Galactose oxidase

James W. Whittaker

doi:10.1016/S0065-3233(02)60050-6

Galactose oxidase

James W. Whittaker

Research output: Contribution to journal › Review article › peer-review

71 Scopus citations

Abstract

The free radidal-coupled copper catalytic motif has emerged as the unifying feature of a new family of enzymes, the radical copper oxidases. Their highly evolved active sites include a novel amino acid modification, the Tyr-Cys dimer, that forms spontaneously through self-processing of the protein during its maturation. The active site is remarkable in the extent to which metal ligands participate in the catalytic process. Rather than simply coordinating the metal ion, the ligands perform essential redox and proton-transfer functions in the chemistry of the active site, directed by their interactions with the copper center in the protein. The wide phylogenetic distribution and range of functions represented within the family hint of a fundamental role for these enzymes in the biology of oxygen. The roles for these enzymes are further expanding through a variety of biotechnological applications.

Original language	English (US)
Pages (from-to)	1-49
Number of pages	49
Journal	Advances in Protein Chemistry
Volume	60
DOIs	https://doi.org/10.1016/S0065-3233(02)60050-6
State	Published - 2002

ASJC Scopus subject areas

Biochemistry

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10.1016/S0065-3233(02)60050-6

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title = "Galactose oxidase",

abstract = "The free radidal-coupled copper catalytic motif has emerged as the unifying feature of a new family of enzymes, the radical copper oxidases. Their highly evolved active sites include a novel amino acid modification, the Tyr-Cys dimer, that forms spontaneously through self-processing of the protein during its maturation. The active site is remarkable in the extent to which metal ligands participate in the catalytic process. Rather than simply coordinating the metal ion, the ligands perform essential redox and proton-transfer functions in the chemistry of the active site, directed by their interactions with the copper center in the protein. The wide phylogenetic distribution and range of functions represented within the family hint of a fundamental role for these enzymes in the biology of oxygen. The roles for these enzymes are further expanding through a variety of biotechnological applications.",

author = "Whittaker, {James W.}",

note = "Funding Information: I thank Mei Whittaker for discussions and for valuable assistance in preparation of the manuscript. Support from National Institutes of Health Grant GM 46749 is also gratefully acknowledged.",

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TY - JOUR

T1 - Galactose oxidase

AU - Whittaker, James W.

N1 - Funding Information: I thank Mei Whittaker for discussions and for valuable assistance in preparation of the manuscript. Support from National Institutes of Health Grant GM 46749 is also gratefully acknowledged.

PY - 2002

Y1 - 2002

N2 - The free radidal-coupled copper catalytic motif has emerged as the unifying feature of a new family of enzymes, the radical copper oxidases. Their highly evolved active sites include a novel amino acid modification, the Tyr-Cys dimer, that forms spontaneously through self-processing of the protein during its maturation. The active site is remarkable in the extent to which metal ligands participate in the catalytic process. Rather than simply coordinating the metal ion, the ligands perform essential redox and proton-transfer functions in the chemistry of the active site, directed by their interactions with the copper center in the protein. The wide phylogenetic distribution and range of functions represented within the family hint of a fundamental role for these enzymes in the biology of oxygen. The roles for these enzymes are further expanding through a variety of biotechnological applications.

AB - The free radidal-coupled copper catalytic motif has emerged as the unifying feature of a new family of enzymes, the radical copper oxidases. Their highly evolved active sites include a novel amino acid modification, the Tyr-Cys dimer, that forms spontaneously through self-processing of the protein during its maturation. The active site is remarkable in the extent to which metal ligands participate in the catalytic process. Rather than simply coordinating the metal ion, the ligands perform essential redox and proton-transfer functions in the chemistry of the active site, directed by their interactions with the copper center in the protein. The wide phylogenetic distribution and range of functions represented within the family hint of a fundamental role for these enzymes in the biology of oxygen. The roles for these enzymes are further expanding through a variety of biotechnological applications.

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DO - 10.1016/S0065-3233(02)60050-6

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AN - SCOPUS:0036403372

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VL - 60

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EP - 49

JO - Advances in Protein Chemistry

JF - Advances in Protein Chemistry

ER -

Galactose oxidase

Abstract

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