Structural investigations of modified haemoglobins by nuclear magnetic resonance spectroscopy

Isocyanide binding kinetics to monomeric hemoproteins. A study on the ligand partition between solvent and heme pocket

The kinetics of methyl-, ethyl-, iso-propyl-, and ter-butyl-isocyanide binding to Aplysia limacina myoglobin (distal His----Lys) and the isolated beta chains from hemoglobin Zurich (distal His----Arg) have been investigated by flash photolysis at various temperatures above 0 degrees C. Sperm whale (Physter catodon) myoglobin and the isolated beta chains from normal adult hemoglobin have been used as references. In most reaction systems investigated the apparent extent of photolysis increases with temperature. For sperm whale myoglobin and the normal beta chains the increase is of the same magnitude and not correlated to the type of ligand used. On the contrary, for the two proteins lacking the distal histidine, the phenomenon is dependent on the size of the alkyl side chain of the ligand. The results, analyzed on the basis of the multibarrier model (Austin, R.H., K.W. Beeson, L. Eisenstein, H. Frauenfelder, and I.C. Gunsalus, 1975, Biochemistry, 16:5355-5373), suggest that the partition of the ligand molecules between the solvent and the heme pocket, occurring during the photolysis process, is primarily determined by interactions between the ligand and residues in the heme cavity rather than by diffusion through the protein matrix.

Studies on the oxidation of hemoglobin Zurich (beta 63 E7 Arg)

Autoxidation and chemically-induced oxidation of hemoglobin Zurich (beta 63 E7 Arg) have been investigated by electron paramagnetic resonance and optical absorption spectroscopy. The results show that the replacement of the distal histidine of the hemoglobin beta chains by an arginine greatly enhances the susceptibility of the heme-iron to oxidative challenge. Both the kinetics and the products of the oxidation are pH dependent. Thus, at acidic and neutral pH, treatment of the protein with ferricyanide leads to a fast conversion of the oxy-protein to aquo-methemoglobin, which, eventually, is slowly converted to hemichromes. In contrast, the hydroxy-met derivative, formed upon chemical oxidation at high pH, is rapidly converted to hemichromes. The electron paramagnetic resonance features of the ferric derivatives of hemoglobin Zurich are somewhat singular, reflecting the modifications of the heme environment in the distal region of the abnormal chains. However, they can be related to heme complexes having their structural counterparts in oxidation products of hemoglobin A.

Haem degradation in abnormal haemoglobins

The coupled oxidation of certain abnormal haemoglobins leads to different bile-pigment isomer distributions from that of normal haemoglobin. The isomer pattern may be correlated with the structure of the abnormal haemoglobin in the neighbourhood of the haem pocket. This is support for haem degradation by an intramolecular reaction.