therefore, YqjM is the first representative of a new bacterial subfamily of OYE homologs.

Quinoproteins: structure, function, and biotechnological applications.

A new class of oxidoreductase containing an amino acid-derived o-quinone cofactor, of which the most typical is pyrroloquinoline quinone (PQQ), is called quinoproteins, and has been recognized as the third redox enzyme following pyridine nucleotide- and flavin-dependent dehydrogenases. Some quinoproteins include a heme c moiety in addition to the quinone cofactor in the molecule and are called quinohemoproteins. PQQ-containing quinoproteins and quinohemoproteins have a common structural basis, in which PQQ is deeply embedded in the center of the unique superbarrel structure. Increased evidence for the structure and function of quinoproteins has revealed their unique position within the redox enzymes with respect to catalytic and electron transfer properties, and also to physiological and energetic function. The peculiarities of the quinoproteins, together with their unique substrate specificity, have encouraged their biotechnological application in the fields of biosensing and bioconversion of useful compounds, and also to environmental treatment.

The crystal structure of d-glyceraldehyde-3-phosphate dehydrogenase from the hyperthermophilic archaeon Methanothermus fervidus in the presence of NADP + at 2.1 Å resolution

The crystal structure of the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from the archaeon Methanothermus fervidus has been solved in the holo form at 2.1 Å resolution by molecular replacement. Unlike bacterial and eukaryotic homologous enzymes which are strictly NAD +-dependent, GAPDH from this organism exhibits a dual-cofactor specificity, with a marked preference for NADP + over NAD +. The present structure is the first archaeal GAPDH crystallized with NADP +. GAPDH from M. fervidus adopts a homotetrameric quaternary structure which is topologically similar to that observed for its bacterial and eukaryotic counterparts. Within the cofactor-binding site, the positively charged side-chain of Lys33 decisively contributes to NADP + recognition through a tight electrostatic interaction with the adenosine 2′-phosphate group. Like other GAPDHs, GAPDH from archaeal sources binds the nicotinamide moiety of NADP + in a syn conformation with respect to the adjacent ribose and so belongs to the B-stereospecific class of oxidoreductases. Stabilization of the syn conformation is principally achieved through hydrogen bonding of the carboxamide group with the side-chain of Asp171, a structural feature clearly different from what is observed in all presently known GAPDHs from bacteria and eukaryotes. Within the catalytic site, the reported crystal structure definitively confirms the essential role previously assigned to Cys140 by site-directed mutagenesis studies. In conjunction with new mutation results reported in this paper, inspection of the crystal structure gives reliable evidence for the direct implication of the side-chain of His219 in the catalytic mechanism. M. fervidus grows optimally at 84°C with a maximal growth temperature of 97°C. The paper includes a detailed comparison of the present structure with four other homologous enzymes extracted from mesophilic as well as thermophilic organisms. Among the various phenomena related to protein thermostabilization, reinforcement of electrostatic and hydrophobic interactions as well as a more efficient molecular packing appear to be essentially promoted by the occurrence of two additional α-helices in the archaeal GAPDHs. The first one, named α4, is located in the catalytic domain and participates in the enzyme architecture at the quaternary structural level. The second one, named αJ, occurs at the C terminus and contributes to the molecular packing within each monomer by filling a peripherical pocket in the tetrameric assembly.

Trypanosoma brucei tryparedoxin, a thioredoxin-like protein in African trypanosomes

A gene has been cloned from Trypanosoma brucei which encodes a protein of 144 amino acid residues containing the thioredoxin-like motif WCPPCR. Overexpression of the gene in E. coli resulted in 4 mg pure protein from 100 ml bacterial cell culture. Recombinant T. brucei tryparedoxin acts as a thiol-disulfide oxidoreductase. It is spontaneously reduced by trypanothione. This dithiol, exclusively found in parasitic protozoa, also reduces E. coli glutaredoxin but not thioredoxin. The trypanothione/tryparedoxin couple is an effective reductant of T. brucei ribonucleotide reductase. Like thioredoxins it has a poor GSH:disulfide transhydrogenase activity. The catalytic properties of tryparedoxin are intermediate between those of classical thioredoxins and glutaredoxins which indicates that these parasite proteins may form a new class of thiol-disulfide oxidoreductases.

Peroxidase and laccase as catalysts for removal of the phenylhydrazide protecting group under mild conditions

A new method is proposed for the removal of the phenylhydrazide protecting group by the action of peroxidase or laccase, the enzymes attributed to the class of oxidoreductases. The deblocking procedure is performed under mild oxidative conditions, i.e., aqueous solution and neutral or close to neutral pH. Such mild oxidizing agents as 1 mM H(2)O(2) and air oxygen are used for unmasking. The method is available for the deblocking of both alpha- and gamma-carboxyl groups. The enzyme-catalyzed removal of the phenylhydrazide protecting group causes no oxidative modification nor destruction of methionine or tryptophan side chains.

Evolutionary divergence of pobA, the structural gene encoding p-hydroxybenzoate hydroxylase in an Acinetobacter calcoaceticus strain well-suited for genetic analysis

The pobA gene encoding p-hydroxybenzoate hydroxylase (PobA) from Acinetobacter calcoaceticus has been developed as a genetic tool for the analysis of structure-function relationships in this enzyme. By exploiting the favorable genetic system of A. calcoaceticus strain ADP1, it is possible both to select and to map mutations which disturb PobA activity; characterization and sequence determination of mutants derived in this manner may complement site-directed studies with the homologous Pseudomonas aeruginosa gene. We have determined the nucleotide (nt) sequence of A. calcoaceticus pobA and performed a systematic comparison of the deduced amino acid (aa) sequence with that of the PobA enzyme from Pseudomonas fluorescens, for which the three-dimensional structure is known. Despite a 26% difference in the G + C content of the homologous genes, constraints against structural divergence of the proteins were revealed by an overall identity of 62.4% in the aligned aa sequences of PobA. Clusters of identical sequence occur at previously identified sites of ligand binding and at regions associated with subunit-subunit interaction. Based on the conservation of specific residues involved in flavin binding, we have assembled a consensus sequence for nicotinamide-flavoprotein monooxygenases which differs from that of the oxidoreductase class of flavoproteins. In addition to the conserved regions shared by the two PobA homologs, there are isolated pockets of divergence. The nt sequence divergence in one such region within the A. calcoaceticus gene can be attributed to the acquisition of short nt sequence repetitions.

Characterization of a broad-range disulfide reductase from Streptomyces clavuligerus and its possible role in beta-lactam antibiotic biosynthesis.

Streptomyces clavuligerus is a potent producer of penicillin and cephalosporin antibiotics. A key step in the biosynthesis of these beta-lactam compounds is the cyclization of the thiol tripeptide delta-(L-alpha-aminoadipyl)-L-cysteinyl-D-valine (ACV) to isopenicillin N by the enzyme isopenicillin N synthase (IPNS). However, bis-ACV, the oxidized disulfide form of the tripeptide, is not a substrate for IPNS. We show here that S. clavuligerus possesses an NADPH-dependent disulfide reductase of broad substrate specificity that efficiently catalyzes the reduction of disulfide bonds in bis-ACV and in other low-molecular-weight disulfide containing compounds and proteins. The disulfide reductase comprises two protein components, a 70-kDa reductase consisting of two identical subunits, and a 12-kDa heat-stable protein reductant. The structural and functional properties of the disulfide reductase resemble those of the thioredoxin class of oxidoreductases. When the disulfide reductase system is coupled with IPNS, it quantitatively converts bis-ACV to isopenicillin N. These findings suggest that the disulfide reductase may play a role in the biosynthesis of penicillins and cephalosporins in streptomycetes. We also show here that S. clavuligerus lacks glutathione reductase and have previously reported that Streptomyces species do not contain glutathione. This disulfide reductase may therefore be important in determining the thiol-disulfide redox balance in streptomycetes.

Molecular cloning and analysis of the gene encoding the NADH oxidase from Streptococcus faecalis 10C1 : Comparison with NADH peroxidase and the flavoprotein disulfide reductases

The gene encoding the streptococcal flavoprotein NADH oxidase (NOXase), which catalyzes the four-electron reduction of O 2 → 2H 2O, has been cloned and sequenced from the genome of Streptococcus (Enterococcus) faecalis 10C1 (ATCC 11700). The deduced NOXase protein sequence corresponds to a molecular mass of 48.9 kDa and contains three previously sequenced cysteinyl peptides obtained with the purified enzyme. In Escherichia coli, the expressed nox gene produced a catalytically active product, which retained its immunoreactivity to affinity-purified NOXase antisera. Alignment of the NOXase protein sequence with that of streptococcal NADH peroxidase (NPXase) revealed that the proteins are 44% identical. Among the most highly conserved segments is a sequence containing Cys42; this residue is known to exist as a stabilized cysteine-sulfenic acid (Cys-SOH) in NPXase and serves as the non-flavin redox center. In addition, three previously identified NPXase segments, known to be involved in FAD and NAD(P)-binding in other pyridine nucleotide-linked flavoprotein oxidoreductases, are strongly conserved in NOXase. Overall, the extensive homology observed between NOXase and NPXase suggests that the monomer chain fold of the oxidase closely resembles that of the peroxidase. Both sequences share limited but significant homology to those of glutathione reductase and other members of the flavoprotein disulfide reductase family. These and other considerations suggest that these two unusual streptococcal flavoproteins constitute a distinct class of FAD-dependent oxidoreductases, the flavoprotein peroxide reductases, easily contrasted with enzymes such as glutathione reductase and thioredoxin reductase.

Alkyl hydroperoxide reductase from Salmonella typhimurium. Sequence and homology to thioredoxin reductase and other flavoprotein disulfide oxidoreductases.

The DNA sequence of the Salmonella typhimurium ahp locus was determined. The locus was found to contain two genes that encode the two proteins (C22 and F52a) that comprise the S. typhimurium alkyl hydroperoxide reductase activity. The predicted sequence of the F52a protein component of the alkyl hydroperoxide reductase was found to be highly homologous to the Escherichia coli thioredoxin reductase protein (34% identity with many conservative substitutions). The homology was found to be particularly striking in the region containing the redox-active cysteines of the thioredoxin reductase molecule, and among the identities were the redox-active cysteines themselves. Aside from the strong similarity to thioredoxin reductase, overall homology between the F52a protein and other flavoprotein disulfide oxidoreductases such as glutathione reductase, dihydrolipoamide dehydrogenase, and mercuric reductase was found to be rather limited, and the conserved active site segment common to the three proteins was not observed within the F52a protein. However, three short segments that have been implicated in FAD and NAD binding were found to be conserved between the F52a protein and the other disulfide reductases. These results suggest that the alkyl hydroperoxide reductase is the second known member of a class of disulfide oxidoreductases which was represented previously by thioredoxin reductase alone; they also allow the putative assignment of several functional domains.