High frequencies of α-thalassaemia are the result of natural selection by malaria

Flint, Jonathan; Hill, Adrian V. S.; Bowden, Donald Keith; Oppenheimer, Stephen; Sill, P. R.; Serjeantson, S. W.; Bana-Koiri, J; Bhatia, Kuldeep; Alpers, Michael P.; Boyce, A. J.

doi:10.1038/321744a0

Cited by 367 publications

(224 citation statements)

References 37 publications

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“…For example, there does not appear to be any of the common malariaresistant variants in native people of the new world (Livingstone, 1985), apparently because their Asian ancestors were not exposed to malaria and malaria was only brought to the new world by early Spanish explorers in the 1600s and 1700s. In addition, there are convincing examples of microgeographic variation in bthalassemia with higher frequencies at lower altitudes in Sardinia where malaria was historically endemic compared with higher altitudes (Siniscalco et al, 1961) and variation of a-thalassemia (Flint et al, 1986) and bthalassemia (Hill et al, 1988) in Melanesia correlated with altitude, which is highly correlated with malaria endemicity.…”

Section: General Backgroundmentioning

confidence: 99%

“…The distribution of both a and b thalassemia variants correspond closely to the regions that have historically had high rates of malaria (Weatherall and Clegg, 2001) and the local distribution of these variants also corresponds to endemic malaria (Siniscalco et al, 1961;Flint et al, 1986;Hill et al, 1988). In addition, several studies have shown protection from severe malaria for individuals with a þ thalassemia, compared with individuals without thalassemia (Allen et al, 1997;Mockenhaupt et al, 2004;Williams et al, 2005b).…”

Section: A-thalassemiamentioning

confidence: 99%

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Population genetics of malaria resistance in humans

2011

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Section: General Backgroundmentioning

confidence: 99%

Section: A-thalassemiamentioning

confidence: 99%

Population genetics of malaria resistance in humans

2011

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“…1 One of the clearest manifestations of such genetic control is malaria, where the parasite seems to have influenced the gene pool of the human host in areas of endemic disease, including retention of otherwise deleterious, disease-causing alleles at erythroid-specific genes (reviewed in Fortin et al 2 ). These include polymorphisms in the Duffy gene at the GATA-1-binding site of the chemokine receptor (DARC, also known as Fy) expressed on erythrocytes, 3 sickle cell anemia, 4 a and b thalassemia, 5,6 glucose-6-phosphate dehydrogenase (G6PD) enzyme deficiency, 7,8 and alterations in proteins associated with red cell integrity, such as deletions in the erythrocytic band 3 protein 9 or in the erythrocytic structural protein glycophorin C. 10 Furthermore, Class I and II HLA haplotypes 11 and genetically controlled variations in the level of the proinflammatory cytokine TNFa 12 have been shown to affect the severity and outcome of malaria. Finally, genetic linkage studies by whole genome scanning have shown that several chromosomal regions additionally affect innate susceptibility, extent of host response, and type of disease, 2 although the individual genes involved have yet to be identified.…”

Section: Introductionmentioning

confidence: 99%

Phenotypic expression of pyruvate kinase deficiency and protection against malaria in a mouse model

Min‐Oo

Fortin

et al. 2004

Genes Immun

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The recombinant congenic mouse strains AcB55 and AcB61 are extremely resistant to malaria (Plasmodium chabaudi AS) despite the presence of susceptibility alleles at the known Char1/Char2 resistance loci. Resistance in AcB55 and AcB61 is controlled by a locus on chromosome 3 (Char4) shown to be allelic with or tightly linked to a loss-of-function mutation in pyruvate kinase (Pklr). AcB55 and AcB61 show important splenomegaly prior to infection caused by the expansion of the red pulp, and display histological signs of extramedullary erythropoiesis in the liver. Examination of splenic cell populations by flow cytometry demonstrates elevated numbers of TER119-positive erythroid precursor cells (430% of total spleen cells), while RNA expression studies show elevated expression of erythrocyte-specific transcripts such as globin, transferrin receptor, and Nramp2/Slc11a2 in the spleen of both strains. Hematological profiling in both strains is consistent with the presence of anemia as evidenced by low total erythrocyte counts, decreased hemoglobin, as well as abnormally high numbers of circulating reticulocytes (15-20%). These results strongly suggest that the mutant Pklr allele (Pklr 269A ) of AcB55/61 strains causes hemolytic anemia compensated by constitutive erythropoiesis, which in turn protects the mice against P. chabaudi infection. The possible molecular basis of the Pklr protective effect is discussed and is under current investigation in these two strains.

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“…The high frequency of hemoglobinopathies generally occurs in areas with historically endemic malaria and it appears that the alteration of the amount and/or type of globin molecules from these disorders confers protection from malarial parasites. In particular, the distribution of α + thalassemia variants corresponds closely with regions that have had historically high rates of malaria and the local distribution of these variants also corresponds to historically endemic malaria (Flint et al, 1986). Haldane (1949) first suggested that genetic variants were important for resistance to malaria and proposed that there may be heterozygote advantage for β thalassemia variants maintaining genetic variation at the β globin locus.…”

Section: Introductionmentioning

confidence: 99%

“…The haplotypes for the deletional chromosomes with 2, 1, and 0 α globin genes are indicated by αα, −α, and −−, respectively, and the homozygous genotypes for α + thalassemia and α 0 thalassemia are indicated by −α/−α and −−/−−. Heterozygotes for α + thalassemia have three normal genes, −α/αα, and are often difficult to distinguish from normal individuals while homozygotes for α + thalassemia have a mild anemia with little known fitness consequences in nonmalarial environments (Flint et al, 1986). Homozygotes for α 0 thalassemia have hydrops fetalis (fetal edema from anemia), do not survive, and are stillborn.…”

Section: Introductionmentioning

confidence: 99%

Selection and Mutation for α Thalassemia in Nonmalarial and Malarial Environments

Hedrick

2011

Annals of Human Genetics

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Summaryα thalassemia is the result of the loss of one or both copies of the two human α globin genes. α thalassemia appears to be the most common monogenic disease in the world and is in high frequency where malaria is, or has been, endemic. In nonmalarial environments, α thalassemia is rare and its frequency can be explained by a balance of deletional mutation and purifying selection. In malarial environments, the loss of one or two copies of the four α globin genes in normal diploid genotypes confers resistance (lower mortality) to malaria. Fitness estimates from data from Kenyan and Papua New Guinea populations are used to predict the increase in the −α haplotype (with one deleted gene). The frequency of double deletions (−− haplotypes) is higher in some Asian populations than that of single deletions. In this case, heterozygotes with normal αα haplotypes are expected to have the highest fitness. Overall, this population genetic examination provides an evolutionary framework for understanding the worldwide frequency of α thalassemia and the deletions that cause it in both nonmalarial and malarial environments.

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High frequencies of α-thalassaemia are the result of natural selection by malaria

Cited by 367 publications

References 37 publications

Population genetics of malaria resistance in humans

Population genetics of malaria resistance in humans

Phenotypic expression of pyruvate kinase deficiency and protection against malaria in a mouse model

Selection and Mutation for α Thalassemia in Nonmalarial and Malarial Environments

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