Mononuclear Iron‐(hydro/semi)quinonate Complexes Featuring Neutral and Charged Scorpionates: Synthetic Models of Intermediates in the Hydroquinone Dioxygenase Mechanism

Baum, Amanda E.; Lindeman, Sergey V.; Fiedler, Adam T.

doi:10.1002/ejic.201501380

Cited by 8 publications

(8 citation statements)

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“…The increase in χ T as the temperature was raised from 50 to 300 K is likely due to the thermal population of the S = 5 / 2 excited state. Interestingly, Fiedler’s mononuclear five-coordinate iron(II) p -semiquinonate complexes exhibit ferromagnetic coupling between the high-spin iron(II) center and the p -semiquinonateradical to yield an S = 5 / 2 ground state, as indicated by electron paramagnetic resonance (EPR) and DFT data 57 , 58 . The ferromagnetic coupling observed in the iron(II) p -semi-quinonate complexes (DFT-computed J values of ~65 cm −1 , H = −2 JS 1 ∙ S 2 ) was attributed to the orthogonal orientation of the magnetic orbitals.…”

Section: Resultsmentioning

confidence: 99%

Electronic, Magnetic, and Redox Properties and O₂ Reactivity of Iron(II) and Nickel(II) o-Semiquinonate Complexes of a Tris(thioether) Ligand: Uncovering the Intradiol Cleaving Reactivity of an Iron(II) o-Semiquinonate Complex

et al. 2017

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The iron(II) semiquinonate character within the iron(III) catecholate species has been proposed by numerous studies to account for the O2 reactivity of intradiol catechol dioxygenases, but a well-characterized iron(II) semiquinonate species that exhibits intradiol cleaving reactivity has not yet been reported. In this study, a detailed electronic structure description of the first iron(II) o-semiquinonate complex, [PhTttBu]Fe(phenSQ) [PhTttBu = phenyltris(tert-butylthiomethyl)borate; phenSQ = 9,10-phenanthrenesemiquinonate; Wang et al. Chem. Commun. 2014, 50, 5871–5873], was generated through a combination of electronic and Mössbauer spectroscopies, SQUID magnetometry, and density functional theory (DFT) calculations. [PhTttBu]Fe(phenSQ) reacts with O2 to generate an intradiol cleavage product, diphenic anhydride, in 16% yield. To assess the dependence of the intradiol reactivity on the identity of the metal ion, the nickel analogue, [PhTttBu]Ni(phenSQ), and its derivative, [PhTttBu]Ni(3,5-DBSQ) (3,5-DBSQ = 3,5-di-tert-butyl-1,2-semiquinonate), were prepared and characterized by X-ray crystallography, mass spectrometry, 1H NMR and electronic spectroscopies, and SQUID magnetometry. DFT calculations, evaluated on the basis of the experimental data, support the electronic structure descriptions of [PhTttBu]Ni(phenSQ) and [PhTttBu]Ni(3,5-DBSQ) as high-spin nickel(II) complexes with antiferromagnetically coupled semiquinonate ligands. Unlike its iron counterpart, [PhTttBu]Ni(phenSQ) decomposes slowly in an O2 atmosphere to generate 14% phenanthrenequinone with a negligible amount of diphenic anhydride. [PhTttBu]Ni(3,5-DBSQ) does not react with O2. This dramatic effect of the metal-ion identity supports the hypothesis that a metal(III) alkylperoxo species serves as an intermediate in the intradiol cleaving reactions. The redox properties of all three complexes were probed using cyclic voltammetry and differential pulse voltammetry, which indicate an inner-sphere electron-transfer mechanism for the formation of phenanthrenequinone. The lack of O2 reactivity of [PhTttBu]Ni(3,5-DBSQ) can be rationalized by the high redox potential of the metal-ligated 3,5-DBSQ/3,5-DBQ couple.

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Section: Resultsmentioning

confidence: 99%

Electronic, Magnetic, and Redox Properties and O₂ Reactivity of Iron(II) and Nickel(II) o-Semiquinonate Complexes of a Tris(thioether) Ligand: Uncovering the Intradiol Cleaving Reactivity of an Iron(II) o-Semiquinonate Complex

et al. 2017

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“…145,146,147,148,149,150,151 Studies of relevant model complexes have confirmed that such an intermediate is feasible due to the "noninnocent" nature of dioxolene ligands. 152,153,154,155,156,157 However, spectroscopic studies of Fe-HPCD employing mutant enzyme and/or unactivated substrate have failed to detect a catalytically viable Fe(II)/SQ species, 158,159,160 and a recent density functional theory (DFT) analysis of the iron-based mechanism favored a superoxo-Fe(III)-catecholate description instead. 161 Thus, the precise electronic structure of the M/O2 adduct remains a matter of dispute, and we will return to this topic below.…”

Section: Extradiol Catechol Dioxygenasesmentioning

confidence: 99%

Oxygen activation by mononuclear Mn, Co, and Ni centers in biology and synthetic complexes

Fiedler

Fischer

2016

J Biol Inorg Chem

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The active sites of metalloenzymes that catalyze O-dependent reactions generally contain iron or copper ions. However, several enzymes are capable of activating O at manganese or nickel centers instead, and a handful of dioxygenases exhibit activity when substituted with cobalt. This minireview summarizes the catalytic properties of oxygenases and oxidases with mononuclear Mn, Co, or Ni active sites, including oxalate-degrading oxidases, catechol dioxygenases, and quercetin dioxygenase. In addition, recent developments in the O reactivity of synthetic Mn, Co, or Ni complexes are described, with an emphasis on the nature of reactive intermediates featuring superoxo-, peroxo-, or oxo-ligands. Collectively, the biochemical and synthetic studies discussed herein reveal the possibilities and limitations of O activation at these three "overlooked" metals.

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“…Fiedlersg roup has recently shown that mononuclear iron(III) 2-(1-methylbenzimidazol-2-yl)hydroquinonate complexes of tridentate facial N 3 ligands undergo deprotonation to generate the corresponding iron(II) semiquionate radical species. [26] Thes uperoxide radical (II)c an attack the C1 carbon of the carboxysemiquinonato group to form an alkylperoxide intermediate (III). [27] The para-hydroxy group on the aromatic ring then participates in directing the heterolytic O À Oc leavage of the alkylperoxo intermediate (III)t hrough Criegee type rearrangement to form an anhydride intermediate (IV).…”

mentioning

confidence: 99%

Mimicking the Aromatic‐Ring‐Cleavage Activity of Gentisate‐1,2‐Dioxygenase by a Nonheme Iron Complex

2016

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Gentisate-1,2-dioxygenase (GDO), a nonheme iron enzyme in the cupin superfamily, catalyzes the cleavage of the aromatic-ring of 2,5-dihydroxybenzoic acid (gentisic acid) to form maleylpyruvic acid in the microbial aerobic degradation of aromatic compounds. To develop a functional model of GDO, we have isolated a nonheme iron(II) complex, [(Tp )Fe (DHN-H)] (Tp =hydrotris(3,5-diphenylpyrazole-1-yl)borate, DHN-H=1,4-dihydroxy-2-naphthoate). In the reaction with O , the biomimetic complex oxidatively cleaves the aromatic ring of the coordinated substrate with the incorporation of both the oxygen atoms from molecular oxygen into the cleavage product. The presence of para-hydroxy group on the substrate plays a crucial role in directing the aromatic-ring cleaving reaction.

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Mononuclear Iron‐(hydro/semi)quinonate Complexes Featuring Neutral and Charged Scorpionates: Synthetic Models of Intermediates in the Hydroquinone Dioxygenase Mechanism

Cited by 8 publications

References 120 publications

Electronic, Magnetic, and Redox Properties and O₂ Reactivity of Iron(II) and Nickel(II) o-Semiquinonate Complexes of a Tris(thioether) Ligand: Uncovering the Intradiol Cleaving Reactivity of an Iron(II) o-Semiquinonate Complex

Electronic, Magnetic, and Redox Properties and O₂ Reactivity of Iron(II) and Nickel(II) o-Semiquinonate Complexes of a Tris(thioether) Ligand: Uncovering the Intradiol Cleaving Reactivity of an Iron(II) o-Semiquinonate Complex

Oxygen activation by mononuclear Mn, Co, and Ni centers in biology and synthetic complexes

Mimicking the Aromatic‐Ring‐Cleavage Activity of Gentisate‐1,2‐Dioxygenase by a Nonheme Iron Complex

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Mononuclear Iron‐(hydro/semi)quinonate Complexes Featuring Neutral and Charged Scorpionates: Synthetic Models of Intermediates in the Hydroquinone Dioxygenase Mechanism

Cited by 8 publications

References 120 publications

Electronic, Magnetic, and Redox Properties and O2 Reactivity of Iron(II) and Nickel(II) o-Semiquinonate Complexes of a Tris(thioether) Ligand: Uncovering the Intradiol Cleaving Reactivity of an Iron(II) o-Semiquinonate Complex

Electronic, Magnetic, and Redox Properties and O2 Reactivity of Iron(II) and Nickel(II) o-Semiquinonate Complexes of a Tris(thioether) Ligand: Uncovering the Intradiol Cleaving Reactivity of an Iron(II) o-Semiquinonate Complex

Oxygen activation by mononuclear Mn, Co, and Ni centers in biology and synthetic complexes

Mimicking the Aromatic‐Ring‐Cleavage Activity of Gentisate‐1,2‐Dioxygenase by a Nonheme Iron Complex

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Electronic, Magnetic, and Redox Properties and O₂ Reactivity of Iron(II) and Nickel(II) o-Semiquinonate Complexes of a Tris(thioether) Ligand: Uncovering the Intradiol Cleaving Reactivity of an Iron(II) o-Semiquinonate Complex

Electronic, Magnetic, and Redox Properties and O₂ Reactivity of Iron(II) and Nickel(II) o-Semiquinonate Complexes of a Tris(thioether) Ligand: Uncovering the Intradiol Cleaving Reactivity of an Iron(II) o-Semiquinonate Complex