Flavin-linked peroxide reductases: protein-sulfenic acids and the oxidative stress response.

Sequence analyses of the Streptococcus faecalis NADH peroxidase and the flavoprotein component of the Salmonella typhimurium alkyl hydroperoxide reductase indicate clear evolutionary links with members of the flavoprotein disulfide reductase family. However, chemical and spectroscopic evidence demonstrate that the non-flavin redox center in NADH peroxidase is an unusual stabilized cysteine-sulfenic acid (Cys-SOH) derivative, and not a cystine disulfide as found in the disulfide reductases. This redox-active element, when appropriately stabilized by the respective protein environment, appears to play key roles in both the catalytic and regulatory aspects of the bacterial response to oxidative stress.

Structural, redox, and mechanistic parameters for cysteine-sulfenic acid function in catalysis and regulation.

A primary objective of this review is to facilitate the application of the chemical and structural approaches that are currently being employed in the identification of Cys-SOH, as both transient intermediates and stable redox forms, in biochemical systems where these derivatives are suspected of playing key roles in redox catalysis or regulation. These range from high-resolution crystallographic analyses benefiting from recent technological advances in rapid data collection at cryogenic temperatures to 13C NMR investigations of [3-(13)C]Cys-labeled proteins and chemical modification protocols that can be integrated with both UV-visible and fluorescence spectroscopic as well as mass spectrometric (especially ESI, MALDI-TOF, and even FT ion-cyclotron-resonance) analyses. In summarizing the diversity of biological functions currently identified with Cys-SH reversible Cys-SOH redox cycles (Fig. 17), it should also be [figure: see text] emphasized that in at least one protein (nitrile hydratase) stable Cys-SOH and Cys-SO2H derivatives play important structural roles while also modulating the electronic properties of the iron center; in neither case is the Cys-SOH residue itself involved in reduction and oxidation. The somewhat incomplete structural descriptions of the oxidized Cys forms involved in redox regulation of some transcription factors (e.g., BPV-1 E2 protein and activator protein-1) indicate that there is ample room for the application of the types of investigations employed, for example, with NADH peroxidase and the AhpC peroxiredoxin, with a view toward defining the potential roles of Cys-SOH in these very important contexts of intracellular redox signaling. These advances will also build on the recent progress in defining sulfenic acid stabilization and properties in small molecule model systems, as evidenced in the work of Okazaki, Goto, and others. When viewed in the perspective of Allison's 1976 review on the subject of sulfenic acids in proteins, the reader will hopefully come to appreciate the conclusion that the concept of protein-sulfenic acids has now become a very well-defined and established principle of biochemistry, with current efforts in this and other laboratories being directed to bring about still more detailed understanding of Cys-SOH function in both redox and nonredox modes of enzyme catalysis and regulation of protein function.

E. coli F1-ATPase: site-directed mutagenesis of the beta-subunit.

Residues beta Glu-181 and beta Glu-192 of E. coli F1-ATPase (the DCCD-reactive residues) were mutated to Gln. Purified beta Gln-181 F1 showed 7-fold impairment of 'unisite' Pi formation from ATP and a large decrease in affinity for ATP. Thus the beta-181 carboxyl group in normal F1 significantly contributes to catalytic site properties. Also, positive catalytic site cooperativity was attenuated from 5 X 10(4)- to 548-fold in beta Gln-181 F1. In contrast, purified beta Gln-192 F1 showed only 6-fold reduction in 'multisite' ATPase activity. Residues beta Gly-149 and beta Gly-154 were mutated to Ile singly and in combination. These mutations, affecting residues which are strongly conserved in nucleotide-binding proteins, were chosen to hinder conformational motion in a putative 'flexible loop' in beta-subunit. Impairment of purified F1-ATPase ranged from 5 to 61%, with the double mutant F1 less impaired than either single mutant. F1 preparations containing beta Ile-154 showed 2-fold activation after release from membranes, suggesting association with F0 restrained turnover on F1 in these mutants.

Structure of the nucleotide-binding domain in the beta-subunit of Escherichia coli F1-ATPase.

We propose a working model for the tertiary structure of the nucleotide-binding domain of the beta-subunit of E. coli F1-ATPase, derived from secondary structure prediction and from comparison of the amino acid sequence with the sequences of other nucleotide-binding proteins of known three-dimensional structure. The model is consistent with previously published results of specific chemical modification studies and of analyses of mutations in the beta-subunit and its implications for subunit interactions and catalytic mechanism in F1-ATPases are discussed.

Analysis of the kinetic and redox properties of NADH peroxidase C42S and C42A mutants lacking the cysteine-sulfenic acid redox center.

The flavoprotein NADH peroxidase from Enterococcus faecalis 10C1 has been shown to contain, in addition to FAD, an unusual cysteine-sulfenic acid (Cys-SOH) redox center. The non-flavin center cycles between reduced (Cys-SH) and oxidized (Cys-SOH) states, and the 2.16 A crystal structure of the non-native cysteine-sulfonic acid (Cys-SO3H) form of the wild-type peroxidase supports the proposed catalytic role of Cys42. In this study, we have employed a site-directed mutagenesis approach in which Cys42 is replaced with Ser and Ala, neither side chain of which is capable of redox activity. Reductive titrations of both C42S and C42A mutants lead directly to full FAD reduction with 1 equiv of either dithionite or NADH, consistent with elimination of the Cys-SOH center. Direct determinations of the redox potentials for the FAD/FADH2 couples yield values of -219 and -197 mV, respectively, for C42S and C42A peroxidases, indicating that the presence of Cys42-SH in the two-electron-reduced wild-type enzyme lowers the flavin potential by approximately 100 mV. Anaerobic stopped-flow analyses of the reduction of C42S and C42A peroxidases by NADH demonstrate that in both cases flavin reduction is rapid; these results are confirmed by enzyme-monitored, steady-state kinetic analyses which, in addition, give turnover numbers approximately 0.04% that of wild-type enzyme. These results are entirely consistent with the role proposed for Cys42 in the catalytic redox cycle of wild-type NADH peroxidase and indirectly support its function as a peroxidatic center in the homologous NADH oxidase.

Directed mutagenesis of the strongly conserved aspartate 242 in the beta-subunit of Escherichia coli proton-ATPase.

Oligonucleotide-directed mutagenesis was used to substitute Asn or Val for residue Asp-242 in the beta-subunit of Escherichia coli F1-ATPase. Asp-242 is strongly conserved in beta-subunits of F1-ATPase enzymes, in a region of sequence which shows homology with numerous nucleotide-binding proteins. By analogy with adenylate kinase (Fry, D.C., Kuby, S.A., and Mildvan, A.S. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 907-911), beta-Asp-242 of F1-ATPase might participate in catalysis through electrostatic effects on the substrate Mg2+ or through hydrogen bonding to the substrate(s); an acid-base catalytic role is also plausible. The substitutions Asn and Val were chosen to affect the charge, hydrogen-bonding ability, and hydrophobicity of residue beta-Asp-242. Both mutations significantly impaired oxidative phosphorylation rates in vivo and membrane ATPase and ATP-driven proton-pumping activities in vitro. Asn-242 was more detrimental than Val-242. Purified soluble mutant F1-ATPases had normal molecular size and subunit composition, and displayed 7% (beta-Asn-242) and 17% (beta-Val-242) of normal specific Mg-ATPase activity. The relative MgATPase activities of both mutant enzymes showed similar pH dependence to normal. Relative MgATPase and CaATPase activities of normal and mutant enzymes were compared at widely varied pMg and pCa. The mutations had little effect on KM MgATP, but KM CaATP was reduced. The data showed that the carboxyl side-chain of beta-Asp-242 is not involved in catalysis either as a general acid-base catalyst or through direct involvement in any protonation/deprotonation-linked mechanism, nor is it likely to be directly involved in liganding to substrate Mg2+ during the reaction. Specificity constants (kcat/KM) for MgATP and CaATP were reduced in both mutant enzymes, showing that the mutations destabilized interactions between the catalytic nucleotide-binding domain and the transition state.

Random mutagenesis of the gene for the beta-subunit of F1-ATPase from Escherichia coli.

ATP synthesis by oxidative phosphorylation in Escherichia coli occurs in catalytic sites on the beta-subunits of F1-ATPase. Random mutagenesis of the beta-subunit combined with phenotypic screening is potentially important for studies of the catalytic mechanism. However, when applied to haploid strains, this approach is hampered by a preponderance of mutants in which assembly of F1-ATPase in vivo is defective, precluding enzyme purification. Here we mutagenized plasmids carrying the uncD (beta-subunit) gene with hydroxylamine or N-methyl-N'-nitro-N-nitrosoguanidine and isolated, by phenotypic screening and complementation tests, six plasmids carrying mutant uncD alleles. When the mutant plasmids were used to transform a suitable uncD- strain, assembly of F1-ATPase in vivo occurred in each case. Moreover, in one case (beta Gly-223----Asp) F1-ATPase assembly proceeded although it had previously been reported that this mutation, when present on the chromosome of a haploid strain, prevented assembly of the enzyme in vivo. Therefore, this work demonstrates an improved approach for random mutagenesis of the F1-beta-subunit. Six new mutant uncD alleles were identified: beta Cys-137----Tyr; beta Gly-142----Asp; beta Gly-146----Ser; beta Gly-207----Asp; beta-Gly-223----Asp; and a double mutant beta Pro-403----Ser,Gly-415----Asp which we could not separate. The first five of these lie within or very close to the predicted catalytic nucleotide-binding domain of the beta-subunit. The double mutant lies outside this domain; we speculate that the region around residues beta 403-415 is part of an alpha-beta intersubunit contact surface. Membrane ATPase and ATP-driven proton pumping activities were impaired by all six mutations. Purified F1-ATPase was obtained from each mutant and shown to have impaired specific ATPase activity.

Kinetic characterization of the unisite catalytic pathway of seven beta-subunit mutant F1-ATPases from Escherichia coli.

We have studied the kinetics of "unisite" ATP hydrolysis and synthesis in seven mutant Escherichia coli F1-ATPase enzymes. The seven mutations are distributed over a 105-residue segment of the catalytic nucleotide-binding domain in beta-subunit and are: G142S, K155Q, K155E, E181Q, E192Q, M209I, and R246C. We report forward and reverse rate constants and equilibrium constants in all seven mutant enzymes for the four steps of unisite kinetics, namely (i) ATP binding/release, (ii) ATP hydrolysis/synthesis, (iii) Pi release/binding, and (iv) ADP release/binding. The seven mutant enzymes displayed a wide range of deviations from normal in both rate and equilibrium constants, with no discernible common pattern. Notably, steep reductions in Kd ATP were seen in some cases, the value of Kd Pi was high, and K2 (ATP hydrolysis/synthesis) was relatively unaffected. Significantly, when the data from the seven mutations were combined with previous data from two other E. coli F1-beta-subunit mutations (D242N, D242V), normal E. coli F1, soluble and membranous mitochondrial F1, it was found that linear free energy relationships obtained for both ATP binding/release (log k+1 versus log K1) and ADP binding/release (log k-4 versus log K-4). Two conclusions follow. 1) The seven mutations studied here cause subtle changes in interactions between the catalytic nucleotide-binding domain and substrate ATP or product ADP. 2) The mitochondrial, normal E. coli, and nine total beta-subunit mutant enzymes represent a continuum in which subtle structural differences in the catalytic site resulted in changes in binding energy; therefore insights into the nature of energy coupling during ATP hydrolysis and synthesis by F1-ATPase may be ascertained by detailed studies of this group of enzymes.

Adenosine triphosphatase and nucleotide binding activity of isolated beta-subunit preparations from Escherichia coli F1F0-ATP synthase.

Adenosine triphosphatase activity and nucleotide binding affinity of isolated beta-subunit preparations from Escherichia coli F1F0-ATP synthase were studied. The aim was to find out whether isolated beta-subunit would provide an experimental model in which effects of mutations on catalysis per se, unencumbered by complications due to their effects on positive catalytic cooperativity, could be studied. Three types of purified, isolated beta-subunit preparations were studied. Type I-beta was from a strain lacking all F1F0 subunits except beta and epsilon. Type II-beta was from F1 carrying the alpha S375F mutation which blocks positive catalytic cooperativity. Type III-beta was from normal F1. Type I- and II-beta had very low ATPase activity (less than 10(-4) s-1) which was azide-insensitive, aurovertin-insensitive, and unaffected by anti-beta antibody. Type I-beta activity was EDTA-insensitive. We conclude that isolated beta-subunit from E. coli F1F0 has zero or at most very low intrinsic ATPase activity. Type III-beta had low ATPase activity (8.4 x 10(-5) s-1 to 1.1 x 10(-3) s-1 in seven different preparations). This activity was aurovertin-sensitive, but varied in azide sensitivity from 0 to 34% inhibited. The azide-sensitive component, like F1 and alpha 3 beta 3 gamma oligomer, was inhibited by anti-beta and anti-alpha antibodies. The azide-insensitive component was stimulated by anti-beta and unaffected by anti-alpha. We show here that (alpha beta)-oligomer has ATPase activity which is azide-insensitive, aurovertin-sensitive, stimulated by anti-beta, and unaffected by anti-alpha. The intrinsic ATPase activity of Type III-beta could be due to contaminating (alpha beta)-oligomer plus alpha 3 beta 3 gamma-oligomer. Isolated beta had very low affinity for nucleotide as compared to the first catalytic site on F1. Taken together with the very low ATPase activity of isolated beta (even if real), the work shows that isolated beta is not a good experimental model of F1 catalysis.

Thermodynamic analyses of the catalytic pathway of F1-ATPase from Escherichia coli. Implications regarding the nature of energy coupling by F1-ATPases.

Thermodynamic properties of 12 different F1-ATPase enzymes were analyzed in order to gain insights into the catalytic mechanism and the nature of energy coupling to delta mu H+. The enzymes were normal soluble Escherichia coli F1, a group of nine beta-subunit mutant soluble E. coli F1 enzymes (G142S, K155Q, K155E, E181Q, E192Q, M209I, D242N, D242V, R246C), and both soluble and membrane-bound bovine heart mitochondrial F1. Unisite activity was studied by use of Gibbs free energy diagrams, difference energy diagrams, and derivation of linear free energy relationships. This allowed construction of binding energy diagrams for both the unisite ATP hydrolysis and ATP synthesis reaction pathways, which were in agreement. The binding energy diagrams showed that the step of Pi binding is a major energy-requiring step in ATP synthesis, as is the step of ATP release. It is suggested that there are two major catalytic enzyme conformations, and ATP- and an ADP-binding conformation. The effects of the mutations on the rate-limiting steps of multisite as compared to unisite activity were correlated, suggesting a direct link between the rate-limiting steps of the two types of activity. Multisite activity was analyzed by Arrhenius plots and by study of relative promotion from unisite to multisite rate. Changes in binding energy due to mutation were seen to have direct effects on multisite catalysis. From all the data, a model is derived to describe the mechanism of ATP synthesis. ATP hydrolysis, and energy coupling to delta mu H+ in F1F0-ATPases.

Directed mutagenesis of the dicyclohexylcarbodiimide-reactive carboxyl residues in beta-subunit of F1-ATPase of Escherichia coli.

Previous studies in which dicyclohexylcarbodiimide (DCCD) was used to inactivate F1-ATPase enzymes have suggested that two glutamate residues in the beta-subunit are essential for catalysis. In the Escherichia coli F1-ATPase, these are residues beta-Glu-181 and beta-Glu-192. Oligonucleotide-directed mutagenesis was used to change these residues to beta-Gln-181 and beta-Gln-192. The beta-Gln-181 mutation produced strong impairment of oxidative phosphorylation in vivo and also of ATPase and ATP-driven proton-pumping activities in membranes assayed in vitro. A low level of each activity was detected and an F1-ATPase appeared to be assembled normally on the membranes. Therefore, it is suggested that the carboxyl side chain at residue beta-181 is important, although not absolutely required, for catalysis in both directions on E. coli F1-ATPase. The beta-Gln-192 mutation produced partial inhibition of oxidative phosphorylation in vivo and membrane ATPase activity was reduced by 78%. These results contrast with the complete or near-complete inactivation seen when E. coli F1-ATPase is reacted with DCCD and imply that DCCD-inactivation is attributable more to the attachment of the bulky DCCD molecule than to the derivatization of the carboxyl side chain of residue beta-Glu-192. M. Ohtsubo and colleagues (Biochem. Biophys. Res. Commun. (1987) 146, 705-710) described mutagenesis of the F1-beta-subunit of thermophilic bacterium PS3. Mutations (Glu----Gln) of the residues homologous to Glu-181 and Glu-192 of E. coli F1-beta-subunit both caused total inhibition of ATPase activity. Therefore, there was a marked difference in results obtained when the same residues were modified in the PS3 and E. coli F1-beta-subunits.

A mutation in the alpha-subunit of F1-ATPase from Escherichia coli affects the binding of F1 to the membrane.

The mutation Gly-29----Asp in the alpha-subunit of the F1-ATPase from Escherichia coli was characterized and shown to cause the following effects. 1) Oxidative phosphorylation was markedly impaired in vivo 2) Membrane ATPase and ATP-driven proton-pumping activities were decreased markedly. 3) Membranes were proton-permeable, and membrane-bound ATPase was dicyclohexylcarbodiimide-insensitive. Therefore, it appeared that integration between F1 and F0 was abnormal. This was confirmed directly by the demonstration that the mutant F1 bound poorly to stripped membranes from a normal strain. Purified, soluble mutant F1 had normal ATPase activity. These results suggest that residue Gly-29, which is strongly conserved in alpha-subunits of F1-ATPases, lies in a region of the alpha-subunit important for membrane binding. Thus, three regions of the F1-alpha-subunit have now been recognized, specialized for membrane binding, nucleotide binding, and alpha/beta intersubunit signal transmission, respectively. The approximate locations of the three regions are described.

Directed mutations of the strongly conserved lysine 155 in the catalytic nucleotide-binding domain of beta-subunit of F1-ATPase from Escherichia coli.

The amino acid sequence -Gly-X-X-X-X-Gly-Lys- occurs in many, diverse, nucleotide-binding proteins, and there is evidence that it forms a flexible loop which interacts with one or other of the phosphate groups of bound nucleotide. This sequence occurs as -Gly-Gly-Ala-Gly-Val-Gly-Lys- in the beta-subunit of the enzyme F1-ATPase, where it is thought to form part of the catalytic nucleotide-binding domain. Mutants of Escherichia coli were generated in which residue beta-lysine 155, at the end of the above sequence, was replaced by glutamine or glutamate. Properties of the soluble purified F1-ATPase from each mutant were studied. The results showed: 1) replacement of lysine 155 by Gln or Glu decreased the steady-state rate of ATP hydrolysis by 80 and 66%, respectively. 2) Characteristics of ATP hydrolysis at a single site were not markedly changed in the mutant enzymes, implying that lysine 155 is not directly involved in bond cleavage during ATP hydrolysis or bond formation during ATP synthesis. 3) The binding affinity for MgATP was weakened considerably in the mutants (Lys much much greater than Gln greater than Glu), whereas the binding affinity for MgADP was affected only mildly (Lys = Gln greater than Glu), suggesting that lysine 155 interacts with the gamma-phosphate of ATP bound at a single high affinity catalytic site. 4) The major determinant of inhibition of steady-state ATPase turnover rate in the mutant enzymes was an attenuation of positive catalytic cooperativity. 5) The data are consistent with the idea that during multisite catalysis residue 155 of beta-subunit undergoes conformational movement which changes substrate and product binding affinities.

Protein-sulfenic acid stabilization and function in enzyme catalysis and gene regulation.

Sulfenic acids (R-SOH) result from the stoichiometric oxidations of thiols with mild oxidants such as H2O2; in solution, however, these derivatives accumulate only transiently due to rapid self-condensation reactions, further oxidations to the sulfinic and/or sulfonic acids, and reactions with nucleophiles such as R-SH. In contrast, oxidations of cysteinyl side chains in proteins, where disulfide bond formation can be prevented and where the reactivity of the nascent cysteine-sulfenic acid (Cys-SOH) can be controlled, have previously been shown to yield stable active-site Cys-SOH derivatives of papain and glyceraldehyde-3-phosphate dehydrogenase. More recently, however, functional Cys-SOH residues have been identified in the native oxidized forms of the FAD-containing NADH peroxidase and NADH oxidase from Streptococcus faecalis; these two proteins constitute a new class within the flavoprotein disulfide reductase family. In addition, Cys-SOH derivatives have been suggested to play important roles in redox regulation of the DNA-binding activities of transcription factors such as Fos and Jun, OxyR, and bovine papillomavirus type 1 E2 protein. Structural inferences for the stabilization of protein-sulfenic acids, drawn from the refined 2.16-A structure of the streptococcal NADH peroxidase, provide a molecular basis for understanding the proposed redox functions of these novel cofactors in both enzyme catalysis and transcriptional regulation.

The active-site histidine-10 of enterococcal NADH peroxidase is not essential for catalytic activity.

In order to test the proposal [Stehle, T., Claiborne, A., & Schulz, G. E. (1993) Eur. J. Biochem. 211, 221-226] that the active-site His10 of NADH peroxidase functions as an essential acid-base catalyst, we have analyzed mutants in which this residue has been replaced by Gln or Ala. The k(cat) values for both H10Q and H10A peroxidases, and the pH profile for k(cat) with H10Q, are very similar to those observed with wild-type peroxidase. Both mutants, however, exhibit K(m)(H2O2) values much higher (50-70-fold) than that for wild-type enzyme, and stopped-flow analysis of the H2O2 reactivity of two-electron reduced H10Q demonstrates that this difference is due to a 150-fold decrease in the second-order rate constant for this reaction with the mutant. Stopped-flow analyses also confirm that reduction of the enzyme by NADH is essentially unaffected by His10 replacement and remains largely rate-limiting in turnover; the formation of an E.NADH intermediate in the conversion of E-->EH2 is confirmed by diode-array spectral analyses with H10A. Both H10Q and H10A mutants, in their oxidized E(FAD, Cys42-sulfenic acid) forms, exhibit enhanced long-wavelength absorbance bands (lambda(max) = 650 nm and 550 nm, respectively), which most likely reflect perturbations in a charge-transfer interaction between the Cys42-sulfenic acid and FAD. Combined with the 50-fold increase in the second-order rate constant for H2O2 inactivation (via Cys42-sulfenic acid oxidation) of the H10Q mutant, these observations support the proposal that His10 functions in part to stabilize the unusual Cys42-sulfenic acid redox center within the active-site environment.

Directed mutagenesis of the beta-subunit of F1-ATPase from Escherichia coli.

Oligonucleotide-directed mutagenesis was used to generate six mutant strains of Escherichia coli which had the following specific amino acid substitutions in the beta-subunit of F1-ATPase: (i) Lys-155----Gln; (ii) Lys-155----Glu; (iii) Gly-149----Ile; (iv) Gly-154----Ile; (v) Tyr-297----Phe;(vi) Tyr-354----Phe. The effects of each mutation on growth of cells on succinate plates or limiting (3 mM) glucose and on cell membrane ATPase activity and ATP-driven pH gradient formation were studied. The results showed Lys-155 to be essential for catalysis, as has been predicted previously from sequence homology and structural considerations; however, the results appear to contradict the hypothesis that Lys-155 interacts with one of the substrate phosphate groups because the Lys-155----Glu mutation was less detrimental than Lys-155----Gln. Gly-149 and Gly-154 have been predicted to be involved in essential conformational changes in F1-ATPase by virtue of their position in a putative glycine-rich flexible loop structure. The mutation of Gly-154----Ile caused strong impairment of catalysis, but the Gly-149----Ile mutation produced only moderate impairment. The two tyrosine residues chosen for mutation were residues which have previously received much attention due to their being the sites of reaction of the inactivating chemical modification reagents 4-chloro-7-nitrobenzofurazan (Tyr-297) and p-fluorosulfonylbenzoyl-5'-adenosine (Tyr-354). We found that mutation of Tyr-297----Phe caused only minor impairment of catalysis, and mutation of Tyr-354----Phe produced no impairment. Therefore, a direct role for either of these tyrosine residues in catalysis is unlikely.

Limited proteolysis as a structural probe of the soluble alpha-glycerophosphate oxidase from Streptococcus sp.

As reported previously [Parsonage, D., Luba, J., Mallett, T. C., and Claiborne, A. (1998) J. Biol. Chem. 273, 23812-23822], the flavoprotein alpha-glycerophosphate oxidases (GlpOs) from a number of enterococcal and streptococcal sources contain a conserved 50-52 residue insert that is completely absent in the homologous alpha-glycerophosphate dehydrogenases. On limited proteolysis with trypsin, the GlpO from Streptococcus sp. (m = 67.6 kDa) is readily converted to two major fragments corresponding to masses of approximately 40 and 23 kDa. The combined application of sequence and mass spectrometric analyses demonstrates that the 40-kDa fragment represents the N-terminus of intact GlpO (Met1-Lys368; 40.5 kDa), while the 23-kDa band represents a C-terminal fragment (Ala405-Lys607; 22.9 kDa). Hence, limited proteolysis in effect excises most of the GlpO insert (Ser355-Lys404), indicating that this represents a flexible region on the protein surface. The active-site and other spectroscopic properties of the enzyme, including both flavin and tryptophan fluorescence spectra, titration behavior with both dithionite and sulfite, and preferential binding of the anionic form of the oxidized flavin, were largely unaffected by proteolysis. Enzyme-monitored turnover analyses of the intact and nicked streptococcal GlpOs (at [GlpO] approximately 10 microM) demonstrate that the single major catalytic defect in the nicked enzyme corresponds to a 20-fold increase in K(m)(Glp); the basis for this altered kinetic behavior is derived from an 8-fold decrease in the second-order rate constant for reduction of the nicked enzyme, as measured in anaerobic stopped-flow experiments. These results indicate that the flexible surface region represented by elements of the GlpO insert plays an important role in mediating efficient flavin reduction.

The soluble alpha-glycerophosphate oxidase from Enterococcus casseliflavus. Sequence homology with the membrane-associated dehydrogenase and kinetic analysis of the recombinant enzyme.

The soluble flavoprotein alpha-glycerophosphate oxidase from Enterococcus casseliflavus catalyzes the oxidation of a "non-activated" secondary alcohol, in contrast to the flavin-dependent alpha-hydroxy- and alpha-amino acid oxidases. Surprisingly, the alpha-glycerophosphate oxidase sequence is 43% identical to that of the membrane-associated alpha-glycerophosphate dehydrogenase from Bacillus subtilis; only low levels of identity (17-22%) result from comparisons with other FAD-dependent oxidases. The recombinant alpha-glycerophosphate oxidase is fully active and stabilizes a flavin N(5)-sulfite adduct, but only small amounts of intermediate flavin semiquinone are observed during reductive titrations. Direct determination of the redox potential for the FAD/FADH2 couple yields a value of -118 mV; the protein environment raises the flavin potential by 100 mV in order to provide for a productive interaction with the reducing substrate. Steady-state kinetic analysis, using the enzyme-monitored turnover method, indicates that a ping-pong mechanism applies and also allows the determination of the corresponding kinetic constants. In addition, stopped-flow studies of the reductive half-reaction provide for the measurement of the dissociation constant for the enzyme. alpha-glycerophosphate complex and the rate constant for reduction of the enzyme flavin. These and other results demonstrate that this enzyme offers a very promising paradigm for examining the protein determinants for flavin reactivity and mechanism in the energy-yielding metabolism of alpha-glycerophosphate.

Purification and analysis of streptococcal NADH peroxidase expressed in Escherichia coli.

Using the T7 RNA polymerase expression system, a modified plasmid vector has been developed which gives reliable, high level expression in Escherichia coli of the gene encoding streptococcal NADH peroxidase. The recombinant enzyme has been purified to homogeneity using a revised protocol which yields over 35 mg of pure protein per liter of culture. Recombinant NADH peroxidase is fully active and exhibits spectroscopic and redox properties identical to those for the enzyme purified from Streptococcus faecalis 10C1. Reductive titrations and thiol analyses confirm the presence of the unusual cysteine-sulfenic acid (Cys-SOH) redox center identified previously. N-terminal sequence analysis, analytical gel filtration, and preliminary x-ray diffraction data all confirm the structural identity of the recombinant and S. faecalis enzymes. Steady-state kinetic analysis of the peroxidase, coupled with results from static titration experiments is consistent with a limiting type of ternary complex mechanism and allows the determination of many of the corresponding kinetic constants. In addition, preliminary 1H NMR spectra of the enzyme at millimolar concentrations show good dispersion in the amide region and indicate that the recombinant peroxidase is suitable for one-dimensional NMR work with labeled amino acids.

Equilibrium analyses of the active-site asymmetry in enterococcal NADH oxidase: role of the cysteine-sulfenic acid redox center.

Recent studies [Mallett, T. C., and Claiborne, A. (1998) Biochemistry 37, 8790-8802] of the O2 reactivity of C42S NADH oxidase (O2 --> H2O2) revealed an asymmetric mechanism in which the two FADH2.NAD+ per reduced dimer display kinetic inequivalence. In this report we provide evidence indicating that the fully active, recombinant wild-type oxidase (O2 --> 2H2O) displays thermodynamic inequivalence between the two active sites per dimer. Using NADPH to generate the free reduced wild-type enzyme (EH2'/EH4), we have shown that NAD+ titrations lead to differential behavior as only one FADH2 per dimer binds NAD+ tightly to give the charge-transfer complex. The second FADH2, in contrast, transfers its electrons to the single Cys42-sulfenic acid (Cys42-SOH) redox center, which remains oxidized during the reductive titration. Titrations of the reduced NADH oxidase with oxidized 3-acetylpyridine and 3-aminopyridine adenine dinucleotides further support the conclusion that the two FADH2 per dimer in wild-type enzyme can be described as distinct "charge-transfer" and "electron-transfer" sites, with the latter site giving rise to either intramolecular (Cys42-SOH) or bimolecular (pyridine nucleotide) reduction. The reduced C42S mutant is not capable of intramolecular electron transfer on binding pyridine nucleotides, thus confirming that the Cys42-SOH center is in fact the source of the redox asymmetry observed with wild-type oxidase. These observations on the role of Cys42-SOH in the expression of thermodynamic inequivalence as observed in wild-type NADH oxidase complement the previously described kinetic inequivalence of the C42S mutant; taken together, these results provide the overlapping framework for an alternating sites cooperativity model of oxidase action.