Graham R. Moran

Spectroscopic and electronic structure studies of aromatic electrophilic attack and hydrogen-atom abstraction by non-heme iron enzymes

(4-Hydroxy)mandelate synthase (HmaS) and (4-hydroxyphenyl)pyruvate dioxygenase (HPPD) are two α-keto acid dependent mononuclear non-heme iron enzymes that use the same substrate, (4-hydroxyphenyl)pyruvate, but exhibit two different general reactivities. HmaS performs hydrogen-atom abstraction to yield benzylic hydroxylated product (S)-(4-hydroxy)mandelate, whereas HPPD utilizes an electrophilic attack mechanism that results in aromatic hydroxylated product homogentisate. These enzymes provide a unique opportunity to directly evaluate the similarities and differences in the reaction pathways used for these two reactivities. An FeII methodology using CD, magnetic CD, and variable-temperature, variable-field magnetic CD spectroscopies was applied to HmaS and compared with that for HPPD to evaluate the factors that affect substrate interactions at the active site and to correlate these to the different reactivities exhibited by HmaS and HPPD to the same substrate. Combined with density functional theory calculations, we found that HmaS and HPPD have similar substrate-bound complexes and that the role of the protein pocket in determining the different reactivities exhibited by these enzymes (hydrogen-atom abstraction vs. aromatic electrophilic attack) is to properly orient the substrate, allowing for ligand field geometric changes along the reaction coordinate. Elongation of the FeIVO bond in the transition state leads to dominant FeIIIO•− character, which significantly contributes to the reactivity with either the aromatic π-system or the CH σ-bond.

The diverse and pervasive chemistries of the α-keto acid dependent enzymes

The number of identified and confirmed α-keto acid dependent oxygenases is increasing rapidly. All of these enzymes have a relatively simple liganding arrangement for a single ferrous ion but collectively conduct a highly diverse set of chemistries. While hydroxylations and a variety of oxidation reactions have been most commonly observed, new reactions involving dealkylations, epimerizations and halogenations have recently been discovered. In this minireview we present what is known of the α-keto acid dependent enzymes and offer an argument that the chemistry that is unique to each enzyme occurs only after the production of a pivotal ferryl-oxo intermediate.

Activation of α-keto acid-dependent dioxygenases: application of an {FeNO}7/{FeO2}8 methodology for characterizing the initial steps of O2 activation.

The α-keto acid-dependent dioxygenases are a major subgroup within the O(2)-activating mononuclear nonheme iron enzymes. For these enzymes, the resting ferrous, the substrate plus cofactor-bound ferrous, and the Fe(IV)═O states of the reaction have been well studied. The initial O(2)-binding and activation steps are experimentally inaccessible and thus are not well understood. In this study, NO is used as an O(2) analogue to probe the effects of α-keto acid binding in 4-hydroxyphenylpyruvate dioxygenase (HPPD). A combination of EPR, UV-vis absorption, magnetic circular dichroism (MCD), and variable-temperature, variable-field (VTVH) MCD spectroscopies in conjunction with computational models is used to explore the HPPD-NO and HPPD-HPP-NO complexes. New spectroscopic features are present in the α-keto acid bound {FeNO}(7) site that reflect the strong donor interaction of the α-keto acid with the Fe. This promotes the transfer of charge from the Fe to NO. The calculations are extended to the O(2) reaction coordinate where the strong donation associated with the bound α-keto acid promotes formation of a new, S = 1 bridged Fe(IV)-peroxy species. These studies provide insight into the effects of a strong donor ligand on O(2) binding and activation by Fe(II) in the α-keto acid-dependent dioxygenases and are likely relevant to other subgroups of the O(2) activating nonheme ferrous enzymes.

Two roads diverged: the structure of hydroxymandelate synthase from Amycolatopsis orientalis in complex with 4-hydroxymandelate.

The crystal structure of the hydroxymandelate synthase (HMS).Co2+.hydroxymandelate (HMA) complex determined to a resolution of 2.3 A reveals an overall fold that consists of two similar beta-barrel domains, one of which contains the characteristic His/His/acid metal-coordination motif (facial triad) found in the majority of Fe2+-dependent oxygenases. The fold of the alpha-carbon backbone closely resembles that of the evolutionarily related enzyme 4-hydroxyphenylpyruvate dioxygenase (HPPD) in its closed conformation with a root-mean-square deviation of 1.85 A. HPPD uses the same substrates as HMS but forms instead homogentisate (HG). The active site of HMS is significantly smaller than that observed in HPPD, reflecting the relative changes in shape that occur in the conversion of the common HPP substrate to the respective HMA or HG products. The HMA benzylic hydroxyl and carboxylate oxygens coordinate to the Co2+ ion, and three other potential H-bonding interactions to active site residue side chains are observed. Additionally, it is noted that there is a buried well-ordered water molecule 3.2 A from the distal carboxylate oxygen. The p-hydroxyl group of HMA is within hydrogen-bonding distance of the side chain hydroxyl of a serine residue (Ser201) that is conserved in both HMS and HPPD. This potential hydrogen bond and the known geometry of iron ligation for the substrate allowed us to model 4-hydroxyphenylpyruvate (HPP) in the active sites of both HMS and HPPD. These models suggest that the position of the HPP substrate differs between the two enzymes. In HMS, HPP binds analogously to HMA, while in HPPD, the p-hydroxyl group of HPP acts as a hydrogen-bond donor and acceptor to Ser201 and Asn216, respectively. It is suggested that this difference in the ring orientation of the substrate and the corresponding intermediates influences the site of hydroxylation.

The three-his triad in Dke1: comparisons to the classical facial triad.

The oxygen activating mononuclear non-heme ferrous enzymes catalyze a diverse range of chemistry yet typically maintain a common structural motif: two histidines and a carboxylate coordinating the iron center in a facial triad. A new Fe(II) coordinating triad has been observed in two enzymes, diketone-cleaving dioxygenase, Dke1, and cysteine dioxygenase (CDO), and is composed of three histidine residues. The effect of this three-His motif in Dke1 on the geometric and electronic structure of the Fe(II) center is explored via a combination of absorption, CD, MCD, and VTVH MCD spectroscopies and DFT calculations. This geometric and electronic structure of the three-His triad is compared to that of the classical (2-His-1-carboxylate) facial triad in the alpha-ketoglutarate (alphaKG)-dependent dioxygenases clavaminate synthase 2 (CS2) and hydroxyphenylpyruvate dioxygenase (HPPD). Comparison of the ligand fields at the Fe(II) shows little difference between the three-His and 2-His-1-carboxylate facial triad sites. Acetylacetone, the substrate for Dke1, will also bind to HPPD and is identified as a strong donor, similar to alphaKG. The major difference between the three-His and 2-His-1-carboxylate facial triad sites is in MLCT transitions observed for both types of triads and reflects their difference in charge. These studies provide insight into the effects of perturbation of the facial triad ligation of the non-heme ferrous enzymes on their geometric and electronic structure and their possible contributions to reactivity.

Structural and mechanistic comparisons of the metal-binding members of the vicinal oxygen chelate (VOC) superfamily

The vicinal oxygen chelate family of enzymes catalyzes a highly diverse set of chemistries that derives from one common mechanistic trait: bidentate coordination to a divalent metal center by a substrate or intermediate or transition state through vicinal oxygen atoms. The array of reactions catalyzed by this family is mediated structurally by a common fold and protein-chelating residues that secure and localize a metal ion. The common fold has topological symmetry being comprised of two βαβββ units that form an incompletely closed barrel of β-sheet about the metal ion. Interestingly, despite the diversity of the reactions catalyzed and the large number of metals observed to bind and promote the chemistry, this semi-symmetrical open barrel extends metal liganding side chains inward from a highly positionally conserved constellation of amino acid residues within the structure. Moreover, the core barrel fold arises from an array of possible intra/inter domain and subunit arrangements of the individual βαβββ units that are universally observed to stack side-by-side contacting along the first β-strand of each. While there are examples of enzymes that use this fold and do not bind a metal ion, this review is concerned with summarizing the key structural and mechanistic correlations that can be made for the metal-dependent vicinal oxygen chelate enzyme family members.

Renalase Is an α-NAD(P)H Oxidase/Anomerase

Renalase is a protein hormone secreted into the blood by the kidney that is reported to lower blood pressure and slow heart rate. Since its discovery in 2005, renalase has been the subject of conjecture pertaining to its catalytic function. While it has been widely reported that renalase is the third monoamine oxidase (monoamine oxidase C) that oxidizes circulating catecholamines such as epinephrine, there has been no convincing demonstration of this catalysis in vitro. Renalase is a flavoprotein whose structural topology is similar to known oxidases, lysine demethylases, and monooxygenases, but its active site bears no resemblance to that of any known flavoprotein. We have identified the catalytic activity of renalase as an α-NAD(P)H oxidase/anomerase, whereby low equilibrium concentrations of the α-anomer of NADPH and NADH initiate rapid reduction of the renalase flavin cofactor. The reduced cofactor then reacts with dioxygen to form hydrogen peroxide and releases nicotinamide dinucleotide product in the β-form. These processes yield an apparent turnover number (0.5 s(-1) in atmospheric dioxygen) that is at least 2 orders of magnitude more rapid than any reported activity with catechol neurotransmitters. This highly novel activity is the first demonstration of a role for naturally occurring α-NAD(P)H anomers in mammalian physiology and the first report of a flavoprotein catalyzing an epimerization reaction.

Form Follows Function: Structural and Catalytic Variation in the Class A Flavoprotein Monooxygenases

Flavoprotein monooxygenases (FPMOs) exhibit an array of mechanistic solutions to a common chemical objective; the monooxygenation of a target substrate. Each FPMO efficiently couples reduction of a flavin cofactor by NAD(P)H to oxygenation of the target substrate via a (hydro)peroxyflavin intermediate. This purpose of this review is to describe in detail the Class A flavoprotein hydroxylases (FPMO) in the context of the other FPMO classes (B–F). Both one and two component FPMOs are found in nature. Two-component enzymes require, in addition to the monooxygenase, the involvement of a reductase that first catalyzes the reduction of the flavin by NAD(P)H. The Class A and B FPMOs are single-component and manage to orchestrate the same net reaction within a single peptide. The Class A enzymes have, by some considerable margin, the most complete research record. These enzymes use choreographed movements of the flavin ring that facilitate access of the organic substrates to the active site, provide a means for interaction of NADPH with the flavin, offer a mechanism to sequester the dioxygen reduction chemistry from solvent and a means to release the product. The majority of the discrete catalytic events of the catalytic cycle can be observed directly in exquisite detail using spectrophotometric kinetic methods and many of the key mechanistic conclusions are further supported by structural data. This review attempts to compile each of the key observations made for both paradigm and newly discovered examples of Class A FPMOs into a complete catalytic description of one enzymatic turnover.

Kynurenine 3-Monooxygenase from Pseudomonas fluorescens: Substrate-like Inhibitors both Stimulate Flavin Reduction and Stabilize the Flavin−Peroxo Intermediate yet Result in the Production of Hydrogen Peroxide

Kynurenine 3-monooxygenase (KMO) is a flavin-dependent hydroxylase that catalyzes the conversion of l-kynurenine (l-Kyn) to 3-hydroxykynurenine (3OHKyn) in the pathway for tryptophan catabolism. KMO inhibition has been widely suggested as an early treatment for stroke and other neurological disorders that involve ischemia. We have investigated the reductive and the oxidative half-reactions of a stable form of KMO from Pseudomonas fluorescens (KMO). The binding of l-Kyn by the enzyme is relatively slow and involves at least two reversible steps. The rate constant for reduction of the flavin cofactor by NADPH increases by a factor of approximately 2.5 x 10(3) when l-Kyn is bound. The rate of reduction of the KMO.l-Kyn complex is 160 s(-1), and the K(d) for the NADPH complex is 200 microM with charge-transfer absorption bands for the KMO(RED).l-Kyn.NADP(+) complex accumulating after reduction. The reduction potential of KMO is -188 mV and is unresponsive to the addition of l-Kyn or other inhibitory ligands. KMO inhibitors whose structures are reminiscent of l-Kyn such as m-nitrobenzoylalanine and benzoylalanine also stimulate reduction of flavin by NADPH and, in the presence of dioxygen, result in the stoichiometric liberation of hydrogen peroxide, diminishing the perceived therapeutic potential of inhibitors of this type. In the presence of the native substrate, the oxidative half-reaction exhibits triphasic absorbance data. A spectrum consistent with that of a peroxyflavin species accumulates and then decays to yield the oxidized enzyme. This species then undergoes minor spectral changes that, based on flavin difference spectra defined in the presence of 3OHKyn, can be correlated with product release. The oxidative half-reaction observed in the presence of saturating benzoylalanine or m-nitrobenzoylalanine also shows the accumulation of a peroxyflavin species that then decays to yield hydrogen peroxide without hydroxylation.

Role of Substrate Positioning in the Catalytic Reaction of 4-Hydroxyphenylpyruvate Dioxygenase-A QM/MM Study

Ring hydroxylation and coupled rearrangement reactions catalyzed by 4-hydroxyphenylpyruvate dioxygenase were studied with the QM/MM method ONIOM(B3LYP:AMBER). For electrophilic attack of the ferryl species on the aromatic ring, five channels were considered: attacks on the three ring atoms closest to the oxo ligand (C1, C2, C6) and insertion of oxygen across two bonds formed by them (C1-C2, C1-C6). For the subsequent migration of the carboxymethyl substituent, two possible directions were tested (C1→C2, C1→C6), and two different mechanisms were sought (stepwise radical, single-step heterolytic). In addition, formation of an epoxide (side)product and benzylic hydroxylation, as catalyzed by the closely related hydroxymandelate synthase, were investigated. From the computed reaction free energy profiles it follows that the most likely mechanism of 4-hydroxyphenylpyruvate dioxygenase involves electrophilic attack on the C1 carbon of the ring and subsequent single-step heterolytic migration of the substituent. Computed values of the kinetic isotope effect for this step are inverse, consistent with available experimental data. Electronic structure arguments for the preferred mechanism of attack on the ring are also presented.