MWC allosteric model explains unusual hemoglobin-oxygen binding curves from sickle cell drug binding

Eric R Henry,Julia Harper,Kristen E Glass,Belhu Metaferia,John M Louis,William A Eaton

doi:10.1016/j.bpj.2021.04.024

Eric R Henry, Julia Harper + Show 4 more

Open Access

https://doi.org/10.1016/j.bpj.2021.04.024

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Journal: Biophysical journal	Publication Date: Apr 29, 2021
Citations: 11	License type: cc-by

Affiliation: National Institutes of Health

Abstract

An oxygen-affinity-modifying drug, voxelotor, has very recently been approved by the FDA for treatment of sickle cell disease. The proposed mechanism of action is by preferential binding of the drug to the R quaternary conformation, which cannot copolymerize with the T conformation to form sickle fibers. Here, we report widely different oxygen dissociation and oxygen association curves for normal blood in the presence of voxelotor and interpret the results in terms of the allosteric model of Monod, Wyman, and Changeux with the addition of drug binding. The model does remarkably well in quantitatively explaining a complex data set with just the addition of drug binding and dissociation rates for the R and T conformations. Whereas slow dissociation of the drug from R results in time-independent dissociation curves, the changing association curves result from slow dissociation of the drug from T, as well as extremely slow binding of the drug to T. By calculating true equilibrium curves from the model parameters, we show that there would be a smaller decrease in oxygen delivery from the left shift in the dissociation curve caused by drug binding if drug binding and dissociation for both R and T were rapid. Our application of the Monod, Wyman, and Changeux model demonstrates once more its enormous power in explaining many different kinds of experimental results for hemoglobin. It should also be helpful in analyzing oxygen binding and in vivo delivery in future investigations of oxygen-affinity-modifying drugs for sickle cell disease.

Highlights

Understanding oxygen binding by hemoglobin and its relation to the pathogenesis and treatment of sickle cell disease has a long and interesting history [1,2,3]
That increasing the affinity of hemoglobin S is being widely used as a therapeutic strategy to treat sickle cell disease (reviewed in [12]), it is important to revisit the issue of the relation between in vitro and in vivo oxygen binding and dissociation
It has been known since the very early reports of sickle cell disease that sickling is highly dependent on oxygen pressure [13] and, more recently, that the kinetics of sickling are exquisitely sensitive to the average number of oxygen molecules bound to the hemoglobin S tetramer, usually expressed as the fractional saturation with oxygen [14,15,16,17,18,19,20]

Summary

Introduction

Understanding oxygen binding by hemoglobin and its relation to the pathogenesis and treatment of sickle cell disease has a long and interesting history [1,2,3]. We show that slow binding and dissociation of the drug results in very different oxygen dissociation and association curves that can be readily explained with a straightforward application of the MWC model that includes drug binding.

Results

Conclusion