The non-specificity of dog serum albumin and the N-terminal model peptide glycylglycyl-L-tyrosine N-methylamide for nickel is due to the lack of histidine in the third position.

Equilibrium dialysis of dog serum albumin (DSA) against Ni(II) in 0.1 M-N-ethylmorpholine/HCl, pH 7.53, demonstrates the absence of a specific Ni(II)-binding site in DSA. To evaluate at the molecular level the influence of the genetic substitution of L-tyrosine for L-histidine at the N-terminal of DSA, a simple model tripeptide of the N-terminal residues, glycylglycyl-L-tyrosine N-methylamide, was synthesized and its Ni(II)-binding properties studied. A comparison of the visible absorption characteristics of Ni(II)-DSA with those of Ni(II)-glycylglycyl-L-tyrosine N-methylamide reveals a similar change from octahedral to planar co-ordination as the pH is increased. Both systems exhibit a low Ni(II)-binding affinity at physiological pH, with DSA binding a greater percentage of Ni(II) owing to the availability of at least two binding sites of similar affinities. The complex equilibria between Ni(II) and glycylglycyl-L-tyrosine N-methylamide were studied by analytical potentiometry (0.15 M-NaCl, 25 degrees C). Four major complex species, MHA, MH-1A2, MH-2A2 and MH-3A [where M and A represent Ni(II) ion and anionic peptide respectively], were detected, MHA being the single species at physiological pH. There is no evidence for the involvement of the phenolic hydroxy group in the octahedral MHA complex, or within the plane of co-ordination in the high-pH species. The results provide direct evidence that the low Ni(II)-binding affinity of DSA is due to the genetic substitution of tyrosine for histidine at the N-terminal region of the protein.