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27 - Genetic Modulation of Sickle Cell Disease and Thalassemia

from SECTION SEVEN - SPECIAL TOPICS IN HEMOGLOBINOPATHIES

Published online by Cambridge University Press:  03 May 2010

Martin H. Steinberg ,
Bernard G. Forget ,
Douglas R. Higgs  and
David J. Weatherall
By
Martin H. Steinberg  and
Ronald L. Nagel
Martin H. Steinberg
Affiliation:
Boston University
Bernard G. Forget
Affiliation:
Yale University, Connecticut
Douglas R. Higgs
Affiliation:
MRC Institute of Molecular Medicine, University of Oxford
David J. Weatherall
Affiliation:
Albert Einstein College of Medicine, New York
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Summary

INTRODUCTION

Sickle cell anemia is a typical mendelian, single gene disease. Nevertheless, because of its characteristic phenotypic heterogeneity it resembles a multigenic trait. That is, the mutation in HBB is necessary, but alone insufficient to account for the phenotypic differences among patients, and other genes and the environment are likely to modulate its phenotype. In β thalassemia, and even in HbH disease, genotype–phenotype correlations are also often difficult to establish. Modulation of the phenotypes of these disorders by epistatic and other modifying genes has been a subject of increasing interest. Although studies based on candidate-modulating genes – genes chosen for study on the basis of their possible affects on a phenotype – have started to suggest genes and pathways that might modulate the phenotype of sickle cell anemia, a complete picture of genetic modulators should emerge as genome-wide association studies mature.

It is likely that fetal hemoglobin (HbF) concentration, and its distribution among erythrocytes is the major genetic modulator of both sickle cell disease and the β thalassemias. The coincidence of α thalassemia with sickle cell anemia or β thalassemia is another powerful modulatory influence. Individually, other genetic modulators are likely to have small effects, yet together the interactions of modulatory genes (and environmental factors) might have an important influence on morbidity and mortality.

In this chapter we will first discuss HbF and the genetic elements and genes that might modulate its levels and then the effects of α thalassemia in sickle cell disease and β thalassemia.

Information

Type
Chapter
Information
Disorders of Hemoglobin
Genetics, Pathophysiology, and Clinical Management
 , pp. 638 - 657
Publisher: Cambridge University Press
Print publication year: 2009

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