Mercuric reductase enzyme from a mercury-volatilizing strain of Thiobacillus ferrooxidans.

Cell-free mercury volatilization activity (mercuric reductase) was obtained from a mercury-volatilizing Thiobacillus ferrooxidans strain, and the properties of intact-cell and cell-free activities were compared with those determined by plasmid R100 in Escherichia coli. Intact cells of T. ferrooxidans volatilized mercury at pH 2.5, whereas cells of E. coli did not. Cell-free enzyme preparations from both bacteria functioned best at or above neutral pH and not at all at pH 2.5. The T. ferrooxidans mercuric reductase was a soluble enzyme that was dependent upon added NAD(P)H. The enzyme activity was stable at 80 degrees C, required an added thiol compound, and was stimulated by EDTA. Antisera against purified mercuric reductases from transposon Tn501 and plasmid R831 (which inactivated mercuric reductases from a wide range of enteric and pseudomonad strains) did not inactivate the enzyme from T. ferrooxidans.     

Purification and properties of glutathione reductase from the cyanobacterium Anabaena sp. strain 7119.

An NADPH-glutathione reductase (EC 1.6.4.2) has been purified 6,000-fold to electrophoretic homogeneity from the filamentous cyanobacterium Anabaena sp. strain 7119. The purified enzyme exhibits a specific activity of 249 U/mg and is characterized by being a dimeric flavin adenine dinucleotide-containing protein with a ratio of absorbance at 280 nm to absorbance at 462 nm of 5.8, a native molecular weight of 104,000, a Stokes radius of 4.13 nm, and a pI of 4.02. The enzyme activity is inhibited by sulfhydryl reagents and heavy-metal ions, especially in the presence of NADPH, with oxidized glutathione behaving as a protective agent. As is the case with the same enzyme from other sources, the kinetic data are consistent with a branched mechanism. Nevertheless, the cyanobacterial enzyme presents three distinctive features with respect to that isolated from non-photosynthetic organisms: (i) absolute specificity for NADPH, (ii) an alkaline optimum pH value of ca. 9.0, and (iii) strong acidic character of the protein, as estimated by column chromatofocusing. The kinetic parameters are very similar to those found for the chloroplast enzyme, but the molecular weight is lower, being comparable to that of non-photosynthetic microorganisms. A protective function, analogous to that assigned to the chloroplast enzyme, is suggested.     

Purification and properties of 5-keto-d-fructose reductase from a mutant strain derived from Corynebacterium sp.

5-Keto-d-fructose reductase was purified about 300-fold from a mutant strain derived from Corynebacterium sp. SHS 0007 (ATCC 31090). The enzyme appeared to be homogeneous by SDS-polyacrylamide gel electrophoresis. The enzyme converted 5-keto-d-fructose to l-sorbose in the presence of NADPH. The reduction did not occur in the presence of NADH. The reverse reaction was not observed. The molecular weight of the enzyme was estimated to be about 33,000 by gel filtration and SDS-polyacrylamide gel electrophoresis. The enzyme appeared to be monomeric. The optimum pH was 6.0–7.0 for the reductase. The K_m value (pH 7.0, 30°C) of the enzyme for 5-keto-d-fructose was 5.9 mM. The enzyme was relatively inactive on 2, 5-diketo-d-gluconate in the presence of NADPH.     

Characterization of the arsenate respiratory reductase from Shewanella sp. strain ANA-3

Microbial arsenate respiration contributes to the mobilization of arsenic from the solid to the soluble phase in various locales worldwide. To begin to predict the extent to which As(V) respiration impacts arsenic geochemical cycling, we characterized the expression and activity of the Shewanella sp. strain ANA-3 arsenate respiratory reductase (ARR), the key enzyme involved in this metabolism. ARR is expressed at the beginning of the exponential phase and persists throughout the stationary phase, at which point it is released from the cell. In intact cells, the enzyme localizes to the periplasm. To purify ARR, a heterologous expression system was developed in Escherichia coli. ARR requires anaerobic conditions and molybdenum for activity. ARR is a heterodimer of ~131 kDa, composed of one ArrA subunit (~95 kDa) and one ArrB subunit (~27 kDa). For ARR to be functional, the two subunits must be expressed together. Elemental analysis of pure protein indicates that one Mo atom, four S atoms associated with a bis-molybdopterin guanine dinucleotide cofactor, and four to five [4Fe-4S] are present per ARR. ARR has an apparent melting temperature of 41°C, a K_m of 5 μM, and a V_max of 11,111 μmol of As(V) reduced min⁻¹ mg of protein⁻¹ and shows no activity in the presence of alternative electron acceptors such as antimonite, nitrate, selenate, and sulfate. The development of a heterologous overexpression system for ARR will facilitate future structural and/or functional studies of this protein family.     

Large-scale purification and characterization of dihydrofolate reductase from a methotrexate-resistant strain of Lactobacillus casei.

Dihydrofolate reductase has been purified from a methotrexate-resistant strain of Lactobacillus casei NCB 6375. By careful attention to growth conditions, up to 2.5 g of enzyme is obtained from a 400 litre culture. The purification procedure, involving poly-ethyleneimine treatment, DEAE-cellulose chromatography and affinity chromatography on methotrexate-aminohexyl-Sepharose, operates on the gram scale, with overall yields of 50-60%. Elution of the affinity column by reverse (upward) flow was used, as it led to recovery of the enzyme in a much smaller volume. The enzyme obtained appears to be more than 98% pure, as judged by gel electrophoresis, isoelectric focusing, and gel filtration. It has a mol.wt. of approx. 17900 and a turnover number of 4s-1 (50mM-triethanolamine/400mM-KCl, pH 7.2, 25 degrees C) with dihydrofolate and NADPH as substrates. The turnover number for folate is 0.02s-1. Michaelis constants for a variety of substrates have been measured by using a new fluorimetric assay (0.36 muM-dihydrofolate; 0.78 muM-NADPH), and binding constants determined by using the quenching of protein fluorescence (dihydrofolate, 2.25 X 10(6)M-1; NADPH, greater than 10(8)M-1). The pH/activity profile shows a single maximum at pH 7.3; at this pH, marked activation by 0.5M-NaCl is observed.     

Purification and characterization of phenylacetaldehyde reductase from a styrene-assimilating Corynebacterium strain, ST-10.

A novel phenylacetaldehyde reductase was purified about 50-fold to homogeneity from Corynebacterium sp. strain ST-10, which can assimilate gaseous styrene as the sole carbon and energy source. The enzyme was inductively synthesized when grown on gaseous styrene and had an important role in styrene metabolism in vivo. The enzyme had a molecular weight of 155,000 and was composed of four identical subunits (molecular weight, 42,000). The enzyme catalyzed the reduction of not only phenylacetaldehyde but also various aldehydes and ketones; however, it did not catalyze the reverse reaction, the dehydrogenation of 2-phenylethanol. The enzyme required NADH as a cofactor and showed no activity with NADPH; therefore, it was defined as an NADH-dependent phenylacetaldehyde reductase. The enzyme stereospecifically produced (S)-(-)-1-phenylethanol from acetophenone; therefore, it would be useful as a biocatalyst.     

Cloning, sequencing, and analysis of aklaviketone reductase from Streptomyces sp. strain C5.

DNA sequence analysis of a region of the Streptomyces sp. strain C5 daunomycin biosynthesis gene cluster, located just upstream of the daunomycin polyketide biosynthesis genes, revealed the presence of six complete genes. The two genes reading right to left include genes encoding the potentially translationally coupled gene products, an acyl carrier protein and a ketoreductase, and the four genes reading divergently, left to right, include two open reading frames of unknown function followed by a gene encoding an apparent glycosyltransferase and dauE, encoding aklaviketone reductase. Extracts of Streptomyces lividans TK24 containing recombinant DauE catalyzed the NADPH-specific conversion of aklaviketone, maggiemycin, and 7-oxodaunomycinone to aklavinone, epsilon-rhodomycinone, and daunomycinone, respectively. Neither the product of dauB nor that of the ketoreductase gene directly downstream of the acyl carrier protein gene demonstrated aklaviketone reductase activity.     

Degradation of chloroaromatics: purification and characterization of maleylacetate reductase from Pseudomonas sp. strain B13.

Maleylacetate reductase of Pseudomonas sp. strain B13 was purified to homogeneity by chromatography on DEAE-cellulose, Butyl-Sepharose, Blue-Sepharose, and Sephacryl S100. The final preparation gave a single band by polyacrylamide gel electrophoresis under denaturing conditions and a single symmetrical peak by gel filtration under nondenaturing conditions. The subunit M(r) value was 37,000 (determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis). Estimation of the native M(r) value by gel filtration gave a value of 74,000 with a Superose 6 column, indicating that the enzyme is dimeric. The pH and temperature optima were 5.4 and 50 degrees C, respectively. The pI of the enzyme was estimated to be 7.0. The apparent Km values for maleylacetate and NADH were 58 and 30 microM, respectively, and the maximum velocity was 832 U/mg of protein for maleylacetate. Maleylacetate and various substituted maleylacetates, such as 2-chloro- and 2-methyl-maleylacetate, were reduced at significant rates. NADPH was also used as a cofactor instead of NADH with nearly the same Vmax value, but its Km value was estimated to be 77 microM. Reductase activity was inhibited by a range of thiol-blocking reagents. The absorption spectrum indicated that there was no bound cofactor or prosthetic group in the enzyme.     

Purification and properties of the NADH reductase component of alkene monooxygenase from Mycobacterium strain E3.

Alkene monooxygenase, a multicomponent enzyme system which catalyzes the epoxidation of short-chain alkenes, is induced in Mycobacterium strain E3 when it is grown on ethene. We purified the NADH reductase component of this enzyme system to homogeneity. Recovery of the enzyme was 19%, with a purification factor of 920-fold. The enzyme is a monomer with a molecular mass of 56 kDa as determined by gel filtration and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. It is yellow-red with absorption maxima at 384, 410, and 460 nm. Flavin adenine dinucleotide (FAD) was identified as a prosthetic group at a FAD-protein ratio of 1:1. Tween 80 prevented irreversible dissociation of FAD from the enzyme during chromatographic purification steps. Colorimetric analysis revealed 2 mol each of iron and acid-labile sulfide, indicating the presence of a [2Fe-2S] cluster. The presence of this cluster was confirmed by electron paramagnetic resonance spectroscopy (g values at 2.011, 1.921, and 1.876). Anaerobic reduction of the reductase by NADH resulted in formation of a flavin semiquinone.     

X-ray crystal structure of benzoate 1,2-dioxygenase reductase from Acinetobacter sp. strain ADP1

One of the major processes for aerobic biodegradation of aromatic compounds is initiated by Rieske dioxygenases. Benzoate dioxygenase contains a reductase component, BenC, that is responsible for the two-electron transfer from NADH via FAD and an iron-sulfur cluster to the terminal oxygenase component. Here, we present the structure of BenC from Acinetobacter sp. strain ADP1 at 1.5 A resolution. BenC contains three domains, each binding a redox cofactor: iron-sulfur, FAD and NADH, respectively. The [2Fe-2S] domain is similar to that of plant ferredoxins, and the FAD and NADH domains are similar to members of the ferredoxin:NADPH reductase superfamily. In phthalate dioxygenase reductase, the only other Rieske dioxygenase reductase for which a crystal structure is available, the ferredoxin-like and flavin binding domains are sequentially reversed compared to BenC. The BenC structure shows significant differences in the location of the ferredoxin domain relative to the other domains, compared to phthalate dioxygenase reductase and other known systems containing these three domains. In BenC, the ferredoxin domain interacts with both the flavin and NAD(P)H domains. The iron-sulfur center and the flavin are about 9 A apart, which allows a fast electron transfer. The BenC structure is the first determined for a reductase from the class IB Rieske dioxygenases, whose reductases transfer electrons directly to their oxygenase components. Based on sequence similarities, a very similar structure was modeled for the class III naphthalene dioxygenase reductase, which transfers electrons to an intermediary ferredoxin, rather than the oxygenase component.     

Purification and properties of heterodisulfide reductase from Methanobacterium thermoautotrophicum (strain Marburg)

The reduction of the heterodisulfide of coenzyme M (H-S-CoM) and 7-mercaptoheptanoyl-L-threonine phosphate (H-S-HTP) is a key reaction in the metabolism of methanogenic bacteria. The heterodisulfide reductase catalyzing this step was purified 80-fold to apparent homogeneity from Methanobacterium thermoautotrophicum. The native enzyme showed an apparent molecular mass of 550 kDa. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis revealed the presence of three different subunits of apparent molecular masses 80 kDa, 36 kDa, and 21 kDa. The enzyme, which was brownish yellow, contained per mg protein 7 +/- 1 nmol FAD, 130 +/- 10 nmol non-heme iron and 130 +/- 10 nmol acid-labile sulfur, corresponding to 4 mol FAD and 72 mol FeS/mol native enzyme. The purified heterodisulfide reductase catalyzed the reduction of CoM-S-S-HTP (app. Km = 0.1 mM) with reduced benzylviologen at a specific rate of 30 mumol.min-1.mg protein-1 (kcat = 68 s-1) and the reduction of methylene blue with H-S-CoM (app. Km = 0.2 mM) plus H-S-HTP (app. Km less than 0.05 mM) at a specific rate of 15 mumol.min-1.mg-1. The enzyme was highly specific for CoM-S-S-HTP and H-S-CoM plus H-S-HTP. The physiological electron donor/acceptor remains to be identified.     

Purification and characterization of nitrous oxide reductase from Pseudomonas aeruginosa strain P2

Nitrous oxide reductase, which catalyzes the reduction of N2O to N2, was purified in a largely oxidized form from Pseudomonas aeruginosa strain P2 by a simple anaerobic procedure to yield an enzyme with a peptide purity of 95-98%. For the native (dimeric) enzyme, Mr = 120,000 and for the denatured subunit, Mr = 73,000. The enzyme contained four Cu atoms/subunit, was purple in color, and exhibited a broad absorption band at 550 nm with an extinction coefficient of about 11,000 M-1 x cm-1 referenced to the dimer. It was nearly inactive as prepared but could be activated by incubation with 2-(N-cyclohexylamino)ethane sulfonate buffer, pH 10, to specific activities as high as 27 mumol of N2O x min-1 x mg-1.Km for N2O and benzyl viologen radical cation was about 2 and 4 microM, respectively, both before and after enzyme activation. Activation increased the t1/2 for turnover-dependent inactivation from about 30 s to 5-10 min. Reduction of the enzyme by dithionite was kinetically biphasic and resulted in the loss of the 550-nm band and ultimate appearance of a 670-nm band. Isoelectric focusing revealed five components with pI values from 5.2 to 5.7. The pI values did not change following activation. The copper CD spectrum of the enzyme as prepared was different from that for the activated enzyme, whereas those for the enzyme after exposure to air and the activated enzyme were similar. Because the activated enzyme is a mixture of activated and inactive species, the specific activity of the activated species must be substantially greater than the observed value. Molecular heterogeneity may also explain the decreased optical absorbance and CD amplitude that resulted from the activation process. The data overall reinforce the view that the absorption spectrum of nitrous oxide reductase is not a good predictor of absolute activity.     

Purification and properties of NADH-ferredoxinNAP reductase, a component of naphthalene dioxygenase from Pseudomonas sp. strain NCIB 9816.

Cells of Pseudomonas sp. strain NCIB 9816, after growth with naphthalene or salicylate, contain a multicomponent enzyme system that oxidizes naphthalene to cis-(1R,2S)-dihydroxy-1,2-dihydronaphthalene. We purified one of these components to homogeneity and found it to be an iron-sulfur flavoprotein that loses the flavin cofactor during purification. Dialysis against flavin adenine dinucleotide (FAD) showed that the enzyme bound 1 mol of FAD per mol of enzyme protein. The enzyme consisted of a single polypeptide with an apparent molecular weight of 36,300. The purified protein contained 1.8 g-atoms of iron and 2.0 g-atoms of acid-labile sulfur and showed absorption maxima at 278, 340, 420, and 460 nm, with a broad shoulder at 540 nm. The purified enzyme catalyzed the reduction of cytochrome c, dichlorophenolindophenol, Nitro Blue Tetrazolium, and ferricyanide. These activities were enhanced in the presence of added FAD. The ability of the enzyme to catalyze the reduction of the ferredoxin involved in naphthalene reduction and other electron acceptors indicates that it functions as an NAD(P)H-oxidoreductase in the naphthalene dioxygenase system. The results suggest that naphthalene dioxygenase requires two proteins with three redox groups to transfer electrons from NADH to the terminal oxygenase.     

Mutational analysis of NADH-binding residues in triphenylmethane reductase from Citrobacter sp. strain KCTC 18061P

Triphenylmethane reductase (TMR) catalyzes the NADH-dependent reduction of triphenylmethane dyes. Sequence alignment revealed a region with a conserved GXXGXXG motif near its N-terminus, which corresponds to a conserved structural motif of known dinucleotide-binding proteins. To verify whether some of these glycine residues are important for the enzyme catalysis, these three glycine residues (Gly-7, Gly-10 and Gly-13) were individually replaced by alanine using site-directed mutagenesis. The secondary structures of these mutants, as measured by circular dichroism spectroscopy, did not show remarkable differences as compared with the wild type. The V(max)/K(m) values of mutants G7A and G13A for both Basic fuchsin and NADH were increased about three and twofold over that of the wild type, respectively, whereas the V(max)/K(m) value of mutant G10A were decreased about sixfold. These results suggest that these three glycine residues are involved in the interaction with both substrate and cofactor for the catalytic activity of TMR.     

Cloning and characterization of dihydrofolate reductase from a facultative alkaliphilic and halotolerant bacillus strain

Elucidation of the molecular basis of the stability of enzymes from extremophilic organisms is of fundamental importance for various industrial applications. Due to the wealth of structural data from various species, dihydrofolate reductase (DHFR, EC 1.5.1.3) provides an excellent model for systematic investigations. In this report, DHFR from alkaliphilic Bacillus halodurans C-125 was cloned and expressed in E. coli. Functional analyses revealed that BhDHFR exhibits the most alkali-stable phenotype of DHFRs characterized so far. Optimal enzyme activity was observed in a slightly basic pH region ranging from 7.25 to 8.75. Alkali-stability is associated with a remarkable resistance to elevated temperatures (half-life of 60 min at 52.5°C) and to high concentrations of urea (up to 3 M). Although the secondary structure shows distinct similarities to those of mesophilic DHFR molecules, BhDHFR exhibits molecular features contributing to its alkaliphilic properties. Interestingly, the unique phenotype is diminished by C-terminal addition of a His-tag sequence. Therefore, His-tag-derivatized BhDHFR offers the opportunity to obtain deeper insights into the specific mechanisms of alkaliphilic adaption by comparison of the three dimensional structure of both BhDHFR molecules.     

Purification and characterization of aldose reductase and aldehyde reductase from human kidney.

Aldose reductase and aldehyde reductases have been purified to homogeneity from human kidney and have molecular weights of 32,000 and 40,000 and isoelectric pH 5.8 and 5.3, respectively. Aldose reductase, beside catalyzing the reduction of various aldehydes, reduces aldo-sugars, whereas aldehyde reductase, does not reduce aldo-sugars. Aldose reductase activity is expressed with either NADH or NADPH as cofactor, whereas aldehyde reductase utilizes only NADPH. Both enzymes are inhibited to varying degrees by aldose reductase inhibitors. Antibodies against bovine lens aldose reductase precipitated aldose reductase but not aldehyde reductase. The sequence of addition of the substrates to aldehyde reductase is ordered and to aldose reductase is random, whereas for both the enzymes the release of product is ordered with NADP released last.     

An arsenate reductase from Synechocystis sp. strain PCC 6803 exhibits a novel combination of catalytic characteristics

The deduced protein product of open reading frame slr0946 from Synechocystis sp. strain PCC 6803, SynArsC, contains the conserved sequence features of the enzyme superfamily that includes the low-molecular-weight protein-tyrosine phosphatases and the Staphylococcus aureus pI258 ArsC arsenate reductase. The recombinant protein product of slr0946, rSynArsC, exhibited vigorous arsenate reductase activity (V(max) = 3.1 micro mol/min. mg), as well as weak phosphatase activity toward p-nitrophenyl phosphate (V(max) = 0.08 micro mol/min. mg) indicative of its phosphohydrolytic ancestry. pI258 ArsC from S. aureus is the prototype of one of three distinct families of detoxifying arsenate reductases. The prototypes of the others are Acr2p from Saccharomyces cerevisiae and R773 ArsC from Escherichia coli. All three have converged upon catalytic mechanisms involving an arsenocysteine intermediate. While SynArsC is homologous to pI258 ArsC, its catalytic mechanism exhibited a unique combination of features. rSynArsC employed glutathione and glutaredoxin as the source of reducing equivalents, like Acr2p and R773 ArsC, rather than thioredoxin, as does the S. aureus enzyme. As postulated for Acr2p and R773 ArsC, rSynArsC formed a covalent complex with glutathione in an arsenate-dependent manner. rSynArsC contains three essential cysteine residues like pI258 ArsC, whereas the yeast and E. coli enzymes require only one cysteine for catalysis. As in the S. aureus enzyme, these "extra" cysteines apparently shuttle a disulfide bond to the enzyme's surface to render it accessible for reduction. SynArsC and pI258 ArsC thus appear to represent alternative branches in the evolution of their shared phosphohydrolytic ancestor into an agent of arsenic detoxification.