An Anionic, Tetragonal Copper(II) Superoxide Complex

Donoghue, Patrick J.; Gupta, Aalo K.; Boyce, David W.; Cramer, Christopher J.; Tolman, William B.

doi:10.1021/ja106244k

Cited by 114 publications

(119 citation statements)

References 31 publications

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“…Cu-superoxide species have been proposed as reactive intermediates in H-atom abstraction in the noncoupled binuclear Cu enzymes (1,29,30), although a Cu(II)-superoxide enzyme species has yet to be spectroscopically characterized. Alternatively, a variety of inorganic Cu(II)-superoxide model complexes have been trapped at low temperature (31)(32)(33)(34)(35). These include a diazacyclooctane supported complex (1) (32) (SI Appendix, Fig.…”

Section: Results and Analysismentioning

confidence: 99%

Spectroscopic and computational insight into the activation of O ₂ by the mononuclear Cu center in polysaccharide monooxygenases

Kjaergaard

Qayyum

Wong

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

203

252

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Strategies for O 2 activation by copper enzymes were recently expanded to include mononuclear Cu sites, with the discovery of the copper-dependent polysaccharide monooxygenases, also classified as auxiliary-activity enzymes 9-11 (AA9-11). These enzymes are finding considerable use in industrial biofuel production. Crystal structures of polysaccharide monooxygenases have emerged, but experimental studies are yet to determine the solution structure of the Cu site and how this relates to reactivity. From X-ray absorption near edge structure and extended X-ray absorption fine structure spectroscopies, we observed a change from four-coordinate Cu(II) to three-coordinate Cu(I) of the active site in solution, where three protein-derived nitrogen ligands coordinate the Cu in both redox states, and a labile hydroxide ligand is lost upon reduction. The spectroscopic data allowed for density functional theory calculations of an enzyme active site model, where the optimized Cu(I) and (II) structures were consistent with the experimental data. The O 2 reactivity of the Cu(I) site was probed by EPR and stopped-flow absorption spectroscopies, and a rapid one-electron reduction of O 2 and regeneration of the resting Cu(II) enzyme were observed. This reactivity was evaluated computationally, and by calibration to Cu-superoxide model complexes, formation of an end-on Cu-AA9-superoxide species was found to be thermodynamically favored. We discuss how this thermodynamically difficult one-electron reduction of O 2 is enabled by the unique protein structure where two nitrogen ligands from His1 dictate formation of a T-shaped Cu(I) site, which provides an open coordination position for strong O 2 binding with very little reorganization energy.X-ray absorption spectroscopy | DFT | dioxygen activation | biofuels

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Section: Results and Analysismentioning

confidence: 99%

Spectroscopic and computational insight into the activation of O ₂ by the mononuclear Cu center in polysaccharide monooxygenases

Kjaergaard

Qayyum

Wong

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

203

252

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“…Dioxygen binds to mononuclear copper centers in models of metalloenzyme active sites, forming either side-on 41–44 (η 2 ) or end-on 45–58 (η 1 ) species, which lead to different electronic structures. Active site optimizations were performed with O 2 bound to the copper center in both η 1 and η 2 configurations and in both triplet and singlet spin states.…”

Section: 3 O2 Activation By the Cu(i) Active Sitementioning

confidence: 99%

Structure of the Reduced Copper Active Site in Preprocessed Galactose Oxidase: Ligand Tuning for One-Electron O₂ Activation in Cofactor Biogenesis

et al. 2016

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Galactose oxidase (GO) is a copper-dependent enzyme that accomplishes 2e− substrate oxidation by pairing a single copper with an unusual cysteinylated tyrosine (Cys-Tyr) redox cofactor. Previous studies have demonstrated that the post-translational biogenesis of Cys-Tyr is copper- and O2-dependent, resulting in a self-processing enzyme system. To investigate the mechanism of cofactor biogenesis in GO, the active-site structure of Cu(I)-loaded GO was determined using X-ray absorption near edge structure (XANES) and extended X-ray absorption fine structure (EXAFS) spectroscopy, and density-functional theory (DFT) calculations were performed on this model. Our results show that the active-site tyrosine lowers the Cu potential to enable the thermodynamically unfavorable 1e− reduction of O2, and the resulting Cu(II)-O2•− is activated towards H-atom abstraction from cysteine. The final step of biogenesis is a concerted reaction involving coordinated Tyr ring deprotonation where Cu(II) coordination enables formation of the Cys-Tyr crosslink. These spectroscopic and computational results highlight the role of the Cu(I) in enabling O2 activation by 1e− and the role of the resulting Cu(II) in enabling substrate activation for biogenesis.

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“…Mechanistic experiments led to the proposed mechanism shown in Figure 42. In contrast to the generally electrophilic reactivity of 80-84, complex 85 ( Figure 39) acts as a base and was surmised to have nucleophilic character, presumably because of the overall negative charge of the complex and the strong electron donating properties of the pyridine(dicarboxamide) supporting ligand [290]. Thus, 85 is unreactive with alkyl-substituted phenols, appears to be protonated by p-nitrophenol, does not oxidize PPh 3 , and may be trapped by [(TMPA)-Cu(I)]OTf to yield a trans-η 1 :η 1 -peroxo-dicopper(II,II) complex [290].…”

Section: Mononuclear Models Of Monocopper Active Sites In Enzymesmentioning

confidence: 99%

Transition Metal Complexes and the Activation of Dioxygen

Yee

Tolman

2014

Metal Ions in Life Sciences

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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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An Anionic, Tetragonal Copper(II) Superoxide Complex

Cited by 114 publications

References 31 publications

Spectroscopic and computational insight into the activation of O ₂ by the mononuclear Cu center in polysaccharide monooxygenases

Spectroscopic and computational insight into the activation of O ₂ by the mononuclear Cu center in polysaccharide monooxygenases

Structure of the Reduced Copper Active Site in Preprocessed Galactose Oxidase: Ligand Tuning for One-Electron O₂ Activation in Cofactor Biogenesis

Transition Metal Complexes and the Activation of Dioxygen

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An Anionic, Tetragonal Copper(II) Superoxide Complex

Cited by 114 publications

References 31 publications

Spectroscopic and computational insight into the activation of O 2 by the mononuclear Cu center in polysaccharide monooxygenases

Spectroscopic and computational insight into the activation of O 2 by the mononuclear Cu center in polysaccharide monooxygenases

Structure of the Reduced Copper Active Site in Preprocessed Galactose Oxidase: Ligand Tuning for One-Electron O2 Activation in Cofactor Biogenesis

Transition Metal Complexes and the Activation of Dioxygen

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Product

Resources

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Spectroscopic and computational insight into the activation of O ₂ by the mononuclear Cu center in polysaccharide monooxygenases

Spectroscopic and computational insight into the activation of O ₂ by the mononuclear Cu center in polysaccharide monooxygenases

Structure of the Reduced Copper Active Site in Preprocessed Galactose Oxidase: Ligand Tuning for One-Electron O₂ Activation in Cofactor Biogenesis