Abstract
The genetic structure of the indigenous hunter-gatherer peoples of southern Africa, the oldest known lineage of modern human, is important for understanding human diversity. Studies based on mitochondrial1 and small sets of nuclear markers2 have shown that these hunter-gatherers, known as Khoisan, San, or Bushmen, are genetically divergent from other humans1,3. However, until now, fully sequenced human genomes have been limited to recently diverged populations4,5,6,7,8. Here we present the complete genome sequences of an indigenous hunter-gatherer from the Kalahari Desert and a Bantu from southern Africa, as well as protein-coding regions from an additional three hunter-gatherers from disparate regions of the Kalahari. We characterize the extent of whole-genome and exome diversity among the five men, reporting 1.3 million novel DNA differences genome-wide, including 13,146 novel amino acid variants. In terms of nucleotide substitutions, the Bushmen seem to be, on average, more different from each other than, for example, a European and an Asian. Observed genomic differences between the hunter-gatherers and others may help to pinpoint genetic adaptations to an agricultural lifestyle. Adding the described variants to current databases will facilitate inclusion of southern Africans in medical research efforts, particularly when family and medical histories can be correlated with genome-wide data.
Similar content being viewed by others
Main
Four indigenous Namibian hunter-gatherers !Gubi, G/aq'o, D#kgao and !Aî (referred to here as KB1, NB1, TK1 and MD8, respectively), each the eldest member of his community, were chosen for genome sequencing based on their linguistic group, geographical location and Y-chromosome haplogroup representation (Fig. 1 and Supplementary Table 1). The Bantu individual is Archbishop Desmond Tutu (ABT), who represents Sotho-Tswana and Nguni speakers (from the broad Niger–Congo languages), the two largest southern African Bantu groups.
As the genomes of our study participants were expected to diverge more from the human reference genome than do the publicly accessible Yoruban, European and Asian genomes4,5,6,7,8, we aimed to generate a genome sequence that would provide sufficient quality for both mapping against the human reference and de novo assembly. Therefore, the genome of KB1 was sequenced to 10.2-fold coverage using the Roche/454 GS FLX platform with Titanium chemistry, giving an average read length of 350 base pairs (bp). To address aspects of genome structure, additional long-insert libraries for KB1 were sequenced using the Roche/454 Titanium paired-end technology, with insert sizes up to 17 kilobases (kb) and 12.3-fold non-redundant clone coverage. The genome of NB1 was sequenced using the same platform to twofold coverage. The genome of ABT was sequenced to over 30-fold coverage using Applied Biosystems’ short-read technology, SOLiD 3.0. In addition, all five of the study participants’ genomes were sequenced to at least 16-fold coverage in protein-coding regions (exomes) that were enriched by Nimblegen sequence capture (2.1 M array) and subsequently sequenced on the Roche/454 Titanium platform (1.5–1.9 gigabases (Gb) of sequence per individual). Supplementary Table 2 reports the volume of data obtained, whereas Supplementary Table 3 gives exome statistics.
The sequence data were validated by a variety of techniques, including comparison of the whole-genome and exome sequences, whole-genome sequencing by another platform (Illumina, 23.2-fold for KB1 and 7.2-fold for ABT), high-density genotyping (Illumina 1 Million SNPs), comparison of read-depth information with comparative genomic hybridization data, as well as validation of selected variants using TaqMan allelic discrimination and/or Sanger sequencing. We estimate the false-positive rate of our final single nucleotide polymorphism (SNP) calls for KB1 as 0.0009, and the false-negative rate as 0.09 (see Supplementary Information for details).
We created a de novo assembly of the KB1 genome, using the Phusion assembler9. The assembled contigs total 2.79 Gb, with an N50 contig size of 5.5 kb. The total scaffold size, including estimated gaps, is 3.09 Gb, with an N50 scaffold size of 156 kb. The largest scaffold assembled spans 3.2 Mb. Frequently, the Roche GS FLX sequence data resulted in contigs and scaffolds that do not map against the human reference genome. Many of these scaffolds corresponded to gaps in the current human reference assembly, including gaps over 200,000 bp in length (see Supplementary Information).
Single-nucleotide differences from the human reference genome assembly (NCBI Build 36, also known as hg18) were identified for the five southern African genomes and compared with those from eight available personal genomes4,5,6,7,8. In what follows, the term ‘SNP’ means a single-nucleotide difference from the human reference assembly, not including insertions/deletions of a base, and without restrictions on allele frequency in a population. SNPs were called using the software Newbler (for Roche/454), Corona Lite (for SOLiD) and MAQ10 (for Illumina).
Consistent with the view that southern Africans are among the most divergent human populations, we identified more SNPs in KB1, and to a lesser extent in ABT, than have been reported in other individual human genomes (Fig. 2 and Table 1), although a portion of the variation in SNP numbers may stem from differences in technology and levels of coverage. The number of SNPs that are novel (that is, not previously seen in other individuals) is far higher for KB1 and ABT than for other individual whole genomes (Table 1). KB1 and ABT each have approximately 1 million SNPs that are not shared with each other or with the published Yoruban, Asian or European complete genomes4,5,6,7,8 (Fig. 2). In the 117 megabases (Mb) of sequenced exome-containing intervals, the average rate of nucleotide differences between a pair of the Bushmen was 1.2 per kilobase, compared to an average of 1.0 per kilobase differing between a European and Asian individual. The higher SNP rate in Bushmen is reflected by the offset of the red and black lines in Fig. 3b. The autosomal diversity of the study participants is mirrored by the diversity of the mitochondrial genomes. Whereas Europeans on average show approximately 20 differences from the Cambridge reference sequence (CRS)11, our southern African participants show up to 100 mitochondrial SNPs relative to the CRS (Supplementary Tables 4 and 5 and Supplementary Figs 1 and 2). More importantly, despite all mitochondrial sequences belonging to the same haplogroup L0, up to 84 differences are observed between pairs of participants’ mitochondrial genomes (Supplementary Table 4).
To determine whether the novel SNPs represent ancestral alleles or arose since Bushmen separated from other populations, we examined the homologous nucleotide in the chimpanzee genome. SNPs that match the chimpanzee genome indicate that the difference is ancestral, whereas differences from chimpanzee indicate a derived allele. Of the 743,714 novel SNPs in KB1, the human reference genome matches with the chimpanzee genome for 87% of these, whereas the KB1 genome matches chimpanzee for only 6%. For the remaining 7%, the chimpanzee nucleotide could not be determined (6%) or differed from both the Bushman and the reference (1%). These fractions are essentially unchanged if we account for the estimated 3,600 false-positive SNP calls (that is, 0.0009 of 4 million), which can be assumed to appear as novel variants. Thus, very few of the novel differences in KB1’s genome are ancestral nucleotides retained in the Bushmen; instead, the vast majority are changes that accumulated since the Bushmen lineage diverged from other human populations.
The large number of novel SNPs raises concerns regarding the ability of current genotyping arrays to capture effectively the true extent of genetic diversity and haplotype structure represented in southern Africa. Assessing percentage heterozygosity for 1,105,569 autosomal SNPs using current-content Illumina arrays, we were surprised to find lower heterozygosity in KB1 compared to a region-matched European control (Supplementary Data and Supplementary Fig. 3a, b), because it is well known that genetic diversity is highest in Africa. However, analysis of whole-genome sequencing data for KB1 and ABT revealed high percentages of heterozygous SNPs (59% and 60%, respectively), as expected. This discrepancy underscores the inadequacy of current SNP arrays for analysing southern African populations.
The local density of SNPs identified in KB1 varies considerably across the genome (Supplementary Fig. 4), and this variation in density is also seen in other individual genomes (data not shown). Some of the hotspots are common to all individuals examined, whereas others show striking local differences among individuals, such as the statistically significant (P < 10-5; see Supplementary Information) KB1 hotspot shown in Fig. 3a. This region corresponds to the 17q21.3 inversion12, which contains several genes, including those encoding CRHR1 (a corticotropin-releasing hormone receptor) and MAPT (microtubule-associated protein tau). Analysis of diagnostic sequence variants as well as direct typing of a 238-bp indel13 (Supplementary Fig. 5) confirm that KB1 is heterozygous for the 17q21.3 H2 haplotype, a surprising finding because the H2 allele is found at low frequencies in non-European populations12. Read depth and array-CGH indicate that the H2 allele carried by KB1 does not contain the 75-kb duplication present on all analysed European H2 alleles14,15,16 (Supplementary Fig. 6a, b). The KB1 H2 haplotype may represent the ancestral sequence and structure of the H2 haplotype that was present in African populations before its increased frequency in European and Middle Eastern populations12.
We also observed a genome-wide trend for elevated SNP levels in promoter regions (Fig. 3b). Promoter regulatory elements tend to be enriched near nucleosome borders, which are where we observed peak SNP levels, particularly in the composite Bushmen genomes. It is possible that increased SNP frequency in these genomic regions could drive phenotypic changes in humans.
We identified 27,641 distinct amino acid substitutions among our five participants, compared to the human reference sequence, many occurring in more than one individual. Of these, 10,929 appear in one or more of the previously sequenced personal genomes considered here, an additional 3,566 are found in public databases (see Supplementary Information) and the remaining 13,146 are novel and distributed among 7,720 distinct genes. The following discussion of putative phenotypes for the genotypes found in Bushmen is intended to illustrate how the presence of observed SNPs and their previous association with phenotypes can lead to testable hypotheses. These are only candidates for the suggested functions, and experimental tests must be conducted to investigate them further.
Of the 14,495 (that is, 10,929 + 3,566) previously identified amino acid SNPs, 621 were found in databases providing disease associations or other phenotypic information. Some of these are easily related to the Bushmen lifestyle, such as lack of the European-derived lactase persistence allele (a functional promoter variant in the LCT gene) and of the SLC24A5 allele associated with light-coloured skin. In other instances, agreement with the human reference sequence is informative, such as the lack of the African-specific Duffy null (DARC) malaria-resistance allele17. The lack of malaria-resistance alleles in the Bushmen populations might have significant consequences on an already dwindling population of well-adapted foragers, when forced into a farming lifestyle that brings increased pathogen loads17. Therefore, these genetic markers may allow for the tracing of the rate of human adaptation in changing environments18 (see Supplementary Information).
Although a number of SNPs observed in the Bushmen have been related to phenotypes in other ethnic groups in the literature and online databases, one should remain sceptical about the validity of untested associations. In the Supplementary Information, we illustrate this point with dbSNP entry rs1051339 for the LIPA gene, which is annotated in one public database as associated with ‘Wolman’s syndrome’, a devastating failure in lipid metabolism (Supplementary Fig. 7).
We observed SNPs reported to be associated with enhanced physiology (Supplementary Table 6). KB1, MD8, TK1 and ABT are homozygous for an allele of VDR associated with higher bone mineral density; KB1 is homozygous for an allele of UGT1A3 associated with increased metabolism of endo- and xenobiotics; KB1, NB1 and ABT are homozygous for an allele of ACTN3 associated with increased sprint and power performance; KB1 is heterozygous for an allele of CLCNKB encoding a chloride channel that has a greater ability to reabsorb chloride ions from the renal glomerulus—a property that would probably be advantageous in the desert. Other interesting SNPs include one that retains the function of the CYP2G gene (Supplementary Fig. 8a, b), and two at positions in the taste receptor gene TAS2R38 conferring the ability to taste a bitter compound (phenylthiocarbamide), which may reflect a need in hunter-gatherers to avoid toxic plants (see Supplementary Information for detailed discussion).
The 13,146 novel amino acid SNPs reported here will be a rich resource for future work, providing many new candidate functional sites that have not been included in whole-genome association studies so far. Approximately 25% of these SNPs are predicted to have functional implications by a suite of computational methods (see Supplementary Information). The Gene Ontology categories that are prominently represented in the 6,623 genes with one or more novel Bushmen SNP (that is, excluding from the 7,720 genes with novel SNPs those unique to ABT) include many functions that are known to evolve quickly in humans, such as immune response, reproduction and sensory perception (Supplementary Table 7). See the Supplementary Information for detailed descriptions of computational analyses of genes related to lipid metabolism and sensory perception.
As all of our study participants are of old age (∼80 years) and seemingly in good health, the novel coding variants described in this study can be correlated to health status and phenotypes over the entire human lifespan. The Bushmen participants have reached their advanced age despite living under harsh conditions due to periodical famine and untreated illnesses. As some of the Bushmen coding alleles have been associated in the published literature with disease, our results may help to reassess those earlier reports, as well as help to identify potential population-specific pharmacogenetic incompatibilities of certain drugs that are globally prescribed.
Segmental duplications were detected in 17,601 distinct autosomal genes in the KB1 genome and copy numbers estimated following procedures described earlier19 (Supplementary Fig. 6a, b). Copy numbers estimated from read depth are more reliable for longer segments, so we specifically targeted regions larger than 20 kb. In total, we detected 886 intervals (each >20 kb) of autosomal segmental duplication (93.5 Mb), which includes 100 intervals (3.9 Mb) that are not predicted to be duplicated in sample NA18507 (a HapMap sample from Yoruba, Nigeria)19. Using array-CGH, 58 of these intervals (2.6 Mb) had increased copy numbers in KB1 relative to NA18507, the only other published African genome. The set of validated duplications includes a 140-kb interval on chromosome 10 spanning the CYP2E1 gene, which encodes a cytochrome P450 protein that is induced by ethanol and metabolizes many toxicological substrates20 (Supplementary Fig. 6a).
Next, we specifically estimated copy numbers for all autosomal RefSeq genes and designed a custom oligonucleotide array targeting genes where KB1 and NA18507 are predicted to differ by at least one copy. This validated 193 genes as differing in copy number between KB1 and NA18507 (53 where NA18507 has more copies and 140 where KB1 has more copies; Supplementary Table 8). For 26 of these genes, KB1 is estimated to have at least two copies more than in NA18507, Han Chinese YH, and European-descent J. Watson. This gene set includes salivary amylase (AMY1A, KB1 copy number estimate = 15; this may be consistent with a forager lifestyle21), the alpha defensins (DEFA1, KB1 copy number estimate = 12.5) and γ-glutamyltransferase 1 (GGT1, KB1 copy number estimate = 13.2).
Sequencing and extensive genotyping revealed genetic relationships among our participants and other human groups. Placement of complete mitochondrial genomes (Supplementary Table 9), including additional Tuu (KB2) and Juu (NB8) females on the maternal tree of ref. 1 (Supplementary Fig. 1a–c) positioned our participants within the clade L0 basal branch. Surprisingly, ABT was placed in clade L0d, a Bushmen-specific mitochondrial lineage. We identified 75 (of 1,220) Bushmen-informative SNPs on the Y chromosome (Supplementary Fig. 9). In contrast to the other Bushmen, MD8 showed a Bantu Y-chromosome lineage consistent with ABT. Clade A (Supplementary Table 10), B (Supplementary Table 11) and E (Supplementary Table 12) Y-marker analysis allowed for haplogroup validation and ABT’s E1b1a8a classification (http://ycc.biosci.arizona.edu/)22.
We performed principal component analysis (PCA) using the EIGENSTRAT software23 on 174,272 autosome-wide SNPs common across the data sets (generated using 1M or 610K Illumina, or Affymetrix SNP6.0 arrays). Data on 10 Bushmen and 20 Xhosa24 were projected with 20 Yoruba and 20 Europeans from available (HapMap and Coriell) data, and 5 Bushmen (SAN) from the Human Genome Diversity Panel (HGDP) data. Population-wide PCA defines the Bushmen as distinct from the Niger–Congo populations as from Europeans (Fig. 4a). Within-Africa analysis separates Bushmen from the divergent western and southern African populations (Fig. 4b), whereas ABT clearly falls within the Southern Bantu cluster. Variable relatedness of the Xhosa to Yoruba may suggest past admixture and/or historical diversity within this broadly defined population24. Within the Bushmen group, we predict that the Ju/’hoansi and HGDP San are essentially the same population. Divergence of KB1 and MD8 may be explained by recent Bantu admixture (assumed for MD8) or by unique sub-populations with a small percentage of ancient Bantu admixture. Although limited by sample size, a four population test17 suggests weak and/or inconclusive admixture in KB1 and our Ju/’hoansi participants. A different test (see Supplementary Table 14) shows gene-flow between ancestors of KB1 and ABT, confirming the mitochondrial results, but without determining the direction of flow. In contrast to KB1, NB1 and TK1, gene flow between Bushmen and southern African Bantu could be confirmed through ABT’s L0 type mitochondria and the Bantu-specific Y-chromosomal markers in MD8. Whether the migrations underlying these instances followed a general pattern of either patri- or matrilocality25 will have to await a detailed population-structure analysis based on novel-content arrays that include the 1.3 million new genetic markers from this study.
As the Bushmen hunter-gatherers have never adopted agricultural practices throughout their cultural history26, the sequence variants found in their genomes may reflect an ancient adaptation to a foraging lifestyle. In the case of the Kalahari Bushmen, adaptation to life in arid climates must have occurred as well, as several phenotypic traits have been noted that are absent in other human groups, such as the ability to store water and lipid metabolites in body tissues26. These physiological and genetic differences may guide future studies into the much debated question of whether population replacement, rather than cultural exchange, has driven the expansion of agriculture in the southern regions of Africa27, as was observed for late Stone Age populations in Europe28,29.
Methods Summary
Using guidelines approved by the Institutional Review Board of Penn State University, USA, (IRB 28460 and IRB 28890), the University of Limpopo Ethics Committee, South Africa (Limpopo Provincial Government #011/2008), and the Human Research Ethics Committee of the University of New South Wales, Australia (HREC 08089 and HREC 08244), all participants consented either in writing (ABT) or via video-recorded verbal consent (Bushmen). The collection of human DNA in Namibia was conducted under a permit by the Ministry of Health and Social Services (MoHSS) of the Namibian Government. None of the Bushmen participants had any previously known genetic conditions. ABT is a survivor of poliomyelitis, tuberculosis and prostate cancer.
Several whole-genome shotgun DNA libraries for KB1 and NB1 were prepared and sequenced using methods previously described for the Roche/454 platform. Exome sequences for the five participants and whole-genome sequence for ABT were obtained as described in the paper. Mapping of the 454 sequencing reads to the human reference sequence (NCBI Build 36) was performed using a locally produced aligner called lastz (http://www.bx.psu.edu/miller_lab) and in-house scripts.
Access to our data
It is challenging to provide convenient access to the large and complex data sets resulting from the sequencing and analysis of a human genome. In addition to submitting data to standard repositories, we provide all data sets in an immediately useful form through the Galaxy bioinformatics platform (http://usegalaxy.org), a web application designed to integrate data with analysis tools. In addition to downloading, data sets can be transformed in a variety of ways and compared with existing annotations (see ‘Data and analysis user’s guide’ at http://galaxycast.org). The positions of the SNPs for each Bushman and ABT can be viewed in a customized installation of the UCSC Genome Browser (http://main.genome-browser.bx.psu.edu/), along with supporting evidence (number of reads for each allele and hyperlinks to the actual reads) and computationally predicted phenotypic consequences for SNPs in coding regions.
Accession codes
Primary accessions
Gene Expression Omnibus
Data deposits
All sequence data have been deposited in the NCBI short read archive, with accession number SRA010356. The sequences and associated data are freely available from http://galaxy.psu.edu/bushman. SNP and indel information has been placed into the dbSNP database under handle BUSHMAN. The GEO id for the array data is GSE19048.
References
Gonder, M. K. et al. Whole-mtDNA genome sequence analysis of ancient African lineages. Mol. Biol. Evol. 24, 757–768 (2007)
Myers, S. et al. A fine-scale map of recombination rates and hotspots across the human genome. Science 310, 321–324 (2005)
Tishkoff, S. A. et al. The genetic structure and history of Africans and African Americans. Science 324, 1035–1044 (2009)
Ahn, S. M. et al. The first Korean genome sequence and analysis: full genome sequencing for a socio-ethnic group. Genome Res. 19, 1622–1629 (2009)
Bentley, D. R. et al. Accurate whole human genome sequencing using reversible terminator chemistry. Nature 456, 53–59 (2008)
Levy, S. et al. The diploid genome sequence of an individual human. PLoS Biol. 5, e254 (2007)
Wang, J. et al. The diploid genome sequence of an Asian individual. Nature 456, 60–65 (2008)
Wheeler, D. A. et al. The complete genome of an individual by massively parallel DNA sequencing. Nature 452, 872–876 (2008)
Mullikin, J. C. & Ning, Z. The phusion assembler. Genome Res. 13, 81–90 (2003)
Li, H., Ruan, J. & Durbin, R. Mapping short DNA sequencing reads and calling variants using mapping quality scores. Genome Res. 18, 1851–1858 (2008)
Andrews, R. M. et al. Reanalysis and revision of the Cambridge reference sequence for human mitochondrial DNA. Nature Genet. 23, 147 (1999)
Stefansson, H. et al. A common inversion under selection in Europeans. Nature Genet. 37, 129–137 (2005)
Baker, M. et al. Association of an extended haplotype in the tau gene with progressive supranuclear palsy. Hum. Mol. Genet. 8, 711–715 (1999)
Antonacci, F. et al. Characterization of six human disease-associated inversion polymorphisms. Hum. Mol. Genet. 18, 2555–2566 (2009)
McCarroll, S. A. et al. Integrated detection and population-genetic analysis of SNPs and copy number variation. Nature Genet. 40, 1166–1174 (2008)
Zody, M. C. et al. Evolutionary toggling of the MAPT 17q21.31 inversion region. Nature Genet. 40, 1076–1083 (2008)
Reich, D. et al. Reduced neutrophil count in people of African descent is due to a regulatory variant in the Duffy antigen receptor for chemokines gene. PLoS Genet. 5, e1000360 (2009)
Coop, G. et al. The role of geography in human adaptation. PLoS Genet. 5, e1000500 (2009)
Alkan, C. et al. Personalized copy number and segmental duplication maps using next-generation sequencing. Nature Genet. 41, 1061–1067 (2009)
Kessova, I. & Cederbaum, A. I. CYP2E1: biochemistry, toxicology, regulation and function in ethanol-induced liver injury. Curr. Mol. Med. 3, 509–518 (2003)
Perry, G. H. et al. Diet and the evolution of human amylase gene copy number variation. Nature Genet. 39, 1256–1260 (2007)
Karafet, T. M. et al. New binary polymorphisms reshape and increase resolution of the human Y chromosomal haplogroup tree. Genome Res. 18, 830–838 (2008)
Patterson, N., Price, A. L. & Reich, D. Population structure and eigenanalysis. PLoS Genet. 2, e190 (2006)
Patterson, N. et al. Genetic structure of a unique admixed population: implications for medical research. Hum. Mol. Genet. 19, 411–419 (2009)
Oota, H. et al. Human mtDNA and Y-chromosome variation is correlated with matrilocal versus patrilocal residence. Nature Genet. 29, 20–21 (2001)
Le Roux, W. & White, A. Voices of the San: Living in Southern Africa Today (Kwela, 2004)
Berniell-Lee, G. et al. Genetic and demographic implications of the Bantu expansion: insights from human paternal lineages. Mol. Biol. Evol. 26, 1581–1589 (2009)
Malmstrom, H. et al. Ancient DNA reveals lack of continuity between neolithic hunter-gatherers and contemporary Scandinavians. Curr. Biol. 19, 1758–1762 (2009)
Bramanti, B. et al. Genetic discontinuity between local hunter-gatherers and central Europe’s first farmers. Science 326, 137–140 (2009)
Heine, B. & Nurse, D. in African Languages: An Introduction (Cambridge Univ. Press, 2000)
Acknowledgements
We particularly want to thank Archbishop Desmond Tutu, !Gubi, G/aq’o, D#kgao and !Aî, as well as their respective families and communities for their willingness to participate in this study. This work is supported by the Pennsylvania State University. The genome sequencing of the four Namibian individuals was supported by Roche Applied Sciences and the exome sequencing capture by Nimblegen (to S.C.S.). Sequencing of Archbishop Tutu’s genome was supported by AppliedBiosystems (whole genome) (to R.A.G.) and Roche Applied Sciences (exome) (to S.C.S.). Whole-genome genotyping and NRY haplotyping was supported by the Cancer Institute of New South Wales (to V.M.H.). Travel was supported by Penn State University (to S.C.S.) and Hyperion Asset Management Australia (to V.M.H.). We thank K. Walters for assistance in researching geographic facts and help with Fig. 1, B. Schultz for his help with Supplementary Table 5 and R.-A. Hardie for her help with Supplementary Fig. 8b. T. Loughran assisted with medical sample collection. We thank the 1000 Genome Project for early access and use of their data. This work was also supported by the Intramural Research Program of the National Human Genome Research Institute, National Institutes of Health (J.C.M.). A.R. was supported by an NSF grant DEB-0733029 and K.D.M. was supported by a grant R01GM087472 from NIH. S.C.S. is supported by the Gordon and Betty Moore Foundation. V.M.H. is a Cancer Institute of New South Wales Fellow.
Author Contributions S.C.S. and V.M.H. managed the project. S.C.S. and V.M.H. collected and processed the blood samples during field trips in 2008 and 2009. S.C.S., V.M.H. and W.M. designed research. Sequencing data was generated by L.P.T., L.R.K., D.C.P., D.I.D., J.G., P.B., D.M.M., J.G.R., L.V.N., V.M.H. and S.C.S. Genotyping was performed by D.C.P., E.A.T., W.S.T. and V.M.H. Data were analysed by S.C.S., W.M., A.R., B.G., R.S.H., C.R., D.C.P., F.Z., Y.S., C.A., J.M.K., D.I.D., J.Q., R.B., Q.W., Q.M., Z.Z., N.E.W., A.M.B., P.M., C.G.D., R.S.H., K.D.M., A.N., E.R.M., N.P., T.H.P., Y.Z., F.C., J.C.M., R.C.H., B.F.P., E.E.E., R.A.G., T.T.H. and V.M.H.; A.O., A.W.S., H.O. and P.V. assisted with field work. S.C.S., W.M. and V.M.H. wrote the manuscript with input from the co-authors.
Author information
Authors and Affiliations
Corresponding authors
Supplementary information
Supplementary Information
This file contains a Supplementary Discussion, Supplementary Tables 1-15, Supplementary Figures 1-9 with Legends, Supplementary Methods and Supplementary References. (PDF 3250 kb)
Rights and permissions
This article is distributed under the terms of the Creative Commons Attribution-Non-Commercial-Share Alike licence (http://creativecommons.org/licenses/by-nc-sa/3.0/), which permits distribution, and reproduction in any medium, provided the original author and source are credited. This licence does not permit commercial exploitation, and derivative works must be licensed under the same or similar licence.
About this article
Cite this article
Schuster, S., Miller, W., Ratan, A. et al. Complete Khoisan and Bantu genomes from southern Africa. Nature 463, 943–947 (2010). https://doi.org/10.1038/nature08795
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1038/nature08795