A spectroscopic study of the haemin--human-serum-albumin system.

The interaction of haemin with human serum albumin has been reexamined. The absorption spectrum of the bound haem is identical with that of uncomplexed monomeric haemin in solution, and it is suggested, on the basis of an interaction of albumin with iron-free protoporphyrin IX, that the iron is not implicated in the interaction with the protein. A ferric cyanide derivative, and a ferrous haem derivative of methaemalbumin can be recognised, but not azide or fluoride derivatives. The bound haemin gives rise to extrinsic Cotton effects, which are different in detail in the derivatives, and in the complex with protoporphyrin IX Spectrophotometric titrations show that there is one strong binding site for haemin and several weaker sites. The latter are associated with optical activity opposite in sign to that of the strong complex. The binding profiles are little affected by pH over a wide range, by ionic strength or by the presence of 40% (v/v) dimethylsulphoxide/water, in which the free haemin is monomeric. The binding of haemin to albumin has been followed by spectrophotometry, circular dichroism and fluorescence. The binding of haemin quenches the protein fluorescence, which progressively changes in character from tryptophan to tyrosine type. The haem at the primary binding site thus strongly quenches the tryptophan specifically. From fluorescence titrations at a range of protein concentrations, binding isotherms were constructed, and gave an association constant for the strong site of 50 μM−1. From binding isotherms based on absorption measurements we can infer the existence of at least four sites with much lower binding constants. A long-chain fatty acid anion was found to compete with haemin only for the weaker binding sites, so that binding beyond one mole per mole of protein can be essentially eliminated. The open-chain tetrapyrrole, bilirubin, was found, in agreement with earlier work, not to compete with haemin, as regards the strongest binding sites of either ligand. Between the weaker sites, however, evidence of competition was obtained.

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