Random chemical modification of the oxygen-linked chloride-binding sites of hemoglobin: Those in the central dyad axis may influence the transition between deoxy- and oxy-hemoglobin

Abstract

The features of random chemical modification are defined with reference to acetylation of bovine hemoglobin, which has been performed in a random manner so that all of the amino groups that participate in functional chloride binding (i.e., those that are oxygen-linked) could be identified. Random chemical modification, which has objectives different from those of both specific (selective) and extensive chemical modification, has been achieved for bovine hemoglobin with the mild reagent,¹⁴C-methyl acetate phosphate; retention of function was demonstrated by a Hill coefficient ofn=2.2 for the modified hemoglobin. After removal of unmodified Hb chains, the mixture of randomly modified acetylated α or β chains was subjected to tandem treatment with trypsin and chymotrypsin. Peptides were purified by HPLC and identified by amino acid analysis. The amount of radioactivity in the acetylated amino group of a purified peptide was taken as an estimate of the degree of chloride binding. For bovine Hb, two amino groups of the α-chain (Val-1 and Lys-99) and three amino groups of the β-chain (Met-1, Lys-81, and Lys-103) were shown to be oxygen-linked (i.e., to have incorporated significantly more radioactivity in the deoxy conformation compared to the same site in the oxy conformation). Three of these sites were already known chloride-binding sites [i.e., Val-1(α), the N-terminus of the α-chain, and two sites between the 2 β-chains of bovine hemoglobin, Met-1(β) and Lys-81(β); these findings support the conclusions of the random modification approach. Two other chloride-binding sites, Lys-99(α) and Lys-103(β), align the sides of the central dyad axis connecting the two well-known major chloride-binding sites of bovine Hb. The interrelationship of these five chloride-binding sites was assessed by improved molecular graphics. When viewed through the central dyad axis, the functional chloride-binding sites in the central cavity appear to be symmetrically related and to connect the two major chloride-binding sites. Modifiers or mutants that are directed at these regions in the central dyad axis may favor the deoxy conformation to provide a lower oxygen affinity by preventing the constriction of the central cavity that normally occurs upon oxygenation.