Properties of Hemoglobin Solutions in Red Cells

doi:10.1085/jgp.52.5.825

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Properties of Hemoglobin Solutions in Red Cells

C. M. Gary-Bobo ¹ and A. K. Solomon ¹

¹ From the Biophysical Laboratory, Harvard Medical School, Boston, Massachusetts 02115.

Dr. Gary-Bobo's present address is Laboratoire de Physiologie Cellulaire, Collège de France, Paris, France

The present studies are concerned with a detailed examinationof the apparent anomalous osmotic behavior of human red cells.Red cell water has been shown to behave simultaneously as solventwater for nonelectrolytes and nonsolvent water, in part, forelectrolytes. The nonsolvent properties are based upon assumptionsinherent in the conventional van't Hoff equation. However, calculationsaccording to the van't Hoff equation give osmotic volumes considerablyin excess of total cell water when the pH is lowered beyondthe isoelectric point for hemoglobin; hence the van't Hoff equationis inapplicable for the measurement of the solvent propertiesof the red cell. Furthermore, in vitro measurements of osmoticand other properties of 3.7 millimolal solutions of hemoglobinhave failed to reveal the presence of any salt exclusion. Anew hypothesis has been developed from thermodynamic principlesalone, which predicts that, at constant pH, the net charge onthe hemoglobin molecule decreases with increased hemoglobinconcentration. The existence of such cooperative interactionmay be inferred from the effect of pH on the changes in hemoglobinnet charge as the spacing between the molecules decreases. Theresultant movement of counterions across the cell membrane causesthe apparent anomalous osmotic behavior. Quantitative agreementhas been found between the anion shift predicted by the equationand that observed in response to osmotic gradients. The proposedmechanism appears to be operative in a variety of tissues andcould provide an electrical transducer for osmotic signals.

Submitted on May 6, 1968

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