Protein dynamics control proton transfers to the substrate on the His72Asn mutant of p-hydroxybenzoate hydroxylase

p-Hydroxybenzoate hydroxylase (PHBH) hydroxylates activated benzoates using NADPH as a reductant and O(2) as an oxygenating substrate. Because the flavin, when reduced, will quickly react with oxygen in either the presence or absence of a phenolic substrate, it is important to regulate flavin reduction to prevent the uncontrolled reaction of NADPH and oxygen to form H(2)O(2). Reduction is controlled by the protonation state of the aromatic substrate p-hydroxybenzoate (pOHB), which when ionized to the phenolate facilitates the movement of flavin between two conformations, termed "in" and "out". When the hydrogen bond network that provides communication between the substrate and solvent is disrupted by changing its terminal residue, His72, to Asn, protons from solution no longer equilibrate rapidly with pOHB bound to the active site [Palfey, B. A., Moran, G. R., Entsch, B., Ballou, D. P., and Massey, V. (1999) Biochemistry 38, 1153-1158]. Thus, one population of the His72Asn enzyme reduces rapidly and has the phenolate form of pOHB bound at the active site and the flavin in the out conformation. The remaining population of the His72Asn enzyme reduces slowly and has the phenolic form of pOHB bound and the flavin in the in conformation. We have investigated the mechanisms of proton transfer between solvent and pOHB bound to the His72Asn form of the enzyme by double-mixing and single-mixing stopped-flow experiments. We find that, depending on the initial ionization state of bound pOHB and the new pH of the solution, the ionization/protonation of pOHB proceeds through the direct reaction of hydronium or hydroxide with the enzyme-ligand complex and leads to the conversion of one flavin conformation to the other. Our kinetic data indicate that the enzyme with the flavin in the in conformation reacts in two steps. Inspection of crystal structures suggests that the hydroxide ion would react at the re-face of the flavin, and its reaction with pOHB is limited by the movement of Pro293, a conserved residue in similar flavoprotein hydroxylases. We hypothesize that this type of breathing mode by the protein may have been used to compensate for the lack of an efficient proton-transfer network in ancestral hydroxylases, permitting useful catalysis prior to the emergence of specialized proton-transfer mechanisms.     

Kinetics of proton-linked flavin conformational changes in p-hydroxybenzoate hydroxylase

p-Hydroxybenzoate hydroxylase (PHBH) is an FAD-dependent monooxygenase that catalyzes the hydroxylation of p-hydroxybenzoate (pOHB) to 3,4-dihydroxybenzoate in an NADPH-dependent reaction. Two structural features are coupled to control the reactivity of PHBH with NADPH: a proton-transfer network that allows protons to be passed between the sequestered active site and solvent and a flavin that adopts two positions: "in", where the flavin is near pOHB, and "out", where the flavin is near NADPH. PHBH uses the proton-transfer network to test for the presence of a suitable aromatic substrate before allowing the flavin to adopt the NADPH-accessible conformation. In this work, kinetic analysis of the His72Asn mutant, with a disrupted proton-transfer network, showed that flavin movement could occur in the presence or absence of NADPH but that NADPH stimulated movement to the reactive conformation required for hydride transfer. Substrate and solvent isotope effects on the transient kinetics of reduction of the His72Asn mutant showed that proton transfer was linked to flavin movement and that the conformational change occurred in a step separate from that of hydride transfer. Proton transfers during the reductive half-reaction were observed directly in the wild-type enzyme by performing experiments in the presence of a fluorescent pH-indicator dye in unbuffered solutions. NADPH binding caused rapid proton release from the enzyme, followed by proton uptake after flavin reduction. Solvent and substrate kinetic isotope effects showed that proton-coupled flavin movement and reduction also occurred in different steps in wild-type PHBH. These results allow a detailed kinetic scheme to be proposed for the reductive half-reaction of the wild-type enzyme. Three kinetic models considered for substrate-induced isomerization are analyzed in the Appendix.     

Mechanistic insights into p-hydroxybenzoate hydroxylase from studies of the mutant Ser212Ala.

In the crystal structure of native p-hydroxybenzoate hydroxylase, Ser212 is within hydrogen bonding distance (2.7 A) of one of the carboxylic oxygens of p-hydroxybenzoate. In this study, we have mutated residue 212 to alanine to study the importance of the serine hydrogen bond to enzyme function. Comparisons between mutant and wild type (WT) enzymes with the natural substrate p-hydroxybenzoate showed that this residue contributes to substrate binding. The dissociation constant for this substrate is 1 order of magnitude higher than that of WT, but the catalytic process is otherwise unchanged. When the alternate substrate, 2,4-dihydroxybenzoate, is used, two products are formed (2,3,4-trihydroxybenzoate and 2,4, 5-trihydroxybenzoate), which demonstrates that this substrate can be bound in two orientations. Kinetic studies provide evidence that the intermediate with a high extinction coefficient previously observed in the oxidative half-reaction of the WT enzyme with this substrate is composed of contributions from both the dienone form of the product and the C4a-hydroxyflavin. During the reduction of the enzyme-2,4-dihydroxybenzoate complex by NADPH with 2, 4-dihydroxybenzoate, a rapid transient increase in flavin absorbance is observed prior to hydride transfer from NADPH to FAD. This is direct evidence for movement of the flavin before reduction occurs.     

A rate-limiting conformational change of the flavin in p-hydroxybenzoate hydroxylase is necessary for ligand exchange and catalysis: studies with 8-mercapto- and 8-hydroxy-flavins

The FAD of p-hydroxybenzoate hydroxylase (PHBH) is known to exist in two conformations. The FAD must be in the in-position for hydroxylation of p-hydroxybenzoate (pOHB), whereas the out-position is essential for reduction of the flavin by NADPH. In these investigations, we have used 8-mercapto-FAD and 8-hydroxy-FAD to probe the movement of the flavin in catalysis. Under the conditions employed, 8-mercapto-FAD (pK(a) = 3.8) and 8-hydroxy-FAD (pK(a) = 4.8) are mainly anionic. The spectral characteristics of the anionic forms of these flavins are very sensitive to their environment, making them sensitive probes for detecting movement of the flavin during catalysis. With these flavin analogues, the enzyme hydroxylates pOHB efficiently, but at a rate much slower than that of enzyme with FAD. Reaction of oxygen with reduced forms of these modified enzymes in the absence of substrate appears to proceed through the formation of the flavin-C4a-hydroperoxide intermediate, as with normal enzyme, but the decay of this intermediate is so fast compared to its formation that very little accumulates during the reaction. However, after elimination of H2O2 from the flavin-C4a-hydroperoxide, a perturbed oxidized enzyme spectrum is observed (Eox*), and this converts slowly to the spectrum of the resting oxidized form of the enzyme (Eox). In the presence of pOHB, PHBH reconstituted with 8-mercapto-FAD also shows the additional oxidized intermediate (Eox*) after the usual oxygenated C4a-intermediates have formed and decayed in the course of the hydroxylation reaction. This Eox* to Eox step is postulated to be due to flavin movement. Furthermore, binding of pOHB to resting (Eox) follows a three-step equilibrium mechanism that is also consistent with flavin movement being the rate-limiting step. The rate for the slowest step during pOHB binding is similar to that observed for the conversion of Eox* to Eox during the oxygen reaction in the absence or presence of substrate. Steady-state kinetic analysis of PHBH substituted with 8-mercapto-FAD demonstrated that the apparent k(cat) is also similar to the rate of Eox* conversion to Eox. Presumably, the protein environment surrounding the flavin in Eox* differs slightly from that of the final resting form of the enzyme (Eox).     

Properties of p-hydroxybenzoate hydroxylase when stabilized in its open conformation

p-Hydroxybenzoate hydroxylase is extensively studied as a model for single-component flavoprotein monooxygenases. It catalyzes a reaction in two parts: (1) reduction of the FAD in the enzyme by NADPH in response to binding of p-hydroxybenzoate to the enzyme and (2) oxidation of reduced FAD with oxygen in an environment free from solvent to form a hydroperoxide, which then reacts with p-hydroxybenzoate to form an oxygenated product. These different reactions are coordinated through conformational rearrangements of the protein and the isoalloxazine ring during catalysis. Until recently, it has not been clear how p-hydroxybenzoate gains access to the buried active site. In 2002, a structure of a mutant form of the enzyme without substrate was published that showed an open conformation with solvent access to the active site [Wang, J., Ortiz-Maldonado, M., Entsch, B., Massey, V., Ballou, D., and Gatti, D. L. (2002) Proc. Natl. Acad. Sci. U.S.A. 99, 608-613]. The wild-type enzyme does not form high-resolution crystals without substrate. We hypothesized that the wild-type enzyme without substrate also forms an open conformation for binding p-hydroxybenzoate, but only transiently. To test this idea, we have studied the properties of two different mutant forms of the enzyme that are stabilized in the open conformation. These mutant enzymes bind p-hydroxybenzoate very fast, but with very low affinity, as expected from the open structure. The mutant enzymes are extremely inactive, but are capable of slowly forming small amounts of product by the normal catalytic pathway. The lack of activity results from the failure of the mutants to readily form the out conformation required for flavin reduction by NADPH. The mutants form a large fraction of an abnormal conformation of the reduced enzyme with p-hydroxybenzoate bound. This conformation of the enzyme is unreactive with oxygen. We conclude that transient formation of this open conformation is the mechanism for sequestering p-hydroxybenzoate to initiate catalysis. This overall study emphasizes the role that protein dynamics can play in enzymatic catalysis.     

Using Raman spectroscopy to monitor the solvent-exposed and "buried" forms of flavin in p-hydroxybenzoate hydroxylase

X-ray crystallographic studies of several complexes involving FAD bound to p-hydroxybenzoate hydroxylase (PHBH) have revealed that the isoalloxazine ring system of FAD is capable of adopting in two positions on the protein. In one, the "in" form, the ring is surrounded by protein groups and has little contact with solvent; in the second, "out" form, the ring is largely solvent exposed. Using Raman difference spectroscopy, it has been possible to obtain Raman spectra for the flavin ring in both conformational states for different complexes in solution. The spectra consist of a rich assortment of isoalloxazine ring modes whose normal mode origin can be assigned by using density functional theory and ab initio calculations. Further insight into the sensitivity of these modes to changes in environment is provided by the Raman spectra of lumiflavin in the solid state, in DMSO and in aqueous solution. For the protein complexes, the Raman difference spectra of flavin bound to wt PHBH and wt PHBH plus substrate, p-hydroxybenzoate, provided examples of the "in" conformation. These data are compared to those for flavin bound to wt PHBH plus 2,4-dihydroxybenzoate, where X-ray analysis show that the flavin is "out". There are several spectral regions where characteristic differences exist for flavin in the "in" or "out" conformation, these occur near 1700, 1500, 1410, 1350, 1235, and 1145 cm(-)(1). These spectral features can be used as empirical marker bands to determine the populations of "in" and "out" for any complex of PHBH and to monitor changes in those populations with perturbations to the system, e.g., by changing temperature or pH. Thus, it will now be possible to determine the conformational state of the flavin in PHBH for those complexes that have resisted X-ray crystallographic analysis. Raman difference data are also presented for the Tyr222Phe mutant. The Raman data show that the isoalloxazine ring is predominantly "out" for Tyr222Phe. However, in the presence of the substrate p-hydroxybenzoate there is clear evidence from the Raman marker bands that a mixed population of "in" and "out" exists with the majority being in the "out" state. This is consistent with the conclusions drawn from crystallographic studies on this complex (Gatti, D. L., Palfey, B. A., Lah, M. S., Entsch, B., Massey, V., Ballou, D. P., and Ludwig, M. L. (1994) Science, 266, 110-114).     

Crystal structure of p-hydroxybenzoate hydroxylase reconstituted with the modified FAD present in alcohol oxidase from methylotrophic yeasts: evidence for an arabinoflavin.

The flavin prosthetic group (FAD) of p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens was replaced by a stereochemical analog, which is spontaneously formed from natural FAD in alcohol oxidases from methylotrophic yeasts. Reconstitution of p-hydroxybenzoate hydroxylase from apoprotein and modified FAD is a rapid process complete within seconds. Crystals of the enzyme-substrate complex of modified FAD-containing p-hydroxybenzoate hydroxylase diffract to 2.1 A resolution. The crystal structure provides direct evidence for the presence of an arabityl sugar chain in the modified form of FAD. The isoalloxazine ring of the arabinoflavin adenine dinucleotide (a-FAD) is located in a cleft outside the active site as recently observed in several other p-hydroxybenzoate hydroxylase complexes. Like the native enzyme, a-FAD-containing p-hydroxybenzoate hydroxylase preferentially binds the phenolate form of the substrate (pKo = 7.2). The substrate acts as an effector highly stimulating the rate of enzyme reduction by NADPH (kred > 500 s-1). The oxidative part of the catalytic cycle of a-FAD-containing p-hydroxybenzoate hydroxylase differs from native enzyme. Partial uncoupling of hydroxylation results in the formation of about 0.3 mol of 3,4-dihydroxybenzoate and 0.7 mol of hydrogen peroxide per mol NADPH oxidized. It is proposed that flavin motion in p-hydroxybenzoate hydroxylase is important for efficient reduction and that the flavin "out" conformation is associated with the oxidase activity.     

Reaction of 2-thio-FAD-reconstituted p-hydroxybenzoate hydroxylase with hydrogen peroxide. Formation of a covalent flavin-protein linkage

Hydrogen peroxide reacts with 2-thio-FAD-reconstituted p-hydroxybenzoate hydroxylase to yield a long wavelength intermediate (lambda max = 360, 620 nm) which can be isolated in stable form on removal of excess H2O2. The blue flavin derivative slowly decays in a second peroxide-dependent reaction to yield a new flavin product lacking long wavelength absorbance (lambda max = 408, 472 nm). This final peroxide-modified enzyme binds p-hydroxybenzoate with a 10-fold lower affinity than does the native enzyme; furthermore, substrate binding leads to the inhibition of enzyme reduction by NADPH. Trichloroacetic acid treatment of the final peroxide-modified enzyme results in the quantitative conversion of the bound flavin to free FAD. However, gel filtration of the modified enzyme in guanidine hydrochloride at neutral pH leads to the co-elution of protein and modified flavin. The nondenatured peroxide product reacts rapidly with hydroxylamine to yield 2-NHOH-substituted FAD. These observations indicate that the secondary reaction of peroxide with the blue intermediate from 2-thio-FAD p-hydroxybenzoate hydroxylase results in the formation of an acid-labile covalent flavin-protein linkage within the enzyme active site, involving the flavin C-2 position.     

Role of protein flexibility in the catalytic cycle of p-hydroxybenzoate hydroxylase elucidated by the Pro293Ser mutant

Proline 293 of p-hydroxybenzoate hydroxylase from Pseudomonas aeruginosa is in a highly conserved region of the flavoprotein aromatic hydroxylases. It is thought to impart rigidity to the backbone, as it partially cradles the FAD in these hydroxylases. Thus, this residue has been substituted with serine by site-directed mutagenesis to investigate the importance of flexibility of the peptide segment in catalysis. Differential scanning calorimetry demonstrated that the mutation has decreased the stability of the folded mutant protein compared to the wild-type PHBH. The increased flexibility in the protein backbone enhanced the accessibility of the flavin hydroperoxide intermediate to the solvent, causing an increase in the elimination of H(2)O(2) from this labile intermediate and, consequently, a decrease in the efficiency of substrate hydroxylation. Additionally, the increased accessibility of this mutant form of the enzyme makes it more susceptible than the wild-type enzyme to being trapped in the hydroxyflavin intermediate form in the presence of high levels of p-hydroxybenzoate. The mutation also lowers the pK(a) of the phenolic oxygen of bound p-hydroxybenzoate, and eliminates the pH dependence of the rate constant for flavin reduction by NADPH. These experimental observations lead to a model that explains how the wild-type protein can sense the charge of the 4-substituent of the aromatic ligand and link this charge to a flavin conformational change that is required for reaction with NADPH: (i) The peptide oxygen of Pro 293 is repelled by the negative charge of the phenolic oxygen of p-hydroxybenzoate. (ii) This repulsion is transmitted through the peptide backbone, causing the movement of Asn 300. (iii) The change in the position of Asn 300 triggers the movement of the flavin from the largely buried "in" conformation to the exposed, reactive "out" conformation.     

Studies of the mechanism of phenol hydroxylase: mutants Tyr289Phe, Asp54Asn, and Arg281Met

Three residues in the active site of the flavoprotein phenol hydroxylase (PHHY) were independently changed by site-directed mutagenesis. One of the mutant forms of PHHY, Tyr289Phe, is reduced by NADPH much slower than is the wild-type enzyme, although it has a slightly higher redox potential than the wild-type enzyme. In the structure of the wild-type enzyme, residue Tyr289 is hydrogen-bonded with the FAD when the latter is at the "out" position but has no direct contact with the flavin when it is "in". The oxidative half-reaction of PHHY is not significantly affected by this mutation, contrary to the concept that Tyr289 is a critical residue in the hydroxylation reaction [Enroth, C., Neujahr, H., Schneider, G., and Lindqvist, Y. (1998) Structure 6, 605-617; Ridder, L., Mullholland, A. J., Rietjens, I. M. C. M., and Vervoort, J. (2000) J. Am. Chem. Soc. 122, 8728-8738]. Tyr289 may help stabilize the FAD in the out conformation where it can be reduced by NADPH. For the Asp54Asn mutant form of PHHY, the initial step of the oxidative half-reaction is significantly slower than for the wild-type enzyme. Asp54Asn utilizes less than 20% of the reduced flavin for hydroxylating the substrate with the remainder forming H(2)O(2). Similar changes are observed when Arg281, a residue between Asp54 and the solvent, is mutated to Met. These two residues are suggested to be part of the active site environment the enzyme provides for the flavin cofactor to function optimally in the oxidative half-reaction. In the construction of the mutant forms of PHHY, it was determined that 11 of the previously reported amino acid residues in the sequence of PHHY were incorrect.     

Reactions of anthranilate hydroxylase with salicylate, a nonhydroxylated substrate analogue. Steady state and rapid reaction kinetics

Steady state and rapid reaction kinetics of the flavoprotein anthranilate hydroxylase (EC 1.14.12.2) have been examined with the nonhydroxylated substrate analogue, salicylate. Since the reaction with salicylate does not involve events in which aromatic substrate is oxygenated, it provides a simpler model for studying the hysteresis exhibited by this enzyme. It is shown that the first turnover of the enzyme is slower than subsequent turnovers owing in part to slow initial binding reactions of salicylate with the enzyme. The reductive half-reaction of the first turnover is also slow since rapid reduction of the enzyme flavin requires bound aromatic substrate. The oxidative half-reaction involves reaction of the reduced enzyme-salicylate complex with oxygen to form a flavin C4a-hydroperoxide, which then decays to oxidized flavoenzyme and H2O2. Several lines of evidence indicate that salicylate remains bound to the enzyme at the end of the catalytic cycle so that in turnovers subsequent to the first, the slow steps involving salicylate binding are avoided.     

NMR studies on p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens and salicylate hydroxylase from Pseudomonas putida

p-Hydroxybenzoate hydroxylase from Pseudomonas fluorescens and salicylate hydroxylase from Pseudomonas putida have been reconstituted with 13C- and 15N-enriched FAD. The protein preparations were studied by 13C-NMR, 15N-NMR and 31P-NMR techniques in the oxidized and in the two-electron-reduced states. The chemical shift values are compared with those of free flavin in water or chloroform. It is shown that the pi electron distribution in oxidized free p-hydroxybenzoate hydroxylase is comparable to free flavin in water, and it is therefore suggested that the flavin ring is solvent accessible. Addition of substrate has a strong effect on several resonances, e.g. C2 and N5, which indicates that the flavin ring becomes shielded from solvent and also that a conformational change occurs involving the positive pole of an alpha-helix microdipole. In the reduced state, the flavin in p-hydroxybenzoate hydroxylase is bound in the anionic form, i.e. carrying a negative charge at N1. The flavin is bound in a more planar configuration than when free in solution. Upon binding of substrate the resonances of N1, C10a and N10 shift upfield. It is suggested that these upfield shifts are the result of a conformational change similar, but not identical, to the one observed in the oxidized state. The 13C chemical shifts of FAD bound to apo(salicylate hydroxylase) indicate that in the oxidized state the flavin ring is also fairly solvent accessible in the free enzyme. Addition of substrate has a strong effect on the hydrogen bond formed with O4 alpha. It is suggested that this is due to the exclusion of water from the active site by the binding of substrate. In the reduced state, the flavin is anionic. Addition of substrate forces the flavin ring to adopt a more planar configuration, i.e. a sp2-hybridized N5 atom and a slightly sp3-hybridized N10 atom. The NMR results are discussed in relation to the reaction catalyzed by the enzymes.     

Conformational changes combined with charge-transfer interactions are essential for reduction in catalysis by p-hydroxybenzoate hydroxylase

p-Hydroxybenzoate hydroxylase is a flavoprotein monooxygenase that catalyzes a reaction in two parts: reduction of the enzyme cofactor FAD by NADPH in response to binding p-hydroxybenzoate to the enzyme and reaction of reduced FAD with oxygen to form a hydroperoxide, which then oxygenates p-hydroxybenzoate. Three different reactions, each with specific requirements, are achieved by moving the position of the isoalloxazine ring in the protein structure. In this paper, we examine the operation of protein conformational changes and the significance of charge-transfer absorption bands associated with the reduction of FAD by NADPH when the substrate analogue, 5-hydroxypicolinate, is bound to the enzyme. It was discovered that the enzyme with picolinate bound was reduced at a rate similar to that with p-hydroxybenzoate bound at high pH. However, there was a large effect of pH upon the rate of reduction in the presence of picolinate with a pK(a) of 7.4, identical to the pK(a) of picolinate bound to the enzyme. The intensity of charge-transfer bands observed between FAD and NADPH during the reduction process correlated with the rate of flavin reduction. We conclude that high rates of reduction of the enzyme require (a) the isoalloxazine of the flavin be held by the protein in a solvent-exposed position and (b) the movement of a loop of protein so that the pyridine ring of NADPH can move into position to form a complex with the isoalloxazine that is competent for hydride transfer and that is indicated by a strong charge-transfer interaction.     

Oxidation-reduction potential studies on p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens

The oxidation-reduction potential of p-hydroxybenzoate hydroxylase (4-hydroxybenzoate, NADPH: oxygen oxidoreductase (3-hydroxylating), EC 1.14.13.2) from Pseudomonas fluorescens has been measured in the presence and absence of p-hydroxybenzoate using spectrocoulometry. The native enzyme demonstrated a two-electron midpoint potential of -129 mV during the initial reductive titration. The midpoint potential observed during subsequent oxidative and reductive titrations was -152 mV. This marked hysteresis is proposed to arise from the oxidation and reduction of the known air-sensitive thiol group on the enzyme (Van Berkel, W.J.H. and Müller, F. (1987) Eur. J. Biochem. 167, 35-46). Redox titrations of the enzyme in the presence of substrate showed a two-electron midpoint potential of -177 mV. No spectral or electrochemical evidence for the thermodynamic stabilization of any flavin semiquinone was observed in the titrations performed. These data show that the affinity of the apoenzyme for the hydroquinone form of FAD is 150-fold greater than for the oxidized flavin and that the substrate is bound to the reduced enzyme with a 3-fold lower affinity than to the oxidized enzyme. These data are consistent with the view that the stimulatory effect of substrate binding on the rate of enzyme reduction by NADPH is due to the respective geometries of the bound FAD and NADPH rather than to a large perturbation of the oxidation-reduction potential of the bound flavin coenzyme.     

Kinetic and structural basis of reactivity of pentaerythritol tetranitrate reductase with NADPH, 2-cyclohexenone, nitroesters, and nitroaromatic explosives

The reaction of pentaerythritol tetranitrate reductase with reducing and oxidizing substrates has been studied by stopped-flow spectrophotometry, redox potentiometry, and X-ray crystallography. We show in the reductive half-reaction of pentaerythritol tetranitrate (PETN) reductase that NADPH binds to form an enzyme-NADPH charge transfer intermediate prior to hydride transfer from the nicotinamide coenzyme to FMN. In the oxidative half-reaction, the two-electron-reduced enzyme reacts with several substrates including nitroester explosives (glycerol trinitrate and PETN), nitroaromatic explosives (trinitrotoluene (TNT) and picric acid), and alpha,beta-unsaturated carbonyl compounds (2-cyclohexenone). Oxidation of the flavin by the nitroaromatic substrate TNT is kinetically indistinguishable from formation of its hydride-Meisenheimer complex, consistent with a mechanism involving direct nucleophilic attack by hydride from the flavin N5 atom at the electron-deficient aromatic nucleus of the substrate. The crystal structures of complexes of the oxidized enzyme bound to picric acid and TNT are consistent with direct hydride transfer from the reduced flavin to nitroaromatic substrates. The mode of binding the inhibitor 2,4-dinitrophenol (2,4-DNP) is similar to that observed with picric acid and TNT. In this position, however, the aromatic nucleus is not activated for hydride transfer from the flavin N5 atom, thus accounting for the lack of reactivity with 2,4-DNP. Our work with PETN reductase establishes further a close relationship to the Old Yellow Enzyme family of proteins but at the same time highlights important differences compared with the reactivity of Old Yellow Enzyme. Our studies provide a structural and mechanistic rationale for the ability of PETN reductase to react with the nitroaromatic explosive compounds TNT and picric acid and for the inhibition of enzyme activity with 2,4-DNP.     

Removal of a methyl group causes global changes in p-hydroxybenzoate hydroxylase

p-Hydroxybenzoate hydroxylase (PHBH) is a homodimeric flavoprotein monooxygenase that catalyzes the hydroxylation of p-hydroxybenzoate to form 3,4-dihydroxybenzoate. Controlled catalysis is achieved by movement of the flavin and protein between three conformations, in, out, and open [Entsch, B., et al. (2005) Arch. Biochem. Biophys. 433, 297-311]. The open conformation is important for substrate binding and product release, the in conformation for reaction with oxygen and hydroxylation, and the out conformation for the reduction of FAD by NADPH. The open conformation is similar to the structure of Arg220Gln-PHBH in which the backbone peptide loop of residues 43-46, located on the si side of the flavin, is rotated. In this paper, we examine the structure and properties of the Ala45Gly-PHBH mutant enzyme. The crystal structure of the Ala45Gly enzyme is an asymmetric dimer, with one monomer similar (but not identical) to wild-type PHBH, while the other monomer has His72 flipped into solvent and replaced with Glu73 as one of several changes in the structure. The two structures correlate with evidence from kinetic studies for two forms of Ala45Gly-PHBH. One form of the enzyme dominates turnover and hydroxylates, while the other contributes little to turnover and fails to hydroxylate. Ala45Gly-PHBH favors the in conformation over alternative conformations. The effect of this mutation on the structure and function of PHBH illustrates the importance of the si side loop in the conformational state of PHBH and, consequently, the function of the enzyme. This work demonstrates some general principles of how enzymes use conformational movements to allow both access and egress of substrates and product, while restricting access to the solvent at a critical stage in catalysis.     

para-Hydroxybenzoate hydroxylase containing 6-hydroxy-FAD is an effective enzyme with modified reaction mechanisms

The flavin prosthetic group (FAD) of p-hydroxybenzoate hydroxylase (EC 1.14.13.2) from Pseudomonas fluorescens, was replaced by 6-hydroxy-FAD (an extra hydroxyl group on the carbon at position 6 of the isoalloxazine ring of FAD). The catalytic cycle of this modified enzyme was analyzed and compared to the function of native (FAD) enzyme. Transient state kinetic analyses of the multiple changes in the chemical state of the flavin were the principal methods used to probe the mechanism. Four known substrates of the native enzyme were used to probe the reaction. With the natural substrate, p-hydroxybenzoate, the 6-hydroxy-FAD enzyme activity was 12-15% of native enzyme, due to a slower release of product from the enzyme, and less than one product molecule was formed per NADPH oxidized, due to an increased rate of nonproductive decomposition of the transient peroxyflavin essential to the catalytic pathway. More extensive changes in mechanism were observed with the substrates, 2,4-dihydroxybenzoate and p-aminobenzoate. The results suggest that, during catalysis, when the reduced state of FAD is ready for oxygen reaction, the substrate is located below and close to the C-4a/N-5 edge of the isoalloxazine ring. The nature of the high extinction, transient state of flavin, formed upon transfer of oxygen to substrate is discussed. It is not a flavin cation, and is unlikely to be an oxygen-substituted analogue of N-3/C-4 dihydroflavin.     

Molecular modeling reveals the possible importance of a carbonyl oxygen binding pocket for the catalytic mechanism of p-hydroxybenzoate hydroxylase

p-Hydroxybenzoate hydroxylase catalyzes the hydroxylation of an aromatic substrate and uses flavin as a cofactor. The reaction probably occurs via a flavin 4a-hydroperoxide intermediate. In this study the crystal structure of 4a,5-epoxyethano-3-methyl-4a,5-dihydrolumiflavin, an analogue of the flavin 4a-hydroperoxide intermediate, was fitted to the active site in the crystal structure of the p-hydroxybenzoate hydroxylase-3,4-dihydroxybenzoate complex. This model of an important catalytic intermediate fitted very well in the active site of p-hydroxybenzoate hydroxylase. The most striking result was that whereas with the normal flavin, the 0-4 of the flavin ring makes only poor hydrogen bonds with the protein, with the flavin 4a-hydroperoxide analogue, the same 0-4 makes strong hydrogen bonds with the NH groups of Gly-46 and Val-47. These two NH groups form a carbonyl oxygen binding pocket which has a geometry almost identical to the oxyanion hole found in several proteases. The possible consequences of this model for the reaction mechanism of p-hydroxybenzoate hydroxylase are discussed.     

Dihydroorotate dehydrogenase B of Enterococcus faecalis. Characterization and insights into chemical mechanism.

Enterococcus faecalis dihydroorotate dehydrogenase B is a heterodimer of 28 and 33 kDa encoded by the pyrK and pyrDb genes. Both subunits copurify during all chromatographic steps, and, as determined by HPLC, one FMN and one FAD are bound per heterodimer. The enzyme catalyzes efficient oxidation of 4-S-NADH by orotate. Isotope effect and pH data suggest that reduction of flavin by NADH at the PyrK site is only partially rate limiting with no kinetically significant proton transfer occurring in the reductive half-reaction; therefore, a group exhibiting a pK of 5.7 +/- 0.2 represents a residue involved in binding of NADH rather than in catalysis. The reducing equivalents are shuttled between the NADH-oxidizing flavin in PyrK and the orotate-reacting flavin in PyrDb, by iron-sulfur centers through flavin semiquinones as intermediates. A solvent kinetic isotope effect of 2.5 +/- 0.2 on V is indicative of rate-limiting protonation in the oxidative half-reaction and most likely reflects the interaction between the isoalloxazine N1 of the orotate-reducing flavin and Lys 168 (by analogy with L. lactis DHODase A). The oxidative half-reaction is facilitated by deprotonation of the group(s) with pK(s) of 5.8-6.3 and reflects either deprotonation of the reduced flavin or binding of orotate; this step is followed by hydride transfer to C6 and general acid-assisted protonation (pK of 9.1 +/- 0.2) at C5 of the product.     

Effect of monovalent anions on the mechanism of phenol hydroxylase

The mechanism of phenol hydroxylase (EC 1.14.13.7) has been studied by steady state and rapid reaction kinetic techniques. Both techniques give results consistent with the Bi Uni Uni Bi ping-pong mechanism proposed for other flavin-containing aromatic hydroxylases. The enzyme binds phenolic substrate and NADPH in that order, followed by reduction of the flavin and release of NADP+. A transient charge transfer complex between reduced enzyme and NADP+ can be detected. Molecular oxygen then reacts with the reduced enzyme-substrate complex. Two to three flavin-oxygen intermediates can be detected in the oxidative half-reaction depending on the substrate, provided monovalent anions are present. Oxygen transfer is complete with the formation of the second intermediate. Based on its UV absorption spectrum and on the fact that oxygen transfer has taken place, the last of these intermediates is presumably the flavin C(4a)-hydroxide. Monovalent anions are uncompetitive inhibitors of phenol hydroxylase. The mechanistic step most affected is the dehydration of the flavin C(4a)-hydroxide to give oxidized enzyme. Chloride also kinetically stabilizes the blue flavin semiquinone of phenol hydroxylase during photoreduction. These data suggest binding of monovalent anions results in stabilization of a proton on the N(5) position of the flavin.