Hemoglobins, XXVIII. Phosphate-protein-interaction, gene expression and function: the genetic and allosteric control of the oxygen affinity of the fetal blood (author's transl)

This work describes possible molecular mechanisms concerning the control of oxygen affinity in fetal blood of mammalia. There is a genetic control of oxygen affinity through a fetal gene: at constant phosphate concentration (Hb less than P2-glycerate) in humans there is a hemoglobin with only five binding sites to 2,3-bisphosphoglycerate, resulting in an increased oxygen affinity. In several species (sheep, cattle, goat) with Met-Leu as the N-terminal group of the beta-chains, the 2,3-bisphosphoglycerate binding sites are deleted in positions beta 1 and beta 2, so that the regulation is phosphate-independent and thus providing a fetal hemoglobin with an increased oxygen affinity. The allosteric control is observed in pigs. In the postembryonal development "adult" hemoglobin with seven contacts (beta-chains) is demonstrated. The increased oxygen affinity is achieved here by a reduced biosynthesis of 2,3-bisphosphoglycerate (Hb greater than P2-glycerate) (Rapoport-Luebering-cycle). The functional control is discussed with respect to the ontogeny of the hemoglobins.