Evidence for the formation of the 4a-carbinolamine during the tyrosine-dependent oxidation of tetrahydrobiopterin by rat liver phenylalanine hydroxylase

In the presence of phenylalanine and molecular oxygen, activated phenylalanine hydroxylase catalyzes the oxidation of tetrahydrobiopterin. The oxidation of this tetrahydropterin cofactor also proceeds if the substrate, phenylalanine, is replaced by its product, tyrosine, in the initial reaction mixture. These two reactions have been defined as coupled and uncoupled, respectively, because in the former reaction 1 mol of phenylalanine is hydroxylated for every mole of tetrahydrobiopterin oxidized, whereas in the latter reaction there is no net hydroxylation of tyrosine during the oxidation of the tetrahydropterin. During the course of the coupled oxidation of tetrahydrobiopterin, a pterin 4a-carbinolamine intermediate can be detected by ultraviolet spectroscopy (Kaufman, S. (1976) in Iron and Copper Proteins (Yasunobu, K. T., Mower, H. F., and Hayaishi, O., eds) pp. 91-102, Plenum Publishing Corp., New York). Dix and Benkovic (Dix, T. A., and Benkovic, S. J. (1985) Biochemistry 24, 5839-5846) have postulated that the formation of this intermediate only occurs when the oxidation of the tetrahydropteridine is tightly coupled to the concomitant hydroxylation of the aromatic amino acid. However, during the tyrosine-dependent uncoupled oxidation of tetrahydrobiopterin by phenylalanine hydroxylase, we have detected the formation of a spectral intermediate with ultraviolet absorbance that is essentially identical to that of the carbinolamine. Furthermore, this absorbance can be eliminated by the addition of 4a-carbinolamine dehydratase, an enzyme which catalyzes the dehydration of the 4a-carbinolamine. Quantitation of this intermediate suggests that there are two pathways for the tyrosine-dependent uncoupled oxidation of tetrahydrobiopterin by phenylalanine hydroxylase because only about 0.3 mol of the intermediate is formed per mol of the cofactor oxidized.     

Mechanism of oxygen activation by tyrosine hydroxylase

The mechanism by which the tetrahydropterin-requiring enzyme tyrosine hydroxylase (TH) activates dioxygen for substrate hydroxylation was explored. TH contains one ferrous iron per subunit and catalyzes the conversion of its tetrahydropterin cofactor to a 4a-carbinolamine concomitant with substrate hydroxylation. These results are in accord with shared mechanisms of oxygen activation by TH and the more commonly studied tetrahydropterin-dependent enzyme phenylalanine hydroxylase (PAH) and strongly suggest that a peroxytetrahydropterin is the hydroxylating species generated during TH turnover. In addition, TH can also utilize H2O2 as a cofactor for substrate hydroxylation, a result not previously established for PAH. A detailed mechanism for the reaction is proposed. While the overall pattern of tetrahydropterin-dependent oxygen activation by TH and PAH is similar, the H2O2-dependent hydroxylation performed by TH provides an indication that subtle differences in the Fe ligand field exist between the two enzymes. The mechanistic ramifications of these results are briefly discussed.     

Studies on the partially uncoupled oxidation of tetrahydropterins by phenylalanine hydroxylase

The uncoupled portion of the partially uncoupled oxidation of tetrahydropterins by phenylalanine hydroxylase can be described by the same model as we have recently derived for the fully uncoupled reaction (Davis, M.D. and Kaufman, S. (1989) J. Biol. Chem.264, 8585–8596). Although essentially no hydrogen peroxide is formed during the fully coupled oxidation of tetrahydrobiopterin or 6-methyltetrahydropterin by phenylalanine hydroxylase when phenylalanine is the amino acid substrate, significant amounts of hydrogen peroxide are formed during the partially uncoupled oxidation of 6-methyltetrahydropterin whenpara-fluorophenylalanine orpara-chlorophenylalanine are used in place of phenylalanine. Similarly, during the partially uncoupled oxidation of the unsubstituted pterin, tetrahydropterin, even in the presence of phenylalanine, hydrogen peroxide formation is detected. The 4a-carbinolamine tetrahydropterin intermediate has been observed during the fully uncoupled tyrosine-dependent oxidations of tetrahydropterin and 6-methyltetrahydropterin by lysolecithin-activated phenylalanine hydroxylase, suggesting that this species is also a common intermediate for uncoupled oxidations by this enzyme.Abbreviations BH₄ 6-[dihydroxypropyl-(L-erythro)-5,6,7,8-tetrahydropterin (tetrahydrobiopterin) - 6MPH₄ 6-methyl-5,6,7,8-tetrahydropterin - PH₄ 5,6,7,8-tetrahydropterin - BH₃OH 4a-hydroxytetrahydropterin (4a-carbinolamine) - qBH₂ quinonoid dihydrobiopterin - q6MPH₂ quinonoid dihydro-6-methylpterin - qPH₂ quinoid dihydropterin - PAH phenylalanine hydroxylase - DHPR dihydropteridine reductase - PHS phenylalanine hydroxylase stimulating enzyme which is 4a-carbinolamine dehydratase - SOD superoxide dismutase - HPLC high performance liquid chromatography - R.T. retention time Special issue dedicated to Dr. Santiago Grisolia.     

Reaction of rat liver phenylalanine hydroxylase with fatty acid hydroperoxides. Characterization and mechanism

Rat liver phenylalanine hydroxylase must be in a reduced form to be catalytically active (Marota, J.J. A., and Shiman, R. (1984) Biochemistry 23, 1303-1311). In this communication we show that a fatty acid hydroperoxide, 13-hydroperoxylinoleic acid (LOOH), can efficiently oxidize the reduced enzyme. In the process, the hydroperoxide is decomposed, oxygen consumed, and hydrogen peroxide formed. Enzyme reduction by the tetrahydropterin cofactor and reoxidation by LOOH can occur as two single steps or, when the enzyme concentration is low compared to that of the substrates, as part of a catalytic cycle. In this latter case, phenylalanine hydroxylase is a hydroperoxide-dependent tetrahydropterin oxidase. The reaction requires 1.0 mol of O2, 1.0 mol of tetrahydropterin, and 0.5 mol of LOOH to yield 1.0 mol of quinonoid dihydropterin, 0.4 mol of H2O2, and fatty acid products. Thus far, the catalytic and single-step reactions appear the same in all properties, consistent with the steady-state reaction following a ping-pong mechanism. Phenylalanine hydroxylase is an excellent catalyst for this reaction: the turnover number with LOOH is slightly greater than with phenylalanine; the Km(app) for LOOH is 11 +/- 4 microM; and the kcat/Km ratio for LOOH is about 25 times greater than for phenylalanine. LOOH and phenylalanine appear to react at different sites on phenylalanine appear to react at different sites on phenylalanine hydroxylase, and the reaction of LOOH is inhibited only slightly by phenylalanine and not at all by 5-deaza-6-methyltetrahydropterin, a competitive inhibitor of phenylalanine hydroxylation. The reaction of LOOH with phenylalanine hydroxylase strongly resembles the nonenzymatic reaction of LOOH with hematin, implying similar mechanisms for the two reactions and implicating the enzyme's non-heme iron as both the site of reaction of LOOH and of electron transfer during oxidation and reduction. The formation of hydrogen peroxide during a reaction of phenylalanine hydroxylase is unusual. Indirect evidence indicates a reduced oxygen species, formed on the enzyme during the reduction step, is (partially) released as H2O2 when the hydroperoxide reacts.     

The pH dependence of binding of inhibitors to bovine adrenal tyrosine hydroxylase

The inhibition of purified bovine adrenal tyrosine hydroxylase by several product and substrate analogues has been studied to probe the kinetic mechanism. Norepinephrine, dopamine, and methylcatechol are competitive inhibitors versus tetrahydropterins and noncompetitive inhibitors versus tyrosine. 3-Iodotyrosine is an uncompetitive inhibitor versus tetrahydropterins and a competitive inhibitor versus tyrosine. The Ki value for 3-iodotyrosine depends on the tetrahydropterin used. These results are consistent with tetrahydropterin binding first to the free enzyme followed by binding of tyrosine. 5-Deaza-6-methyltetrahydropterin is a noncompetitive inhibitor versus tetrahydropterins and tyrosine. The effect of varying the concentration of tyrosine on the Ki value for 5-deaza-6-methyltetrahydropterin is consistent with the binding of this inhibitor to both the free enzyme and to an enzyme-dihydroxyphenylalanine complex. Dihydroxyphenylalanine also is a noncompetitive inhibitor versus tetrahydropterins and tyrosine; the effect of changing the fixed substrate is consistent with the binding of this inhibitor to both the free enzyme and to the enzyme-tetrahydropterin complex. The effect of pH on the Ki values was determined in order to measure the pKa values of amino acid residues involved in substrate binding. Tight binding of catechols requires that a group with a pKa value of 7.6 be deprotonated. Binding of 3-iodotyrosine involves two groups with pKa values of 7.5 and about 5.5, one of which must be protonated for binding. Binding of 5-deaza-6-methyltetrahydropterin requires that a group on the free enzyme with a pKa value of 6.1 be protonated. The Ki value for dihydroxyphenylalanine is relatively insensitive to pH, but the inhibition pattern changes from noncompetitive to competitive above pH 7.5, consistent with the measured pKa values for binding to the free enzyme and to the enzyme-tetrahydropterin complex.     

Hydroxylation of 4-methylphenylalanine by rat liver phenylalanine hydroxylase

Rat liver phenylalanine hydroxylase that has been activated with lysolecithin catalyzes the hydroxylation of 4-methylphenylalanine in the presence of a pterin cofactor. Two products, 4-hydroxymethylphenylalanine and 3-methyltyrosine, can be detected. The total amount of amino acids hydroxylated is equal to the amount of tetrahydropterin oxidized. Isotopic labeling studies with 18O2 and H2(18)O show that the hydroxyl groups of both products are derived from molecular oxygen and not from water. Results obtained with 2H-labeled substrates support the conclusion that these products are formed via different mechanistic pathways. Our previous investigations on substrate analogs, as well as the present results, indicate that a highly reactive oxygen-containing intermediate, such as an enzyme-bound iron-oxo compound, must be the hydroxylating species. Our present results could stimulate further discussion of the possibility that the reaction mechanism for the "NIH-shift" of the methyl group may not involve the spontaneous opening of an epoxide intermediate.     

Characterization of metal ligand mutants of tyrosine hydroxylase: insights into the plasticity of a 2-histidine-1-carboxylate triad

The amino acid ligands to the active site iron in the aromatic amino acid hydroxylase tyrosine hydroxylase are two histidines and a glutamate. This 2-histidine-1-carboxylate motif has been found in a number of other metalloenzymes which catalyze a variety of oxygenase reactions. As a probe of the plasticity of this metal binding site, each of the ligands in TyrH has been mutated to glutamine, glutamate, or histidine. The H336E and H336Q enzymes show dramatic decreases in iron affinity but retain substantial activity for both tyrosine hydroxylation and tetrahydropterin oxidation. The H331E enzyme shows a lesser decrease in iron affinity and is unable to hydroxylate tyrosine. Instead, this enzyme oxidizes tetrahydropterin in the absence of added tyrosine. The E376H enzyme has no significant activity, while the E376Q enzyme hydroxylates tyrosine at about 0.4% the wild-type rate. When dopamine is bound to either the H336Q or H331E enzymes, the position of the long wavelength charge-transfer absorbance band is consistent with the change in the metal ligand. In contrast, the H336E enzyme does not form a stable binary complex with dopamine, while the E376H and E376Q enzymes catalyze dopamine oxidation.     

Insights into the catalytic mechanisms of phenylalanine and tryptophan hydroxylase from kinetic isotope effects on aromatic hydroxylation

Phenylalanine hydroxylase (PheH) and tryptophan hydroxylase (TrpH) catalyze the aromatic hydroxylation of phenylalanine and tryptophan, forming tyrosine and 5-hydroxytryptophan, respectively. The reactions of PheH and TrpH have been investigated with [4-(2)H]-, [3,5-(2)H(2)]-, and (2)H(5)-phenylalanine as substrates. All (D)k(cat) values are normal with Delta117PheH, the catalytic core of rat phenylalanine hydroxylase, ranging from 1.12-1.41. In contrast, for Delta117PheH V379D, a mutant protein in which the stoichiometry between tetrahydropterin oxidation and amino acid hydroxylation is altered, the (D)k(cat) value with [4-(2)H]-phenylalanine is 0.92 but is normal with [3,5-(2)H(2)]-phenylalanine. The ratio of tetrahydropterin oxidation to amino acid hydroxylation for Delta117PheH V379D shows a similar inverse isotope effect with [4-(2)H]-phenylalanine. Intramolecular isotope effects, determined from the deuterium contents of the tyrosine formed from [4-(2)H]-and [3,5(2)H(2)]-phenylalanine, are identical for Delta117PheH and Delta117PheH V379D, suggesting that steps subsequent to oxygen addition are unaffected in the mutant protein. The inverse effects are consistent with the reaction of an activated ferryl-oxo species at the para position of the side chain of the amino acid to form a cationic intermediate. The normal effects on the (D)k(cat) value for the wild-type enzyme are attributed to an isotope effect of 5.1 on the tautomerization of a dienone intermediate to tyrosine with a rate constant 6- to7-fold that for hydroxylation. In addition, there is a slight ( approximately 34%) preference for the loss of the hydrogen originally at C4 of phenylalanine. With (2)H(5)-indole-tryptophan as a substrate for Delta117PheH, the (D)k(cat) value is 0.89, consistent with hydroxylation being rate-limiting in this case. When deuterated phenylalanines are used as substrates for TrpH, the (D)k(cat) values are within error of those for Delta117PheH V379D. Overall, these results are consistent with the aromatic amino acid hydroxylases all sharing the same chemical mechanism, but with the isotope effect for hydroxylation by PheH being masked by tautomerization of an enedione intermediate to tyrosine.     

芳香族氨基酸羟化酶家族结构与催化功能

芳香族氨基酸羟化酶(AAAH）家族是一类单加氢酶,包括苯丙氨酸羟化酶(PAH)、酪氨酸羟化酶(TH)和色氨酸羟化酶(TPH). 在辅因子四氢生物蝶呤、铁原子及氧存在下,分别催化苯丙氨酸、酪氨酸、色氨酸的羟化反应. 多种疾病如苯丙酮尿症、帕金森氏病以及神经相关疾病的发病机制均与这类酶有关. 本文综述近年来对芳香族氨基酸羟化酶家族蛋白结构功能、底物特异性、催化机制等方面的研究进展,为该类酶的定向进化及功能应用提供新思路.     

Study of the initial reaction of enzymatic oxidation of 1,8-dimethylnaphthalene]

Crude enzymatic preparation has been obtained from Pseudomonas bacteria which oxidises 1,8-DMN during 10-hour incubation with the following formation of the same products which are formed when this compound is oxidized by the intact cells. The first product of the oxidation is 1-methyl-8-oxymethylnaphtalene (compound I), obtained as a result of hydroxylation of one methyl group. Probably hydroxylase of 1,8-DMN may be referred to the class of oxigenases of the basis of the absence of 18O incorporation from H218O to compound I, and also resulting from the data on absorption of molecular oxygen during the reaction. The enzyme is completely inhibited by chelating agents of Fe2+ NAD(P)H and Fe2+ stimulates the reaction of 1.8 DMN oxidation.     

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.     

Determination of phenylalanine hydroxylase activity by liquid chromatography/electrochemistry

An assay method is presented for the determination of phenylalanine hydroxylase activity in biological samples. The procedure is rapid and requires little sample. Multiple components of the enzyme system are determined and therefore serve as internal checks of the assay system. Liquid chromatography/electrochemistry is employed to follow the oxidation of the tetrahydropterin cofactor to the dihydropterin and to follow the formation of tyrosine. The KM and Vmax values of both phenylalanine and 6-methyl-5,6,7,8-tetrahydropterin were determined for mouse liver phenylalanine hydroxylase. Determination of the stoichiometry of the reaction showed that 1 mol of dihydropterin and 1 mol of tyrosine are formed per mole of tetrahydropterin that is oxidized. The reaction rate was linear for several minutes and over a wide range of enzyme (protein) concentrations.     

Reduction and oxidation of the active site iron in tyrosine hydroxylase: kinetics and specificity

Tyrosine hydroxylase (TyrH) is a pterin-dependent enzyme that catalyzes the hydroxylation of tyrosine to form dihydroxyphenylalanine. The oxidation state of the active site iron atom plays a central role in the regulation of the enzyme. The kinetics of reduction of ferric TyrH by several reductants were determined by anaerobic stopped-flow spectroscopy. Anaerobic rapid freeze-quench EPR confirmed that the change in the near-UV absorbance of TyrH upon adding reductant corresponded to iron reduction. Tetrahydrobiopterin reduces wild-type TyrH following a simple second-order mechanism with a rate constant of 2.8 +/- 0.1 mM(-)(1) s(-)(1). 6-Methyltetrahydropterin reduces the ferric enzyme with a second-order rate constant of 6.1 +/- 0.1 mM(-)(1) s(-)(1) and exhibits saturation kinetics. No EPR signal for a radical intermediate was detected. Ascorbate, glutathione, and 1,4-benzoquinone all reduce ferric TyrH, but much more slowly than tetrahydrobiopterin, suggesting that the pterin is a physiological reductant. E332A TyrH, which has an elevated K(m) for tetrahydropterin in the catalytic reaction, is reduced by tetrahydropterins with the same kinetic parameters as those of the wild-type enzyme, suggesting that BH(4) does not bind in the catalytic conformation during the reduction. Oxidation of ferrous TyrH by molecular oxygen can be described as a single-step second-order reaction, with a rate constant of 210 mM(-)(1) s(-)(1). S40E TyrH, which mimics the phosphorylated state of the enzyme, has oxidation and reduction kinetics similar to those of the wild-type enzyme, suggesting that phosphorylation does not directly regulate the interconversion of the ferric and ferrous forms.     

Influence of steric bulk and electrostatics on the hydroxylation regiospecificity of tryptophan hydroxylase: characterization of methyltryptophans and azatryptophans as substrates

Tryptophan hydroxylase is a pterin-dependent amino acid hydroxylase that catalyzes the incorporation of one atom of molecular oxygen into tryptophan to form 5-hydroxytryptophan. The substrate specificity and hydroxylation regiospecificity of tryptophan hydroxylase have been investigated using tryptophan analogues that have methyl substituents or nitrogens incorporated into the indole ring. The products of the reactions show that the regiospecificity of tryptophan hydroxylase is stringent. Hydroxylation does not occur at the 4 or 6 carbon in response to changes in substrate topology or atomic charge. 5-Hydroxymethyltryptophan and 5-hydroxy-4-methyltryptophan are the products from 5-methyltryptophan. These products establish that the hydroxylating intermediate is sufficiently potent to hydroxylate benzylic carbons and that the direction of the NIH shift in tryptophan hydroxylase is from carbon 5 to carbon 4. The effects on the V/K values for the amino acids indicate that the enzyme is most sensitive to changes at position 5 of the indole ring. The V(max) values for amino acid hydroxylation differ at most by a factor of 3 from that observed for tryptophan, while the efficiencies of hydroxylation with respect to tetrahydropterin consumption vary 6-fold, consistent with oxygen transfer to the amino acid being partially or fully rate limiting in productive catalysis.     

Component interactions in the soluble methane monooxygenase system from Methylococcus capsulatus (Bath).

The soluble methane monooxygenase system of Methylococcus capsulatus (Bath) includes three protein components: a 251-kDa non-heme dinuclear iron hydroxylase (MMOH), a 39-kDa iron-sulfur- and FAD-containing reductase (MMOR), and a 16-kDa regulatory protein (MMOB). The thermodynamic stability and kinetics of formation of complexes between oxidized MMOH and MMOB or MMOR were measured by isothermal titration calorimetry and stopped-flow fluorescence spectroscopy at temperatures ranging from 3.3 to 45 degrees C. The results, in conjunction with data from equilibrium analytical ultracentrifugation studies of MMOR and MMOB, indicate that free MMOR and MMOB exist as monomers in solution and bind MMOH with 2:1 stoichiometry. The role of component interactions in the catalytic mechanism of sMMO was investigated through simultaneous measurement of oxidase and hydroxylase activities as a function of varied protein component concentrations during steady-state turnover. The partitioning of oxidase and hydroxylase activities of sMMO is highly dependent on both the MMOR concentration and the nature of the organic substrate. In particular, NADH oxidation is significantly uncoupled from methane hydroxylation at MMOR concentrations exceeding 20% of the hydroxylase concentration but remains tightly coupled to propylene epoxidation at MMOR concentrations ranging up to the MMOH concentration. The steady-state kinetic data were fit to numerical simulations of models that include both the oxidase activities of free MMOR and of MMOH/MMOR complexes and the hydroxylase activity of MMOH/MMOB complexes. The data were well described by a model in which MMOR and MMOB bind noncompetitively at distinct interacting sites on the hydroxylase. MMOB manifests its regulatory effects by differentially accelerating intermolecular electron transfer from MMOR to MMOH containing bound substrate and product in a manner consistent with its activating and inhibitory effects on the hydroxylase.     

Identification of iron ligands in tyrosine hydroxylase by mutagenesis of conserved histidinyl residues.

Tyrosine hydroxylase catalyzes the hydroxylation of tyrosine and other aromatic amino acids using a tetrahydropterin as the reducing substrate. The enzyme is a homotetramer; each monomer contains a single nonheme iron atom. Five histidine residues are conserved in all tyrosine hydroxylases that have been sequenced to date and in the related eukaryotic enzymes phenylalanine and tryptophan hydroxylase. Because histidine has been suggested as a ligand to the iron in these enzymes, mutant tyrosine hydroxylase proteins in which each of the conserved histidines had been mutated to glutamine or alanine were expressed in Escherichia coli. The H192Q, H247Q, and H317A mutant proteins contained iron in comparable amounts to the wild-type enzyme, about 0.6 atoms/sub-unit. In contrast, the H331 and H336 mutant proteins contained no iron. The first three mutant enzymes were active, with Vmax values 39, 68, and 7% that of the wild-type enzyme, and slightly altered V/Km values for both tyrosine and 6-methyltetrahydropterin. In contrast, the H331 and H336 mutant enzymes had no detectable activity. The EPR spectra of the H192Q and H247Q enzymes are indistinguishable from that of wild-type tyrosine hydroxylase, whereas that of the H317A enzyme indicated that the ligand field of the iron had been slightly perturbed. These results are consistent with H331 and H336 being ligands to the active site iron atom.     

Stereoselective effects in the interactions of pterin cofactors with rat-liver phenylalanine 4-monooxygenase

The (6R) and (6S) epimers of l-erythro-tetrahydrobiopterin (BH4) and some of its structural analogs, were tested as cofactors and non-covalent effectors in the phenylalanine 4-monooxygenase (phenylalanine hydroxylase, EC 1.14.16.1) reaction. The oxidation-reduction potentials (Em,7) of the free (not enzyme-bound) form of the (6R) and (6S) epimers were rather similar (range 174-184 mV) for the oxidation of tetrahydropterins to quinonoid dihydropterins. Rapid-mixing kinetic experiments were performed at 20 degrees C under conditions which allow only a few turnover reactions of the enzyme. Three main oxidation products were identified spectroscopically at pH 6.8 for all three tetrahydropterins tested: the C(4a)-hydroxy derivatives, the quinonoid dihydropterins, and the stable 7,8-dihydropterins (in that sequence). The formation of the C(4a)-hydroxy forms closely paralleled that of tyrosine, and supports the proposal that this covalent adduct is formed as an immediate product on completion of the catalytic cycle. Assay of the initial rate of C(4a)-hydroxy derivative formation represents a new approach in kinetic studies of this enzyme, and the kinetic parameters obtained for the phenylalanine-activated enzyme are presented. The affinity of binding of (6R)-BH4 and (6S)-BH4 to phenylalanine hydroxylase was also estimated on the basis of their quenching of the intrinsic tryptophan fluorescence of the enzyme. The apparent affinities were found to correspond well to the Km values estimated in kinetic studies of the hydroxylation reaction with the phenylalanine activated enzyme, i.e. higher for (6R)-BH4 than for (6S)-BH4. The lower V value observed for the native enzyme with the (6R) epimer in steady-state kinetics is explained by its higher potency as a negative effector, since the oxidation-reduction potentials of the two diastereomers were similar. Dihydrobiopterin (BH2) was found to inhibit the hydroxylation reaction and quenched the intrinsic tryptophan fluorescence of the enzyme with the same concentration dependence as that observed with (6S)-BH4.     

Uncoupling of the substrate monooxygenation and reduced pyridine nucleotide oxidation activities of salicylate hydroxylase by flavins

The NAD(P)H oxidation and substrate monooxygenation activities of Pseudomonas cepacia salicylate hydroxylase can be uncoupled by added flavins. The uncoupling is postulated to result from a reducing equivalent exchange between the hydroxylase-bound FADH₂ and the added flavins, leading to the reduction of the latter species and the regeneration of oxidized holoenzyme without hydroxylating the salicylate substrate. When exogenous FMN was added, the salicylate hydroxylase-catalyzed NAD(P)H oxidation could be coupled to the bacterial bioluminescence reaction, which is specific for fully reduced FMN as a substrate. The quantum yield of the coupled bioluminescence, based on the amount of NADH oxidized independently of salicylate monooxygenation, was determined to be 0.14 correlating closely with the known quantum yield of about 0.17 for reduced FMN in the luciferase-catalyzed bioluminescence reaction. A series of flavin derivatives were tested for their effects on the uncoupling of NAD(P)H oxidation and substrate monooxygenation activities of salicylate hydroxylase. Results indicated that the efficiency for interactions between the bound FADH₂ and free flavins was sensitive to the position of structural modification, size, and charge of the added flavin species, suggesting that the bound FADH₂ was partially exposed to aqueous medium under conditions of actual catalysis.     

Purification and characterization of a two-component monooxygenase that hydroxylates nitrilotriacetate from "Chelatobacter" strain ATCC 29600.

An assay based on the consumption of nitrilotriacetate (NTA) was developed to measure the activity of NTA monooxygenase (NTA-Mo) in cell extracts of "Chelatobacter" strain ATCC 29600 and to purify a functional, NTA-hydroxylating enzyme complex. The complex consisted of two components that easily dissociated during purification and upon dilution. Both components were purified to more than 95% homogeneity, and it was possible to reconstitute the functional, NTA-hydroxylating enzyme complex from pure component A (cA) and component B (cB). cB exhibited NTA-stimulated NADH oxidation but was unable to hydroxylate NTA. It had a native molecular mass of 88 kDa and contained flavin mononucleotide (FMN). cA had a native molecular mass of 99 kDa. No catalytic activity has yet been shown for cA alone. Under unfavorable conditions, NADH oxidation was partly or completely uncoupled from hydroxylation, resulting in the formation of H2O2. Optimum hydroxylating activity was found to be dependent on the molar ratio of the two components, the absolute concentration of the enzyme complex, and the presence of FMN. Uncoupling of the reaction was favored in the presence of high salt concentrations and in the presence of flavin adenine dinucleotide. The NTA-Mo complex was sensitive to sulfhydryl reagents, but inhibition was reversible by addition of excess dithiothreitol. The Km values for Mg(2+)-NTA, FMN, and NADH were determined as 0.5 mM, 1.3 microM, and 0.35 mM, respectively. Of 26 tested compounds, NTA was the only substrate for NTA-Mo.     

A flexible loop in tyrosine hydroxylase controls coupling of amino acid hydroxylation to tetrahydropterin oxidation

The role of a polypeptide loop in tyrosine hydroxylase (TyrH) whose homolog in phenylalanine hydroxylase (PheH) takes on a different conformation when substrates are bound has been studied using site-directed mutagenesis. The loop spans positions 177 to 191; alanine was introduced into those positions, introducing one alanine substitution per TyrH variant. Mutagenesis of residues in the center of the loop resulted in alterations in the KM values for substrates, the Vmax value for dihydroxyphenylalanine (DOPA) synthesis, and the coupling of tetrahydropterin oxidation to tyrosine hydroxylation. The variant with the most altered KM value for 6-methyltetrahydropterin was TyrH F184A. The variants with the most affected K(tyr) values were those with substitutions in the center of the loop, TyrH K183A, F184A, D185A, P186A and D187A. These five variants also had the most reduced Vmax values for DOPA synthesis. Alanine substitution in positions 182-186 resulted in lowered ratios of tyrosine hydroxylation to tetrahydropterin oxidation. TyrH F184Y and PheH Y138F, variants with the residue at the center of the loop substituted with the residue present at the homologous position in the other hydroxylase, were also studied. The V/K(tyr) to V/K(phe) ratios for these variants were altered significantly, but the results did not suggest that F184 of TyrH or Y138 of PheH plays a dominant role in determining amino acid substrate specificity.