Bracing copper for the catalytic oxidation of C-H bonds

Luisa Ciano; Gideon John Davies; William Tolman; Paul Howard Walton

doi:10.1038/s41929-018-0110-9

Bracing copper for the catalytic oxidation of C-H bonds

Luisa Ciano, Gideon John Davies, William Tolman, Paul Howard Walton

Research output: Contribution to journal › Article › peer-review

Abstract

A structural unit found in the active site of some copper proteins, the histidine brace, is comprised of an N-terminal histidine that chelates a single copper ion through its amino terminus NH2 and the π–N of its imidazole side chain. Coordination is completed by the τ-N of a further histidine side chain, to give an overall N3 T-shaped coordination at the copper ion. The histidine brace appears in several proteins, including lytic polysaccharide monooxygenases LPMOs and particulate methane monooxygenases pMMOs, both of which catalyse the oxidation of substrates with strong C–H bonds (bond dissociation enthalpies ~100 kcal mol–1). As such, the copper histidine brace is the focus of research aimed at understanding how nature catalyses the oxidation of unactivated C–H bonds. In this Perspective, we evaluate these studies, which further give bioinspired direction to coordination chemists in the design and preparation of small molecule copper oxidation catalysts.

Original language	English
Pages (from-to)	571-577
Number of pages	7
Journal	Nature Catalysis
Volume	1
Early online date	10 Aug 2018
DOIs	https://doi.org/10.1038/s41929-018-0110-9
Publication status	E-pub ahead of print - 10 Aug 2018

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title = "Bracing copper for the catalytic oxidation of C-H bonds",

abstract = "A structural unit found in the active site of some copper proteins, the histidine brace, is comprised of an N-terminal histidine that chelates a single copper ion through its amino terminus NH2 and the π–N of its imidazole side chain. Coordination is completed by the τ-N of a further histidine side chain, to give an overall N3 T-shaped coordination at the copper ion. The histidine brace appears in several proteins, including lytic polysaccharide monooxygenases LPMOs and particulate methane monooxygenases pMMOs, both of which catalyse the oxidation of substrates with strong C–H bonds (bond dissociation enthalpies ~100 kcal mol–1). As such, the copper histidine brace is the focus of research aimed at understanding how nature catalyses the oxidation of unactivated C–H bonds. In this Perspective, we evaluate these studies, which further give bioinspired direction to coordination chemists in the design and preparation of small molecule copper oxidation catalysts.",

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AU - Tolman, William

AU - Walton, Paul Howard

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N2 - A structural unit found in the active site of some copper proteins, the histidine brace, is comprised of an N-terminal histidine that chelates a single copper ion through its amino terminus NH2 and the π–N of its imidazole side chain. Coordination is completed by the τ-N of a further histidine side chain, to give an overall N3 T-shaped coordination at the copper ion. The histidine brace appears in several proteins, including lytic polysaccharide monooxygenases LPMOs and particulate methane monooxygenases pMMOs, both of which catalyse the oxidation of substrates with strong C–H bonds (bond dissociation enthalpies ~100 kcal mol–1). As such, the copper histidine brace is the focus of research aimed at understanding how nature catalyses the oxidation of unactivated C–H bonds. In this Perspective, we evaluate these studies, which further give bioinspired direction to coordination chemists in the design and preparation of small molecule copper oxidation catalysts.

AB - A structural unit found in the active site of some copper proteins, the histidine brace, is comprised of an N-terminal histidine that chelates a single copper ion through its amino terminus NH2 and the π–N of its imidazole side chain. Coordination is completed by the τ-N of a further histidine side chain, to give an overall N3 T-shaped coordination at the copper ion. The histidine brace appears in several proteins, including lytic polysaccharide monooxygenases LPMOs and particulate methane monooxygenases pMMOs, both of which catalyse the oxidation of substrates with strong C–H bonds (bond dissociation enthalpies ~100 kcal mol–1). As such, the copper histidine brace is the focus of research aimed at understanding how nature catalyses the oxidation of unactivated C–H bonds. In this Perspective, we evaluate these studies, which further give bioinspired direction to coordination chemists in the design and preparation of small molecule copper oxidation catalysts.

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JO - Nature Catalysis

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Bracing copper for the catalytic oxidation of C-H bonds

Abstract

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