Crystal structure of the pristine peroxidase ferryl center and its relevance to proton-coupled electron transfer

Chreifi, Georges; Baxter, E.L.; Doukov, Tzanko; Cohen, Aina E.; McPhillips, S.E.; Song, Jianguo; Meharenna, Yergalem T.; Soltis, S. Michael; Poulos, T.L.

doi:10.1073/pnas.1521664113

Cited by 65 publications

(75 citation statements)

References 44 publications

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“…S1 and Results), 12 is completely absent in the coproheme decarboxylase. The coproheme is instead ligated by an uncharged proximal His (Fig 2–4) and its open coordination position is flanked by a distal Gln.…”

Section: Discussionmentioning

confidence: 79%

Structure-Based Mechanism for Oxidative Decarboxylation Reactions Mediated by Amino Acids and Heme Propionates in Coproheme Decarboxylase (HemQ)

et al. 2017

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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.

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Section: Discussionmentioning

confidence: 79%

Structure-Based Mechanism for Oxidative Decarboxylation Reactions Mediated by Amino Acids and Heme Propionates in Coproheme Decarboxylase (HemQ)

et al. 2017

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“…106–111 Hydrogen peroxide (H 2 O 2 ) has also been shown to convert Fe(III) compounds to Fe(V)═O species, 112, 113 or its redox equivalent. 107, 109, 111 In contrast to Fe(IV)═O compounds, 52, 98, 114–123 however, very few synthetic non-heme Fe(V)═O species have been observed. 93, 95, 96, 104, 113, 124 The most thoroughly characterized example, [Fe(V)(TAML)(O)] − , incorporates an electron-donating tetra-anionic carboxamide ligand ( vide inf ra ), TAML 4–93, 95, 104, 125, 126 .…”

Section: Resultsmentioning

confidence: 99%

Metal-Assisted Oxo Atom Addition to an Fe(III) Thiolate

et al. 2016

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Cysteinate oxygenation is intimately tied to the function of both cysteine dioxygenases (CDOs) and nitrile hydratases (NHases), and yet the mechanisms by which sulfurs are oxidized by these enzymes are unknown, in part because intermediates have yet to be observed. Herein, we report a five-coordinate bis-thiolate ligated Fe(III) complex, [FeIII(S2Me2N3-(Pr,Pr))]+ (2), that reacts with oxo atom donors (PhIO, IBX-ester, and H2O2) to afford a rare example of a singly oxygenated sulfenate, [FeIII(η2-SMe2O)(SMe2)N3(Pr,Pr)]+ (5), resembling both a proposed intermediate in the CDO catalytic cycle and the essential NHase Fe-S(O)Cys114 proposed to be intimately involved in nitrile hydrolysis. Comparison of the reactivity of 2 with that of a more electron-rich, crystallographically characterized derivative, [FeIIIS2Me2NMeN2amide(Pr,Pr)]− (8), shows that oxo atom donor reactivity correlates with the metal ion’s ability to bind exogenous ligands. Density functional theory calculations suggest that the mechanism of S-oxygenation does not proceed via direct attack at the thiolate sulfurs; the average spin-density on the thiolate sulfurs is approximately the same for 2 and 8, and Mulliken charges on the sulfurs of 8 are roughly twice those of 2, implying that 8 should be more susceptible to sulfur oxidation. Carboxamide-ligated 8 is shown to be unreactive towards oxo atom donors, in contrast to imine-ligated 2. Azide (N3−) is shown to inhibit sulfur oxidation with 2, and a green intermediate is observed, which then slowly converts to sulfenate-ligated 5. This suggests that the mechanism of sulfur oxidation involves initial coordination of the oxo atom donor to the metal ion. Whether the green intermediate is an oxo atom donor adduct, Fe-O═I-Ph, or an Fe(V)═O remains to be determined.

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“…9,10 Recent experimental findings have sparked discussions on whether protonation occurs at the Fe IV –oxo species or at a proximal site that then forms a H-bond to the oxido ligand. 11,12 The importance of protonated Fe IV –oxo species extends beyond heme proteins to non-heme systems that include the Rieske-type monooxygenases and synthetic systems, such as the one suggested by Fukusumi and Nam. 13,14 Unlike non-heme Fe IV –oxo species in which considerable progress has been made in understanding their properties, 15–20 there is a dearth of experimental evidence for protonated non-heme, Fe IV –oxo complexes.…”

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confidence: 99%

“…10,21–23 Furthermore, most synthetic systems lack intramolecular H-bonding networks that are vital in regulating the site of protonation in proteins with Fe IV –oxo units. 11,12 …”

mentioning

confidence: 99%

“…We argue these types of interactions are not limited to just our system and may occur within the active site of a protein or a synthetic complex, especially those with presumed high valent Fe–OH units. 11,12 For instance, mechanisms for non-heme iron enzymes and their synthetic models often invoke Fe IV –OH and Fe V –OH intermediates, 14,39–41 but evidence for the protonation of an Fe IV –oxo unit has only been observed in heme-containing proteins such as Compound II of P450s and the chloroperoxidases. 8,42,43 Such reactivity has yet to be definitively observed in other metalloproteins that invoke high valent Fe–OH species such as the Rieske non-heme oxygenases.…”

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confidence: 99%

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Reactivity of an Fe^IV-Oxo Complex with Protons and Oxidants

et al. 2016

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High valent Fe–OH species are often invoked as key intermediates but have only been observed in Compound II of cytochrome P450s. To further address the properties of non-heme FeIV–OH complexes we demonstrate the reversible protonation of a synthetic FeIV–oxo species containing a tris-urea tripodal ligand. The same protonated FeIV–oxo species can be prepared via oxidation, suggesting a putative FeV–oxo species was initially generated. Computational, Mössbauer, XAS, and NRVS studies indicate that protonation of the FeIV–oxo complex most likely occur on the tripodal ligand, which undergoes a structural change that results in the formation of a new intramolecular hydrogen bond with the oxido ligand that aids in stabilizing the protonated adduct. We suggest that similar species for protonated high valent Fe–oxo species may occur in the active sites of proteins. This finding further argues for caution when assigning unverified high valent Fe–OH species to mechanisms.

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Crystal structure of the pristine peroxidase ferryl center and its relevance to proton-coupled electron transfer

Cited by 65 publications

References 44 publications

Structure-Based Mechanism for Oxidative Decarboxylation Reactions Mediated by Amino Acids and Heme Propionates in Coproheme Decarboxylase (HemQ)

Structure-Based Mechanism for Oxidative Decarboxylation Reactions Mediated by Amino Acids and Heme Propionates in Coproheme Decarboxylase (HemQ)

Metal-Assisted Oxo Atom Addition to an Fe(III) Thiolate

Reactivity of an Fe^IV-Oxo Complex with Protons and Oxidants

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Crystal structure of the pristine peroxidase ferryl center and its relevance to proton-coupled electron transfer

Cited by 65 publications

References 44 publications

Structure-Based Mechanism for Oxidative Decarboxylation Reactions Mediated by Amino Acids and Heme Propionates in Coproheme Decarboxylase (HemQ)

Structure-Based Mechanism for Oxidative Decarboxylation Reactions Mediated by Amino Acids and Heme Propionates in Coproheme Decarboxylase (HemQ)

Metal-Assisted Oxo Atom Addition to an Fe(III) Thiolate

Reactivity of an FeIV-Oxo Complex with Protons and Oxidants

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Reactivity of an Fe^IV-Oxo Complex with Protons and Oxidants