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.     

FAD analogues as prosthetic groups of human glutathione reductase. Properties of the modified enzyme species and comparisons with the active site structure

Human glutathione reductase (NADPH + GSSG + H+ in equilibrium with NADP+ + 2 GSH) is a suitable enzyme for correlating spectroscopic properties and chemical reactivities of protein-bound FAD analogues with structural data. FAD, the prosthetic group of the enzyme, was replaced by FAD analogues, which were modified at the positions 8, 1, 2, 4, 5 and 6, respectively, of the isoalloxazine ring. When compared with a value of 100% for native glutathione reductase, the specific activities of most enzyme species ranged from 40% to 17%, in the order of the prosthetic groups 8-mercapto-FAD greater than 8-azido-FAD = 8-F-FAD = 8-C1-FAD greater than 4-thio-FAD = 1-deaza-FAD greater than 2-thio-FAD. The enzymic activities indicate a correct orientation of the bound analogues. The enzyme species containing 5-deaza-FAD and 6-OH-FAD, respectively, had no more glutathione reductase activity than the FAD-free apoenzyme. 5-Deaza-FAD X glutathione reductase was crystallized for X-ray diffraction analysis. Detailed studies were focussed on position 8 of the flavin. 8-Cl-FAD X glutathione reductase and 8-F-FAD X glutathione reductase reacted only poorly with HS- to give 8-mercapto-FAD X glutathione reductase, which suggests that the region around Val61 hinders the halogen anion from leaving the tetrahedral intermediate. Other experiments showed that position 8 is accessible to certain solvent-borne reagents. 8-Mercapto-FAD X glutathione reductase, for instance, reacted readily and stoichiometrically with the thiol reagent methylmethanethiosulfonate. 8-Mercapto-FAD X glutathione reductase does not exhibit a long wavelength charge transfer absorption band upon reduction, as it is the case for the 2-electron-reduced FAD-containing enzyme. This behaviour indicates that the charge transfer interaction between flavin and the thiolate of Cys63 in the native enzyme is not per se essential for catalysis. The absorption spectrum of the blue anionic 8-mercapto-FAD bound to glutathione reductase suggests that the protein concurs to the stabilization of a negative charge in the pyrimidine subnucleus. In light of the protein structure this effect is attributed to the dipole moment of alpha-helix 338-354 which starts out close to the N(1)/C(2)/O(2 alpha) region of the flavin. 1-Deaza-FAD binds as tightly as FAD to the apoenzyme. The resulting holoenzyme was found to be enzymically active but structurally unstable. In this respect 1-deaza-FAD . glutathione reductase mimics the properties of the enzyme species found in inborn glutathione reductase deficiency.(ABSTRACT TRUNCATED AT 400 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.     

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.     

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 redox-active disulfide in mercuric ion reductase: catalysis by mutant enzymes restricted to flavin redox chemistry

Mercuric reductase, a flavoenzyme that possess a redox-active cystine, Cys135Cys140, catalyzes the reduction of Hg(II) to Hg(0) by NADPH. As a probe of mechanism, we have constructed mutants lacking a redox-active disulfide by eliminating Cys135 (Ala135Cys140), Cys140 (Cys135Ala140), or both (Ala135Ala140). Additionally, we have made double mutants that lack Cys135 (Ala135Cys139Cys140) or Cys140 (Cys135Cys139Ala140) but introduce a new Cys in place of Gly139 with the aim of constructing dithiol pairs in the active site that do not form a redox-active disulfide. The resulting mutant enzymes all lack redox-active disulfides and are hence restricted to FAD/FADH2 redox chemistry. Each mutant enzyme possesses unique physical and spectroscopic properties that reflect subtle differences in the FAD microenvironment. These differences are manifested in a 23-nm range in enzyme-bound FAD lambda max values, an 80-nm range in thiolate to flavin charge-transfer absorbance maxima, and a ca. 100-mV range in FAD reduction potential. Preliminary evidence for the Ala135Cys139Cys140 mutant enzyme suggests that this protein forms a disulfide between the two adjacent Cys residues. Hg(II) titration experiments that correlate the extent of charge-transfer quenching with Hg(II) binding indicate that the Ala135Cys140 protein binds Hg(II) with substantially less avidity than does the wild-type enzyme. All mutant mercuric reductases catalyze transhydrogenation and oxygen reduction reactions through obligatory reduced flavin intermediates at rates comparable to or greater than that of the wild-type enzyme. For these activities, there is a linear correlation between log kappa cat and enzyme-bound FAD reduction potential. In a sensitive Hg(II)-mediated enzyme-bound FADH2 reoxidation assay, all mutant enzymes were able to undergo at least one catalytic event at rates 50-1000-fold slower than that of the wild-type enzyme. We have also observed the reduction of Hg(II) by free FADH2. In multiple-turnover assays which monitored the production of Hg(0), two of the mutant enzymes were observed to proceed through at least 30 turnovers at rates ca. 1000-fold slower than that of wild-type mercuric reductase. We conclude that the Cys135 and Cys140 thiols serve as Hg(II) ligands that orient the Hg(II) for subsequent reduction by a reduced flavin intermediate.     

Mechanism of flavin reduction in the class 1A dihydroorotate dehydrogenase from Lactococcus lactis

Dihydroorotate dehydrogenases (DHODs) oxidize dihydroorotate (DHO) to orotate (OA) using the FMN prosthetic group to abstract a hydride equivalent from C6 and a protein residue (cysteine for class 1A DHODs) to deprotonate C5. The fundamental question of whether the scission of the two DHO C-H bonds is concerted or stepwise was addressed for the class 1A enzyme from Lactococcus lactis by determining kinetic isotope effects (KIEs) on flavin reduction in anaerobic stopped-flow experiments. Isotope effects were determined at two pH values. At pH 7.0, KIEs were approximately 2-fold for DHO labeled singly at the 5-position or the 6-position and approximately 4-fold for DHO labeled at both the 5- and 6-positions. At pH 8.5, the KIEs observed for DHO labeled at the 5-position, the 6-position, and the 5- and 6-positions were approximately 2-, approximately 3-, and approximately 6-fold, respectively. These isotope effects are consistent with a concerted oxidation of DHO. The pH dependence of reduction was also determined, and a pKa of 8.3 was found. This pKa can be attributed to the ionization of the active site cysteine which deprotonates C5 of DHO during the reaction. To further investigate the importance of the active site base, two site-directed mutants were also studied: Cys130Ala (removal of the active site base) and Cys130Ser (replacement with the active site base used by class 2 DHODs). Both mutant enzymes exhibited binding affinities for DHO similar to that of the wild-type enzyme. Reduction of both mutants was extremely slow compared to that of the wild type; the rate of reduction increased with pH, showing no sign of a plateau. Interestingly, double-deuterium isotope effects on the Cys130Ser mutant also showed a concerted mechanism for flavin reduction.     

Reactivity of chicken liver xanthine dehydrogenase containing modified flavins

Native FAD was removed from chicken liver xanthine dehydrogenase (XDH) and replaced with a number of artificial flavins of different redox potential. Dithionite titration of the 2-thio-FAD- or 4-thio-FAD (high potential)-containing enzymes showed that the first center to be reduced was the flavin. With native enzyme, iron-sulfur centers are the first to be reduced. With the low potential flavin, 6-OH-FAD, the enzyme-bound flavin was the last center to be reduced in reductive titration with xanthine. These shifts in the reduction profile support the hypothesis that the distribution of reducing equivalents in multi-center oxidation-reduction enzymes of this type is determined by the relative potentials of the centers. The reaction of molecular oxygen with fully reduced 2-thio-FAD XDH or 4-thio-FAD XDH resulted in 5 electron eq being released in a fast phase and one in a slow phase. Reduction of these enzymes by xanthine was limited at a rate comparable to that for the release of urate from native XDH. Xanthine/O2 turnover with these enzymes (and native XDH) resulted in approximately 40-50% of the xanthine reducing equivalents appearing as superoxide. Steady state turnover experiments involving all modified flavin-containing enzymes, as well as native enzyme, showed that shifting the flavin potential either positive or negative relative to FAD caused a decrease in catalytic activity in the xanthine/NAD reductase reaction. In the case of the xanthine/O2 reductase activity, there is no simple obvious relationship between the activity and the redox potential of the reconstituted flavin.     

Role of cysteine residues in human NADH-cytochrome b5 reductase studied by site-directed mutagenesis. Cys-273 and Cys-283 are located close to the NADH-binding site but are not catalytically essential

Human NADH-cytochrome b5 reductase (EC 1.6.2.2) contains 4 cyteine residues (Cys-203, -273, -283, and -297). Cys-283 was previously proposed to be involved in NADH binding by chemical modification (Hackett, C. S., Novoa, W. B., Ozols, J., and Strittmatter, P. (1986) J. Biol. Chem. 261, 9854-9857). In the present study the role of cysteines in the enzyme was probed by replacing these residues by Ser, Ala, or Gly employing site-directed mutagenesis and chemical modification. Four mutants, in which 1 of the 4 Cys residues was replaced by Ser, retained comparable kcat and Km values to those of the wild type. All of these mutants were as sensitive as the wild type to treatment with SH modifiers, while a double mutant, C273S/C283S was resistant. Since inhibition by SH modifiers was protected by NADH, Cys-273 and Cys-283 were implicated to be close to the NADH-binding site. C273A and C273A/C283A mutants showed approximately one-fifth of the enzyme-FAD reduction rate of the wild type as revealed by steady-state kinetics and by stopped-flow analysis. Anaerobic titration has shown that reduction and re-oxidation processes including formation of the red semiquinone of these mutants were not significantly altered from those of the wild type. From these results it was concluded that none of the Cys residues of the enzyme are essential in the catalytic reaction, but Cys-273 conserved among the enzymes homologous to NADH-cytochrome b5 reductase homologous to NADH-cytochrome b5 reductase plays role(s) in facilitating the reaction. A difference spectrum with a peak at 317 nm, which was formerly considered to be derived from the interaction between NAD+ and Cys-283 of the reduced enzyme, appeared upon binding of NAD+ not only to the reduced wild type enzyme but also to the C273A/C283A mutant in which both of the Cys residues close to the NADH-binding site were replaced.     

The binding and spectral alterations of oxidized flavin mononucleotide by bacterial luciferase

The binding of oxidized flavin mononucleotide (FMN) to bacterial luciferase was studied by equilibrium dialysis. A Scatchard plot of the data indicates a single FMN binding site per luciferase molecule, with a dissociation constant of 2.4 × 10^?4 M at 2° in 0.05 M Bis-Tris, 0.2 M NaCl, pH 7.0. The visible absorbance spectrum of luciferase-bound FMN is altered considerably relative to the spectrum of free FMN. The spectrum of the bound flavin shows an apparent splitting of the 443-nm peak yielding well-defined maxima at 458 nm and 434 nm.     

Insight into the chemistry of flavin reduction and oxidation in Escherichia coli dihydroorotate dehydrogenase obtained by rapid reaction studies

Dihydroorotate dehydrogenase (DHOD) oxidizes dihydroorotate (DHO) to orotate in the only redox reaction of pyrimidine biosynthesis. The enzyme from Escherichia coli is a membrane-bound FMN-containing enzyme that is thought to use ubiquinone as the oxidizing substrate. The chemistry of the reduction of the flavin in DHOD from E. coli by the substrate dihydroorotate (DHO) was studied at 4 degrees C in anaerobic stopped-flow experiments conducted over a broad range of pH values. A Michaelis complex that was characterized by a approximately 20 nm red-shift of the oxidized flavin absorbance formed within the dead-time of the stopped-flow instrument ( approximately 1 ms) upon mixing with DHO. The flavin of the intermediate was reduced by DHO, forming a reduced flavin-orotate charge-transfer complex. The rate constant for the flavin reduction reaction increased with pH, from a value of 1 s(-1) at pH 6.5 to approximately 360 s(-1) at pH values greater than an observed pK(a) of 9.5 which was ascribed to Ser175, the active-site base. At all pH values, the reduced flavin-orotate charge-transfer complex dissociated too slowly to be catalytically relevant. Therefore, the oxidizing quinone substrate must bind to the reduced enzyme-orotate complex at a site distinct from the substrate binding site, in agreement with steady-state kinetic studies [Bj?rnberg, O., Grüner, A.-C., Roepstorff, P., and Jensen, K. F. (1999) Biochemistry 38, 2899-2908]. Menadione was used as a model quinone substrate to oxidize dithionite-reduced DHOD. The reduced enzyme-orotate complex reacted rapidly with menadione (180 s(-1)), demonstrating that the reduced enzyme-orotate complex is a catalytically competent intermediate.     

Exploring the conformational equilibrium of E. coli thioredoxin reductase: characterization of two catalytically important states by ultrafast flavin fluorescence spectroscopy

The conformational dynamics of wild-type Escherichia coli thioredoxin reductase (TrxR) and the mutant enzyme C138S were studied by ultrafast time-resolved fluorescence of the flavin cofactor in combination with circular dichroism (both in the flavin fingerprint and far-UV regions) and steady-state fluorescence and absorption spectroscopy. The spectroscopic data show two conformational states of the enzyme (named FO and FR), of which the physical characteristics differ considerably. Ultrafast fluorescence lifetime measurements make it possible to distinguish between the two different populations: Dominant picosecond lifetimes of approximately 1 ps (contribution 75%) and 7 ps (8%) are associated with the FO species in TrxR C138S. Long-lived fluorescence with two time constants in the range of 0.2-1 ns (total contribution 17%) originates from enzyme molecules in the FR conformation. The near absence of fast lifetime components in oxidized wild-type TrxR supports the idea of this enzyme being predominantly in the FR conformation. The emission spectrum of the FO conformation is blue-shifted with respect to that of the FR conformation. Because of the large difference in fluorescence characteristics, fluorescence measurements on time scales longer than 100 ps are fully determined by the fraction of enzyme molecules in the FR conformation. Binding of the thiol reagent phenyl mercuric acetate to wild-type enzyme and TrxR C138S stabilizes the enzymes in the FR conformation. Specific binding of the NADPH-analog, AADP(+), to the FR conformation resulted in dynamic fluorescence quenching in support of the multiple quenching sites model. Raising the temperature from 277K-323K resulted in a moderate shift to the FR conformation for TrxR C138S. High concentrations of the cosolvent glycerol triggered the domain rotation from the FO to the FR conformation.     

Release of flavin from the mitochondrial NADH-dehydrogenase complex

The conditions leading to the release of flavin mononucleotide from the NADH-dehydrogenase Complex I of the mitochondrial respiratory chain were studied. Upon incubation of a mitochondrial suspension for 1-4 h, a spontaneous release of flavin mononucleotide to the aqueous phase was observed. The release abruptly increased even at insignificant damage of mitochondria (by heating, very small quantities of detergents or washings, NaHCO3, and acidic or alkaline pH). This was detected by the enhancement in the intensity of flavin fluorescence and the degree of its depolarization. The loss of flavin mononucleotide leads to the loss of the NADH:ubiquinone reductase activity (but not the NADH: ferricyanide reductase activity). It is suggested that the loss of flavin mononucleotide from Complex I by the action of temperature, detergents, alkali and other agents can be a cause of many mitochondrial diseases.     

Active-site structural comparison of streptococcal NADH peroxidase and NADH oxidase. Reconstitution with artificial flavins.

The apoproteins of the streptococcal NADH peroxidase (H2O2----2H2O) and NADH oxidase (O2----2H2O) stabilize the neutral forms of 6-hydroxy- and 6-mercapto-FAD, respectively. The redox behavior of the 6-hydroxy-FAD peroxidase closely mimics that of the native enzyme with both dithionite and NADH. Both oxidase and peroxidase preferentially stabilize the N(1)-protonated p-quinonoid species of 8-mercapto-FAD, and the 8-position of the bound flavin is accessible to solvent in both proteins. The 8-mercapto-FAD peroxidase yields an EH2 spectrum on reduction virtually identical to that seen with 8-mercapto-FAD glutathione reductase, but no distinct EH2.NADH form appears. The dramatic decreases in reactivity at the flavin 2- and 4-positions for both the peroxidase and the oxidase, assessed with the reconstituted 2- and 4-thio-FAD enzymes, suggest that these positions are buried by elements of both protein structures. Furthermore, reconstitution of the peroxidase with the higher potential 2- and 4-thioflavins yields enzyme forms which are fully reducible with 1.4 eq of NADH/FAD, giving rise to stable thio-FADH2.NAD+ complexes. This behavior closely mimics that of the native NADH oxidase and provides further evidence supporting the hypothesis that a major functional distinction between the two structurally related proteins is determined by the redox potential and/or NADH reactivity of the bound flavin coenzyme.     

Alteration of the iron-sulfur cluster composition of Escherichia coli dimethyl sulfoxide reductase by site-directed mutagenesis.

We have used site-directed mutagenesis to alter the [Fe-S] cluster composition of Escherichia coli dimethyl sulfoxide (DMSO) reductase (DmsABC). The electron-transfer subunit (DmsB) of this enzyme contains 16 Cys residues arranged in 4 groups (I-IV) which provide ligands to 4 [4Fe-4S] clusters [Cammack, R., & Weiner, J. H. (1990) Biochemistry 29, 8410-8416]. Strong homologies exist between these Cys groups and the four Cys groups of the electron-transfer subunit (NarH) of E. coli nitrate reductase (NarGHJI), which contains a [3Fe-4S] cluster in addition to multiple [4Fe-4S] clusters. The Cys group primarily involved in providing ligands to the [3Fe-4S] cluster of NarH has a Trp residue at a position equivalent to Cys102 of DmsB. We have mutated Cys102 to Trp, Ser, Tyr, and Phe and have investigated the altered enzymes in terms of their enzymatic activities and EPR properties. The mutant enzymes do not support electron transfer from menaquinol to DMSO, although they retain high rates of electron transport from reduced benzyl viologen to DMSO. The mutations cause major changes in the EPR properties of the enzyme in the fully reduced and oxidized states. In the oxidized state, new species are observed in all the mutants; these have spectral features comprising a peak at g = 2.03 (gz) and a peak-trough at g = 2.00 (gxy). The temperature dependencies, microwave power dependencies, and spin quantitations of these species are consistent with the Trp102, Ser102, Phe102, and Tyr102 mutations causing conversion of one of the [4Fe-4S] clusters present in the wild-type enzyme into [3Fe-4S] clusters in the mutant enzymes.     

Kinetic mechanism and quaternary structure of Aminobacter aminovorans NADH:flavin oxidoreductase: an unusual flavin reductase with bound flavin

The homodimeric NADH:flavin oxidoreductase from Aminobacter aminovorans is an NADH-specific flavin reductase herein designated FRD(Aa). FRD(Aa) was characterized with respect to purification yields, thermal stability, isoelectric point, molar absorption coefficient, and effects of phosphate buffer strength and pH on activity. Evidence from this work favors the classification of FRD(Aa) as a flavin cofactor-utilizing class I flavin reductase. The isolated native FRD(Aa) contained about 0.5 bound riboflavin-5'-phosphate (FMN) per enzyme monomer, but one bound flavin cofactor per monomer was obtainable in the presence of excess FMN or riboflavin. In addition, FRD(Aa) holoenzyme also utilized FMN, riboflavin, or FAD as a substrate. Steady-state kinetic results of substrate titrations, dead-end inhibition by AMP and lumichrome, and product inhibition by NAD(+) indicated an ordered sequential mechanism with NADH as the first binding substrate and reduced FMN as the first leaving product. This is contrary to the ping-pong mechanism shown by other class I flavin reductases. The FMN bound to the native FRD(Aa) can be fully reduced by NADH and subsequently reoxidized by oxygen. No NADH binding was detected using 90 microM FRD(Aa) apoenzyme and 300 microM NADH. All results favor the interpretation that the bound FMN was a cofactor rather than a substrate. It is highly unusual that a flavin reductase using a sequential mechanism would require a flavin cofactor to facilitate redox exchange between NADH and a flavin substrate. FRD(Aa) exhibited a monomer-dimer equilibrium with a K(d) of 2.7 microM. Similarities and differences between FRD(Aa) and certain flavin reductases are discussed.     

Adduct formation between sulfite and the flavin of phototrophic bacterial flavocytochromes c. Kinetics of sequential bleach, recolor, and rebleach of flavin as a function of pH.

The kinetics of sulfite adduct formation with the bound flavin in flavocytochromes c from the purple phototrophic bacterium Chromatium vinosum and the green phototrophic bacterium Chlorobium thiosulfatophilum have been investigated as a function of pH. Both species of flavocytochrome c rapidly react with sulfite to form a flavin sulfite adduct (k = 10(3)-10(5) M-1 s-1) which is bleached at 450-475 nm and has associated charge-transfer absorbance at 660 nm. The rate constant for adduct formation in flavocytochrome c is 2-4 orders of magnitude faster than for model flavins of comparable redox potential and is likely to be due to a basic residue near the N-1 position of the flavin, which not only raises the redox potential but also stabilizes the negatively charged adduct. There is a pK for adduct formation at 6.5, which suggests that the order of magnitude larger rate constant at pH 5 as compared to pH 10 in flavocytochrome c is due the influence of another positive charge, possibly a protonated histidine residue. The adduct is indefinitely stable at pH 5 but decomposes (the flavin recolors) in a first-order process accelerating above pH 6 (at pH 10, k = 0.1 s-1). The pK for recoloring is 8.5, which is suggestive of a cysteine sulfhydryl. On the basis of the observed pK and available chemical information, we believe that recoloring is due to a secondary effect of the reaction of sulfite with a protein cystine disulfide, which is adjacent to the flavin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electron-transferring flavoprotein from pig kidney: flavin analogue studies

Apo-electron-transferring flavoprotein from pig kidney (apo-ETF) has been prepared by an acid ammonium sulfate procedure and reconstituted with FAD analogues to probe the flavin binding site. The 8-position of the bound flavin is accessible to solvent as judged by the reaction of 8-Cl-FAD-ETF with sodium sulfide and thiophenol. A series of 8-alkylmercapto-FAD analogues containing increasingly bulky substituents bind tightly to apo-ETF and can be reduced to the dihydroflavin level by octanoyl-CoA in the presence of catalytic levels of the medium-chain acyl-CoA dehydrogenase. Bulky substituents severely slow the rate of these interflavin electron-transfer reactions. In the case of the 8-cyclohexylmercapto derivative, this decrease reflects a sizable increase in the Km for ETF (approximately 14-fold) with only a 20% decrease in Vmax. Reduction of all of these 8-substituted derivatives involves the accumulation of ETF anion radical intermediates. Dihydro-5-deaza-FAD dehydrogenase, unlike the corresponding 1-deazaflavin substitution, is unable to reduce native ETF despite a strongly favorable redox potential difference. These results, together with data from the native proteins, are consistent with obligatory 1-electron transfer between dehydrogenase and ETF possibly involving the exposed dimethylbenzene edge of ETF. Irradiation of apo-ETF reconstituted with the photoaffinity analogue 8-azidoflavin leads to approximately 10% covalent incorporation of the flavin. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of apo-ETF labeled with tritiated 8-azido-FAD shows preferential labeling of the smaller subunit (88%, Mr 30,000 subunit; 12%, Mr 33,000 subunit).(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanism of flavin transfer and oxygen activation by the two-component flavoenzyme styrene monooxygenase

Styrene monooxygenase (SMO) from Pseudomonas putida S12 is a two-component flavoenzyme composed of the NADH-specific flavin reductase, SMOB, and FAD-specific styrene epoxidase, SMOA. Here, we report the cloning, and expression of native and histidine-tagged versions of SMOA and SMOB and studies of the flavin transfer and styrene oxygenation reactions. In the reductive half-reaction, SMOB catalyzes the two-electron reduction of FAD with a turnover number of 3200 s(-1). Single turnover studies of the reaction of reduced SMOA with substrates indicate the formation of a stable oxygen intermediate with the absorbance characteristics of a flavin hydroperoxide. Based on the results of numerical simulations of the steady-state mechanism of SMO, we find that the observed coupling of NADH and styrene oxidation can be best explained by a model, which includes both the direct transfer and passive diffusion of reduced FAD from SMOB to SMOA.     

Insight to pyrazinamide resistance inMycobacterium tuberculosisby molecular docking

Pyrazinamide (PZA) - an important drug in the anti-tuberculosis therapy, activated by an enzyme Pyrazinamidase (PZase). The basis of PZA resistance in Mycobacterium tuberculosis was owing to mutation in pncA gene coding for PZase. Homology modeling of PZase was performed using software Discovery Studio (DS) 2.0 based on the crystal structure of the PZase from Pyrococcus horikoshii (PDB code 1im5), in this study. The model comprises of one sheet with six parallel strands and seven helices with the amino acids Asp8, Asp49, Trp68, Lys96, Ala134, Thr135 and Cys138 at the active site. Five mutants were generated with Gly at position 8, Thr at position 96, Arg at position 104, Tyr and Ser at position 138. The Wild-type (WT) and five mutant models were docked with PZA. The results indicate that the mutants Lys96Thr, Ser104Arg Asp8Gly and Cys138Tyr may contribute to higher level drug resistance than Cys138Ser. These models provide the first in-silico evidence for the binding interaction of PZA with PZase and form the basis for rationalization of PZA resistance in naturally occurring pncA mutant strains of M. tuberculosis.