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.     

Oxygen reactivity of p-hydroxybenzoate hydroxylase containing 1-deaza-FAD

The flavin prosthetic group (FAD) of p-hydroxybenzoate hydroxylase (EC 1.14.13.2) was replaced by 1-deaza-FAD (carbon substituted for nitrogen at position 1). An improved method for production of apoenzyme by precipitation with acidic ammonium sulfate was developed. The modified enzyme, in the presence of p-hydroxybenzoate, catalyzed the oxidation of NADPH by oxygen, yielding NADP+ and H2O2, but the ability to hydroxylate p-hydroxybenzoate and other substrates was lost. An analysis of the mechanism of NADPH-oxidase catalysis showed a close analogy between the reaction pathways for native and modified enzymes. In the presence of p-hydroxybenzoate, the rate of NADPH consumption catalyzed by the 1-deaza-FAD form was about 11% that of the native enzyme. Both formed a stabilized flavin-C (4a)-OOH intermediate upon reaction of reduced enzyme with oxygen, but the 1-deaza-FAD enzyme could not utilize this peroxide to hydroxylate substrates, and the peroxide decomposed to oxidized enzyme and H2O2.     

Analysis of the active site of the flavoprotein p-hydroxybenzoate hydroxylase and some ideas with respect to its reaction mechanism

The flavoprotein p-hydroxybenzoate hydroxylase has been studied extensively by biochemical techniques by others and in our laboratory by X-ray crystallography. As a result of the latter investigations, well-refined crystal structures are known of the enzyme complexed (i) with its substrate p-hydroxybenzoate and (ii) with its reaction product 3,4-dihydroxybenzoate and (iii) the enzyme with reduced FAD. Knowledge of these structures and the availability of the three-dimensional structure of a model compound for the reactive flavin 4a-hydroperoxide intermediate has allowed a detailed analysis of the reaction with oxygen. In the model of this reaction intermediate, fitted to the active site of p-hydroxybenzoate hydroxylase, all possible positions of the distal oxygen were surveyed by rotating this oxygen about the single bond between the C4a and the proximal oxygen. It was found that the distal oxygen is free to sweep an arc of about 180 degrees in the active site. The flavin 4a-peroxide anion, which is formed after reaction of molecular oxygen with reduced FAD, might accept a proton from an active-site water molecule or from the hydroxyl group of the substrate. The position of the oxygen to be transferred with respect to the substrate appears to be almost ideal for nucleophilic attack of the substrate onto this oxygen. The oxygen is situated above the 3-position of the substrate where the substitution takes place, at an angle of about 60 degrees with the aromatic plane, allowing strong interactions with the pi electrons of the substrate. Polarization of the peroxide oxygen-oxygen bond by the enzyme may enhance the reactivity of flavin 4a-peroxide.     

Inactivation of monomeric sarcosine oxidase by reaction with N-(cyclopropyl)glycine

Monomeric sarcosine oxidase (MSOX) catalyzes the oxidative demethylation of sarcosine (N-methylglycine) and contains covalently bound flavin adenine dinucleotide (FAD). The present study demonstrates that N-(cyclopropyl)glycine (CPG) is a mechanism-based inhibitor. CPG forms a charge transfer complex with MSOX that reacts under aerobic conditions to yield a covalently modified, reduced flavin (lambda(max) = 422 nm, epsilon(422) = 3.9 mM(-1) cm(-1)), accompanied by a loss of enzyme activity. The CPG-modified flavin is converted at an 8-fold slower rate to 1,5-dihydro-FAD (EFADH(2)), which reacts rapidly with oxygen to regenerate unmodified, oxidized enzyme. As a result, CPG-modified MSOX reaches a CPG-dependent steady-state concentration under aerobic conditions and reverts back to unmodified enzyme upon removal of excess reagent. No loss of activity is observed under anaerobic conditions where EFADH(2) is formed in a reaction that goes to completion at low CPG concentrations. Aerobic denaturation of CPG-modified enzyme yields unmodified, oxidized flavin at a rate similar to the anaerobic denaturation reaction, which yields 1,5-dihydro-FAD. The CPG-modified flavin can be reduced with borohydride, a reaction that blocks conversion to unmodified flavin upon removal of excess CPG or enzyme denaturation. The possible chemical mechanism of inactivation and structure of the CPG-modified flavin are discussed.     

Absorption spectra of radical forms of 2,4-dihydroxybenzoic acid, a substrate for p-hydroxybenzoate hydroxylase.

Combined optical and conductimetric measurements in aqueous solution indicate that at high pH (greater than or equal to 10).OH radicals react with the phenoxide form of 2,4-dihydroxybenzoic acid to form transiently phenoxyl radicals and a small amount of hydroxyeyclohexadienyl (HCHD) radicals by 150 ns. The respective yields of 88 and 12% of the total.OH radical yield were deduced from conductance and optical changes as well as from studies using a low potential reductant. The HCHD radical possesses a pKa of 8.0 +/- 0.1 and the constructed spectrum of the deprotonated forms of HCHD has a lambda max at 420 nm with a minimum extinction coefficient of approximately 7250 M-1 cm-1. The red shift in lambda max and increase in extinction coefficient compared to the revised spectral properties of the protonated form of the HCHD radical (lambda max at 390 nm with extinction coefficient of approximately 4500 M-1 cm-1), together with the pKa of the HCHD radical, provide an explanation for the pH-dependent spectral changes of the so-called highly absorbing intermediate II species, observed in the functioning of the enzyme p-hydroxybenzoate hydroxylase. These results add further to the evidence in support of the proposal that intermediate II is composed of species which absorb similarly to the flavin 4(a)-hydroxide and a form of the substrate/product such as the HCHD radical (Anderson, R. F., Patel, K. B., and Stratford, M. R. L. (1987) J. Biol. Chem. 262, 17475-17479).     

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.     

Oxidation of 2-thioflavins by peroxides. Formation of flavin 2-S-oxides

The reaction of 2-thioriboflavin (sulfur replacing the oxygen substituent at position 2 alpha) with hydrogen peroxide at pH approximately 10 leads to a blue flavin (lambda max = 565 nm) which was purified in stable, homogeneous form. Titrations of 2-thioflavins with m-chloroperoxybenzoic acid also yield the same blue flavins with consumption of 1 eq of peracid. Anaerobic reduction of the blue flavin by sodium dithionite requires 4e- eq, and leads to formation of 1,5-dihydro-2-thioflavin. Oxidation of the latter with O2 restores the original 2-thioflavin. pH titration of the blue flavin shows two pKa values of 2.4 and 6.6, with no apparent ionization in the pH range 8-11. These results suggest that the blue flavin is a flavin 2-S-oxide. The visible absorption spectra of flavin 2-S-oxides show a pronounced dependence on solvent polarity. This property suggests that these flavin analogs may be useful hydrophilic/hydrophobic probes of flavoprotein active sites. Flavin 2-S-oxides can be oxidized further to the 2-sulfinate and 2-sulfonate analogs, some properties of which are described.     

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).     

Oxygen reactions in p-hydroxybenzoate hydroxylase utilize the H-bond network during catalysis

para-Hydroxybenzoate hydroxylase is a flavoprotein monooxygenase that catalyses a reaction in two parts: reduction of the flavin adenine dinucleotide (FAD) in the enzyme by reduced nicotinamide adenine dinucleotide phosphate (NADPH) in response to binding p-hydroxybenzoate to the enzyme and oxidation of reduced FAD with oxygen to form a hydroperoxide, which then oxygenates p-hydroxybenzoate. These different reactions are coordinated through conformational rearrangements of the protein and isoalloxazine ring during catalysis. Earlier research showed that reduction of FAD occurs when the isoalloxazine of the FAD moves to the surface of the protein to allow hydride transfer from NADPH. This move is coordinated with protein rearrangements that are triggered by deprotonation of buried p-hydroxybenzoate through a H-bond network that leads to the surface of the protein. In this paper, we examine the involvement of this same H-bond network in the oxygen reactions-the initial formation of a flavin-C4a-hydroperoxide from the reaction between oxygen and reduced flavin, the electrophilic attack of the hydroperoxide upon the substrate to form product, and the elimination of water from the flavin-C4a-hydroxide to form oxidized enzyme in association with product release. These reactions were measured through absorbance and fluorescence changes in the FAD during the reactions. Results were collected over a range of pH for the reactions of wild-type enzyme and a series of mutant enzymes with the natural substrate and substrate analogues. We discovered that the rate of formation of the flavin hydroperoxide is not influenced by pH change, which indicates that the proton required for this reaction does not come from the H-bond network. The rate of the hydroxylation reaction increases with pH in a manner consistent with a pK(a) of 7.1. We conclude that the H-bond network abstracts the phenolic proton from p-hydroxybenzoate in the transition state of oxygen transfer. The rate of formation of oxidized enzyme increases with pH in a manner consistent with a pK(a) of 7.1, indicating the involvement of the H-bond network. We conclude that product deprotonation enhances the rate of a specific conformational change required for both product release and the elimination of water from C4a-OH-FAD.     

Action mechanism of Escherichia coli DNA photolyase. II. Role of the chromophores in catalysis

DNA photolyase repairs pyrimidine dimers in DNA in a reaction that requires visible light. Photolyase from Escherichia coli is normally isolated as a blue protein and contains 2 chromophores: a blue FAD radical plus a second chromophore that exhibits an absorption maximum at 360 nm when free in solution. Oxidation of the FAD radical is accompanied by a reversible loss of activity which is proportional to the fraction of the enzyme flavin converted to FADox. Quantitative reduction of the radical to fully reduced FAD causes a 3-fold increase in activity. The results show that a reduced flavin is required for activity and suggest that flavin may act as an electron donor in catalysis. Comparison of the absorption spectrum calculated for the protein-bound second chromophore (lambda max = 390 nm) with fluorescence data and with the relative action spectrum for dimer repair indicates that the second chromophore is the fluorophore in photolyase and that it does act as a sensitizer in catalysis. On the other hand, enzyme preparations containing diminished amounts of the second chromophore do not exhibit correspondingly lower activity. This suggests that reduced flavin may also act as a sensitizer in catalysis. The blue color of the enzyme is lost upon reduction of the FAD radical. The fully reduced E. coli enzyme exhibits absorption and fluorescence properties very similar to yeast photolyase. This indicates that the two enzymes probably contain similar chromophores but are isolated in different forms with respect to the redox state of the flavin.     

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.     

Action mechanism of Escherichia coli DNA photolyase. III. Photolysis of the enzyme-substrate complex and the absolute action spectrum

The absolute action spectrum of Escherichia coli DNA photolyase was determined in vitro. In vivo the photoreactivation cross-section (epsilon phi) is 2.4 X 10(4) M-1 cm-1 suggesting that the quantum yield (phi) is about 1.0 if one assumes that the enzyme has the same spectral properties (e.g. epsilon 384 = 1.8 X 10(4) M-1 cm-1) in vivo as those of the enzyme purified to homogeneity. The relative action spectrum of the pure enzyme (blue enzyme that contains FAD neutral semiquinone radical) agrees with the relative action spectrum for photoreactivation of E. coli, having lambda max = 384 nm. However, the absolute action spectrum of the blue enzyme yields a photoreactivation cross-section (epsilon phi = 1.2 X 10(3) at 384 nm) that is 20-fold lower than the in vivo values indicative of an apparent lower quantum yield (phi approximately equal to 0.07) in vitro. Reducing the enzyme with dithionite results in reduction of the flavin semiquinone and a concomitant 12-15-fold increase in the quantum yield. These results suggest that the flavin cofactor of the enzyme is fully reduced in vivo and that, upon absorption of a single photon in the 300-500 nm range, the photolyase chromophore (which consists of reduced FAD plus the second chromophore) donates an electron to the pyrimidine dimer causing its reversal to two pyrimidines. The reduced chromophore is regenerated at the end of the photochemical step thus enabling the enzyme to act catalytically.+     

Mechanistic studies of p-hydroxybenzoate hydroxylase reconstituted with 2-Thio-FAD

2-Thio-FAD (oxygen substituent at position 2 is replaced by sulfur) was used to reconstitute the apoenzyme of p-hydroxybenzoate hydroxylase. The 2-thio-FAD enzyme differs from native enzyme in several respects. While the native enzyme catalyzes the fully coupled hydroxylation of p-hydroxybenzoate, the 2-thio-FAD enzyme shows no hydroxylation of this substrate, instead reducing molecular oxygen to hydrogen peroxide. The rate of reduction of 2-thio-FAD p-hydroxybenzoate hydroxylase by NADPH in the presence of substrate was 7-fold faster than with the native enzyme. However, the oxygen reactivity of the reduced 2-thio-FAD enzyme was less than 1% that of native enzyme. This slow oxygen reaction results in the very high KmO2 observed in steady state kinetic studies of the modified enzyme. Stopped flow studies of the oxygen reaction of the reduced 2-thio-FAD enzyme in the presence of substrate confirmed the formation of a transient intermediate. The spectrum of this intermediate is very similar to those of the flavin-C(4a) adducts obtained with 2-thio-FMN lactate oxidase. This evidence suggests that reduced 2-thio-FAD p-hydroxybenzoate hydroxylase forms a flavin-C(4a)-hydroperoxide on reaction with oxygen in a reaction analogous to that with native enzyme, but that the resulting peroxyflavin is incompetent as an oxygenating species, breaking down instead to oxidized 2-thio-FAD enzyme and hydrogen peroxide.     

Interactions of pyridine nucleotides with redox forms of the flavin-containing NADH peroxidase from Streptococcus faecalis

The flavin-containing NADH peroxidase of Streptococcus faecalis 10C1, which catalyzes the reaction: NADH + H+ + H2O2----NAD+ + 2H2O, has been purified to homogeneity in our laboratory for analyses of both its structure and redox behavior. Our findings indicate that the enzyme is a tetramer of four apparently identical subunits (Mr = 46,000/subunit), each containing one FAD coenzyme and a second non-flavin, nonmetal redox center. There is no evidence of nonequivalence among the flavins. Dithionite reduction of the enzyme occurs in two steps, with end points of 0.96 and 2.05 eq/FAD. The first step generates a two-electron reduced form of the enzyme (EH2) which is spectrally identical with that generated by aerobic addition of NADH. Our studies suggest that the long-wavelength absorbance band (lambda max approximately 540 nm) exhibited by this form results from charge-transfer interaction between the reduced non-flavin redox center and the oxidized flavin. A second type of long-wavelength charge-transfer absorbance band (lambda max approximately 770 nm) is generated on anaerobic addition of 1 eq of NADH to EH2 and results from interaction between oxidized FAD and the reduced pyridine nucleotide. Either the EH2 X NAD+ or the EH2 X NAD+ X NADH forms may be involved in the catalytic mechanism of the enzyme, as both are reactive with hydrogen peroxide.     

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.     

Nature of the reaction intermediates in the flavin adenine dinucleotide-dependent epoxidation mechanism of styrene monooxygenase

Styrene monooxygenase (SMO) is a two-component flavoenzyme composed of an NADH-specific flavin reductase (SMOB) and FAD-specific styrene epoxidase (NSMOA). NSMOA binds tightly to reduced FAD and catalyzes the stereospecific addition of one atom of molecular oxygen to the vinyl side chain of styrene in the enantioselective synthesis of S-styrene oxide. In this mechanism, molecular oxygen first reacts with NSMOA(FAD(red)) to yield an FAD C(4a)-peroxide intermediate. This species is nonfluorescent and has an absorbance maximum of 382 nm. Styrene then reacts with the peroxide intermediate with a second-order rate constant of (2.6 ± 0.1) × 10(6) M(-1) s(-1) to yield a fluorescent intermediate with an absorbance maximum of 368 nm. We compute an activation free energy of 8.7 kcal/mol for the oxygenation step, in good agreement with that expected for a peroxide-catalyzed epoxidation, and acid-quenched samples recovered at defined time points in the single-turnover reaction indicate that styrene oxide synthesis is coincident with the formation phase of the fluorescent intermediate. These findings support FAD C(4a)-peroxide being the oxygen atom donor and the identity of the fluorescent intermediate as an FAD C(4a)-hydroxide product of the styrene epoxidation. Overall, four pH-dependent rate constants corresponding to peroxyflavin formation (pK(a) = 7.2), styrene epoxidation (pK(a) = 7.7), styrene oxide dissociation (pK(a) = 8.3), and hydroxyflavin dehydration (pK(a) = 7.6) are needed to fit the single-turnover kinetics.     

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.     

Chemical modification of arginine residues in p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens: a kinetic and fluorescence study

The flavoprotein p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens was modified by several arginine-specific reagents. Modifications by 2,3-butanedione led to the loss of activity of the enzyme, but the binding of p-hydroxybenzoate and NADPH to the enzyme was little or not at all affected. However the formation of the enzyme-substrate complex of the modified enzyme was accompanied by an increase of the fluorescence of protein-bound FAD, in contrast to that of native enzyme which leads to quenching of the fluorescence. Enzyme modified by phenylglyoxal did not bind p-hydroxybenzoate nor NADPH. Quantification and protection experiments showed that two arginine residues are essential and a model is described which accounts for the results. Modification by 4-hydroxy-3-nitrophenylglyoxal reduced the affinity of the enzyme for the substrate and NADPH. The ligands offered no protection against inactivation. From this it is concluded that one arginine residue is essential at some stage of the catalysis. This residue is not associated with the substrate- or NADPH-binding site of the enzyme. Time-resolved fluorescence studies showed that the average fluorescence lifetime and the mobility of protein-bound FAD are affected by modification of the enzyme.     

Reduced diphosphopyridine nucleotide peroxidase. Intermediates formed on reduction of the enzyme with dithionite or reduced diphosphopyridine nucleotide.

DPNH peroxidase is a flavin adenine dinucleotide-containing flavoprotein. Anaerobic titration of enzyme with dithionite has shown that the active site of the enzyme contains 2 mol of flavin and in addition 1 mol of a non-flavin electron acceptor that is tentatively identified as a disulfide group. Thus complete reduction of the enzyme requires 3 mol of dithionite per mole of active site. The first mole of dithionite reduces the non-flavin acceptor; complex formation between the reduced acceptor and one of the bound flavin molecules causes the formation of a long wavelength absorption band between 500 and 670 nm. The second mole of dithionite reduces the flavin that interacts with the reduced non-flavin group, and the long wavelength band disappears. The third mole of dithionite reduces the second mole of flavin. All groups are reoxidized in the presence of air. DPNH reacts with only two of the enzyme-bound electron acceptors. The first mole of DPNH reduces the non-flavin group to form an intermediate (I) that is almost identical with that formed by dithionite. The second mole of DPNH complexes with the second flavin of Intermediate I to form Intermediate II. This reaction causes a further absorbance increase in the long wavelength region; the tail of the absorption band now extends to 960 nm. The titration data (potassium phosphate, 0.05 M, pH 7.0) can be fitted with dissociation constants of 1 times 10-7 M for the formation of I, and 3 times 10-6 M for the conversion of I to II. In air, species II is oxidized to I; I is stable in air, but is oxidized stoichiometrically to oxidized enzyme by H2O2. Present evidence suggests that bound DPN-plus is responsible for the air stability of species I. Intermediate I, but not oxidized enzyme, reacts slowly with phenylmercuric acetate. This reaction causes loss of the air-stable intermediate and parallel loss in enzyme activity. The inactive enzyme cannot be reduced by DPNH to Species I; DPNH can, however, still react with the second flavin to form the autoxidizable complex. With other methods of enzyme inactivation there is also a direct correlation between residual enzyme activity and the ability of enzyme to form the air-stable intermediate. It is concluded that the air-stable intermediate is an important catalytic species.     

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.