History and Structure of Sub-Saharan Populations of<i>Drosophila melanogaster</i>

Pool, John E.; Aquadro, Charles F.

doi:10.1534/genetics.106.058693

Cited by 73 publications

(121 citation statements)

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“…Moreover, Pennsylvania and Tasmania Y chromosomes are nearly indistinguishable ( Figure 2 and Table 2). Consistent with several surveys of population differentiation showing considerable population structure in Asia (Hale and Singh 1991;Baudry et al 2004;Pool and Aquadro 2006;Schlötterer et al 2006), the Beijing Y chromosome is highly differentiated from the rest of the populations. There is no evidence of substructuring within the Beijing population on the Y chromosome ( Figure 2B).…”

Section: Population Structuresupporting

confidence: 87%

“…There is no evidence of substructuring within the Beijing population on the Y chromosome ( Figure 2B). Outside of the clustering of Zimbabwe and Netherlands Y chromosomes, these results are consistent with the population structure of autosomal, X chromosomal, and mitochondrial loci from these or similar populations (Hale and Singh 1991;Baudry et al 2004;Haddrill et al 2005;Pool and Aquadro 2006;Schlötterer et al 2006). Genomic sequences from non-Y-linked loci exclude the possibility that the similarity of Netherlands and Zimbabwe Y chromosomes are explained by contamination in our fly lines (A.G. Clark, unpublished results).…”

Section: Population Structuresupporting

confidence: 84%

“…We used the average u X estimated from Haddrill et al (2005) for the following populations: Zimbabwe (0.01327); Netherlands (0.00414); and Pennsylvania (0.00557). For Uganda and Beijing, we used estimates of u X from Pool and Aquadro (2006), 0.012 and 0.0036, respectively (Table S1). Because comparable X-linked data (PCR resequence data from noncoding X-linked loci) are not currently available for Tasmania, we assumed a uniform range of u X values that encompass the Cosmopolitan samples that we have considered [u X U(0.0020-0.0045)].…”

Section: Coalescent Methods For Tests Of Neutralitymentioning

confidence: 99%

“…Briefly, Pool and Aquadro (2006) surveyed 10 lines of flies from a China and Uganda population at 4 noncoding X-linked loci at least 10 kb from coding loci in regions of high recombination (Table S1). Haddrill et al (2005) surveyed the introns of 10 X-linked genes across regions of the X chromosome with high recombination in Zimbabwe, Netherlands, and Pennsylvania populations (Table S1).…”

Section: X-linked Polymorphismmentioning

confidence: 99%

“…Moreover, Pool and Aquadro (2006) hypothesized that the ancestral source population for the Out-of-Africa migration to Europe was similar to a Uganda population based on X-linked variation data.…”

Section: Positive Selection In Africamentioning

confidence: 99%

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Surprising Differences in the Variability of Y Chromosomes in African and Cosmopolitan Populations ofDrosophila melanogaster

Larracuente

Clark

2013

Genetics

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The nonrecombining Drosophila melanogaster Y chromosome is heterochromatic and has few genes. Despite these limitations, there remains ample opportunity for natural selection to act on the genes that are vital for male fertility and on Y factors that modulate gene expression elsewhere in the genome. Y chromosomes of many organisms have low levels of nucleotide variability, but a formal survey of D. melanogaster Y chromosome variation had yet to be performed. Here we surveyed Y-linked variation in six populations of D. melanogaster spread across the globe. We find surprisingly low levels of variability in African relative to Cosmopolitan (i.e., non-African) populations. While the low levels of Cosmopolitan Y chromosome polymorphism can be explained by the demographic histories of these populations, the staggeringly low polymorphism of African Y chromosomes cannot be explained by demographic history. An explanation that is entirely consistent with the data is that the Y chromosomes of Zimbabwe and Uganda populations have experienced recent selective sweeps. Interestingly, the Zimbabwe and Uganda Y chromosomes differ: in Zimbabwe, a European Y chromosome appears to have swept through the population.T HE Drosophila melanogaster Y chromosome is highly functionally specialized in male-related activities (Hardy et al. 1981;Kennison 1981;Goldstein et al. 1982). Although it comprises 13% of the male genome (40 Mb;Hoskins et al. 2002), the D. melanogaster Y chromosome has only 13 known protein-coding genes (Goldstein et al. 1982;Carvalho et al. 2000Carvalho et al. , 2001Vibranovski et al. 2008;Krsticevic et al. 2010), all thought to be active only in primary spermatocytes in the testis (Hardy et al. 1981). The remainder of the Y chromosome is heterochromatic and dense in repetitive elements (Hoskins et al. 2002).Although the D. melanogaster Y chromosome is highly repetitive and gene poor, several lines of evidence suggest that it harbors functionally important variation (Chippindale and Rice 2001;Rohmer et al. 2004;Lemos et al. 2008;Lemos et al. 2010). The Y chromosome has contributed to variation in thermotolerance across D. melanogaster populations (Rohmer et al. 2004), has epistatic effects on male fitness (Chippindale and Rice 2001), and has epigenetic effects on the expression of genes across the genome (Lemos et al. 2008Jiang et al. 2010), including specifically in the male germline (Zhang 2000). The functional variation on the Y chromosome has been somewhat of a paradox because, while there is evidence for structural polymorphism (Lyckegaard and Clark 1989), the haploid transmission of the Y chromosome makes it far more difficult to maintain substantial levels of genetic variation (Clark 1987). In one small survey of Y chromosomal variation in a protein-coding gene, kl-5 (DhcYh3), only a single segregating site was discovered in 11 lines of D. melanogaster and no variants were found in 10 lines of Drosophila simulans (Zurovcova and Eanes 1999). A more recent study in a closely related species, D. simulans,...

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Section: Population Structuresupporting

confidence: 87%

Section: Population Structuresupporting

confidence: 84%

Section: Coalescent Methods For Tests Of Neutralitymentioning

confidence: 99%

Section: X-linked Polymorphismmentioning

confidence: 99%

Section: Positive Selection In Africamentioning

confidence: 99%

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Surprising Differences in the Variability of Y Chromosomes in African and Cosmopolitan Populations ofDrosophila melanogaster

Larracuente

Clark

2013

Genetics

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Charting the genotype–phenotype map: lessons from the Drosophila melanogaster Genetic Reference Panel

Mackay

Huang

2017

WIREs Developmental Biology

132

140

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Understanding the genetic architecture (causal molecular variants, their effects and frequencies) of quantitative traits is important for precision agriculture and medicine and predicting adaptive evolution, but is challenging in most species. The Drosophila melanogaster Genetic Reference Panel (DGRP) is a collection of 205 inbred strains with whole genome sequences derived from a single wild population in Raleigh, North Carolina, USA. The large amount of quantitative genetic variation, lack of population structure and rapid local decay of linkage disequilibrium in the DGRP and outbred populations derived from DGRP lines present a favourable scenario for performing genome wide association (GWA) mapping analyses to identify candidate causal genes, polymorphisms and pathways affecting quantitative traits. The many GWA studies utilizing the DGRP have revealed substantial natural genetic variation for all reported traits, little evidence for variants with large effects but enrichment for variants with low P-values, and a tendency for lower frequency variants to have larger effects than more common variants. The variants detected in the GWA analyses rarely overlap those discovered using mutagenesis, and often are the first functional annotations of computationally predicted genes. Variants implicated in GWA analyses typically have sex-specific and genetic background-specific (epistatic) effects, as well as pleiotropic effects on other quantitative traits. Studies in the DGRP reveal substantial genetic control of environmental variation. Taking account of genetic architecture can greatly improve genomic prediction in the DGRP. These features of the genetic architecture of quantitative traits are likely to apply to other species, including humans.

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Population Genomics on the Fly: Recent Advances in Drosophila

Haudry

Laurent

Kapun

2020

Methods in Molecular Biology

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Drosophila melanogaster, a small dipteran of African origin, represents one of the best-studied model organisms. Early work in this system has uniquely shed light on the basic principles of genetics and resulted in a versatile collection of genetic tools that allow to uncover mechanistic links between genotype and phenotype. Moreover, given its world-wide distribution in diverse habitats and its moderate genome-size, Drosophila has proven very powerful for population genetics inference and was one of the first eukaryotes whose genome was fully sequenced. In this bookchapter, we provide a brief historical overview of research in Drosophila and then focus on recent advances during the genomic era. After describing different types and sources of genomic data, we discuss mechanisms of neutral evolution including the demographic history of Drosophila and the effects of recombination and biased gene conversion. Then, we review recent advances in detecting genome-wide signals of selection, such as soft and hard selective sweeps. We further provide a brief introduction to background selection, selection of non-coding DNA and codon usage and focus on the role of structural variants, such as transposable elements and chromosomal inversions, during the adaptive process. Finally, we discuss how genomic data helps to dissect neutral and adaptive evolutionary mechanisms that shape genetic and phenotypic variation in natural populations along environmental gradients. In summary, this book chapter serves as a starting point to Drosophila population genomics and provides an introduction to the system and an overview to data sources, important population genetic concepts and recent advances in the field.

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History and Structure of Sub-Saharan Populations ofDrosophila melanogaster

Cited by 73 publications

References 64 publications

Surprising Differences in the Variability of Y Chromosomes in African and Cosmopolitan Populations ofDrosophila melanogaster

Surprising Differences in the Variability of Y Chromosomes in African and Cosmopolitan Populations ofDrosophila melanogaster

Charting the genotype–phenotype map: lessons from the Drosophila melanogaster Genetic Reference Panel

Population Genomics on the Fly: Recent Advances in Drosophila

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