Copper-induced spectroscopic and structural changes in short peptides derived from azurin.

The active sites of metalloproteins may be mimicked by designing peptides that bind to their respective metal ions. Studying the binding of protein ligands to metal ions along with the associated structural changes is important in understanding metal uptake, transport and electron transfer functions of proteins. Copper-binding metalloprotein azurin is a 128-residue electron transfer protein with a redox-active copper cofactor. Here, we report the copper-binding associated spectroscopic and structural properties of peptide loops (11 and 13 residues) from the copper-binding site of azurin. These peptides develop a beta-turn upon copper-binding with a 1:1 Cu(2+):peptide stoichiometry as seen in circular dichroism and exhibit electronic transitions centered at 340nm and 540nm. Further addition of copper develops a helical feature along with a shift in the absorption maxima to approximately 360nm and approximately 580nmat 2:1 Cu(2+):peptide stoichiometry, indicating stoichiometric dependence of copper-binding geometry. Mass spectrometry indicates the copper-binding to cysteine, histidine and methionine in the peptide with 1:1 stoichiometry, and interestingly, dimerization through a disulfide linkage at 2:1 stoichiometry, as observed previously for denatured azurin. Fluorescence quenching studies on peptides with tryptophan further confirm the copper-binding induced changes in the two peptides are bi-phasic.