Spectroscopic analyses of 2-oxoglutarate-dependent oxygenases: TauD as a case study

Proshlyakov, Denis A.; McCracken, John; Hausinger, Robert P.

doi:10.1007/s00775-016-1406-3

Cited by 27 publications

(30 citation statements)

References 95 publications

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“…The presence of the alkoxide is somewhat surprising, given the high p K a of the hydroxyl group (~ 17). The observation may, however, be consistent with proposals of initial rebound of the deprotonated oxo unit 28 and could have important implications for bifunctional Fe/2OG enzymes that first hydroxylate their substrates and then effect distinct transformations of the alcohol (or alkoxide) intermediates. 8 …”

Section: Resultssupporting

confidence: 86%

Visualizing the Reaction Cycle in an Iron(II)- and 2-(Oxo)-glutarate-Dependent Hydroxylase

et al. 2017

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Iron(II)- and 2-(oxo)-glutarate-dependent oxygenases catalyze diverse oxidative transformations that are often initiated by abstraction of hydrogen from carbon by iron(IV)-oxo (ferryl) complexes. Control of the relative orientation of the substrate C–H and ferryl Fe–O bonds, primarily by direction of the oxo group into one of two cis-related coordination sites (termed inline and offline), may be generally important for control of the reaction outcome. Neither the ferryl complexes nor their fleeting precursors have been crystallographically characterized, hindering direct experimental validation of the offline hypothesis and elucidation of the means by which the protein might dictate an alternative oxo position. Comparison of high-resolution x-ray crystal structures of the substrate complex, an Fe(II)-peroxysuccinate ferryl precursor, and a vanadium(IV)-oxo mimic of the ferryl intermediate in the L-arginine 3-hydroxylase, VioC, reveals coordinated motions of active site residues that appear to control the intermediate geometries to determine reaction outcome.

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Section: Resultssupporting

confidence: 86%

Visualizing the Reaction Cycle in an Iron(II)- and 2-(Oxo)-glutarate-Dependent Hydroxylase

et al. 2017

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“…1 One notable example is the O 2 -activation by iron-containing heme and nonheme enzymes, in which iron–oxygen intermediates have been trapped and characterized using various spectroscopic techniques. 2,3 In biomimetic studies, a large number of iron–oxygen intermediates bearing porphyrin and nonporphyrin ligands have been successfully synthesized as the model compounds of the heme and nonheme iron enzymes, and their chemical properties as well as the mechanisms of the formation of the iron–oxygen intermediates have been elucidated using the model compounds. 4,5 In most of the model studies, artificial oxidants, such as iodosylbenzene (PhIO), peracids, NaOCl, H 2 O 2 , and alkyl hydroperoxides, have been used as surrogates for O 2 for the synthesis of the iron–oxygen intermediates.…”

Section: Introductionmentioning

confidence: 99%

Dioxygen Activation and O–O Bond Formation Reactions by Manganese Corroles

et al. 2017

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Activation of dioxygen (O2) in enzymatic and biomimetic reactions has been intensively investigated over the past several decades. More recently, O–O bond formation, which is the reverse of the O2-activation reaction, has been the focus of current research. Herein, we report the O2-activation and O–O bond formation reactions by manganese corrole complexes. In the O2-activation reaction, Mn(V)-oxo and Mn(IV)-peroxo intermediates were formed when Mn(III) corroles were exposed to O2 in the presence of base (e.g., OH−) and hydrogen atom (H atom) donor (e.g., THF or cyclic olefins); the O2-activation reaction did not occur in the absence of base and H atom donor. Moreover, formation of the Mn(V)-oxo and Mn(IV)-peroxo species was dependent on the amounts of base present in the reaction solution. The role of the base was proposed to lower the oxidation potential of the Mn(III) corroles, thereby facilitating the binding of O2 and forming a Mn(IV)-superoxo species. The putative Mn(IV)-superoxo species was then converted to the corresponding Mn(IV)-hydroperoxo species by abstracting a H atom from H atom donor, followed by the O–O bond cleavage of the putative Mn(IV)-hydroperoxo species to form a Mn(V)-oxo species. We have also shown that addition of hydroxide ion to the Mn(V)-oxo species afforded the Mn(IV)-peroxo species via O–O bond formation and the resulting Mn(IV)-peroxo species reverted to the Mn(V)-oxo species upon addition of proton, indicating that the O–O bond formation and cleavage reactions between the Mn(V)-oxo and Mn(IV)-peroxo complexes are reversible. The present study reports the first example of using the same manganese complex in both O2-activation and O–O bond formation reactions.

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“…14 In biomimetic studies, heme and nonheme iron-oxo complexes have been synthesized, characterized, and investigated in various oxidation reactions over the past several decades. 2,3 Compared to the heme and nonheme iron-oxo species, the chemistry of iron-imido analogs is less clearly understood.…”

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confidence: 99%

Achieving One-Electron Oxidation of a Mononuclear Nonheme Iron(V)-Imido Complex

et al. 2017

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A mononuclear nonheme iron(V)-imido complex bearing a tetraamido macrocyclic ligand (TAML), [FeV(NTs)(TAML)]− (1), was oxidized by one-electron oxidants, affording formation of an iron(V)-imido TAML cation radical species, [FeV(NTs)(TAML+•)] (2); 2 is a diamagnetic (S = 0) complex, resulting from the antiferromagnetic coupling of the low-spin iron(V) ion (S = 1/2) with the one-electron oxidized ligand (TAML+•). 2 is a competent oxidant in C–H bond functionalization and nitrene transfer reaction, showing that the reactivity of 2 is greater than that of 1.

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Spectroscopic analyses of 2-oxoglutarate-dependent oxygenases: TauD as a case study

Cited by 27 publications

References 95 publications

Visualizing the Reaction Cycle in an Iron(II)- and 2-(Oxo)-glutarate-Dependent Hydroxylase

Visualizing the Reaction Cycle in an Iron(II)- and 2-(Oxo)-glutarate-Dependent Hydroxylase

Dioxygen Activation and O–O Bond Formation Reactions by Manganese Corroles

Achieving One-Electron Oxidation of a Mononuclear Nonheme Iron(V)-Imido Complex

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