Cysteine dioxygenase (CDO) is a non-heme iron enzyme that catalyzes the O₂-dependent oxidation of l-cysteine (l-Cys) to produce cysteinesulfinic acid (CSA). Adjacent to the Fe site of CDO is a covalently cross-linked cysteine-tyrosine pair (C93-Y157). While several theories have been proposed for the function of the C93-Y157 pair, the role of this post-translational modification remains unclear. In this work, the steady-state kinetics and O₂/CSA coupling efficiency were measured for wild-type CDO and selected active site variants (Y157F, C93A, and H155A) to probe the influence of second-sphere enzyme-substrate interactions on catalysis. In these experiments, it was observed that both kcat and the O₂/CSA coupling efficiency were highly sensitive to the presence of the C93-Y157 cross-link and its proximity to the substrate carboxylate group. Complementary electron paramagnetic resonance (EPR) experiments were performed to obtain a more detailed understanding of the second-sphere interactions identified in O₂/CSA coupling experiments. Samples of the catalytically inactive substrate-bound Fe(III)-CDO species were treated with cyanide, resulting in a low-spin (S = ¹/₂) ternary complex. Remarkably, both the presence of the C93-Y157 pair and interactions with the Cys carboxylate group could be readily identified by perturbations to the rhombic EPR signal. Spectroscopically validated active site quantum mechanics/molecular mechanics and density functional theory computational models are provided to suggest a potential role for Y157 in the positioning of the substrate Cys in the active site and to verify the orientation of the g-tensor relative to the CDO Fe site molecular axis.
The iron-dependent oxidase UndA cleaves one C3–H bond and the C1–C2 bond of dodecanoic acid to produce 1-undecene and CO2. A published X-ray crystal structure showed that UndA has a heme-oxygenase-like fold, thus associating it with a structural superfamily that includes known and postulated non-heme diiron proteins, but revealed only a single iron ion in the active site. Mechanisms proposed for initiation of decarboxylation by cleavage of the C3–H bond using a monoiron cofactor to activate O2 necessarily invoked unusual or potentially unfeasible steps. Here we present spectroscopic, crystallographic, and biochemical evidence that the cofactor of Pseudomonas fluorescens Pf-5 UndA is actually a diiron cluster and show that binding of the substrate triggers rapid addition of O2 to the Fe2(II/II) cofactor to produce a transient peroxo-Fe2(III/III) intermediate. The observations of a diiron cofactor and substrate-triggered formation of a peroxo-Fe2(III/III) intermediate suggest a small set of possible mechanisms for O2, C3–H and C1–C2 activation by UndA; these routes obviate the problematic steps of the earlier hypotheses that invoked a single iron.
A ribonucleotide reductase (RNR) from Flavobacterium johnsoniae ( Fj) differs fundamentally from known (subclass a-c) class I RNRs, warranting its assignment to a new subclass, Id. Its β subunit shares with Ib counterparts the requirements for manganese(II) and superoxide (O) for activation, but it does not require the O-supplying flavoprotein (NrdI) needed in Ib systems, instead scavenging the oxidant from solution. Although Fj β has tyrosine at the appropriate sequence position (Tyr 104), this residue is not oxidized to a radical upon activation, as occurs in the Ia/b proteins. Rather, Fj β directly deploys an oxidized dimanganese cofactor for radical initiation. In treatment with one-electron reductants, the cofactor can undergo cooperative three-electron reduction to the II/II state, in contrast to the quantitative univalent reduction to inactive "met" (III/III) forms seen with I(a-c) βs. This tendency makes Fj β unusually robust, as the II/II form can readily be reactivated. The structure of the protein rationalizes its distinctive traits. A distortion in a core helix of the ferritin-like architecture renders the active site unusually open, introduces a cavity near the cofactor, and positions a subclass-d-specific Lys residue to shepherd O to the Mn cluster. Relative to the positions of the radical tyrosines in the Ia/b proteins, the unreactive Tyr 104 of Fj β is held away from the cofactor by a hydrogen bond with a subclass-d-specific Thr residue. Structural comparisons, considered with its uniquely simple mode of activation, suggest that the Id protein might most closely resemble the primordial RNR-β.
Cysteine dioxygenase (CDO) is a mononuclear non-heme iron(II)-dependent enzyme critical for maintaining appropriate cysteine (Cys) and taurine levels in eukaryotic systems. Since CDO possesses both an unusual 3-His facial ligation sphere to the iron center and a rare Cys-Tyr crosslink near the active site, the mechanism by which it converts Cys and molecular oxygen to cysteine sulfinic acid is of broad interest. However, as of yet direct experimental support for any of the proposed mechanisms is still lacking. In this study, we have used NO as a substrate analogue for O2 to prepare a species that mimics the geometric and electronic structures of an early reaction intermediate. The resultant unusual S=1/2 {FeNO}7 species was characterized by magnetic circular dichroism, electron paramagnetic resonance, and electronic absorption spectroscopies, as well as computational methods including density functional theory and semi-empirical calculations. The NO adducts of Cys- and selenocysteine (Sec)-bound Fe(II)CDO exhibit virtually identical electronic properties; yet, CDO is unable to oxidize Sec. To explore the differences in reactivity between Cys- and Sec-bound CDO, the geometries and energies of viable O2-bound intermediates were evaluated computationally, and it was found that a low-energy quintet-spin intermediate on the Cys reaction pathway adopts a different geometry for the Sec-bound adduct. The absence of a low-energy O2 adduct for Sec-bound CDO is consistent with our experimental data and may explain why Sec does not act as a substrate for CDO.
SignificanceConversion of ribonucleotides to the 2′-deoxyribonucleotides required for DNA biosynthesis is catalyzed by ribonucleotide reductases (RNRs) via a free-radical mechanism. Known types of RNRs all depend on redox-active transition metals—manganese, iron, or cobalt—for radical initiation. Pathogenic bacteria are challenged by transition metal sequestration and infliction of oxidative stress by their hosts, and the deployment of multiple RNRs with different metal requirements and radical-initiating oxidants is a known bacterial countermeasure. A class I RNR from two bacterial pathogens completely lacks transition metals in its active state and uses a tyrosine-derived dihydroxyphenylalanine radical as its initiator, embodying a novel tactic to combat transition metal- and oxidant-mediated innate immunity and reinforcing bacterial RNRs as potential antibiotic targets.
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