Genetic structure correlates with ethnolinguistic diversity in eastern and southern Africa

Atkinson, Elizabeth G.; Dalvie, Shareefa; Pichkar, Yakov; Kalungi, Allan; Majara, Lerato; Stevenson, Anne; Abebe, Tamrat; Akena, Dickens; Alemayehu, Melkam; Ashaba, Fred K.; Atwoli, Lukoye; Baker, Mark R.; Chibnik, Lori B.; Creanza, Nicole; Daly, Mark J.; Fekadu, Abebaw; Gelaye, Bizu; Gichuru, Stella; Injera, Wilfred E.; James, Roxanne; Kariuki, Symon M.; Kigen, Gabriel; Koen, Nastassja; Koenig, Zan; Kwobah, Edith; Kyebuzibwa, Joseph; Musinguzi, Henry; Mwema, Rehema M.; Neale, Benjamin M.; Newman, Carter P.; Newton, Charles R.; Ongeri, Linnet; Ramachandran, Sohini; Ramesar, Raj; Shiferaw, Welelta; Stein, Dan J.; Stroud, Rocky E.; Teferra, Solomon; Zingela, Zukiswa; Martin, Alicia R.; Team, NeuroGAP-Psychosis Study

doi:10.1101/2021.05.19.444732

Cited by 5 publications

(6 citation statements)

References 59 publications

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“…This correspondence between genetic boundaries – which are associated with both historical migrations and distributions of ethnicities – and linguistic boundaries – associated with dialect and other cultural differences – demonstrate that language and genetics have similar geographic patterns in England. These gene-language patterns at the the English-Welsh and the English-Scottish borders support previous studies that identify the covariation of culture and genetics at ethnic boundaries (22, 24, 26–29). We find that, in addition to more prominent cultural borders, this covariation extends to less dramatic distinctions, including those between South East and South West England and between North and South England.…”

Section: Discussionsupporting

confidence: 88%

“…One such trait is the specific set of languages or dialects a person speaks, since languages contain clues about the history of populations (6,(18)(19)(20)(21) and have been found to co-vary with genetic variation on a worldwide scale (5,6), though this pattern of covariation is not found everywhere (7,22). Finer-scale analyses have found linguistic-genetic covariation in smaller regions as well, including the Caucasus (23,24), the Levant (25), the Amazon (26), and Africa (27,28). Other studies have directly compared the rates of linguistic and genetic change, as these are expected to be highest near geographic or behavioral barriers to the interaction of people (29).…”

Section: Introductionmentioning

confidence: 99%

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Fine-scale cultural variation reinforces genetic structure in England

Pichkar

Creanza

2022

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Genes and languages both maintain signatures of human history. The evolution of genetics and of culture both have features that can track population movements and demographic history. Further, cultural traits may themselves impact these movements and demography. In particular, while speaking a different language appears to act as a barrier to gene flow, it is not clear whether more subtle dialect-level linguistic differences within a language can influence mating preferences and thus affect genetic population structure. We examine the strength of cultural barriers and of association within England using the spatial similarities between rates of linguistic and genetic change. We find that genes and dialect markers have similar spatial distributions at all geographic scales, though these similarities are more pronounced at larger scales. This covariation, in the absence of geographic barriers to coordinate linguistic and genetic differentiation, suggests that some cultural boundaries have maintained genetic population structure in England.

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Section: Discussionsupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Fine-scale cultural variation reinforces genetic structure in England

Pichkar

Creanza

2022

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“…Differential assortment of ancestral allele frequencies across a genome results from selection, mutation or genetic drift, when previously isolated populations interbreed (1,2). Taking advantage of these differences in allele frequencies can help identify population-specific disease risk alleles associated with disease phenotypes due to various ancestries being exposed to distinct environments and pathogens (3).…”

Section: Introductionmentioning

confidence: 99%

“…GWAS is further complicated when individuals have admixture-induced linkage disequilibrium (admixture LD) blocks. Admixture mapping uses the admixture LD blocks inherited from a specific ancestral population to test for an association with the trait of interest (2). Hence, the ancestry rather than the genotypes are traced in the association process (7) and the SNPs that affect the trait of interest can only be localised to their respective ancestral blocks (presented as an admixture peak on a Manhattan plot).…”

Section: Introductionmentioning

confidence: 99%

GWAS in the southern African context

Swart

Eeden

Uren

et al. 2022

Preprint

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Researchers would generally adjust for the possible confounding effect of population structure by considering global ancestry proportions or top principle components. Alternatively, researchers would conduct admixture mapping to increase the power to detect variants with an ancestry effect. This is sufficient in simple admixture scenarios, however, populations from southern Africa can be complex multi-way admixed populations. Duan et al. (2018) first described local ancestry adjusted allelic (LAAA) analysis as a robust method for discovering association signals, while producing minimal false-positives. Their simulation study, however, was limited to a two-way admixed population. Realizing that their findings might not translate to other admixture scenarios, we simulated a three- and five-way admixed population to compare the LAAA model to other models commonly used in GWAS. We found that, given our admixture scenarios, the LAAA model identifies the most causal variants in most of the phenotypes we tested across both the three-way and five-way admixed populations. The LAAA model also produced a high number of false-positives which was potentially caused by the ancestry effect size that we assumed. Considering the extent to which the various models tested differed in their results and considering that the source of a given association is unknown, we recommend that researchers use multiple GWAS models when analysing populations with complex ancestry.

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“…Admixed populations present unique opportunities to identify ancestry-specific disease risk alleles for various populations simultaneously. African ancestries harbour the most genetic diversity and contain more complex linkage disequilibrium (LD) blocks than other continental populations and the precise evolutionary events that shaped their genomes are mostly unknown [ 4 , 5 ]. When the historical events are unknown, it is often difficult to know beforehand which effect (allele, ancestry or the interaction between them) has the most significant effect on the disease phenotype under study.…”

Section: Introductionmentioning

confidence: 99%

GWAS in the southern African context

et al. 2022

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Researchers would generally adjust for the possible confounding effect of population structure by considering global ancestry proportions or top principle components. Alternatively, researchers would conduct admixture mapping to increase the power to detect variants with an ancestry effect. This is sufficient in simple admixture scenarios, however, populations from southern Africa can be complex multi-way admixed populations. Duan et al. (2018) first described local ancestry adjusted allelic (LAAA) analysis as a robust method for discovering association signals, while producing minimal false positive hits. Their simulation study, however, was limited to a two-way admixed population. Realizing that their findings might not translate to other admixture scenarios, we simulated a three- and five-way admixed population to compare the LAAA model to other models commonly used in genome-wide association studies (GWAS). We found that, given our admixture scenarios, the LAAA model identifies the most causal variants in most of the phenotypes we tested across both the three-way and five-way admixed populations. The LAAA model also produced a high number of false positive hits which was potentially caused by the ancestry effect size that we assumed. Considering the extent to which the various models tested differed in their results and considering that the source of a given association is unknown, we recommend that researchers use multiple GWAS models when analysing populations with complex ancestry.

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Genetic structure correlates with ethnolinguistic diversity in eastern and southern Africa

Cited by 5 publications

References 59 publications

Fine-scale cultural variation reinforces genetic structure in England

Fine-scale cultural variation reinforces genetic structure in England

GWAS in the southern African context

GWAS in the southern African context

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