Irene M. C. van Amsterdam scite author profile

The transfer of electrons between proteins is an essential step in biological energy production. Two protein redox partners are often artificially crosslinked to investigate the poorly understood mechanism by which they interact. To better understand the effect of crosslinking on electron transfer rates, we have constructed dimers of azurin by crosslinking the monomers. The measured electron exchange rates, combined with crystal structures of the dimers, demonstrate that the length of the linker can have a dramatic effect on the structure of the dimer and the electron transfer rate. The presence of ordered water molecules in the protein-protein interface may considerably influence the electronic coupling between redox centers.

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Measurement of a CuCu Distance of 26 Å by a Pulsed EPR Method

Amsterdam

Ubbink

Canters

et al. 2003

Angew Chem Int Ed

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Distances between paramagnetic transition‐metal ions in compounds can be studied by using the pulsed electron–electron double‐resonance method. Hereby, the relative orientation (red arrow) of the metal centers (CuII, blue sphere), as well as the principal axes of the g tensor (green arrows) relative to the ligands play an important role (schematic representation: dimer of the copper protein azurin).

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A Poplar Plastocyanin Mutant Suitable for Adsorption onto Gold Surface via Disulfide Bridge

Andolfi

Cannistraro

Canters

et al. 2002

Archives of Biochemistry and Biophysics

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Effects of Dimerization on Protein Electron Transfer

et al. 2001

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In order to investigate the relationship between the rate of protein-protein electron transfer and the structure of the association complex, a dimer of the blue copper protein azurin was constructed and its electron exchange properties were determined. For this purpose, a site for covalent cross-linking was engineered by replacing the surface-exposed asparagine 42 with a cysteine. This mutation enabled the formation of disulfide-linked homo-dimers of azurin. Based on NMR line-broadening experiments, the electron self-exchange (e.s.e.) rate constant for this dimer was determined to be 4.2(+/-0.7) x 10(5)M(-1)s(-1), which is a seven-fold decrease relative to wild-type azurin. This difference is ascribed to a less accessible hydrophobic patch in the dimer. To discriminate between intramolecular electron transfer within a dimer and intermolecular electron transfer between two dimers, the e.s.e. rate constant of (Cu-Cu)-N42C dimers was compared with that of (Zn-Cu)- and (Ag-Cu)-N42C dimers. As Zn and Ag are redox inactive, the intramolecular electron transfer reaction in these latter dimers can be eliminated. The e.s.e. rate constants of the three dimers are the same and an upper limit for the intramolecular electron transfer rate of 10 s(-1) could be determined. This rate is compatible with a Cu-Cu distance of 18 A or more, which is larger than the Cu - Cu distance of 15 A observed in the wild-type crystal structure that shows two monomers that face each other with opposing hydrophobic patches. Modelling of the dimer shows that the Cu-Cu distance should be in the range of 17 A < rCu-Cu < 28 A, which is in agreement with the experimental findings. For efficient electron transfer, it appears crucial that the two molecules interact in the proper orientation. Direct cross-linking may disturb the formation of such an optimal electron transfer complex.

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A New Type 2 Copper Cysteinate Azurin

Amsterdam

Ubbink

Bosch

et al. 2002

Journal of Biological Chemistry

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Anisotropic spin label mobilities in azurin from 95 GHz electron paramagnetic resonance spectroscopy

Finiguerra

Amsterdam

Alagaratnam

et al. 2003

Chemical Physics Letters

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Anti-cooperativity in the two electron oxidation of the S118C disulfide dimer of azurin

Amsterdam

Ubbink

Canters

2002

Inorganica Chimica Acta

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Azurin dimer, crosslinked via disulfide bridge

Amsterdam¹,

Ubbink²,

Einsle³

et al. 2002

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