Assembly of Human Hemoglobin: STUDIES WITH ESCHERICHIA COLI-EXPRESSED α-GLOBIN

Abstract

The alpha-globin of human hemoglobin was expressed in Escherichia coli and was refolded with heme in the presence and in the absence of native beta-chains. The functional and structural properties of the expressed alpha-chains were assessed in the isolated state and after assembly into a functional hemoglobin tetramer. The recombinant and native hemoglobins were essentially identical on the basis of sensitivity to effectors (Cl- and 2,3-diphosphoglycerate), Bohr effect, CO binding kinetics, dimer-tetramer association constants, circular dichroism spectra of the heme region, and nuclear magnetic resonance of the residues in the alpha1beta1 and alpha1beta2 interfaces. However, the nuclear magnetic resonance revealed subtle differences in the heme region of the expressed alpha-chain, and the recombinant human normal adult hemoglobin (HbA) exhibited a slightly decreased cooperativity relative to native HbA. These results indicate that subtle conformational changes in the heme pocket can alter hemoglobin cooperativity in the absence of modifications of quaternary interface contacts or protein dynamics. In addition to incorporation into a HbA tetramer, the alpha-globin refolds and incorporates heme in the absence of the partner beta-chain. Although the CO binding kinetics of recombinant alpha-chains were the same as that of native alpha-chains, the ellipticity of the Soret circular dichroism spectrum was decreased and CO binding kinetics revealed an additional faster component. These results show that recombinant alpha-chain assumes alternating conformations in the absence of beta-chain and indicate that the isolated alpha-chain exhibits a higher degree of conformational flexibility than the alpha-chain incorporated into the hemoglobin tetramer. These findings demonstrate the utility of the expressed alpha-globin as a tool for elucidating the role of this chain in hemoglobin structure-function relationships.