Chlorite dismutase catalyzes O2 release from chlorite with exquisite efficiency and specificity. The spectroscopic properties, ligand binding affinities, and steady state kinetics of chlorite dismutase from Dechloromonas aromatica were examined over pH 3–11.5 to gain insight into how the protonation state of the heme environment influences dioxygen formation. An acid/base transition was observed by UV/visible and resonance Raman spectroscopy with a pKa of 8.7, 2–3 pH units below analogous transitions observed in typical His-ligated peroxidases. This transition marks the conversion of a five coordinate high spin Fe(III) to a mixed high/low spin ferric-hydroxide, as confirmed by resonance Raman (rR) spectroscopy. The two Fe–OH stretching frequencies are quite low, consistent with a weak Fe–OH bond, despite the nearly neutral imidazole side chain of the proximal histidine ligand. The hydroxide is proposed to interact strongly with a distal H-bond donor, thereby weakening the Fe–OH bond. The rR spectra of Cld-CO as a function of pH reveal two forms of the complex, one in which there is minimal interaction of distal residues with the carbonyl oxygen and another, acidic form in which the oxygen is under the influence of positive charge. Recent crystallographic data reveal arginine 183 as the lone H-bond donating residue in the distal pocket. It is likely that this Arg is the strong, positively charged H-bond donor implicated by vibrational data to interact with exogenous axial heme ligands. The same Arg in its neutral (pKa ~ 6.5) form also appears to act as the active site base in binding reactions of protonated ligands, such as HCN, to ferric Cld. The steady state profile for the rate of chlorite decomposition is characterized by these same pKas. The 5 coordinate high spin acidic Cld is more active than the alkaline hydroxide-bound form. The acid form decomposes chlorite most efficiently when the distal Arg is protonated/cationic (maximum kcat = 2.0 (±0.6) × 105 s−1, kcat/KM = 3.2 (±0.4) × 107 M−1s−1, pH 5.2, 4 °C) and to a somewhat lesser extent when it acts as a H-bond donor to the axial hydroxide ligand under alkaline conditions.
This PDF file includes:1. Complete experimental and computational details 2. Supplementary results 3. Supplementary discussion 4. List of supplementary figures 5. Supplementary Figure 1 to 26 6. Abbreviations list 7. Supplementary references 8. QM/MM optimized xyz coordinates of states 1-9 chromatography (HPAEC) coupled to pulsed amperometric detection (PAD) using a Dionex Bio-LC equipped with a CarboPac PA1 column as previously described. 3 To quantify A2 ox , a standard was produced in-house by treating chitobiose (Megazymes) with a chitooligosaccharide oxidase (ChitO) from Fusarium graminearum, which yields 100% conversion of chitobiose to chitobionic acid. 2,4 All chromatograms were recorded using Chromeleon 7.0 software.Chitin binding assay. The capacity of SmAA10A-WT and mutants thereof to bind β-chitin was tested by suspending 10 mg/mL of substrate in sodium phosphate buffer (50 mM, pH 7.0) in a total volume of 600 µL in 2 mL Eppendorf tubes. Reactions were started by the addition of SmAA10A (1 µM final concentration) and were incubated and stirred in an Eppendorf Comfort Thermomixer (at 40 °C, 1000 rpm). Samples were taken (100 µL) after 15, 30, 60, 120 and 240 min and immediately filtrated using a 96-well filter plate (Millipore) operated with a vacuum manifold to obtain the unbound protein fraction.In order to assess the percentage of bound proteins to the substrate, control samples with only enzyme and buffer were included, representing the maximum quantity of protein present in the samples (i.e. 100% unbound). The protein concentration in each sample was determined using the Bradford assay (Bio-Rad, Munich, Germany).H2O2 consumption experiments. H2O2 consumption by SmAA10A-WT and mutants thereof was measured according to a previously described protocol 5 using conditions that were slightly different from the standard reaction conditions described above: in order to be able to monitor the H2O2 consumption within a reasonable timescale the enzyme concentration had to be reduced and EDTA was added to reduce the background reaction of free metals-catalyzed H2O2 reduction (see Figure S6). After optimization, a standard reaction mixture contained the LPMO (50 nM) and H2O2 (100 µM) and EDTA (50 µM), without or with b-chitin (10 g.L -1 ), in sodium phosphate buffer (50 mM, pH 7.0), and the mixtures were incubated at 40 °C in a thermomixer (1000 rpm). The reactions were initiated by addition of AscA (20 µM final concentration). At regular intervals (t = 3, 6, 9, 12, 30 and 60 min), 70 µL of the reaction mixture was sampled, filtered as described above and 25 µL of the filtrate was mixed with 75 µL of a pre-mix of HRP (5 U.mL -1 final concentration) and Amplex® Red (ThermoFisher) (100 µM final concentration) in sodium phosphate buffer (50 mM pH 7.0). H2O2 concentrations waere then determined spectrophotometrically by measuring the absorbance at 540 nm in a microtiter plate reader.An H2O2 standard curve was prepared in the same conditions. Bioinformatics analysis. The sequence of the chitin-binding protein f...
dioxygen ͉ compound I ͉ peroxidase ͉ peroxygenase ͉ chlorite
Chlorite dismutase (Cld) is a heme enzyme capable of rapidly and selectively decomposing chlorite (ClO2−) to Cl− and O2. The ability of Cld to promote O2 formation from ClO2− is unusual. Heme enzymes generally utilize ClO2− as an oxidant for reactions such as oxygen atom transfer to, or halogenation of, a second substrate. The X-ray crystal structure of Dechloromonas aromatica Cld co-crystallized with the substrate analogue nitrite (NO2−) was determined to investigate features responsible for this novel reactivity. The enzyme active site contains a single b-type heme coordinated by a proximal histidine residue. Structural analysis identified a glutamate residue hydrogen-bonded to the heme proximal histidine that may stabilize reactive heme species. A solvent-exposed arginine residue likely gates substrate entry to a tightly confined distal pocket. On the basis of the proposed mechanism of Cld, initial reaction of ClO2− within the distal pocket generates hypochlorite (ClO−) and a compound I intermediate. The sterically restrictive distal pocket probably facilitates the rapid rebound of ClO− with compound I forming the Cl− and O2 products. Common to other heme enzymes, Cld is inactivated after a finite number of turnovers, potentially via the observed formation of an off-pathway tryptophanyl radical species through electron migration to compound I. Three tryptophan residues of Cld have been identified as candidates for this off-pathway radical. Finally, a juxtaposition of hydrophobic residues between the distal pocket and the enzyme surface suggests O2 may have a preferential direction for exiting the active site.
Chlorite dismutase carries out the heme-catalyzed decomposition of ClO2- to Cl- and O2, an unusual transformation with biotechnological and bioremediative applications. The enzyme has been successfully overexpressed for the first time in highly functional form in Escherichia coli and its steady state kinetics studied. The purified enzyme is abundant (55 mg/L cell culture), highly active (approximately 4.7 x 10(3) micromol of ClO2- min(-1) mg(-1) subunit) and nearly stoichiometric in heme; further, it shares spectroscopic and physicochemical features with chlorite dismutases previously isolated from three organisms. A careful study of the enzyme's steady state kinetics has been carried out. ClO2- consumption and O2 release rates were measured, yielding comparable values of kcat (4.5 x 10(5) min(-1)), K(m) (approximately 215 microM), and kcat/Km (3.5 x 10(7) M(-1) s(-1) via either method (4 degrees C, pH 6.8; all values referenced per heme-containing subunit). ClO2-:O2 stoichiometry exhibited a 1:1 relationship under all conditions measured. Though the value of kcat/Km indicates near diffusion control of the reaction, viscosogens had no effect on k(cat)/K(m) or V(max). The product O2 did not inhibit the reaction at saturating [O2], but Cl- is a mixed inhibitor with relatively high values of KI (225 mM for enzyme and 95.6 mM for the enzyme-substrate complex), indicating a relatively low affinity of the heme iron for halogen ions. Chlorite irreversibly inactivates the enzyme after approximately 1.7 x 10(4) turnovers (per heme) and with a half-life of 0.39 min, resulting in bleaching of the heme chromophore. The inactivation K(I) (K(inact)) of 166 microM is similar in magnitude to Km, consistent with a common Michaelis complex on the pathway to both reaction and inactivation. The one-electron peroxidase substrate guaiacol offers incomplete protection of the enzyme from inactivation. Mechanisms in keeping with the available data and the properties of other well-described heme enzymes are proposed.
A recently proposed pathway for heme b biosynthesis, common to diverse bacteria, has the conversion of two of the four propionates on coproheme III to vinyl groups as its final step. This reaction is catalyzed in a cofactor-independent, H2O2-dependent manner by the enzyme HemQ. Using the HemQ from Staphylococcus aureus (SaHemQ) the initial decarboxylation step was observed to rapidly and obligately yield the three-propionate harderoheme isomer III as the intermediate, while the slower second decarboxylation appeared to control the overall rate. Both synthetic harderoheme isomers III and IV reacted when bound to HemQ, the former more slowly than the latter. While H2O2 is the assumed biological oxidant, either H2O2 or peracetic acid yielded the same intermediates and products, though significantly greater than the expected two equivalents were required in both cases and peracetic acid reacted faster. The ability of peracetic acid to substitute for H2O2 suggests that, despite the lack of catalytic residues conventionally present in heme peroxidase active sites, reaction pathways involving high valent iron intermediates cannot be ruled out.
Coproheme decarboxylase catalyzes two sequential oxidative decarboxylations with H2O2 as the oxidant, coproheme III as substrate and cofactor, and heme b as the product. Each reaction breaks a C-C bond and results in net loss of hydride, via steps that are not clear. Solution and solid-state structural characterization of the protein in complex with a substrate analog revealed a highly unconventional H2O2-activating distal environment with the reactive propionic acids (2 and 4) on the opposite side of the porphyrin plane. This suggested that, in contrast to direct C-H bond cleavage catalyzed by a high-valent iron intermediate, the coproheme oxidations must occur through mediating amino acid residues. A tyrosine that hydrogen bonds to propionate 2 in a position analogous to the substrate in ascorbate peroxidase is essential for both decarboxylations, while a lysine that salt bridges to propionate 4 is required solely for the second. A mechanism is proposed in which propionate 2 relays an oxidizing equivalent from a coproheme compound I intermediate to the reactive deprotonated tyrosine, forming Tyr■. This residue then abstracts a net hydrogen atom (H■) from propionate 2, followed by migration of the unpaired propionyl electron to the coproheme iron to yield the ferric harderoheme and CO2 products. A similar pathway is proposed for decarboxylation of propionate 4, but with a lysine residue as an essential proton shuttle. The proposed reaction suggests an extended relay of heme-mediated e−/H+ transfers and a novel route for the conversion of carboxylic acids to alkenes.
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.
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