Positive Natural Selection in the Human Lineage

Sabeti, Pardis C.; Schaffner, Stephen F.; Fry, Ben; Lohmueller, Jason; Varilly, Patrick; Shamovsky, O.; Palma, A.; Mikkelsen, Tarjei S.; Altshuler, David; Lander, Eric S.

doi:10.1126/science.1124309

Cited by 1,059 publications

(1,067 citation statements)

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“…This is particularly true for the Val di Scalve sample, for which the presence of a single predominant haplotype and the results of neutrality tests suggest the occurrence of a founder effect followed by strong genetic Looking back to the evolutionary history of such a young and cosmopolitan species as H. sapiens, it is coherent to believe that our pathogens, which live in the extremely diversified environments colonized by modern humans, may have represented one of the major selective pressures on our genome. Thereby, genes whose function is strictly related to the immune system are supposed to be more likely subjected to the action of natural selection respect to other typology of genes, as recently confirmed by Sabeti et al 38 In particular, genes involved in adaptive immunity, such as TNFRSF13B, are likely to be subjected to recent geographically localized selective pressures, as they may interact with local pathogen landscapes, resulting in increased interpopulations genetic differentiation. We therefore sought for genetic footprints of selection at the TNFRSF13B gene by means of several neutrality tests based on the frequency spectrum of mutations (Tajima's D, Fu and Li's D, F and Fay and Wu's H) and on the comparison of human intraspecific genetic diversity and human/chimpanzee interspecific divergence (McDonald-Kreitman and HKA tests).…”

Section: Tnfrsf13b Evolution and Cvid M Sazzini Et Almentioning

confidence: 90%

An evolutionary approach to the medical implications of the tumor necrosis factor receptor superfamily member 13B (TNFRSF13B) gene

et al. 2009

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Coding variants in tumor necrosis factor receptor superfamily member 13B (TNFRSF13B) have been implicated in common variable immunodeficiency (CVID), but the functional effects of such mutations in relation to the development of the disease have not been entirely established. To examine the potential contribution of TNFRSF13B variants to CVID, we have applied an evolutionary approach by sequencing its coding region in 451 individuals belonging to 26 worldwide populations, in addition to controls, patients with CVID and selective IgA deficiency (IgAD) from Italy. The low level of geographical structure for the observed genetic diversity and the several neutrality tests performed confirm the absence of recent population-specific selective pressures, suggesting that TNFRSF13B may be involved also in innate immune functions, rather than in adaptive immunity only. A slight excess of rare derived alleles was found in patients with CVID, and thus some of these variants may contribute to the disease, implying that CVID probably fits the rare variants rather than the common disease/common variant paradigm. This also confirms the previous suggestion that TNFRSF13B defects alone do not cause CVID and that such an extremely heterogeneous immunodeficiency might be more likely related to additional, still unknown environmental and genetic factors.

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Section: Tnfrsf13b Evolution and Cvid M Sazzini Et Almentioning

confidence: 90%

An evolutionary approach to the medical implications of the tumor necrosis factor receptor superfamily member 13B (TNFRSF13B) gene

et al. 2009

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“…One could envision continuous selective pressure in Afri- can populations leading to the predominance of haplotypes ICOSp.h5, ICOSp.h6, and ICOSp.h7 (Ͼ60%), all bearing ICOSp.2C, whereas the migration out of Africa favored a gradual rise in frequency of ICOSp.h4 and the derived haplotypes ICOSp.h1 and ICOSp.h8. Because these events are expected to have happened over the last 60,000-80,000 years, selective signatures such as EHH over long stretches would be more modest than the selective signature of malaria or cattle domestication, both of which are more recent (12,23,24,32).…”

Section: Discussionmentioning

confidence: 99%

“…In the case of a bottlenecked population, the overall diversity is expected to be reduced, with a few haplotypes accounting for the bulk of the chromosomes. Recent positive selection (20,000 years or less), differentially affecting population groups, is characterized by a pattern of high-frequency haplotypes maintaining long neighboring segments in strong LD (23). To explore the costimulatory locus for such signatures, we analyzed the LD patterns using extended haplotype homozygosity (EHH) statistics, which focus on the relationship between the frequency of a given core haplotype and the span of SNP homozygosity at increasing distances from that core (24).…”

Section: Snp Distributions In Population Groupsmentioning

confidence: 99%

Signatures of strong population differentiation shape extended haplotypes across the human CD28 , CTLA4 , and ICOS costimulatory genes

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Roy

Sabeti

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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The three members of the costimulatory receptor family, CD28, CTLA-4, and ICOS, have complementary effects on T cell activation, and their balance controls the overall outcome of immune and autoimmune responses. They are encoded in a short genomic interval, and overall activity may result from interplay between allelic variants at each locus. With multiethnic DNA panels that represent a wide spectrum of human populations, we demonstrate long-range linkage disequilibrium among the three genes. A large fraction of the variation found in the locus can be explained by the presence of extended haplotypes encompassing variants at CD28, CTLA4, and the ICOS promoter. There are unusual differences in the distribution of some variants and haplotypes between geographic regions. The differences may reflect demographic events and/or the adaptation to diverse environmental and microbial challenges encountered in the course of human migrations and will be important to consider when interpreting association to immune/ autoimmune responsiveness.autoimmunity ͉ linkage disequilibrium ͉ T cell costimulation

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“…The primary models based on effects of positive selection (selection 'for' particular genetic variants, that arise and sweep through populations to some frequency; Sabeti et al 2006;Hughes 2007) that have been proposed include: (1) changing selection pressures, such that common alleles that were advantageous in ancestral environments (for example, 'thrifty' genes affecting the regulation of metabolism) are now deleterious, and derived alleles are selected for (Di Rienzo and Hudson 2005;Di Rienzo 2006), (2) balancing selection, whereby individuals with heterozygous genotypes are favored, resulting in the maintenance at high frequency of deleterious homozygotes, and (3) antagonistic pleiotropy, whereby selected alleles exert positive effects in one context, or early in the lifespan, that are stronger than, or balanced by, negative effects expressed in some other context or later in life (Keller and Miller 2006;Kryukov et al 2007). …”

Section: (C) Common Alleles Subject To Positive Selection or Balancinmentioning

confidence: 99%

“…Thus, just as a phenotype may be adaptive or maladaptive in some environmental context, an allele or haplotype may have increased or decreased in frequency as a result of selection over evolutionary time, or it may be maintained at some intermediate frequency. For evolutionary analyses of mental disorders, a focus at the level of alleles and haplotypes offers a number of useful analytic properties, such as the ability to infer the action of population-genetic processes, including selection for advantageous alleles, selection against deleterious alleles, or genetic drift, from data collected in extant populations (e. g., Biswas and Akey 2006; Sabeti et al 2006;Boyko et al 2008). Such evolutionary-genetic analyses permit rigorous quantification of how natural selection, drift, mutation, and other processes have influenced genetic liability to affective disorders, which in turn provides direct insights into the proximate genetic, physiological and developmental underpinnings of mental disorders, and the role of optimization by selection in ultimate-level studies of adaptive significance (Crespi et al 2007).…”

Section: Introductionmentioning

confidence: 99%

Evolutionary genetics of affective disorders

Crespi¹

2009

Understanding Depression

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I review evolutionary-genetic models for the generation, maintenance and loss of allelic variation underlying polygenic disease, in the context of affective disorders and related conditions. Genetically-based liability to these disorders appears to be due to some combination of mutation-selection balance involving common, small-effect variants and rare, large-effect variants, and natural selection involving antagonistic pleiotropy and balancing selection. At present, the primary usefulness of evolutionary genetics in the study of affective disorders is that it provides important insights into choices of genes, alleles, and haplotypes for analysis via genome-scan and association studies, and motivates a focus on the potential for pleiotropic, beneficial effects of alleles and genotypes that also influence disease risk.

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Positive Natural Selection in the Human Lineage

Cited by 1,059 publications

References 67 publications

An evolutionary approach to the medical implications of the tumor necrosis factor receptor superfamily member 13B (TNFRSF13B) gene

An evolutionary approach to the medical implications of the tumor necrosis factor receptor superfamily member 13B (TNFRSF13B) gene

Signatures of strong population differentiation shape extended haplotypes across the human CD28 , CTLA4 , and ICOS costimulatory genes

Evolutionary genetics of affective disorders

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