The spectroscopic and mechanistic properties of the Cu-containing active site of azurin from Pseudomonas aeruginosa were investigated by the construction of a mutant in which one of the ligands of the metal, His46, was replaced by a glycine. Although the mutation creates a hole in the interior of the protein, the 3D structure of the protein does not change to any appreciable extent. However, the spectroscopic (optical, resonance Raman, EPR) properties of the mutant protein are strongly affected by the mutation. In the presence of external ligands, the properties of the original wild-type protein are restored to a smaller or larger extent, depending on the ligand. It is concluded that the hole created by the mutation, even though it is completely buried inside the protein, can be filled by external ligands, often resulting in the creation of a mixture of so-called type-1 and type-2 copper sites. Also, the redox properties (midpoint potential, kinetics of reduction/oxidation) appeared to be strongly affected by the mutation and the presence of external ligands. The results are compared with previous results obtained on the mutant His117Gly.