Hydrogen peroxide-coupled cis-diol formation catalyzed by naphthalene 1,2-dioxygenase

Naphthalene 1,2-dioxygenase (NDOS) catalyzes the NAD(P)H and O(2)-dependent oxidation of naphthalene to (+)-cis-(1R,2S)-dihydroxy-1,2-dihydronaphthalene. NDOS consists of three protein components: a flavo-[2Fe-2S] reductase (NDR), a ferredoxin electron transfer protein (NDF), and an (alphabeta)(3) oxygenase (NDO) containing a mononuclear iron site and a Rieske-type [2Fe-2S] cluster in each alpha-subunit. The active site is built across a subunit-subunit boundary, and each subunit contributes one type of metal center. Our previous studies have shown that NDO with both metal centers reduced is capable of an O(2)-coupled single turnover to yield the correct cis-diol product in the absence of the NDR and NDF components (Wolfe, M. D., Parales, J. V., Gibson, D. T., and Lipscomb, J. D. (2001) J. Biol. Chem. 276, 1945-1953). It is shown here that addition of H(2)O(2) to NDO allows reaction with naphthalene to rapidly yield the correct product in a "peroxide shunt" reaction that does not require a reduced Rieske cluster. The mononuclear Fe(2+) center is oxidized during turnover, while the Rieske cluster remains in the oxidized state. Peroxide shunt turnover in the presence of (18)O-labeled H(2)O(2), H(2)O, or O(2) shows that both oxygen atoms in the product derive primarily from H(2)O(2). The peroxide shunt halts after one turnover despite the presence of excess H(2)O(2) and naphthalene, but this is not the result of enzyme inactivation. Rather, it appears that the product cannot be released when the mononuclear iron is in the Fe(3+) state, blocking a second turnover. This work supports the hypotheses that the cis-dihydroxylation activity of NDOS requires only the NDO component, that a peroxo intermediate is formed during normal catalysis, and that product release requires an additional reducing equivalent beyond those necessary for the first turnover.     

Benzoate 1,2-dioxygenase from Pseudomonas putida: single turnover kinetics and regulation of a two-component Rieske dioxygenase

The benzoate 1,2-dioxygenase system (BZDOS) from Pseudomonas putida mt-2 catalyzes the NADH-dependent oxidation of benzoate to 1-carboxy-1,2-cis-dihydroxycyclohexa-3,5-diene. Both the oxygenase (BZDO) and reductase (BZDR) components of BZDOS have been purified and characterized kinetically and by optical, EPR, and M?ssbauer spectroscopies. BZDO has an (alpha beta)(3) subunit structure in which each alpha subunit contains a Rieske [2Fe-2S] cluster and a mononuclear iron site. Two different purification protocols were developed for BZDO allowing the mononuclear iron to be stabilized in either the Fe(III) or the Fe(II) state for spectroscopic characterization. Using single turnover reactions, it is shown that fully reduced BZDO alone is capable of yielding the cis-diol product in high yield at rates that exceed the BZDOS turnover number. At the conclusion of turnover, quantification of each oxidation state of the metal sites by EPR and M?ssbauer spectroscopies shows that the Rieske cluster and mononuclear iron are each oxidized in amounts equal to the product yield, suggesting that the two electrons required for catalysis derive from the two metal centers. These results are in agreement with our previous study of naphthalene 1,2-dioxygenase [Wolfe, M. D., Parales, J. V., Gibson, D. T., and Lipscomb, J. D. (2001) J. Biol. Chem. 276, 1945-1953], which belongs to a different Rieske dioxygenase subclass, suggesting that it is a universal characteristic of Rieske dioxygenases that oxygen activation and substrate oxidation are catalyzed by the oxygenase component alone. The EPR spectrum of the Fe(III) center after a single turnover is distinct from either of those of substrate-free or substrate-bound enzyme. The complex with this spectrum is not formed by addition of cis-diol product to the resting Fe(III) form of the enzyme but is observed when the Fe(II) form is oxidized in the presence of product. Together, these results suggest that product exchange occurs only when the mononuclear iron is reduced. Stopped-flow and rapid scan analyses monitoring the oxidation of the Rieske cluster during the single turnover reaction show that it occurs in three phases that are kinetically competent for catalysis. The rate of each phase was found to be dependent on the type of substrate present, suggesting that the substrate influences the rate of electron transfer between the metal clusters. The participation of substrate in the oxygen activation reaction suggests a new aspect of the mechanism of this process by the Rieske dioxygenase class.     

Chemistry of the catalytic conversion of phthalate into its cis-dihydrodiol during the reaction of oxygen with the reduced form of phthalate dioxygenase

The phthalate dioxygenase system, a Rieske non-heme iron dioxygenase, catalyzes the dihydroxylation of phthalate to form the 4,5-dihydro-cis-dihydrodiol of phthalate (DHD). It has two components: phthalate dioxygenase (PDO), a multimer with one Rieske-type [2Fe-2S] and one mononuclear Fe(II) center per monomer, and a reductase (PDR) that contains flavin mononucleotide (FMN) and a plant-type ferredoxin [2Fe-2S] center. This work shows that product formation in steady-state reactions is tightly coupled to electron delivery, with 1 dihydrodiol (DHD) of phthalate formed for every 2 electrons delivered from NADH. However, in reactions of reduced PDO with O(2), only about 0.5 DHD is formed per Rieske center that becomes oxidized. Although the product forms rapidly, its release from PDO is slow in these reactions with oxygen that do not include reductase and NADH. EPR data show that, at the completion of the oxidation, iron in the mononuclear center remains in the ferrous state. In contrast, naphthalene dioxygenase (NDO) [Wolfe, M. D., Parales, J. V., Gibson, D. T., and Lipscomb, J. D. (2001) J. Biol. Chem. 276, 1945-1953] and benzoate dioxygenase (BZDO) [Wolfe, M. D., Altier, D. J., Stubna, A., Popescu, C. V., Munck, E., and Lipscomb, J. D. (2002) Biochemistry, 41, 9611-9626], related Rieske non-heme iron dioxygenases, form 1 DHD per Rieske center oxidized, and the mononuclear center iron ends up ferric. Thus, both electrons from reduced NDO and BZDO monomers are used to form the product, whereas only the reduced Rieske centers in PDO become oxidized during production of DHD. This emphasizes the importance of PDO subunit interaction in catalysis. Electron redistribution was practically unaffected by the presence of oxidized PDR. A scheme is presented that emphasizes some of the differences in the mechanisms involved in substrate hydroxylation employed by PDO and either NDO or BZDO.     

Hydrogen peroxide dependent cis-dihydroxylation of benzoate by fully oxidized benzoate 1,2-dioxygenase

Rieske dioxygenases catalyze the reductive activation of O2 for the formation of cis-dihydrodiols from unactivated aromatic compounds. It is known that O2 is activated at a mononuclear non-heme iron site utilizing electrons supplied by a nearby Rieske iron sulfur cluster. However, it is controversial whether the reactive species is an Fe(III)-(hydro)peroxo or an Fe(II)-(hydro)peroxo (or electronically equivalent species formed by breaking the O-O bond). Here it is shown that benzoate 1,2 dioxygenase oxygenase component (BZDO) prepared in a form with the Rieske cluster oxidized and the mononuclear iron in the Fe(III) state can utilize H2O2 as a source of reduced oxygen to form the correct cis-dihydrodiol product from benzoate. The reaction approaches stoichiometric yield relative to the mononuclear Fe(III) concentration, being limited to a single turnover by inefficient product release from the Fe(III)-product complex. EPR and M?ssbauer studies show that the iron remains ferric throughout this single turnover "peroxide shunt" reaction. These results strongly support Fe(III)-(hydro)peroxo (or Fe(V)-oxo-hydroxo) as the reactive species because there is no source of additional reducing equivalents to form the Fe(II)-(hydro)peroxo state. This conclusion could be further tested in the case of BZDO because the peroxide shunt occurs very slowly compared with normal turnover, allowing the reactive intermediate to be trapped for spectroscopic analysis. We attribute the slow reaction rate to a forced change in the normally strict order of the substrate binding and enzyme reduction steps that regulate the catalytic cycle. The reactive intermediate is a high-spin ferric species exhibiting an unusual negative zero field splitting and other EPR and M?ssbauer spectroscopic properties reminiscent of previously characterized side-on-bound peroxide adducts of Fe(III) model complexes. If the species in BZDO is a similar adduct, its isomer shift is most consistent with an Fe(III)-hydroperoxo reactive state.     

Histidine ligand protonation and redox potential in the rieske dioxygenases: role of a conserved aspartate in anthranilate 1,2-dioxygenase

The Rieske dioxygenase, anthranilate 1,2-dioxygenase, catalyzes the 1,2-dihydroxylation of anthranilate (2-aminobenzoate). As in all characterized Rieske dioxygenases, the catalytic conversion to the diol occurs within the dioxygenase component, AntAB, at a mononuclear iron site which accepts electrons from a proximal Rieske [2Fe-2S] center. In the related naphthalene dioxygenase (NDO), a conserved aspartate residue lies between the mononuclear and Rieske iron centers, and is hydrogen-bonded to a histidine ligand of the Rieske center. Engineered substitutions of this aspartate residue led to complete inactivation, which was proposed to arise from elimination of a productive intersite electron transfer pathway [Parales, R. E., Parales, J. V., and Gibson, D. T. (1999) J. Bacteriol. 181, 1831-1837]. Substitutions of the corresponding aspartate, D218, in AntAB with alanine, asparagine, or glutamate also resulted in enzymes that were completely inactive over a wide pH range despite retention of the hexameric quaternary structure and iron center occupancy. The Rieske center reduction potential of this variant was measured to be approximately 100 mV more negative than that for the wild-type enzyme at neutral pH. The wild-type AntAB became completely inactive at pH 9 and exhibited an altered Rieske center absorption spectrum which resembled that of the D218 variants at neutral pH. These results support a role for this aspartate in maintaining the protonated state and reduction potential of the Rieske center. Both the wild-type and D218A variant AntABs exhibited substrate-dependent rapid phases of Rieske center oxidations in stopped-flow time courses. This observation does not support a role for this aspartate in a facile intersite electron transfer pathway or in productive substrate gating of the Rieske center reduction potential. However, since the single turnovers resulted in anthranilate dihydroxylation by the wild-type enzyme but not by the D218A variant, this aspartate must also play a crucial role in substrate dihydroxylation at or near the mononuclear iron site.     

The reduction of the Rieske iron-sulfur cluster in naphthalene dioxygenase by X-rays

Naphthalene 1,2 dioxygenase (NDO) displays characteristic UV-Vis spectra depending on the oxidation state of the Rieske center. Investigations on crystals of NDO grown for X-ray diffraction experiments showed spectra characteristic of the oxidized form. Crystals reduced in an anaerobic glovebox using sodium-dithionite showed a characteristic reduced spectrum. Spectra of crystals (cooled to 100 K) after being exposed to X-rays for data collection showed spectra corresponding to a reduced Rieske iron center, demonstrating the ability of X-rays to change the oxidation state of the Rieske iron-sulfur cluster in NDO.     

Rieske business: structure-function of Rieske non-heme oxygenases

Rieske non-heme iron oxygenases (RO) catalyze stereo- and regiospecific reactions. Recently, an explosion of structural information on this class of enzymes has occurred in the literature. ROs are two/three component systems: a reductase component that obtains electrons from NAD(P)H, often a Rieske ferredoxin component that shuttles the electrons and an oxygenase component that performs catalysis. The oxygenase component structures have all shown to be of the alpha3 or alpha3beta3 types. The transfer of electrons happens from the Rieske center to the mononuclear iron of the neighboring subunit via a conserved aspartate, which is shown to be involved in gating electron transport. Molecular oxygen has been shown to bind side-on in naphthalene dioxygenase and a concerted mechanism of oxygen activation and hydroxylation of the ring has been proposed. The orientation of binding of the substrate to the enzyme is hypothesized to control the substrate selectivity and regio-specificity of product formation.     

Benzene-induced uncoupling of naphthalene dioxygenase activity and enzyme inactivation by production of hydrogen peroxide

Naphthalene dioxygenase (NDO) is a multicomponent enzyme system that oxidizes naphthalene to (+)-cis-(1R,2S)-1,2-dihydroxy-1, 2-dihydronaphthalene with consumption of O2 and two electrons from NAD(P)H. In the presence of benzene, NADH oxidation and O2 utilization were partially uncoupled from substrate oxidation. Approximately 40 to 50% of the consumed O2 was detected as hydrogen peroxide. The rate of benzene-dependent O2 consumption decreased with time, but it was partially increased by the addition of catalase in the course of the O2 consumption by NDO. Detailed experiments showed that the total amount of O2 consumed and the rate of benzene-induced O2 consumption increased in the presence of hydrogen peroxide-scavenging agents, and further addition of the terminal oxygenase component (ISPNAP) of NDO. Kinetic studies showed that ISPNAP was irreversibly inactivated in the reaction that contained benzene, but the inactivation was relieved to a high degree in the presence of catalase and partially relieved in the presence of 0.1 mM ferrous ion. Benzene- and naphthalene-reacted ISPNAP gave almost identical visible absorption spectra. In addition, hydrogen peroxide added at a range of 0.1 to 0.6 mM to the reaction mixtures inactivated the reduced ISPNAP containing mononuclear iron. These results show that hydrogen peroxide released during the uncoupling reaction acts both as an inhibitor of benzene-dependent O2 consumption and as an inactivator of ISPNAP. It is proposed that the irreversible inactivation of ISPNAP occurs by a Fenton-type reaction which forms a strong oxidizing agent, hydroxyl radicals (. OH), from the reaction of hydrogen peroxide with ferrous mononuclear iron at the active site. Furthermore, when [14C]benzene was used as the substrate, cis-benzene 1,2-dihydrodiol formed by NDO was detected. This result shows that NDO also couples a trace amount of benzene to both O2 consumption and NADH oxidation.     

Methane monooxygenase component B and reductase alter the regioselectivity of the hydroxylase component-catalyzed reactions. A novel role for protein-protein interactions in an oxygenase mechanism.

The soluble methane monooxygenase (MMO) system, consisting of reductase, component B, and hydroxylase (MMOH), catalyzes NADH and O2-dependent monooxygenation of many hydrocarbons. MMOH contains 2 mu-(H or R)oxo-bridged dinuclear iron clusters thought to be the sites of catalysis. Although rapid NADH-coupled turnover requires all three protein components, three less complex systems are also functional: System I, NADH, O2, reductase, and MMOH; System II, H2O2 and oxidized MMOH; System III, MMOH reduced nonenzymatically by 2e- and then exposed to O2 (single turnover). All three systems give the same products, suggesting a common reactive oxygen species. However, the distribution of products observed for most substrates that are hydroxylated in more than one position is different for each system. For several of these substrates, addition of component B to Systems I, II, or III causes the product distributions to shift dramatically. These shifts result in identical product distributions for Systems I and III in which MMOH passes through the 2e- reduced state ([Fe(II).Fe(II)]) during catalysis. In contrast, System II (in which MMOH probably does not become reduced) generally gives a unique product distribution. It is proposed that changes in MMOH structure occurring upon diiron cluster reduction and/or component complex formation cause substrates to be presented differently to the activated oxygen species. Kinetic studies show that component B strongly activates System I and, in most cases, strongly deactivates System II. The effect of component B on product distribution of System I (and III) occurs at less than 5% of the MMOH concentration, while nearly stoichiometric concentrations are required to maximize the rate of System I. This shows that component B has at least two roles in catalysis. EPR monitored titration of reduced MMOH ([Fe(II).Fe(II)]) with component B suggests that the effect of substoichiometric component B on product distribution is due to hysteresis in the MMOH conformational changes.     

Toluene and ethylbenzene oxidation by purified naphthalene dioxygenase from Pseudomonas sp. strain NCIB 9816-4.

Purified naphthalene dioxygenase (NDO) from Pseudomonas sp. strain NCIB 9816-4 oxidized toluene to benzyl alcohol and benzaldehyde by reactions involving benzylic monooxygenation and dioxygen-dependent alcohol oxidation, respectively. Xylene and nitrotoluene isomers were also oxidized to substituted benzyl alcohol and benzaldehyde derivatives. NDO oxidized ethylbenzene sequentially through (S)-1-phenethyl alcohol (77% enantiomeric excess) and acetophenone to 2-hydroxyacetophenone. In addition, NDO also oxidized ethylbenzene through styrene to (R)-1-phenyl-1,2-ethanediol (74% enantiomeric excess) by reactions involving desaturation and dihydroxylation, respectively. Isotope experiments with 18O2, H2 18O, and D2O suggest that 1-phenethyl alcohol is oxidized to acetophenone by a minor reaction involving desaturation followed by tautomerization. The major reaction in the conversion of 1-phenethyl alcohol and benzyl alcohol to acetophenone and benzaldehyde, respectively, probably involves monohydroxylation to form a gem-diol intermediate which stereospecifically loses the incoming hydroxyl group to leave the carbonyl product. These results are compared with similar reactions catalyzed by cytochrome P-450.     

Substrate specificity of naphthalene dioxygenase: effect of specific amino acids at the active site of the enzyme

The three-component naphthalene dioxygenase (NDO) enzyme system carries out the first step in the aerobic degradation of naphthalene by Pseudomonas sp. strain NCIB 9816-4. The three-dimensional structure of NDO revealed that several of the amino acids at the active site of the oxygenase are hydrophobic, which is consistent with the enzyme's preference for aromatic hydrocarbon substrates. Although NDO catalyzes cis-dihydroxylation of a wide range of substrates, it is highly regio- and enantioselective. Site-directed mutagenesis was used to determine the contributions of several active-site residues to these aspects of catalysis. Amino acid substitutions at Asn-201, Phe-202, Val-260, Trp-316, Thr-351, Trp-358, and Met-366 had little or no effect on product formation with naphthalene or biphenyl as substrates and had slight but significant effects on product formation from phenanthrene. Amino acid substitutions at Phe-352 resulted in the formation of cis-naphthalene dihydrodiol with altered stereochemistry [92 to 96% (+)-1R,2S], compared to the enantiomerically pure [>99% (+)-1R,2S] product formed by the wild-type enzyme. Substitutions at position 352 changed the site of oxidation of biphenyl and phenanthrene. Substitution of alanine for Asp-362, a ligand to the active-site iron, resulted in a completely inactive enzyme.     

2-Oxoquinoline 8-monooxygenase oxygenase component: active site modulation by Rieske-[2Fe-2S] center oxidation/reduction

2-Oxoquinoline 8-monooxygenase is a Rieske non-heme iron oxygenase that catalyzes the NADH-dependent oxidation of the N-heterocyclic aromatic compound 2-oxoquinoline to 8-hydroxy-2-oxoquinoline in the soil bacterium Pseudomonas putida 86. The crystal structure of the oxygenase component of 2-oxoquinoline 8-monooxygenase shows a ring-shaped, C3-symmetric arrangement in which the mononuclear Fe(II) ion active site of one monomer is at a distance of 13 A from the Rieske-[2Fe-2S] center of a second monomer. Structural analyses of oxidized, reduced, and substrate bound states reveal the molecular bases for a new function of Fe-S clusters. Reduction of the Rieske center modulates the mononuclear Fe through a chain of conformational changes across the subunit interface, resulting in the displacement of Fe and its histidine ligand away from the substrate binding site. This creates an additional coordination site at the mononuclear Fe(II) ion and can open a pathway for dioxygen to bind in the substrate-containing active site.     

Methane monooxygenase from Methylosinus trichosporium OB3b. Purification and properties of a three-component system with high specific activity from a type II methanotroph

Methane monooxygenase has been purified from the Type II methanotroph Methylosinus trichosporium OB3b. As observed for methane monooxygenase isolated from Type I methanotrophs, three protein components are required: a 39.7-kDa NADH reductase containing 1 mol each of FAD and a [2Fe-2S] cluster, a 15.8-kDa protein factor termed component B that contains no metals or cofactors, and a 245-kDa hydroxylase which appears to contain an oxo- or hydroxo-bridged binuclear iron cluster. Through the use of stabilizing reagents, the hydroxylase is obtained in high yield and exhibits a specific activity 8-25-fold greater than reported for previous preparations. The component B and reductase exhibit 1.5- and 4-fold greater specific activity, respectively. Quantitation of the hydroxylase oxo-bridged cluster using EPR and M?ssbauer spectroscopies reveals that the highest specific activity preparations (approximately 1700 nmol/min/mg) contain approximately 2 clusters/mol. In contrast, hydroxylase preparations exhibiting a wide range of specific activities below 500 nmol/min/mg contain approximately 1 cluster/mol on average. Efficient turnover coupled to NADH oxidation requires all three protein components. However, both alkanes and alkenes are hydroxylated by the chemically reduced hydroxylase under single turnover conditions in the absence of component B and the reductase. Neither of these components catalyzes hydroxylation individually nor do they significantly affect the yield of hydroxylated product from the chemically reduced hydroxylase. Hydroxylase reduced only to the mixed valent [Fe(II).Fe(III)] state is unreactive toward O2 and yields little hydroxylated product on single turnover. This suggests that the catalytically active species is the fully reduced form. The data presented here provide the first evidence based on catalysis that the site of the monooxygenation reaction is located on the hydroxylase. It thus appears likely that the oxo-bridged iron cluster is capable of catalyzing oxygenase reactions without the intervention of other cofactors. This is a novel function for this type of cluster and implies a new mechanism for the generation of highly reactive oxygen capable of insertion into unactivated carbon-hydrogen bonds.     

X-ray absorption spectroscopy of the [2Fe-2S] Rieske cluster in Pseudomonas cepacia phthalate dioxygenase. Determination of core dimensions and iron ligation

We have employed X-ray absorption spectroscopy to obtain structural information about the Rieske Fe/S center in the phthalate dioxygenase (PDO) from Pseudomonas cepacia. Native PDO contains a dinuclear Rieske Fe/S center and an additional mononuclear Fe site. In order to study selectively the Fe/S cluster, we measured data for samples in which the mononuclear site was either depleted of metal or reconstituted with Co or Zn. Our results demonstrate that the iron environment in the Rieske cluster is structurally indistinguishable from that found in other Fe/S clusters, thus strongly supporting the suggestion that the unusually high reduction potentials for Rieske clusters are due to electrostatic rather than structural effects. The average Fe-Fe distance is 2.68 (3) A for both oxidized and reduced Rieske clusters. The average Fe-S distance is 2.24 (2) A in the oxidized cluster and 2.28 (2) A in the reduced cluster. Careful analysis of the EXAFS Debye-Waller factors suggests that the bridging and terminal Fe-S distances for the oxidized cluster are 2.20 and 2.31 A, respectively. Taken together with recent ENDOR results, these studies provide a detailed structural model for the Rieske [2Fe-2S] centers.     

Substitutions of the "bridging" aspartate 178 result in profound changes in the reactivity of the Rieske center of phthalate dioxygenase

Phthalate dioxygenase (PDO) and its reductase (PDR) are parts of a two-component Rieske oxygenase system that initiates the aerobic breakdown of phthalate by forming cis-4,5-dihydro-4,5-dihydroxyphthalate. Aspartate D178 in PDO, which lies between the Rieske [2Fe-2S] center of one subunit and the mononuclear center of the adjacent subunit, is highly conserved among the Rieske dioxygenases. The analogous aspartate has been implicated in electron transfer in naphthalene dioxygenase and in substrate binding and oxygen reactivity in anthranilate dioxygenase. Substitution of D178 with alanine or asparagine in PDO resulted in proteins with significantly increased Fe(II) dissociation constants. The rates of oxidation of the reduced Rieske centers in D178A and D178N were decreased by more than 10(4)-fold; only part of the loss of activity can be attributed to depletion of iron from the mononuclear centers. Reduction of PDO by reduced PDR was also slower in the D178A and D178N variants. Observed decreases in turnover rates of D178A and D178N compared to that of wild-type (WT) PDO (>10(2)-fold) can be ascribed to the cumulative effect of the low intrinsic iron content of the D178A and D178N mutants and the combination of the decreased rates of Rieske center reduction and oxidation. The coupling of dihydrodiol formation approached 100% in WT PDO but was only approximately 16% in D178A and approximately 7% in D178N. In single-turnover experiments, very small amounts of DHD were produced by D178A and D178N "as purified". The presence of saturating amounts of ferrous ion improved coupling to nearly 100% for the D178N variant but only slightly improved coupling for D178A. Thus, although hydroxylation is still possible in the variants, the reactions are largely uncoupled due to slow intramolecular electron transfer rates and the apparent weak binding of iron at the mononuclear centers.     

Reconstitution and characterization of aminopyrrolnitrin oxygenase, a Rieske N-oxygenase that catalyzes unusual arylamine oxidation

Rieske oxygenases catalyze a wide variety of important oxidation reactions. Here we report the characterization of a novel Rieske N-oxygenase, aminopyrrolnitrin oxygenase (PrnD) that catalyzes the unusual oxidation of an arylamine to an arylnitro group. PrnD from Pseudomonas fluorescens Pf5 was functionally expressed in Escherichia coli, and the activity of the purified PrnD was reconstituted, which required in vitro assembly of the Rieske iron-sulfur cluster into the protein and the presence of NADPH, FMN, and an E. coli flavin reductase SsuE. Biochemical and bioinformatics studies indicated that the reconstituted PrnD contains a Rieske iron-sulfur cluster and a mononuclear iron center that are formed by residues Cys(69), Cys(88), His(71), His(91), Asp(323), His(186), and His(191), respectively. The enzyme showed a limited range of substrate specificity and catalyzed the conversion of aminopyrrolnitrin into pyrrolnitrin with K(m) = 191 microM and k(cat) = 6.8 min(-1). Isotope labeling experiments with (18)O(2) and H(2)(18)O suggested that the oxygen atoms in the pyrrolnitrin product are derived exclusively from molecular oxygen. In addition, it was found that the oxygenation of the arylamine substrates catalyzed by PrnD occurs at the enzyme active site and does not involve free radical chain reactions. By analogy to known examples of arylamine oxidation, a catalytic mechanism for the bioconversion of amino pyrrolnitrin into pyrrolnitrin was proposed. Our results should facilitate further mechanistic and crystallographic studies of this arylamine oxygenase and may provide a new enzymatic route for the synthesis of aromatic nitro compounds from their corresponding aromatic amines.     

Regioselectivity and enantioselectivity of naphthalene dioxygenase during arene cis-dihydroxylation: control by phenylalanine 352 in the alpha subunit

The naphthalene dioxygenase (NDO) system catalyzes the first step in the degradation of naphthalene by Pseudomonas sp. strain NCIB 9816-4. The enzyme has a broad substrate range and catalyzes several types of reactions including cis-dihydroxylation, monooxygenation, and desaturation. Substitution of valine or leucine at Phe-352 near the active site iron in the alpha subunit of NDO altered the stereochemistry of naphthalene cis-dihydrodiol formed from naphthalene and also changed the region of oxidation of biphenyl and phenanthrene. In this study, we replaced Phe-352 with glycine, alanine, isoleucine, threonine, tryptophan, and tyrosine and determined the activity with naphthalene, biphenyl, and phenanthrene as substrates. NDO variants F352W and F352Y were marginally active with all substrates tested. F352G and F352A had reduced but significant activity, and F352I, F352T, F352V, and F352L had nearly wild-type activities with respect to naphthalene oxidation. All active enzymes had altered regioselectivity with biphenyl and phenanthrene. In addition, the F352V and F352T variants formed the opposite enantiomer of biphenyl cis-3,4-dihydrodiol [77 and 60% (-)-(3S,4R), respectively] to that formed by wild-type NDO [>98% (+)-(3R,4S)]. The F352V mutant enzyme also formed the opposite enantiomer of phenanthrene cis-1,2-dihydrodiol from phenanthrene to that formed by biphenyl dioxygenase from Sphingomonas yanoikuyae B8/36. A recombinant Escherichia coli strain expressing the F352V variant of NDO and the enantioselective toluene cis-dihydrodiol dehydrogenase from Pseudomonas putida F1 was used to produce enantiomerically pure (-)-biphenyl cis-(3S,4R)-dihydrodiol and (-)-phenanthrene cis-(1S,2R)-dihydrodiol from biphenyl and phenanthrene, respectively.     

Naphthalene dioxygenase: purification and properties of a terminal oxygenase component

Naphthalene dioxygenase from Pseudomonas sp. strain NCIB 9816 is a multicomponent enzyme system that oxidized naphthalene to cis-(1R, 2S)-dihydroxy-1,2-dihydronaphthalene. The terminal oxygenase component B was purified to homogeneity by a three-step procedure that utilized ion-exchange and hydrophobic interaction chromatography. The purified enzyme oxidized naphthalene only in the presence of NADH, oxygen, and partially purified preparations of components A and C. An estimated Mr of 158,000 was obtained by gel filtration. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate revealed the presence of two subunits with molecular weights of ca. 55,000 and 20,000, indicative of an alpha 2 beta 2 quaternary structure. Absorption spectra of the oxidized enzyme showed maxima at 566 (shoulder), 462, and 344 nm, which were replaced by absorption maxima at 520 and 380 nm when the enzyme was reduced anaerobically by stoichiometric quantities of NADH in the presence of the other two components of the naphthalene dioxygenase system. Component B bound naphthalene. Enzyme-bound naphthalene was oxidized to product upon the addition of components A and C, NADH, and O2. These results, together with the detection of the presence of 6.0 g-atoms of iron and 4.0 g-atoms of acid-labile sulfur per mol of the purified enzyme, suggest that component B of the naphthalene dioxygenase system is an iron-sulfur protein which functions in the terminal step of naphthalene oxidation.     

Rates of the phthalate dioxygenase reaction with oxygen are dramatically increased by interactions with phthalate and phthalate oxygenase reductase

The phthalate dioxygenase system, which catalyzes the dihydroxylation of phthalate to form its cis-dihydrodiol (DHD), has two components: phthalate dioxygenase (PDO), a multimer with one Rieske-type [2Fe-2S] and one Fe(II) center per monomer, and phthalate dioxygenase reductase (PDR), which contains flavin mononucleotide (FMN) and a plant-like ferredoxin [2Fe-2S] center. PDR is responsible for transferring electrons from NADH to the Rieske center of PDO, and the Rieske center supplies electrons to the mononuclear center for the oxygenation of substrate. Reduced PDO (PDO(red)) that lacks Fe(II) at the mononuclear metal site (PDO-APO) reacts slowly with O(2) (1.4 x 10(-3) s(-1) at 125 microM O(2) and 22 degrees C), presumably in a direct reaction with the Rieske center. Binding of phthalate and/or PDR(ox) to reduced PDO-APO increases the reactivity of the Rieske center with O(2). When no PDR or phthalate is present, the oxidation of the Rieske center in native PDO(red) [which contains Fe(II) at the mononuclear site] occurs in two phases (approximately 1 and 0.1 s(-1) at 125 mM O(2), 23 degrees C), both much faster than in the absence of Fe(II), presumably because in this case O(2) reacts at the mononuclear Fe(II). Addition of PDR(ox) to native PDO(red) resulted in a large fraction of the Rieske center being oxidized at 5 s(-1), and the addition of phthalate resulted in about 70% of the reaction proceeding at 42 s(-1). With both PDR(ox) and phthalate present, most of the PDO(red) (approximately 80-85%) oxidizes at 42 s(-1), with the remaining oxidizing at approximately 5 s(-1). Thus, the binding of phthalate or PDR(ox) to PDO(red) each results in greater reactivity of PDO with O(2). The presence of both the substrate and PDR was synergistic, making PDO fully catalytically active. A model that explains the observed effects is presented and discussed in terms of PDO subunit cooperativity. It is proposed that, during oxidation of reduced PDO, each of two Rieske centers on separate subunits transfers an electron to the Fe(II) mononuclear center on a third subunit. This explanation is consistent with the observed multiphasic kinetics of the oxidation of the Rieske center and is being further tested by product analysis experiments.     

Plasmon waveguide resonance spectroscopic evidence for differential binding of oxidized and reduced Rhodobacter capsulatus cytochrome c2 to the cytochrome bc1 complex mediated by the conformation of the Rieske iron-sulfur protein

The dissociation constants for the binding of Rhodobacter capsulatus cytochrome c2 and its K93P mutant to the cytochrome bc1 complex embedded in a phospholipid bilayer were measured by plasmon waveguide resonance spectroscopy in the presence and absence of the inhibitor stigmatellin. The reduced form of cytochrome c2 strongly binds to reduced cytochrome bc1 (Kd = 0.02 microM) but binds much more weakly to the oxidized form (Kd = 3.1 microM). In contrast, oxidized cytochrome c2 binds to oxidized cytochrome bc1 in a biphasic fashion with Kd values of 0.11 and 0.58 microM. Such a biphasic interaction is consistent with binding to two separate sites or conformations of oxidized cytochrome c2 and/or cytochrome bc1. However, in the presence of stigmatellin, we find that oxidized cytochrome c2 binds to oxidized cytochrome bc1 in a monophasic fashion with high affinity (Kd = 0.06 microM) and reduced cytochrome c2 binds less strongly (Kd = 0.11 microM) but approximately 30-fold more tightly than in the absence of stigmatellin. Structural studies with cytochrome bc1, with and without the inhibitor stigmatellin, have led to the proposal that the Rieske protein is mobile, moving between the cytochrome b and cytochrome c1 components during turnover. In one conformation, the Rieske protein binds near the heme of cytochrome c1, while the cytochrome c2 binding site is also near the cytochrome c1 heme but on the opposite side from the Rieske site, where cytochrome c2 cannot directly interact with Rieske. However, the inhibitor, stigmatellin, freezes the Rieske protein iron-sulfur cluster in a conformation proximal to cytochrome b and distal to cytochrome c1. We conclude from this that the dual conformation of the Rieske protein is primarily responsible for biphasic binding of oxidized cytochrome c2 to cytochrome c1. This optimizes turnover by maximizing binding of the substrate, oxidized cytochrome c2, when the iron-sulfur cluster is proximal to cytochrome b and minimizing binding of the product, reduced cytochrome c2, when it is proximal to cytochrome c1.