Prospective avenues for human population genomics and disease mapping in southern Africa. Swart, Y., van Eeden, G., Sparks, A., Uren, C., & Möller, M. Molecular genetics and genomics: MGG, May, 2020.
doi  abstract   bibtex   
Population substructure within human populations is globally evident and a well-known confounding factor in many genetic studies. In contrast, admixture mapping exploits population stratification to detect genotype-phenotype correlations in admixed populations. Southern Africa has untapped potential for disease mapping of ancestry-specific disease risk alleles due to the distinct genetic diversity in its populations compared to other populations worldwide. This diversity contributes to a number of phenotypes, including ancestry-specific disease risk and response to pathogens. Although the 1000 Genomes Project significantly improved our understanding of genetic variation globally, southern African populations are still severely underrepresented in biomedical and human genetic studies due to insufficient large-scale publicly available data. In addition to a lack of genetic data in public repositories, existing software, algorithms and resources used for imputation and phasing of genotypic data (amongst others) are largely ineffective for populations with a complex genetic architecture such as that seen in southern Africa. This review article, therefore, aims to summarise the current limitations of conducting genetic studies on populations with a complex genetic architecture to identify potential areas for further research and development.
@article{swart_prospective_2020,
	title = {Prospective avenues for human population genomics and disease mapping in southern {Africa}},
	issn = {1617-4623},
	doi = {10.1007/s00438-020-01684-8},
	abstract = {Population substructure within human populations is globally evident and a well-known confounding factor in many genetic studies. In contrast, admixture mapping exploits population stratification to detect genotype-phenotype correlations in admixed populations. Southern Africa has untapped potential for disease mapping of ancestry-specific disease risk alleles due to the distinct genetic diversity in its populations compared to other populations worldwide. This diversity contributes to a number of phenotypes, including ancestry-specific disease risk and response to pathogens. Although the 1000 Genomes Project significantly improved our understanding of genetic variation globally, southern African populations are still severely underrepresented in biomedical and human genetic studies due to insufficient large-scale publicly available data. In addition to a lack of genetic data in public repositories, existing software, algorithms and resources used for imputation and phasing of genotypic data (amongst others) are largely ineffective for populations with a complex genetic architecture such as that seen in southern Africa. This review article, therefore, aims to summarise the current limitations of conducting genetic studies on populations with a complex genetic architecture to identify potential areas for further research and development.},
	language = {eng},
	journal = {Molecular genetics and genomics: MGG},
	author = {Swart, Yolandi and van Eeden, Gerald and Sparks, Anel and Uren, Caitlin and Möller, Marlo},
	month = may,
	year = {2020},
	pmid = {32440765},
	pmcid = {PMC7240165},
	keywords = {Admixture mapping, Disease risk alleles, Population genetics, Southern Africa},
}
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