Abstract

Cupredoxins host in their scaffold one of the most studied and interesting metal sites in biology: the type 1 (T1) or blue Cu center. Blue Cu proteins have evolved to play key roles in biological electron transfer and have the ability to react with a wide variety of redox partners. The inner coordination sphere of T1 Cu sites conserves two histidines and one cysteine with a short Cu-S(Cys) bond as ligands in a trigonal arrangement, with a variable axial ligand that modulates the electronic structure and reactivity. The structural, electronic and geometric features of T1 Cu centers provide the basis for a site that can be optimized by the protein structure for each biological function. This chapter highlights the properties that make this unique Cu center in biology an efficient and tunable electron transfer site. The contributions of the first coordination shell and the high covalency of the Cu-S(Cys) bond in the T1 Cu site to its distinctive geometric and spectroscopic features are discussed, as well as the role of the protein scaffold in imposing an 'entatic' state with a distorted tetrahedral geometry that minimizes geometric changes upon redox cycling. The analysis of naturally occurring perturbed blue Cu sites provides further insights into how the protein scaffold can tune the properties of the T1 Cu site. Blue Cu sites display a wide range of reduction potentials, as these are tuned to be consistent with their physiologically relevant electron donors and acceptors. The different properties of the protein matrix that play important roles in finetuning the reduction potential of T1 Cu sites are also discussed, including the nature of the axial ligand and outer coordination sphere effects. These concepts are further illustrated by the discussion of examples of biosynthetic blue Cu proteins. Finally, the different features of the T1 Cu site that make it an optimal site for electron transfer (ET) are discussed, in terms of Markus theory for intra- and inter-molecular ET. The active site in multicopper oxidases is used as an example to illustrate the contributions of the anisotropic covalency of the blue Cu site to an efficient ET, while the diverse reactivity of the T1 Cu sites in these enzymes is discussed to dissect the different properties provided by the protein that help tune these unique sites for biological ET.

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