Use of a site-directed triple mutant to trap intermediates: demonstration that the flavin C(4a)-thiol adduct and reduced flavin are kinetically competent intermediates in mercuric ion reductase

A mutant form of mercuric reductase, which has three of its four catalytically essential cysteine residues replaced by alanines (ACAA: Ala135Cys140Ala558Ala559), has been constructed and used for mechanistic investigations. With disruption of the Hg(II) binding site, the mutant enzyme is devoid of Hg(II) reductase activity. However, it appears to fold properly since it binds FAD normally and exhibits very tight binding of pyridine nucleotides as is seen with the wild-type enzyme. This mutant enzyme allows quantitative accumulation of two species thought to function as intermediates in the catalytic sequence of the flavoprotein disulfide reductase family of enzymes. NADPH reduces the flavin in this mutant, and a stabilized E-FADH- form accumulates. The second intermediate is a flavin C(4a)-Cys140 thiol adduct, which is quantitatively accumulated by reaction of oxidized ACAA enzyme with NADP+. The conversion of the Cys135-Cys140 disulfide in wild-type enzyme to the monothiol Cys140 in ACAA and the elevated pKa of Cys140 (6.7 vs 5.0 in wild type) have permitted detection of these intermediates at low pH (5.0). The rates of formation of E-FADH- and the breakdown of the flavin C(4a)-thiol adduct have been measured and indicate that both intermediates are kinetically competent for both the reductive half-reaction and turnover by wild-type enzyme. These results validate the general proposal that electrons flow from NADPH to FADH- to C(4a)-thiol adduct to the FAD/dithiol form that accumulates as the EH2 form in the reductive half-reaction for this class of enzymes.     

Mutagenesis of the N- and C-terminal cysteine pairs of Tn501 mercuric ion reductase: consequences for bacterial detoxification of mercurials

Mercuric ion reductase (the merA gene product) is a unique member of the class of FAD and redox-active disulfide-containing oxidoreductases by virtue of its ability to reduce Hg(II) to Hg(0) as the last step in bacterial detoxification of mercurials. In addition to the active site redox-active disulfide, formed between Cys135 and Cys140 in Tn501 MerA, the protein products of the three merA gene sequences published to date have two additional conserved pairs of cysteines, one near the N-terminus (Cys10Cys13 in Tn501 MerA) and another near the C-terminus (Cys558Cys559 in Tn501 MerA). Neither of these pairs is found in other members of this enzyme family. To assess the possible roles of these peripheral cysteines in the Hg(II) detoxification pathway, we have constructed and characterized one single mutant, Cys10Ala13, and two double mutants, Ala10Ala13 and Ala558Ala559. The N-terminal mutants are fully functional in vivo as determined by HgCl2 resistance studies, showing the N-terminal cysteine pair to be dispensable. In contrast, the Ala558Ala559 mutant is defective for HgCl2 resistance in vivo and Hg(SR)2 reduction in vitro, thereby implicating Cys558 and/or Cys559 in Hg(II) reduction by the wild-type enzyme. Other activities, such as NADPH/thio-NADP+ transhydrogenation, NADPH oxidation, and DTNB reduction, are unimpaired in this mutant.     

Active site of mercuric reductase resides at the subunit interface and requires Cys135 and Cys140 from one subunit and Cys558 and Cys559 from the adjacent subunit: evidence from in vivo and in vitro heterodimer formation

Mercuric reductase catalyzes the two-electron reduction of Hg(II) to Hg(0) using NADPH as the reductant; this reaction constitutes the molecular basis for detoxification of Hg(II) by bacteria. The enzyme is an alpha 2 homodimer and possesses two pairs of cysteine residues, Cys135 and Cys140 (redox-active pair) and Cys558 and Cys559 (C-terminal pair), which are known to be essential for catalysis. In the present study, we have obtained evidence for an intersubunit active site, consisting of a redox-active cysteine pair from one subunit and a C-terminal pair from the adjacent subunit, by reconstituting catalytic activity both in vivo and in vitro starting with two inactive, mutant enzymes, Ala135Ala140Cys558Cys559 (AACC) and Cys135Cys140Ala558Ala559 (CCAA). Genetic complementation studies were used to show that coexpression of AACC and CCAA in the same cell yielded an HgR phenotype, some 10(4)-fold more resistant than cells expressing only one mutant. Purification and catalytic characterization of a similarly coexpressed protein mixture showed the mixture to have activity levels ca. 25% those of wild type; this is the same as that statistically anticipated for a CCAA-AACC heterodimeric/homodimeric mixture with only one functional active site per heterodimer. Actual physical evidence for the formation of active mutant heterodimers was obtained by chaotrope-induced subunit interchange of inactive pure CCAA and AACC homodimers in vitro followed by electrophoretic separation of heterodimers from homodimers. Taken together, these data provide compelling evidence that the active site in mercuric reductase resides at the subunit interface and contains cysteine residues originating from separate polypeptide chains.     

C-terminal cysteines of Tn501 mercuric ion reductase.

Mercuric ion reductase (MerA) catalyzes the reduction of Hg(II) to Hg(0) as the last step in the bacterial mercury detoxification pathway. A member of the flavin disulfide oxidoreductase family, MerA contains an FAD prosthetic group and redox-active disulfide in its active site. However, the presence of these two moieties is not sufficient for catalytic Hg(II) reduction, as other enzyme family members are potently inhibited by mercurials. We have previously identified a second pair of active site cysteines (Cys558 Cys559 in the Tn501 enzyme) unique to MerA, that are essential for high levels of mercuric ion reductase activity [Moore, M. J., & Walsh, C. T. (1989) Biochemistry 28, 1183; Miller, S. M., et al. (1989) Biochemistry 28, 1194]. In this paper, we have examined the individual roles of Cys558 and Cys559 by site-directed mutagenesis of each to alanine. Phenotypic analysis indicates that both merA mutations result in a total disruption of the Hg(II) detoxification pathway in vivo, while characterization of the purified mutant enzymes in vitro shows each to have differential effects on catalytic function. Compared to wild-type enzyme, the C558A mutant shows a 20-fold reduction in kcat and a 10-fold increase in Km, for an overall decrease in catalytic efficiency of 200-fold in kcat/Km. In contrast, mutation of Cys559 to alanine results in less than a 2-fold reduction in kcat and an increase in Km of only 4-5 fold for an overall decrease in catalytic efficiency of only ca. 10-fold in vitro. From these results, it appears that Cys558 plays a more important role in forming the reducible complex with Hg(II), while both Cys558 and Cys559 seem to be involved in efficient scavenging (i.e., tight binding) of Hg(II).     

A hydrogen peroxide-forming NADH oxidase that functions as an alkyl hydroperoxide reductase in Amphibacillus xylanus

The Amphibacillus xylanus NADH oxidase, which catalyzes the reduction of oxygen to hydrogen peroxide with beta-NADH, can also reduce hydrogen peroxide to water in the presence of free flavin adenine dinucleotide (FAD) or the small disulfide-containing Salmonella enterica AhpC protein. The enzyme has two disulfide bonds, Cys128-Cys131 and Cys337-Cys340, which can act as redox centers in addition to the enzyme-bound FAD (K. Ohnishi, Y. Niimura, M. Hidaka, H. Masaki, H. Suzuki, T. Uozumi, and T. Nishino, J. Biol. Chem. 270:5812-5817, 1995). The NADH-FAD reductase activity was directly dependent on the FAD concentration, with a second-order rate constant of approximately 2.0 x 10(6) M(-1) s(-1). Rapid-reaction studies showed that the reduction of free flavin occurred through enzyme-bound FAD, which was reduced by NADH. The peroxidase activity of NADH oxidase in the presence of FAD resulted from reduction of peroxide by free FADH(2) reduced via enzyme-bound FAD. This peroxidase activity was markedly decreased in the presence of oxygen, since the free FADH(2) is easily oxidized by oxygen, indicating that this enzyme system is unlikely to be functional in aerobic growing cells. The A. xylanus ahpC gene was cloned and overexpressed in Escherichia coli. When the NADH oxidase was coupled with A. xylanus AhpC, the peroxidase activity was not inhibited by oxygen. The V(max) values for hydrogen peroxide and cumene hydroperoxide reduction were both approximately 150 s(-1). The K(m) values for hydrogen peroxide and cumene hydroperoxide were too low to allow accurate determination of their values. Both AhpC and NADH oxidase were induced under aerobic conditions, a clear indication that these proteins are involved in the removal of peroxides under aerobic growing conditions.     

Evidence for the participation of Cys558 and Cys559 at the active site of mercuric reductase

Mercuric reductase, with FAD and a reducible disulfide at the active site, catalyzes the two-electron reduction of Hg(II) by NADPH. Addition of reducing equivalents rapidly produces a spectrally distinct EH2 form of the enzyme containing oxidized FAD and reduced active site thiols. Formation of EH2 has previously been reported to require only 2 electrons for reduction of the active site disulfide. We present results of anaerobic titrations of mercuric reductase with NADPH and dithionite showing that the equilibrium conversion of oxidized enzyme to EH2 actually requires 2 equiv of reducing agent or 4 electrons. Kinetic studies conducted both at 4 degrees C and at 25 degrees C indicate that reduction of the active site occurs rapidly, as previously reported [Sahlman, L., & Lindskog, S. (1983) Biochem. Biophys. Res. Commun. 117, 231-237]; this is followed by a slower reduction of another redox group via reaction with the active site. Thiol titrations of denatured Eox and EH2 enzyme forms show that an additional disulfide is the group in communication with the active site. [14C]Iodoacetamide labeling experiments demonstrate that the C-terminal residues, Cys558 and Cys559, are involved in this disulfide. The fluorescence, but not the absorbance, of the enzyme-bound FAD was found to be highly dependent on the redox state of the C-terminal thiols. Thus, Eox with Cys558 and Cys559 as thiols exhibits less than 50% of the fluorescence of Eox where these residues are present as a disulfide, indicating that the thiols remain intimately associated with the active site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence for two conformational states of thioredoxin reductase from Escherichia coli: use of intrinsic and extrinsic quenchers of flavin fluorescence as probes to observe domain rotation.

Thioredoxin reductase (TrxR) from Escherichia coli consists of two globular domains connected by a two-stranded beta sheet: an FAD domain and a pyridine nucleotide binding domain. The latter domain contains the redox-active disulfide composed of Cys 135 and Cys 138. TrxR is proposed to undergo a conformational change whereby the two domains rotate 66 degrees relative to each other (Waksman G, Krishna TSR, Williams CH Jr, Kuriyan J, 1994, J Mol Biol 236:800-816), placing either redox active disulfide (FO conformation) or the NADPH binding site (FR conformation) adjacent to the flavin. This domain rotation model was investigated by using a Cys 138 Ser active-site mutant. The flavin fluorescence of this mutant is only 7% that of wild-type TrxR, presumably due to the proximity of Ser 138 to the flavin in the FO conformation. Reaction of the remaining active-site thiol, Cys 135, with phenylmercuric acetate (PMA) causes a 9.5-fold increase in fluorescence. Titration of the PMA-treated mutant with the nonreducing NADP(H) analogue, 3-aminopyridine adenine dinucleotide phosphate (AADP+), results in significant quenching of the flavin fluorescence, which demonstrates binding adjacent to the FAD, as predicted for the FR conformation. Wild-type TrxR, with or without PMA treatment, shows similar quenching by AADP+, indicating that it exists mostly in the FR conformer. These findings, along with increased EndoGluC protease susceptibility of PMA-treated enzymes, agree with the model that the FO and FR conformations are in equilibrium. PMA treatment, because of steric limitations of the phenylmercuric adduct in the FO form, forces the equilibrium to the FR conformer, where AADP+ binding can cause fluorescence quenching and conformational restriction favors proteolytic susceptibility.     

Oxidation-reduction properties of Escherichia coli thioredoxin reductase altered at each active site cysteine residue.

Thioredoxin is a small oxidation-reduction (redox) mediator protein. Its reduction by NADPH is catalyzed by the flavoenzyme thioredoxin reductase. Site-directed mutagenesis has provided forms of the reductase in which Cys135 and Cys138 have each been changed to a serine residue (Prongay, A. J., Engelke, D. R., and Williams, C. H., Jr. (1989) J. Biol. Chem. 264, 2656-2664). Cys135 and Cys138 form the redox-active disulfide in the oxidized enzyme. The redox properties of the two altered forms of Escherichia coli thioredoxin reductase have been determined from pH 6.0 to 9.0. Photoreduction of TRR(Ser135,Cys138) produces the blue, neutral semiquinone species, which disproportionates (Kf = 0.73) to an apparent maximum of 29% of the total enzyme as the semiquinone. In contrast, the semiquinone formed on TRR(Cys135,Ser138) during a photoreductive titration does not disproportionate and 70% of the enzyme is stabilized as the semiquinione. Reductive titrations have demonstrated that 1 mol of sodium dithionite (2 electrons)/mol of FAD is required to fully reduce TRR(Ser135,Cys138) whereas 2 mol of dithionite/mol of FAD are required to fully reduce TRR(Cys135,Ser138). The oxidation-reduction midpoint potentials for the 1-electron and 2-electron reductions of TRR(Ser135,Cys138) have been determined by NADH/NAD+ titrations in the presence of a mediator, benzyl viologen. The midpoint potential for the 2-electron reduction of TRR(Ser135,Cys138) is -280 mV, at pH 7.0 and 20 degrees C. Thus, the redox potential is similar to that of the FAD/FADH2 couple in the dithiol form of wild type enzyme, -270 mV (corrected to 20 degrees C) (O'Donnell, M. E., and Williams, C. H., Jr. (1983) J. Biol. Chem. 258, 13795-13805). The delta Em/delta pH is -57.1 mV, which corresponds to a proton stoichiometry of 2 H+/2 e-.A maximum of 19% of the enzyme forms a stable semiquinone species during the titration, and the potentials for the oxidized enzyme/semiquinone couple, E2, and the semiquinone/reduced enzyme couple, E1, are -306 and -256 mV, respectively, at pH 7.0 and 20 degrees C. These studies provide evidence that the residue at position 138 exerts a greater effect on the FAD than does the residue at position 135.     

Active site of Escherichia coli DNA photolyase: Asn378 is crucial both for stabilizing the neutral flavin radical cofactor and for DNA repair

Escherichia coli DNA photolyase repairs cyclobutane pyrimidine dimer (CPD) in UV-damaged DNA through a photoinduced electron transfer mechanism. The catalytic activity of the enzyme requires fully reduced FAD (FADH (-)). After purification in vitro, the cofactor FADH (-) in photolyase is oxidized into the neutral radical form FADH (*) under aerobic conditions and the enzyme loses its repair function. We have constructed a mutant photolyase in which asparagine 378 (N378) is replaced with serine (S). In comparison with wild-type photolyase, we found N378S mutant photolyase containing oxidized FAD (FAD ox) but not FADH (*) after routine purification procedures, but evidence shows that the mutant protein contains FADH (-) in vivo as the wild type. Although N378S mutant photolyase is photoreducable and capable of binding CPD in DNA, the activity assays indicate the mutant protein is catalytically inert. We conclude that the Asn378 residue of E. coli photolyase is crucial both for stabilizing the neutral flavin radical cofactor and for catalysis.     

Coenzyme A-disulfide reductase from Staphylococcus aureus: evidence for asymmetric behavior on interaction with pyridine nucleotides

An unusual flavoprotein disulfide reductase, which catalyzes the NADPH-dependent reduction of CoASSCoA, has recently been purified from the human pathogen Staphylococcus aureus [delCardayré, S. B., Stock, K. P., Newton, G. L., Fahey, R. C., and Davies, J. E. (1998) J. Biol. Chem. 273, 5744-5751]. Coenzyme A-disulfide reductase (CoADR) lacks the redox-active protein disulfide characteristic of the disulfide reductases; instead, NADPH reduction yields 1 protein-SH and 1 CoASH. Furthermore, the CoADR sequence reveals the presence of a single putative active-site Cys (Cys43) within an SFXXC motif also seen in the Enterococcus faecalis NADH oxidase and NADH peroxidase, which use a single redox-active cysteine-sulfenic acid in catalysis. In this report, we provide a detailed examination of the equilibrium properties of both wild-type and C43S CoADRs, focusing on the role of Cys43 in the catalytic redox cycle, the behavior of both enzyme forms on reduction with dithionite and NADPH, and the interaction of NADP+ with the corresponding reduced enzyme species. The results of these analyses, combined with electrospray mass spectrometric data for the two oxidized enzyme forms, fully support the catalytic redox role proposed for Cys43 and confirm that this is the attachment site for bound CoASH. In addition, we provide evidence indicating dramatic thermodynamic inequivalence between the two active sites per dimer, similar to that documented for the related enzymes mercuric reductase and NADH oxidase; only 1 FAD is reduced with NADPH in wild-type CoADR. The EH2.NADPH/EH4.NADP+ complex which results is reoxidized quantitatively in titrations with CoASSCoA, supporting a possible role for the asymmetric reduced dimer in catalysis.     

Formation and properties of mixed disulfides between thioredoxin reductase from Escherichia coli and thioredoxin: evidence that cysteine-138 functions to initiate dithiol-disulfide interchange and to accept the reducing equivalent from reduced flavin.

Mutation of one of the cysteine residues in the redox active disulfide of thioredoxin reductase from Escherichia coli results in C135S with Cys138 remaining or C138S with Cys135 remaining. The expression system for the genes encoding thioredoxin reductase, wild-type enzyme, C135S, and C138S has been re-engineered to allow for greater yields of protein. Wild-type enzyme and C135S were found to be as previously reported, whereas discrepancies were detected in the characteristics of C138S. It was shown that the original C138S was a heterogeneous mixture containing C138S and wild-type enzyme and that enzyme obtained from the new expression system is the correct species. C138S obtained from the new expression system having 0.1% activity and 7% flavin fluorescence of wild-type enzyme was used in this study. Reductive titrations show that, as expected, only 1 mol of sodium dithionite/mol of FAD is required to reduce C138S. The remaining thiol in C135S and C138S has been reacted with 5,5'-dithiobis-(2-nitrobenzoic acid) to form mixed disulfides. The half time of the reaction was <5 s for Cys138 in C135S and approximately 300 s for Cys135 in C138S showing that Cys138 is much more reactive. The resulting mixed disulfides have been reacted with Cys32 in C35S mutant thioredoxin to form stable, covalent adducts C138S-C35S and C135S-C35S. The half times show that Cys138 is approximately fourfold more susceptible to attack by the nucleophile. These results suggest that Cys138 may be the thiol initiating dithiol-disulfide interchange between thioredoxin reductase and thioredoxin.     

Role of the covalent flavin linkage in monomeric sarcosine oxidase

Monomeric sarcosine oxidase (MSOX) is a prototypical member of a recently recognized family of amine-oxidizing enzymes that all contain covalently bound flavin. Mutation of the covalent flavin attachment site in MSOX produces a catalytically inactive apoprotein (apoCys315Ala) that forms an unstable complex with FAD (K(d) = 100 muM), similar to that observed with wild-type apoMSOX where the complex is formed as an intermediate during covalent flavin attachment. In situ reconstitution of sarcosine oxidase activity is achieved by assaying apoCys315Ala in the presence of FAD or 8-nor-8-chloroFAD, an analogue with an approximately 55 mV higher reduction potential. After correction for an estimated 65% reconstitutable apoprotein, the specific activity of apoCys315Ala in the presence of excess FAD or 8-nor-8-chloroFAD is 14% or 80%, respectively, of that observed with wild-type MSOX. Unlike oxidized flavin, apoCys315Ala exhibits a high affinity for reduced flavin, as judged by results obtained with reduced 5-deazaFAD (5-deazaFADH(2)) where the estimated binding stoichiometry is unaffected by dialysis. The Cys315Ala.5-deazaFADH(2) complex is also air-stable but is readily oxidized by sarcosine imine, a reaction accompanied by release of weakly bound oxidized 5-deazaFAD. The dramatic difference in the binding affinity of apoCys315Ala for oxidized and reduced flavin indicates that the protein environment must induce a sizable increase in the reduction potential of noncovalently bound flavin (DeltaE(m) approximately 120 mV). The covalent flavin linkage prevents loss of weakly bound oxidized FAD and also modulates the flavin reduction potential in conjunction with the protein environment.     

Analysis of the kinetic and redox properties of the NADH peroxidase R303M mutant: correlation with the crystal structure

The crystal structure of the flavoprotein NADH peroxidase shows that the Arg303 side chain forms a hydrogen bond with the active-site His10 imidazole and is therefore likely to influence the catalytic mechanism. Dithionite titration of an R303M mutant [E(FAD, Cys42-sulfenic acid)] yields a two-electron reduced intermediate (EH(2)) with enhanced flavin fluorescence and almost no charge-transfer absorbance at pH 7.0; the pK(a) for the nascent Cys42-SH is increased by over 3.5 units in comparison with the wild-type EH(2) pK(a) of Cys42-SOH. The crystal structure of the R303M peroxidase has been refined at 2.45 A resolution. In addition to eliminating the Arg303 interactions with His10 and Glu14, the mutant exhibits a significant change in the conformation of the Cys42-SOH side chain relative to FAD and His10 in particular. These and other results provide a detailed understanding of Arg303 and its role in the structure and mechanism of this unique flavoprotein peroxidase.     

FAD semiquinone stability regulates single- and two-electron reduction of quinones by Anabaena PCC7119 ferredoxin:NADP+ reductase and its Glu301Ala mutant

Flavoenzymes may reduce quinones in a single-electron, mixed single- and two-electron, and two-electron way. The mechanisms of two-electron reduction of quinones are insufficiently understood. To get an insight into the role of flavin semiquinone stability in the regulation of single- vs. two-electron reduction of quinones, we studied the reactions of wild type Anabaena ferredoxin:NADP(+)reductase (FNR) with 48% FAD semiquinone (FADH*) stabilized at the equilibrium (pH 7.0), and its Glu301Ala mutant (8% FADH* at the equilibrium). We found that Glu301Ala substitution does not change the quinone substrate specificity of FNR. However, it confers the mixed single- and two-electron mechanism of quinone reduction (50% single-electron flux), whereas the wild type FNR reduces quinones in a single-electron way. During the oxidation of fully reduced wild type FNR by tetramethyl-1,4-benzoquinone, the first electron transfer (formation of FADH*) is about 40 times faster than the second one (oxidation of FADH*). In contrast, the first and second electron transfer proceeded at similar rates in Glu301Ala FNR. Thus, the change in the quinone reduction mechanism may be explained by the relative increase in the rate of second electron transfer. This enabled us to propose the unified scheme of single-, two- and mixed single- and two-electron reduction of quinones by flavoenzymes with the central role of the stability of flavin/quinone ion-radical pair.     

Covalent flavinylation of monomeric sarcosine oxidase: identification of a residue essential for holoenzyme biosynthesis

FAD in monomeric sarcosine oxidase (MSOX) is covalently linked to the protein by a thioether linkage between its 8alpha-methyl group and Cys315. Covalent flavinylation of apoMSOX has been shown to proceed via an autocatalytic reaction that requires only FAD and is blocked by a mutation of Cys315. His45 and Arg49 are located just above the si-face of the flavin ring, near the site of covalent attachment. His45Ala and His45Asn mutants contain covalently bound FAD and exhibit catalytic properties similar to wild-type MSOX. The results rule out a significant role for His45 in covalent flavinylation or sarcosine oxidation. In contrast, Arg49Ala and Arg49Gln mutants are isolated as catalytically inactive apoproteins. ApoArg49Ala forms a stable noncovalent complex with reduced 5-deazaFAD that exhibits properties similar to those observed for the corresponding complex with apoCys315Ala. The results show that elimination of a basic residue at position 49 blocks covalent flavinylation but does not prevent noncovalent flavin binding. The Arg49Lys mutant contains covalently bound FAD, but its flavin content is approximately 4-fold lower than wild-type MSOX. However, most of the apoprotein in the Arg49Lys preparation is reconstitutable with FAD in a reaction that exhibits kinetic parameters similar to those observed for flavinylation of wild-type apoMSOX. Although covalent flavinylation is scarcely affected, the specific activity of the Arg49Lys mutant is only 4% of that observed with wild-type MSOX. The results show that a basic residue at position 49 is essential for covalent flavinylation of MSOX and suggest that Arg49 also plays an important role in sarcosine oxidation.     

Aspartate 120 of Escherichia coli methylenetetrahydrofolate reductase: evidence for major roles in folate binding and catalysis and a minor role in flavin reactivity

Escherichia coli methylenetetrahydrofolate reductase (MTHFR) catalyzes the NADH-linked reduction of 5,10-methylenetetrahydrofolate (CH(2)-H(4)folate) to 5-methyltetrahydrofolate (CH(3)-H(4)folate) using flavin adenine dinucleotide (FAD) as cofactor. MTHFR is unusual among flavin oxidoreductases because it contains a conserved, negatively rather than positively charged amino acid (aspartate 120) near the N1-C2=O position of the flavin. At this location, Asp 120 is expected to influence the redox properties of the enzyme-bound FAD. Modeling of the CH(3)-H(4)folate product into the enzyme active site suggests that Asp 120 may also play crucial roles in folate binding and catalysis. We have replaced Asp 120 with Asn, Ser, Ala, Val, and Lys and have characterized the mutant enzymes. Consistent with a loss of negative charge near the flavin, the midpoint potentials of the mutants increased from 17 to 30 mV. A small kinetic effect on the NADH reductive half-reaction was also observed as the mutants exhibited a 1.2-1.5-fold faster reduction rate than the wild-type enzyme. Catalytic efficiency (k(cat)/K(m)) in the CH(2)-H(4)folate oxidative half-reaction was decreased significantly (up to 70000-fold) and in a manner generally consistent with the negative charge density of position 120, supporting a major role for Asp 120 in electrostatic stabilization of the putative 5-iminium cation intermediate during catalysis. Asp 120 is also intimately involved in folate binding as increases in the apparent K(d) of up to 15-fold were obtained for the mutants. Examining the E(red) + CH(2)-H(4)folate reaction at 4 degrees C, we obtained, for the first time, evidence for the rapid formation of a reduced enzyme-folate complex with wild-type MTHFR. The more active Asp120Ala mutant, but not the severely impaired Asp120Lys mutant, demonstrated the species, suggesting a connection between the extent of complex formation and catalytic efficiency.     

Pleiotropic impact of a single lysine mutation on biosynthesis of and catalysis by N-methyltryptophan oxidase

N-Methyltryptophan oxidase (MTOX) contains covalently bound FAD. N-Methyltryptophan binds in a cavity above the re face of the flavin ring. Lys259 is located above the opposite, si face. Replacement of Lys259 with Gln, Ala, or Met blocks (>95%) covalent flavin incorporation in vivo. The mutant apoproteins can be reconstituted with FAD. Apparent turnover rates (k(cat,app)) of the reconstituted enzymes are ~2500-fold slower than those of wild-type MTOX. Wild-type MTOX forms a charge-transfer E(ox)·S complex with the redox-active anionic form of NMT. The E(ox)·S complex formed with Lys259Gln does not exhibit a charge-transfer band and is converted to a reduced enzyme·imine complex (EH(2)·P) at a rate 60-fold slower than that of wild-type MTOX. The mutant EH(2)·P complex contains the imine zwitterion and exhibits a charge-transfer band, a feature not observed with the wild-type EH(2)·P complex. Reaction of reduced Lys259Gln with oxygen is 2500-fold slower than that of reduced wild-type MTOX. The latter reaction is unaffected by the presence of bound product. Dissociation of the wild-type EH(2)·P complex is 80-fold slower than k(cat). The mutant EH(2)·P complex dissociates 15-fold faster than k(cat,app). Consequently, EH(2)·P and free EH(2) are the species that react with oxygen during turnover of the wild-type and mutant enzyme, respectively. The results show that (i) Lys259 is the site of oxygen activation in MTOX and also plays a role in holoenzyme biosynthesis and N-methyltryptophan oxidation and (ii) MTOX contains separate active sites for N-methyltryptophan oxidation and oxygen reduction on opposite faces of the flavin ring.     

Chromophore function and interaction in Escherichia coli DNA photolyase: reconstitution of the apoenzyme with pterin and/or flavin derivatives

Native DNA photolyase, as isolated from Escherichia coli, contains a neutral flavin radical (FADH.) plus a pterin chromophore (5,10-methenyltetrahydropteroylpolyglutamate) and can be converted to its physiologically significant form by reduction of FADH. to fully reduced flavin (FADH2) with dithionite or by photoreduction. Either FADH2 or the pterin chromophore in dithionite-reduced native enzyme can function as a sensitizer in catalysis. Various enzyme forms (EFADox, EFADH., EFADH2, EPteFADox, EPteFADH., EPteFADH2, EPte) containing stoichiometric amounts of FAD in either of its three oxidation states and/or 5,10-methenyltetrahydrofolate (Pte) have been prepared in reconstitution experiments. Studies with EFADox and EPte showed that these preparations retained the ability to bind the missing chromophore. The results suggest that there could be considerable flexibility in the biological assembly of holoenzyme since the order of binding of the enzyme's chromophores is apparently unimportant, the binding of FAD is unaffected by its redox state, and enzyme preparations containing only one chromophore are reasonably stable. The same catalytic properties are observed with dithionite-reduced native enzyme or EFADH2. These preparations do not exhibit a lag in catalytic assays whereas lags are observed with preparations containing FADox or FADH. in the presence or absence of pterin. Photochemical studies show that these lags can be attributed to enzyme activation under assay conditions in a reaction involving photoreduction of enzyme-bound FADox or FADH. to FADH2. EPte is catalytically inactive, but catalytic activity is restored upon reconstitution of EPte with FADox. The results show that pterin is not required for dimer repair when FADH2 acts as the sensitizer but that FADH2 is required when dimer repair is initiated by excitation of the pterin chromophore. The relative intensity of pterin fluorescence in EPte, EPteFADH., EPteFADox, or EPteFADH2 has been used to estimate the efficiency of pterin singlet quenching by FADH. (93%), FADox (90%), or FADH2 (58%). Energy transfer from the excited pterin to flavin is energetically feasible and may account for the observed quenching of pterin fluorescence and also explain why photoreduction of FADox or FADH. is accelerated by the pterin chromophore. An irreversible photobleaching of the pterin chromophore is accelerated by FADH2 in a reaction that is accompanied by a transient oxidation of FADH2 to FADH.. Both pterin bleaching and FADH2 oxidation are inhibited by substrate.     

Observation of an intermediate tryptophanyl radical in W306F mutant DNA photolyase from Escherichia coli supports electron hopping along the triple tryptophan chain

DNA photolyases repair UV-induced cyclobutane pyrimidine dimers in DNA by photoinduced electron transfer. The redox-active cofactor is FAD in its doubly reduced state FADH-. Typically, during enzyme purification, the flavin is oxidized to its singly reduced semiquinone state FADH degrees . The catalytically potent state FADH- can be reestablished by so-called photoactivation. Upon photoexcitation, the FADH degrees is reduced by an intrinsic amino acid, the tryptophan W306 in Escherichia coli photolyase, which is 15 A distant. Initially, it has been believed that the electron passes directly from W306 to excited FADH degrees , in line with a report that replacement of W306 with redox-inactive phenylalanine (W306F mutant) suppressed the electron transfer to the flavin [Li, Y. F., et al. (1991) Biochemistry 30, 6322-6329]. Later it was realized that two more tryptophans (W382 and W359) are located between the flavin and W306; they may mediate the electron transfer from W306 to the flavin either by the superexchange mechanism (where they would enhance the electronic coupling between the flavin and W306 without being oxidized at any time) or as real redox intermediates in a three-step electron hopping process (FADH degrees * <-- W382 <-- W359 <-- W306). Here we reinvestigate the W306F mutant photolyase by transient absorption spectroscopy. We demonstrate that electron transfer does occur upon excitation of FADH degrees and leads to the formation of FADH- and a deprotonated tryptophanyl radical, most likely W359 degrees. These photoproducts are formed in less than 10 ns and recombine to the dark state in approximately 1 micros. These results support the electron hopping mechanism.     

Communication between the active sites in dimeric mercuric ion reductase: an alternating sites hypothesis for catalysis

Mercuric reductase, a flavoprotein disulfide oxidoreductase, catalyzes the two-electron reduction of Hg(II) to Hg(0) by NADPH. As with all the members of this class of proteins, the enzyme is a dimer of identical subunits with two active sites per dimer, each composed of one FAD and catalytically essential residues from both subunits. In the enzyme from Tn501, these residues include, at a minimum, FAD and cysteines 135 and 140 from one subunit and cysteines 558' and 559' from the other. With this sort of active site arrangement, the enzyme seems perfectly set up for some type of subunit communication. In this report, we present results from several titrations, as well as kinetics studies, that, taken together, are consistent with the occurrence of subunit communication. In particular, the results indicate that pyridine nucleotide complexed dimers of the enzyme are asymmetric. Since the EH2-NADPH complex of the enzyme is the relevant reductant of Hg(II), these observations suggest that the enzyme may function asymmetrically during catalysis. An alternating sites model is proposed for the catalytic reduction of Hg(II), where both subunits of the dimer function in catalysis, but the steps are staggered and the subunits reverse roles after part of the reaction. An attractive feature of this proposal is that it provides a reasonable solution to the thermodynamic dilemma the enzyme faces in needing to both bind Hg(II) very tightly and reduce it.