An isoelectronic NO dioxygenase reaction using a nonheme iron(<scp>iii</scp>)-peroxo complex and nitrosonium ion

Yokoyama, Atsutoshi; Han, Jung Eun; Karlin, Kenneth D.; Nam, Wonwoo

doi:10.1039/c3cc48782b

Cited by 25 publications

(24 citation statements)

References 39 publications

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“…These reactions are thought to proceed through Fe III –PN intermediates, prior to nitrate formation; 14,15 nitrogen dioxide (NO 2 ) may otherwise be released. 16 Thus, metal–PN generation may occur via metal–O 2 plus NO or metal–NO plus O 2 reactions, as shown recently in coordination complexes of chromium, 17a,b iron, 17c copper, 18 hemes, 19 and cobalt–porphyrins. 20 …”

Section: Introductionmentioning

confidence: 66%

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Factors That Control the Reactivity of Cobalt(III)–Nitrosyl Complexes in Nitric Oxide Transfer and Dioxygenation Reactions: A Combined Experimental and Theoretical Investigation

Kumar

Lee

et al. 2016

J. Am. Chem. Soc.

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Metal–nitrosyl complexes are key intermediates involved in many biological and physiological processes of nitric oxide (NO) activation by metalloproteins. In this study, we report the reactivities of mononuclear cobalt(III)–nitrosyl complexes bearing N-tetramethylated cyclam (TMC) ligands, [(14-TMC)CoIII(NO)]2+ and [(12-TMC)CoIII(NO)]2+, in NO-transfer and dioxygenation reactions. The Co(III)–nitrosyl complex bearing 14-TMC ligand, [(14-TMC)CoIII(NO)]2+, transfers the bound nitrosyl ligand to [(12-TMC)CoII]2+ via a dissociative pathway, {[(14-TMC)CoIII(NO)]2+ → {(14-TMC)-Co⋯NO}2+}, thus affording [(12-TMC)CoIII(NO)]2+ and [(14-TMC)CoII]2+ as products. The dissociation of NO from the [(14-TMC)CoIII(NO)]2+ complex prior to NO-transfer is supported experimentally and theoretically. In contrast, the reverse reaction, which is the NO-transfer from [(12-TMC)CoIII(NO)]2+ to [(14-TMC)CoII]2+, does not occur. In addition to the NO-transfer reaction, dioxygenation of [(14-TMC)CoIII(NO)]2+ by O2 produces [(14-TMC)CoII(NO3)]+, which possesses an O,O-chelated nitrato ligand and where, based on an experiment using 18O-labeled O2, two of the three O-atoms in the [(14-TMC)CoII(NO3)]+ product derive from O2. The dioxygenation reaction is proposed to occur via a dissociative pathway, as proposed in the NO-transfer reaction, and via the formation of a Co(II)–peroxynitrite intermediate, based on the observation of phenol ring nitration. In contrast, [(12-TMC)CoIII(NO)]2+ does not react with O2. Thus, the present results demonstrate unambiguously that the NO-transfer/dioxygenation reactivity of the cobalt(III)–nitrosyl complexes bearing TMC ligands is significantly influenced by the ring size of the TMC ligands and/or the spin state of the cobalt ion.

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Section: Introductionmentioning

confidence: 66%

“…In relation to the NOD reactivity, TMC chromium–superoxo, chromium–peroxo, and iron–peroxo complexes were treated with NO or nitrosonium (NO + ) ion, and in all cases metal–peroxynitrite intermediates were implicated as transient intermediates, leading to the formation of nitrite or nitrate metal complexes as final products. 17 …”

Section: Introductionmentioning

confidence: 99%

Factors That Control the Reactivity of Cobalt(III)–Nitrosyl Complexes in Nitric Oxide Transfer and Dioxygenation Reactions: A Combined Experimental and Theoretical Investigation

Kumar

Lee

et al. 2016

J. Am. Chem. Soc.

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“…This seems to also correspond to known aqueous chemistry: peroxynitrite decomposes through various pathways, 3c,21 , including its degradation according to 2 − OON═O → O 2 + 2NO 2 − under basic conditions and relatively high concentration,s 21b,d,e and such reactivity has even been observed in aqueous chemistry with copper ion. 22 Similarly, Nam and co-workers reported formation of macrocyclic ligand-bound metal−PN complexes, for example, LCr III −PN 23 and non-heme-Fe III −PN 24 species, generated from precursor M−O 2 adducts reacting with NO (g) (Scheme 1). A novel case involves reaction of a macrocyclic ligand (L)Co–nitrosyl complex with potassium superoxide (KO 2 ), leading to LCo III −nitrite + ½ O 2(g) products, all proceeding through putative Co–PN intermediates (Scheme 1).…”

Section: Introductionmentioning

confidence: 99%

A Peroxynitrite Dicopper Complex: Formation via Cu–NO and Cu–O₂ Intermediates and Reactivity via O–O Cleavage Chemistry

et al. 2016

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“…To mimic NOD reactivity, we recently reported the reactions of superoxide and peroxide complexes of chromium–TMC (TMC = N-tetramethylated cyclam) with NO; the Cr III –peroxo complex [(12-TMC)Cr IV (O 2 )(Cl)] + reacted with NO to form a Cr III –nitrato complex, [15a] whereas a reaction of the Cr III –superoxo complex [(14-TMC)Cr III (O 2 )(Cl)] + and NO gave the Cr IV –oxo complex ([(14-TMC)Cr IV (O)-(Cl)] + ) plus ·NO 2 . [15b] We have also reported a NOD reaction using an Fe III –peroxo complex and nitrosonium ion (NO + ), which produced an Fe III –nitrato complex.…”

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confidence: 99%

“…[15b] We have also reported a NOD reaction using an Fe III –peroxo complex and nitrosonium ion (NO + ), which produced an Fe III –nitrato complex. [15c] …”

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confidence: 99%

Mechanistic Insight into the Nitric Oxide Dioxygenation Reaction of Nonheme Iron(III)–Superoxo and Manganese(IV)–Peroxo Complexes

et al. 2016

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Reactions of nonheme FeIII–superoxo and MnIV– peroxo complexes bearing a common tetraamido macrocyclic ligand (TAML), namely [(TAML)FeIII(O2)]2− and [(TAML)MnIV(O2)]2−, with nitric oxide (NO) afford the FeIII–NO3 complex [(TAML)FeIII(NO3)]2− and the MnV–oxo complex [(TAML)MnV(O)]−plus NO2−, respectively. Mechanistic studies, including density functional theory (DFT) calculations, reveal that MIII–peroxynitrite (M = Fe and Mn) species, generated in the reactions of [(TAML)FeIII(O2)]2− and [(TAML)MnIV(O2)]2− with NO, are converted into MIV(O) and ·NO2 species through O–O bond homolysis of the peroxynitrite ligand. Then, a rebound of FeIV(O) with ·NO2 affords [(TAML)FeIII(NO3)]2−, whereas electron transfer from MnIV(O) to ·NO2 yields [(TAML)MnV(O)]− plus NO2−.

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An isoelectronic NO dioxygenase reaction using a nonheme iron(iii)-peroxo complex and nitrosonium ion

Cited by 25 publications

References 39 publications

Factors That Control the Reactivity of Cobalt(III)–Nitrosyl Complexes in Nitric Oxide Transfer and Dioxygenation Reactions: A Combined Experimental and Theoretical Investigation

Factors That Control the Reactivity of Cobalt(III)–Nitrosyl Complexes in Nitric Oxide Transfer and Dioxygenation Reactions: A Combined Experimental and Theoretical Investigation

A Peroxynitrite Dicopper Complex: Formation via Cu–NO and Cu–O₂ Intermediates and Reactivity via O–O Cleavage Chemistry

Mechanistic Insight into the Nitric Oxide Dioxygenation Reaction of Nonheme Iron(III)–Superoxo and Manganese(IV)–Peroxo Complexes

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An isoelectronic NO dioxygenase reaction using a nonheme iron(iii)-peroxo complex and nitrosonium ion

Cited by 25 publications

References 39 publications

Factors That Control the Reactivity of Cobalt(III)–Nitrosyl Complexes in Nitric Oxide Transfer and Dioxygenation Reactions: A Combined Experimental and Theoretical Investigation

Factors That Control the Reactivity of Cobalt(III)–Nitrosyl Complexes in Nitric Oxide Transfer and Dioxygenation Reactions: A Combined Experimental and Theoretical Investigation

A Peroxynitrite Dicopper Complex: Formation via Cu–NO and Cu–O2 Intermediates and Reactivity via O–O Cleavage Chemistry

Mechanistic Insight into the Nitric Oxide Dioxygenation Reaction of Nonheme Iron(III)–Superoxo and Manganese(IV)–Peroxo Complexes

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A Peroxynitrite Dicopper Complex: Formation via Cu–NO and Cu–O₂ Intermediates and Reactivity via O–O Cleavage Chemistry