Linkage of organic phosphates to oxygen binding in human hemoglobin at high concentrations

We have performed high-precision oxygen binding studies on human hemoglobin tetramers in the presence of a series of limited, subsaturating amounts of the effector compounds 2,3-diphosphoglycerate (DPG) and inositol hexaphosphate (IHP). The use of thin-layer optical methods enabled the use of high hemoglobin concentrations, preventing complications arising from the dissociation of the tetramer into dimers. Model-independent, simultaneous analysis of all data for each effector demonstrated that the intrinsic oxygen binding characteristics of the molecule are in agreement with those determined in earlier high-precision studies [e.g., Gill, S. J., Di Cera, E., Doyle, M. L., Bishop, G. A., & Robert, C. H. (1987) Biochemistry 26, 3995-4002] and that the affinity of the tetramer for the tightly binding effector IHP changes most markedly between the second and fourth oxygen binding steps, perhaps indicating a large conformational change. The data were then analyzed by using the truncated allosteric model [Di Cera, E., Robert, C. H., & Gill, S. J. (1987) Biochemistry 26, 4003-4008], which is based on the hypothesis that a quaternary conformational change occurs in the hemoglobin tetramer before the third and fourth oxygen molecules bind.     

The interaction of organic phosphates with human and chicken hemoglobin.

In this study of the binding properties of inositol hexaphosphate and 2,3-bisphosphoglycerate to chicken and human deoxyhemoglobin and carboxyhemoglobin were compared. It appeared that in all cases the binding to chicken hemoglobin is much stronger than to human hemoglobin. This is very probably due to the fact that 4 out of the 12 residues, responsible for the binding of phosphates in chicken hemoglobin, are arginines. These are absent in human hemoglobin, where the binding site is made up to only 8 residues. For chicken hemoglobin one strong binding site could be observed in both unliganded and liganded hemoglobin. From these observations we conclude that the same binding site is involved in both the oxy- and deoxy structure showing different affinity to phosphates in the two conformational states. For human hemoglobin we reached the same conclusion.     

Analysis of the interaction of organic phosphates with hemoglobin.

The interaction of organic phosphates with hemoglobin is studied by use of a simple thermodynamic approach. A model-independent analysis is employed to evaluate the accuracy of Adair constants determined in the presence of 2,3-diphosphoglycerate (DPG). The change of oxygen affinity in the presence of phosphates is related to the macroscopic phosphate binding constants of oxy- and deoxyhemoglobin and used to extract such binding constants from oxygen equilibrium measurements. The change of the Bohr effect in the presence of phosphates and the competitive binding of carbon dioxide and DPG are treated quantitatively. The binding of organic phosphates is incorporated into an allosteric model, in which the effect of phosphate on both tertiary and quaternary structure changes is included. By use of this model, the factors which can be responsible for the increased functional heterogeneity of alpha and beta chains in the presence of phosphates are clarified.     

Covalent fixation of hemoglobin to dextran phosphates decreases its oxygen affinity.

The interactions between various dextran phosphates and Hb (hemoglobin) were studied by measuring the oxygen-binding parameters of the mixtures. The effector properties of polymers were found to depend on the concentration of monoalkylmonophosphate groups on the polymers and also on their molecular weights. The covalent fixation of dextran phosphates bearing aldehydic groups to oxyHb and deoxyHb was carried out. The oxygen-binding properties of the conjugates thus obtained depended upon the initial form of the protein. Thus, only the conjugates synthesized from deoxyHb exhibited a low oxygen affinity, which means that, in this case, the linkages between the dextran phosphate and the protein allow a permanent interaction of the phosphate groups with amines of the 2,3-diphosphoglycerate binding site. The Hill coefficient values of these conjugates were smaller than that of free Hb, corresponding to a loss of the cooperativity of the protein upon fixation of polymers. However, as these new conjugates are capable of unloading more O2 than blood when subjected to oxygen pressures corresponding to physiological conditions, they can be regarded as potential erythrocyte substitutes.     

Effect of oxygen binding on the dielectric properties of hemoglobin

The dielectric properties of horse hemoglobin have been investigated in the frequency range for 100 kcps to 15 Mcps at varying degrees of oxygenation. A linear dependence of the specific increment on the degree of oxygenation was found under a variety of experimental conditions, the increment of oxygenated hemoglobin being about 10% larger than that of deoxygenated hemoglobin. A similar difference was obtained with human adult and fetal hemoglobin. No variation of the dielectric parameters as reported by Takashima and Lumry could be detected.     

The oxygen affinity of hemoglobin betaSH chains is concentration dependent.

Oxygen binding to isolated hemoglobin β^SH chains exhibits heterotropic interactions with H⁺, inositol hexaphosphate and CO₂ which implies different structures of the liganded and unliganded β chains. In order to find out if the dissociation behaviour of $\text{β}{}_4{}^{\mathrm{SH}}$ homotetramers is likewise linked to oxygenation, we have measured the oxygen affinity of the pigment as a function of the protein concentration at different pH values. We found that a decrease in protein concentration is associated with a decrease in oxygen affinity. This result accords with predictions reached from studies on the self-association of liganded and unliganded β chains. Furthermore, it was established that both at high and low protein concentrations the oxygen affinity of the β chains is pH dependent.