Fluorescence study of conformational transitions in the structure of myoglobin.

Fluorescence studies of myoglobin and Mb-like structures, apomyoglobin and the complex of apo-Mb with protoporphyrin IX, reveal both the similarity between them, which is due to a common type of polypeptide chain folding, and the distinctions imposed by the influence of the prosthetic group. Close resemblance of structures of holomyoglobin and its metal-free analog, PPIX--apo-Mb, points to a key role of specific interactions between the protein and the protoporphyrin macrocycle rather than the Fe-protein bond in the formation of Mb-like structures. In PPIX--apo-Mb, both the hydrophobic core and the important ionic bonds between different structural elements (<>) stabilizing the Mb structure are almost completely retained. The bond between Fe and proximal His-F8 allows additional integration of the structures of the heme cavity and the myoglobin molecule as a whole, providing its functional activity and highly cooperative conformational transitions. In all the myoglobin-like structures studied, a certain relationship is found between conformational states of the <>, the heme cavity, and the N-terminal part of the molecule. This is probably due to variations in the mutual orientation of the ABCDE and FGH helical domains, depending on the interactions between the protein, the prosthetic group, and the ligand in the heme crevice. The correlation between conformations of the N-terminal and heme regions found at a level of the globin tertiary structure is very important for understanding the mechanisms of homo- and heterotropic regulation in tetrameric hemoglobins.