Grit D. Straganz

Variations of the 2-His-1-carboxylate Theme in Mononuclear Non-Heme FeII Oxygenases

A facial triad of two histidine side chains and one aspartate or glutamate side chain forms the canonical metal‐coordinating motif in the catalytic centers of various mononuclear non‐heme FeII enzymes. Although these active sites are based on totally unrelated protein folds and bring about a wide range of chemical transformations, most of them share the ability to couple dioxygen reduction with the oxygenation of an organic substrate. With the increasing number of protein structures now solved, it has become clear that the 2‐His‐1‐carboxylate signature is less of a paradigm for non‐heme FeII active sites than had long been thought and that it can be replaced by alternative metal centers in various oxygenases, the structure–function relationships and proposed catalytic mechanisms of which are reviewed here. Metal coordination through three histidines and one glutamate constitutes the classical motif described for enzyme members of the cupin protein superfamily, such as aci‐reductone dioxygenase and quercetin dioxygenase, multiple metal forms of which (including the FeII type) are found in nature. Cysteine dioxygenase and diketone dioxygenase, which are strictly FeII‐dependent oxygenases based on the cupin fold, bind the catalytic metal through the homologous triad of histidines, but lack the fourth glutamate ligand. An α‐ketoglutarate‐dependent FeII halogenase shows metal coordination by two histidines as the only protein‐derived ligands, whilst carotene oxygenase, from a different protein fold family, features an FeII site consisting of four histidine side chains. These recently discovered metallocenters are discussed with respect to their metal‐binding properties and the reaction coordinates of the O2‐dependent conversions they catalyze.

Acetylacetone-cleaving enzyme Dke1: a novel C-C-bond-cleaving enzyme from Acinetobacter johnsonii.

The toxicity of acetylacetone has been demonstrated in various studies. Little is known, however, about metabolic pathways for its detoxification or mineralization. Data presented here describe for the first time the microbial degradation of acetylacetone and the characterization of a novel enzyme that initiates the metabolic pathway. From an Acinetobacter johnsonii strain that grew with acetylacetone as the sole carbon source, an inducible acetylacetone-cleaving enzyme was purified to homogeneity. The corresponding gene, coding for a 153 amino acid sequence that does not show any significant relationship to other known protein sequences, was cloned and overexpressed in Escherichia coli and gave high yields of active enzyme. The enzyme cleaves acetylacetone to equimolar amounts of methylglyoxal and acetate, consuming one equivalent of molecular oxygen. No exogenous cofactor is required, but Fe(2+) is bound to the active protein and essential for its catalytic activity. The enzyme has a high affinity for acetylacetone with a K (m) of 9.1 microM and a k(cat) of 8.5 s(-1). A metabolic pathway for acetylacetone degradation and the putative relationship of this novel enzyme to previously described dioxygenases are discussed.

Why do cysteine dioxygenase enzymes contain a 3-His ligand motif rather than a 2His/1Asp motif like most nonheme dioxygenases?

Density functional theory calculations on the oxygen activation process in cysteine dioxygenase (CDO) and three active site mutants whereby one histidine group is replaced by a carboxylic acid group are reported. The calculations predict an oxygen activation mechanism that starts from an Fe(III)-O-O(*) complex that has close lying singlet, triplet, and quintet spin states. A subsequent spin state crossing to the quintet spin state surfaces leads to formation of a ring-structure whereby an O-S bond is formed. This weakens the central O-O bond, which is subsequently broken to give sulfoxide and an iron-oxo complex. The second oxygen atom is transferred to the substrate after a rotation of the sulfoxide group. A series of calculations were performed on cysteine dioxygenase mutants with a 2His/1Asp motif rather than a 3His motif. These calculations focused on the differences in catalytic and electronic properties of nonheme iron systems with a 3His ligand system versus a 2His/1Asp motif, such as taurine/alpha-ketoglutarate dioxygenase (TauD), and predict why CDO has a 3His ligand system while TauD and other dioxygenases share a 2His/1Asp motif. One mutant (H86D) had the ligand trans to the dioxygen group replaced by acetate, while in another set of calculations the ligand trans to the sulfur group of cysteinate was replaced by acetate (H88D). The calculations show that the ligands influence the spin state ordering of the dioxygen bound complexes considerably and in particular stabilize the quintet spin state more so that the oxygen activation step should encounter a lower energetic cost in the mutants as compared to WT. Despite this, the mutant structures require higher O-O bond breaking energies. Moreover, the mutants create more stable iron-oxo complexes than the WT, but the second oxygen atom transfer to the substrate is accomplished with much higher reaction barriers than the WT system. In particular, a ligand trans to the sulfur atom of cysteine that pushes electrons to the iron will weaken the Fe-S bond and lead to dissociation of this bond in an earlier step in the catalytic cycle than the WT structure. On the other hand, replacement of the ligand trans to the dioxygen moiety has minor effects on cysteinate binding but enhances the barriers for the second oxygen transfer process. These studies have given insight into why cysteine dioxygenase enzymes contain a 3His ligand motif rather than 2His/1Asp and show that the ligand system is essential for optimal dioxygenation activity of the substrate. In particular, CDO mutants with a 2His/1Asp motif may give sulfoxides as byproduct due to incomplete dioxygenation processes.

Kinetic and CD/MCD spectroscopic studies of the atypical, three-His-ligated, non-heme Fe2+ center in diketone dioxygenase: the role of hydrophilic outer shell residues in catalysis.

Diketone cleaving enzyme (Dke1) is a dioxygenase with an atypical, three-histidine-ligated, mononuclear non-heme Fe(2+) center. To assess the role in enzyme catalysis of the hydrophilic residues in the active site pocket, residues Glu98, Arg80, Tyr70, and Thr107 were subjected to mutational analysis. Steady state and pre-steady state kinetics indicated a role for Glu98 in promoting both substrate binding and O(2) reduction. Additionally, the Glu98 substitution eliminated the pH dependence of substrate binding (k(cat)(app)/K(M)(app)-pH profile) present in wild-type Dke1 (pK(a) = 6.3 +/- 0.4 and 8.4 +/- 0.4). MCD spectroscopy revealed that the Glu98 --> Gln mutation leads to the conversion of the six-coordinate (6C) resting Fe(2+) center present in the wild-type enzyme at pH 7.0 to a mixture of five-coordinate (5C) and 6C sites. The 6C geometry was restored with a pH shift to 9.5 which also resulted in ligand field (LF) energy splittings identical to that found for wild-type (WT) Dke1 at pH 9.5. In WT Dke1, these LF transitions are shifted up in energy by approximately 300 cm(-1) at pH 9.5 relative to pH 7.0. These data, combined with CD pH titrations which reveal a pK(a) of approximately 8.2 for resting WT Dke1 and the Glu98 --> Gln variant, indicate the deprotonation of a metal-ligated water. Together, the kinetic and spectroscopic data reveal a stabilizing effect of Glu98 on the 6C geometry of the metal center, priming it for substrate ligation. Arg80 and Tyr70 are shown to promote O(2) reduction, while Thr107 stabilizes the Fe(II) cofactor.

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.

Biochemical characterization and mutational analysis of the mononuclear non-haem Fe2+ site in Dke1, a cupin-type dioxygenase from Acinetobacter johnsonii

beta-diketone-cleaving enzyme Dke1 is a homotetrameric Fe2+-dependent dioxygenase from Acinetobacter johnsonii. The Dke1protomer adopts a single-domain beta-barrel fold characteristic of the cupin superfamily of proteins and features a mononuclear non-haem Fe2+ centre where a triad of histidine residues, His-62, His-64 and His-104, co-ordinate the catalytic metal. To provide structure-function relationships for the peculiar metal site of Dke1 in relation to the more widespread 2-His-1-Glu/Asp binding site for non-haem Fe2+,we replaced each histidine residue individually with glutamate and asparagine and compared binding of Fe2+ and four non-native catalytically inactive metals with purified apo-forms of wild-type and mutant enzymes. Results from anaerobic equilibrium microdialysis (Fe2+) and fluorescence titration (Fe2+, Cu2+, Ni2+, Mn2+ and Zn2+) experiments revealed the presence of two broadly specific metal-binding sites in native Dke1 that bind Fe2+ with a dissociation constant (Kd) of 5 microM (site I) and approximately 0.3 mM (site II). Each mutation, except for the substitution of asparagine for His-104, disrupted binding of Fe2+, but not that of the other bivalent metal ions, at site I,while leaving metal binding at site II largely unaffected. Dke1 mutants harbouring glutamate substitutions were completely inactive and not functionally complemented by external Fe2+.The Fe2+ catalytic centre activity (kcat) of mutants with asparagine substitution of His-62 and His-104 was decreased 140- and 220-fold respectively, compared with the kcat value of 8.5 s(-1) for the wild-type enzyme in the reaction with pentane-2,4-dione.The H64N mutant was not catalytically competent, except in the presence of external Fe2+ (1 mM) which elicited about 1/1000 of wild-type activity. Therefore co-ordination of Fe2+ by Dke1 requires an uncharged metallocentre, and three histidine ligands are needed for the assembly of a fully functional catalytic site. Oxidative inactivation of Dke1 was shown to involve conversion of enzyme-bound Fe2+ into Fe3+, which is then released from the metal centre.

More than just a Halogenase: Modification of Fatty Acyl Moieties by a Trifunctional Metal Enzyme

The highly selective oxidative halogenations by non‐heme iron and α‐ketoglutarate‐dependent enzymes are key reactions in the biosynthesis of lipopeptides, and often bestow valuable bioactivity to the metabolites. Here we present the first biochemical characterization of a putative fatty acyl halogenase, HctB, which is found in the hectochlorin biosynthetic pathway of Lyngbya majuscula. Its unprecedented three‐domain structure, which includes an acyl carrier protein domain, allows self‐contained conversion of the covalently tethered hexanoyl substrate. Structural analysis of the native product by 13C NMR reveals high regioselectivity but considerable catalytic promiscuity. This challenges the classification of HctB as a primary halogenase: along with the proposed dichlorination, HctB performs oxygenation and an unprecedented introduction of a vinyl‐chloride moiety into the nonactivated carbon chain. The relaxed substrate specificity is discussed with reference to a molecular model of the enzyme–substrate complex. The results suggest that fatty acyl transformation at the metal center of HctB can bring about considerable structural diversity in the biosynthesis of lipopeptides.

Spectroscopic and Computational Studies of α-keto Acid Binding to Dke1: Understanding the role of the facial triad and the reactivity of β-diketones

The O(2) activating mononuclear nonheme iron enzymes generally have a common facial triad (two histidine and one carboxylate (Asp or Glu) residue) ligating Fe(II) at the active site. Exceptions to this motif have recently been identified in nonheme enzymes, including a 3His triad in the diketone cleaving dioxygenase Dke1. This enzyme is used to explore the role of the facial triad in directing reactivity. A combination of spectroscopic studies (UV-vis absorption, MCD, and resonance Raman) and DFT calculations is used to define the nature of the binding of the α-keto acid, 4-hydroxyphenlpyruvate (HPP), to the active site in Dke1 and the origin of the atypical cleavage (C2-C3 instead of C1-C2) pattern exhibited by this enzyme in the reaction of α-keto acids with dioxygen. The reduced charge of the 3His triad induces α-keto acid binding as the enolate dianion, rather than the keto monoanion, found for α-keto acid binding to the 2His/1 carboxylate facial triad enzymes. The mechanistic insight from the reactivity of Dke1 with the α-keto acid substrate is then extended to understand the reaction mechanism of this enzyme with its native substrate, acac. This study defines a key role for the 2His/1 carboxylate facial triad in α-keto acid-dependent mononuclear nonheme iron enzymes in stabilizing the bound α-keto acid as a monoanion for its decarboxylation to provide the two additional electrons required for O(2) activation.

The Role of Chloride in the Mechanism of O2 Activation at the Mononuclear Nonheme Fe(II) Center of the Halogenase HctB

Mononuclear nonheme Fe(II) (MNH) and α-ketoglutarate (α-KG) dependent halogenases activate O2 to perform oxidative halogenations of activated and nonactivated carbon centers. While the mechanism of halide incorporation into a substrate has been investigated, the mechanism by which halogenases prevent oxidations in the absence of chloride is still obscure. Here, we characterize the impact of chloride on the metal center coordination and reactivity of the fatty acyl-halogenase HctB. Stopped-flow kinetic studies show that the oxidative transformation of the Fe(II)-α-KG-enzyme complex is >200-fold accelerated by saturating concentrations of chloride in both the absence and presence of a covalently bound substrate. By contrast, the presence of substrate, which generally brings about O2 activation at enzymatic MNH centers, only has an ∼10-fold effect in the absence of chloride. Circular dichroism (CD) and magnetic CD (MCD) studies demonstrate that chloride binding triggers changes in the metal center ligation: chloride binding induces the proper binding of the substrate as shown by variable-temperature, variable-field (VTVH) MCD studies of non-α-KG-containing forms and the conversion from six-coordinate (6C) to 5C/6C mixtures when α-KG is bound. In the presence of substrate, a site with square pyramidal five-coordinate (5C) geometry is observed, which is required for O2 activation at enzymatic MNH centers. In the absence of substrate an unusual trigonal bipyramidal site is formed, which accounts for the observed slow, uncoupled reactivity. Molecular dynamics simulations suggest that the binding of chloride to the metal center of HctB leads to a conformational change in the enzyme that makes the active site more accessible to the substrate and thus facilitates the formation of the catalytically competent enzyme–substrate complex. Results are discussed in relation to other MNH dependent halogenases.

Dke1—structure, dynamics, and function: a theoretical and experimental study elucidating the role of the binding site shape and the hydrogen-bonding network in catalysis

This study elucidates the role of the protein structure in the catalysis of β-diketone cleavage at the three-histidine metal center of diketone cleaving enzyme (Dke1) by computational methods in correlation with kinetic and mutational analyses. Molecular dynamics simulations, using quantum mechanically deduced parameters for the nonheme Fe(II) cofactor, were performed and showed a distinct organization of the hydrophilic triad in the free and substrate-ligated wild-type enzyme. It is shown that in the free species, the Fe(II) center is coordinated to three histidines and one glutamate, whereas the substrate-ligated, catalytically competent enzyme–substrate complex has an Fe(II) center with three-histidine coordination, with a small fraction of three-histidine, one-glutamate coordination. The substrate binding modes and channels for the traffic of water and ligands (2,4-pentandionyl anion, methylglyoxal, and acetate) were identified. To characterize the impact of the hydrophobic protein environment around the metal center on catalysis, a set of hydrophobic residues close to the active site were targeted. The variations resulted in an up to tenfold decrease of the O2 reduction rates for the mutants. Molecular dynamics studies revealed an impact of the hydrophobic residues on the substrate stabilization in the active site as well as on the orientations of Glu98 and Arg80, which have previously been shown to be crucial for catalysis. Consequently, the Glu98–His104 interaction in the variants is weaker than in the wild-type complex. The role of protein structure in stabilizing the primary O2 reduction step in Dke1 is discussed on the basis of our results.