Copper coordination in blue proteins

Gray, Harry B.; Malmström, Bo G.; Williams, R. J. P.

doi:10.1007/s007750000146

Cited by 508 publications

(595 citation statements)

References 28 publications

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“…Redox potentials of the copper centers in MCOs have been determined by measuring the absorption spectrum and potential of the partly reduced states of MCO in situ [6,16,[76][77][78]. The redox potential of type I copper ranges over ca.…”

Section: Properties Of Type I Copper In Multicopper Oxidasesmentioning

confidence: 99%

“…Most of the blue copper proteins plastocyanin, azurin, pseudoazurin, amicyanin, rusticyanin, auracyanin, umecyanin, mavicyanin, plantacyanin (cucumber basic protein (CBP)), and stellacyanin have been crystallized and their structural data are available [4,16]. On the other hand, crystal structure analyses of MCOs comprised of more than 500 amino acids have been limited until recently.…”

Section: Introductionmentioning

confidence: 99%

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Structure and function of type I copper in multicopper oxidases

Sakurai

Kataoka

2007

Cell. Mol. Life Sci.

128

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Abstract. The type I copper center in multicopper oxidases is constructed from 1Cys2His and weakly coordinating 1Met or the non-coordinating 1Phe/1Leu, and it exhibits spectral properties and an alkaline transition similar to those of the blue copper center in blue copper proteins. Since the type I copper center in multicopper oxidases is deeply buried inside the protein molecule, electron transfers to and from type I copper are performed through specific pathways: the hydrogen bond between an amino acid located at the substrate binding site and a His residue coordinating type I copper, and the His-Cys-His sequence connecting the type I copper center and the trinuclear copper center comprised of a type II copper and a pair of type III coppers. The intramolecular electron transfer rates can be tuned by mutating the fourth ligand of type I copper. Further, mutation at the Cys ligand gives a vacant type I copper center and traps the reaction intermediate during the four-electron reduction of dioxygen.

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Section: Properties Of Type I Copper In Multicopper Oxidasesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Structure and function of type I copper in multicopper oxidases

Sakurai

Kataoka

2007

Cell. Mol. Life Sci.

128

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“…One of the most intensively studied group of ET proteins is the blue copper proteins (e.g., plastocyanin, azurin, and the family of multi‐copper oxidases) 1. The copper binding sites were shown to confer unique spectroscopic and thermodynamic properties on the copper ions 2. These properties attracted studies aiming at understanding their role in the ET via proteins.…”

Section: Introductionmentioning

confidence: 99%

Electron Transfer Proteins as Electronic Conductors: Significance of the Metal and Its Binding Site in the Blue Cu Protein, Azurin

et al. 2015

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Electron transfer (ET) proteins are biomolecules with specific functions, selected by evolution. As such they are attractive candidates for use in potential bioelectronic devices. The blue copper protein azurin (Az) is one of the most‐studied ET proteins. Traditional spectroscopic, electrochemical, and kinetic methods employed for studying ET to/from the protein's Cu ion have been complemented more recently by studies of electrical conduction through a monolayer of Az in the solid‐state, sandwiched between electrodes. As the latter type of measurement does not require involvement of a redox process, it also allows monitoring electronic transport (ETp) via redox‐inactive Az‐derivatives. Here, results of macroscopic ETp via redox‐active and ‐inactive Az derivatives, i.e., Cu(II) and Cu(I)‐Az, apo‐Az, Co(II)‐Az, Ni(II)‐Az, and Zn(II)‐Az are reported and compared. It is found that earlier reported temperature independence of ETp via Cu(II)‐Az (from 20 K until denaturation) is unique, as ETp via all other derivatives is thermally activated at temperatures >≈200 K. Conduction via Cu(I)‐Az shows unexpected temperature dependence >≈200 K, with currents decreasing at positive and increasing at negative bias. Taking all the data together we find a clear compensation effect of Az conduction around the Az denaturation temperature. This compensation can be understood by viewing the Az binding site as an electron trap, unless occupied by Cu(II), as in the native protein, with conduction of the native protein setting the upper transport efficiency limit.

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“…The blue copper proteins are another example where the potentials of the redox centre span a range of values [88], in this case from 0.37 V vs NHE in P. nigra plastocyanin to 0.785 V vs. NHE in Polyporus versicolor laccase. Again, these differences can be explained by differences in the axial ligands around the Cu centre and by the degree of hydrophobicity of the polypeptide surrounding the redox centre.…”

Section: Energetics: Redox Potentialsmentioning

confidence: 99%

Bioenergetics and Biological Electron Transport

Bartlett

2008

Bioelectrochemistry

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Copper coordination in blue proteins

Cited by 508 publications

References 28 publications

Structure and function of type I copper in multicopper oxidases

Structure and function of type I copper in multicopper oxidases

Electron Transfer Proteins as Electronic Conductors: Significance of the Metal and Its Binding Site in the Blue Cu Protein, Azurin

Bioenergetics and Biological Electron Transport

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