Structural Characterization and Remarkable Axial Ligand Effect on the Nucleophilic Reactivity of a Nonheme Manganese(III)–Peroxo Complex

Annaraj, Jamespandi; Cho, Jaeheung; Lee, Yong Min; Kim, Sung Yeon; Latifi, Reza; Visser, Sam P. de; Nam, Wonwoo

doi:10.1002/anie.200900118

Cited by 119 publications

(156 citation statements)

References 33 publications

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“…A role of the axial ligand has been proposed to be to enhance the nucleophilicity of the O 2 À 2 moiety. This has been recently demonstrated for a non-heme Mn(III)-peroxo complex, for which the authors postulate the axial ligand to facilitate the conversion between the η 2 and η 1 conformations [60]. It was also shown for the 2 )] (tpp ¼ 5,10,15,20-tetrakis-(pentafluorophenyl)porphyrin) that epoxidation of the olefin 2-methyl-1,4-naphthoquinone only proceeds in the presence of 20 % dimethyl sulfoxide, which the authors attributed to increased axial coordination at the Fe(III) center [61].…”

Section: Fe(iii)-hydroperoxo (Alkylperoxo) Intermediatesmentioning

confidence: 85%

Transition Metal Complexes and the Activation of Dioxygen

Yee

Tolman

2014

Sustaining Life on Planet Earth: Metalloenzymes Mastering Dioxygen and Other Chewy Gases

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In order to address how diverse metalloprotein active sites, in particular those containing iron and copper, guide O₂binding and activation processes to perform diverse functions, studies of synthetic models of the active sites have been performed. These studies have led to deep, fundamental chemical insights into how O₂coordinates to mono- and multinuclear Fe and Cu centers and is reduced to superoxo, peroxo, hydroperoxo, and, after O-O bond scission, oxo species relevant to proposed intermediates in catalysis. Recent advances in understanding the various factors that influence the course of O₂activation by Fe and Cu complexes are surveyed, with an emphasis on evaluating the structure, bonding, and reactivity of intermediates involved. The discussion is guided by an overarching mechanistic paradigm, with differences in detail due to the involvement of disparate metal ions, nuclearities, geometries, and supporting ligands providing a rich tapestry of reaction pathways by which O₂is activated at Fe and Cu sites.

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Section: Fe(iii)-hydroperoxo (Alkylperoxo) Intermediatesmentioning

confidence: 85%

Transition Metal Complexes and the Activation of Dioxygen

Yee

Tolman

2014

Sustaining Life on Planet Earth: Metalloenzymes Mastering Dioxygen and Other Chewy Gases

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“…In contrast, a variety of synthetic peroxomanganese(III) species have been generated and characterized, offering insights into the structural, electronic, and reactivity properties of this class of compound. 14–27 Members of this class of compound include side-on peroxomanganese(III) adducts (Mn III -O 2 ) and end-on alkylperoxomanganese(III) adducts (Mn III -OOR). 28,29 …”

Section: Introductionmentioning

confidence: 99%

“…While there are several examples of Mn III -O 2 complexes with anionic supporting ligands, 14,22,25,30 there are no detailed bonding descriptions of such complexes. As many enzymatic Mn III -O 2 adducts are expected to feature anionic ligands, this represents a gap in knowledge.…”

Section: Introductionmentioning

confidence: 99%

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Geometric and electronic structure of a peroxomanganese(iii) complex supported by a scorpionate ligand

et al. 2014

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A monomeric MnII complex has been prepared with the facially-coordinating TpPh2 ligand, (TpPh2 = hydrotris(3,5-diphenylpyrazol-1-yl)borate). The X-ray crystal structure shows three coordinating solvent molecules resulting in a six-coordinate complex with Mn-ligand bond lengths that are consistent with a high-spin MnII ion. Treatment of this MnII complex with excess KO2 at room temperature resulted in the formation of a MnIII-O2 complex that is stable for several days at ambient conditions, allowing for the determination of the X-ray crystal structure of this intermediate. The electronic structure of this peroxomanganese(III) adduct was examined by using electronic absorption, electron paramagnetic resonance (EPR), low-temperature magnetic circular dichroism (MCD), and variable-temperature variable-field (VTVH) MCD spectroscopies. Density functional theory (DFT), time-dependent (TD)-DFT, and multireference ab initio CASSCF/NEVPT2 calculations were used to assign the electronic transitions and further investigate the electronic structure of the peroxomanganese(III) species. The lowest ligand-field transition in the electronic absorption spectrum of the MnIII-O2 complex exhibits a blue shift in energy compared to other previously characterized peroxomanganese(III) complexes that results from a large axial bond elongation, reducing the metal-ligand covalency and stabilizing the σ-antibonding Mn dz2 MO that is the donor MO for this transition.

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“…146 Interestingly, molecular oxygen binds in a side-on fashion rather than end-on in the structure shown in Figure 1.20, which contrasts an end-on bound NO crystal structure as well as biomimetic dioxygen bound structures. 147,148 Addition of hydrogen peroxide to the oxygenase domain led to cis-hydroxylation products efficiently without the need for additional electrons. 149 Moreover, use of H 2 18 O 2 led to isotopically labeled products indicating that both oxygen atoms in the product originate from hydrogen peroxide.…”

Section: Rieske Dioxygenasesmentioning

confidence: 99%

Chapter 1. Experimental and Computational Studies on the Catalytic Mechanism of Non-heme Iron Dioxygenases

Visser¹

Iron-Containing Enzymes

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Structural Characterization and Remarkable Axial Ligand Effect on the Nucleophilic Reactivity of a Nonheme Manganese(III)–Peroxo Complex

Cited by 119 publications

References 33 publications

Transition Metal Complexes and the Activation of Dioxygen

Transition Metal Complexes and the Activation of Dioxygen

Geometric and electronic structure of a peroxomanganese(iii) complex supported by a scorpionate ligand

Chapter 1. Experimental and Computational Studies on the Catalytic Mechanism of Non-heme Iron Dioxygenases

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