Allosteric control of hemoglobin S fiber formation by oxygen and its relation to the pathophysiology of sickle cell disease

Eric R Henry,Frédéric Galactéros,Stéphane Moutereau,John M Louis,David Ostrowski,James Hofrichter,Belhu Metaferia,Pablo Bartolucci,William A Eaton,Swee Lay Thein,Troy Cellmer,Emily B Dunkelberger,Rodolfo Ghirlando,Quan Li

doi:10.1073/pnas.1922004117

Abstract

The pathology of sickle cell disease is caused by polymerization of the abnormal hemoglobin S upon deoxygenation in the tissues to form fibers in red cells, causing them to deform and occlude the circulation. Drugs that allosterically shift the quaternary equilibrium from the polymerizing T quaternary structure to the nonpolymerizing R quaternary structure are now being developed. Here we update our understanding on the allosteric control of fiber formation at equilibrium by showing how the simplest extension of the classic quaternary two-state allosteric model of Monod, Wyman, and Changeux to include tertiary conformational changes provides a better quantitative description. We also show that if fiber formation is at equilibrium in vivo, the vast majority of cells in most tissues would contain fibers, indicating that it is unlikely that the disease would be survivable once the nonpolymerizing fetal hemoglobin has been replaced by adult hemoglobin S at about 1 y after birth. Calculations of sickling times, based on a recently discovered universal relation between the delay time prior to fiber formation and supersaturation, show that in vivo fiber formation is very far from equilibrium. Our analysis indicates that patients survive because the delay period allows the majority of cells to escape the small vessels of the tissues before fibers form. The enormous sensitivity of the duration of the delay period to intracellular hemoglobin composition also explains why sickle trait, the heterozygous condition, and the compound heterozygous condition of hemoglobin S with pancellular hereditary persistence of fetal hemoglobin are both relatively benign conditions.

Highlights

The pathology of sickle cell disease is caused by polymerization of the abnormal hemoglobin S upon deoxygenation in the tissues to form fibers in red cells, causing them to deform and occlude the circulation
We show that control of polymerization by oxygen at equilibrium can be better explained by a recent extension of the famous two-state allosteric model of Monod, Wyman, and Changeux
In this work we show that while the quaternary two-state allosteric model of Monod, Wyman, and Changeux (MWC) [30, 43] with no adjustable parameters provides a remarkably good description of the equilibrium data on fiber formation, a quantitatively better description is provided by applying the tertiary two-state allosteric model [44,45,46,47], which extends the MWC model to include tertiary conformational equilibria

Summary

Introduction

The pathology of sickle cell disease is caused by polymerization of the abnormal hemoglobin S upon deoxygenation in the tissues to form fibers in red cells, causing them to deform and occlude the circulation. Pauling was quite interested in the properties of hemoglobin [11,12,13] and realized from Sherman’s observation of birefringence that it must be due to aggregation of the hemoglobin to form an ordered structure in the red cells In his famous paper showing the difference in electrophoretic pattern of normal and sickle hemoglobin, he reasoned that for Significance. The root cause of pathology in sickle cell disease is the polymerization of the mutant hemoglobin S upon deoxygenation in the tissues to form fibers. Both the amount of fiber at equilibrium and the kinetics of fiber formation depend on the partial pressure of oxygen. Because of the unusual kinetics, polymerization is far out of equilibrium, which explains why patients with the disease manage to survive, while those with high levels of fetal hemoglobin and those with sickle trait (the heterozygous condition) have relatively benign conditions

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