A study of the structure and redox properties of the copper site in azurins
by means of EXAFS, NMR, redox titrations, potentiometry, equilibrium cycli
c voltammetry and rapid scan voltammetry on protein films is reported. The
results are discussed in light of existing theories on structure and functi
on of type-1 copper sites. The exit and entry of electrons take place throu
gh the C-terminal histidine ligand of the copper. The hydrophobic patch thr
ough which this residue penetrates the protein surface plays an important r
ole in partner docking (cf. The rim of the porphyrin ring sticking through
the surface of the cytochromes-c). We find no experimental evidence for str
ain around the metal site. The active centre is able to maintain ET activit
y even in the presence of fairly gross disturbances of the site structure.
The analysis of the thermodynamics of the redox reaction shows that the pro
tein matrix and the solvent play an important role in 'tuning' the redox po
tential around a "design'' value of around 300 mV at room temperature. The
metal site appears "designed'' to stabilise the Cu(ii) instead of the Cu(i)
form. The remarkable evolutionary success of the blue copper proteins is a
scribed to the sturdy overall beta -sandwich structure of the protein in co
mbination with a metal site that is structurally adaptable because three of
its four ligands are located on a loop. The electronic "gate'' that occurs
in the middle of a hydrophobic patch allows for fine tuning of the docking
patch for recognition purposes.