REFERENCES

1. Taliun D, Harris DN, Kessler MD, et al. ; NHLBI Trans-Omics for Precision Medicine (TOPMed) Consortium. Sequencing of 53,831 diverse genomes from the NHLBI TOPMed program. Nature. 2021;590:290-9.

2. All of Us Research Program Genomics Investigators. Genomic data in the all of us research program. Nature. 2024;627:340-6.

3. He G, Yao H, Duan S, et al. ; 10K_CPGDP Consortium. Pilot work of the 10K Chinese people genomic diversity project along the silk road suggests a complex east-west admixture landscape and biological adaptations. Sci China Life Sci. 2025;68:914-33.

4. He G, Duan S, Chen G, et al. Human population genetic history and evolutionary dynamics on the Eastern Tibetan plateau. Mol Biol Evol. 2025;42:msaf258.

5. He G, Chen J, Duan S, et al. ; 10K_CPGDP Consortium. Largest-scale genomic resource reconstructing the genetic origin, population structure, and biological adaptations of the hui people. Mol Biol Evol. 2025;42:msaf225.

6. Lea AJ, Caldas IV, Garske KM, et al. Adaptations to water stress and pastoralism in the Turkana of northwest Kenya. Science. 2025;389:1246-51.

7. He Y, Zhang X, Peng MS, et al. ; Consortium of Anthropological Research in Southeast Asia and Southwest China (CASEAC). Genome diversity and signatures of natural selection in mainland Southeast Asia. Nature. 2025;643:417-26.

8. Silcocks M, Farlow A, Hermes A, et al. ; National Centre for Indigenous Genomics. Indigenous Australian genomes show deep structure and rich novel variation. Nature. 2023;624:593-601.

9. Reis ALM, Rapadas M, Hammond JM, et al. ; National Centre for Indigenous Genomics. The landscape of genomic structural variation in Indigenous Australians. Nature. 2023;624:602-10.

10. Jeong C, Wang K, Wilkin S, et al. A dynamic 6,000-year genetic history of Eurasia’s Eastern steppe. Cell. 2020;183:890-904.e29.

11. Gnecchi-Ruscone GA, Szécsényi-Nagy A, Koncz I, et al. Ancient genomes reveal origin and rapid trans-Eurasian migration of 7^th century Avar elites. Cell. 2022;185:1402-1413.e21.

12. Lee J, Miller BK, Bayarsaikhan J, et al. Genetic population structure of the Xiongnu Empire at imperial and local scales. Sci Adv. 2023;9:eadf3904.

13. Gnecchi-Ruscone GA, Rácz Z, Samu L, et al. Network of large pedigrees reveals social practices of Avar communities. Nature. 2024;629:376-83.

14. Wang K, Tobias B, Pany-Kucera D, et al. Ancient DNA reveals reproductive barrier despite shared Avar-period culture. Nature. 2025;638:1007-14.

15. Bai H, Guo X, Zhang D, et al. The genome of a Mongolian individual reveals the genetic imprints of Mongolians on modern human populations. Genome Biol Evol. 2014;6:3122-36.

16. Zerjal T, Xue Y, Bertorelle G, et al. The genetic legacy of the Mongols. Am J Hum Genet. 2003;72:717-21.

17. Li Q, Dong K, Xu L, et al. The distribution of three candidate cold-resistant SNPs in six minorities in North China. BMC Genomics. 2018;19:134.

18. Lan Q, Zhao C, Wei C, Xu H, Shen C, Zhu B. Genetic insights and evaluation of forensic features in Mongolian and Ewenki groups using the InDel variations. Front Biosci. 2022;27:67.

19. Wang M, Huang Y, Liu K, et al. ; 10K_CPGDP Consortium. Multiple human population movements and cultural dispersal events shaped the landscape of Chinese paternal heritage. Mol Biol Evol. 2024;41.

20. Chang CC, Chow CC, Tellier LC, Vattikuti S, Purcell SM, Lee JJ. Second-generation PLINK: rising to the challenge of larger and richer datasets. Gigascience. 2015;4:7.

21. Wang CC, Yeh HY, Popov AN, et al. Genomic insights into the formation of human populations in East Asia. Nature. 2021;591:413-9.

22. Ning C, Li T, Wang K, et al. Ancient genomes from northern China suggest links between subsistence changes and human migration. Nat Commun. 2020;11:2700.

23. Bergström A, McCarthy SA, Hui R, et al. Insights into human genetic variation and population history from 929 diverse genomes. Science. 2020;367:eaay5012.

24. Choin J, Mendoza-Revilla J, Arauna LR, et al. Genomic insights into population history and biological adaptation in Oceania. Nature. 2021;592:583-9.

25. Alexander DH, Novembre J, Lange K. Fast model-based estimation of ancestry in unrelated individuals. Genome Res. 2009;19:1655-64.

26. Lawson DJ, Hellenthal G, Myers S, Falush D. Inference of population structure using dense haplotype data. PLoS Genet. 2012;8:e1002453.

27. Patterson N, Moorjani P, Luo Y, et al. Ancient admixture in human history. Genetics. 2012;192:1065-93.

28. Mallick S, Micco A, Mah M, et al. The Allen Ancient DNA Resource (AADR) a curated compendium of ancient human genomes. Sci Data. 2024;11:182.

29. Tao L, Yuan H, Zhu K, et al. Ancient genomes reveal millet farming-related demic diffusion from the Yellow River into southwest China. Curr Biol. 2023;33:4995-5002.e7.

30. Du P, Zhu K, Wang M, et al. Genomic dynamics of the Lower Yellow River Valley since the Early Neolithic. Curr Biol. 2024;34:3996-4006.e11.

31. Li S, Wang R, Ma H, et al. Ancient genomic time transect unravels the population dynamics of Neolithic middle Yellow River farmers. Sci Bull. 2024;69:3365-70.

32. Wang F, Wang R, Ma H, et al. Neolithization of Dawenkou culture in the lower Yellow River involved the demic diffusion from the Central Plain. Sci Bull. 2024;69:3677-81.

33. Xiong J, Wang R, Chen G, et al. Inferring the demographic history of Hexi Corridor over the past two millennia from ancient genomes. Sci Bull. 2024;69:606-11.

34. Zhu K, Hu C, Yang M, et al. The demic diffusion of Han culture into the Yunnan-Guizhou plateau inferred from ancient genomes. Natl Sci Rev. 2024;11:nwae387.

35. Fang H, Liang F, Ma H, et al. Dynamic history of the Central Plain and Haidai region inferred from Late Neolithic to Iron Age ancient human genomes. Cell Rep. 2025;44:115262.

36. UK Biobank Whole-Genome Sequencing Consortium. Whole-genome sequencing of 490,640 UK Biobank participants. Nature. 2025;645:692-701.

37. Verma A, Huffman JE, Rodriguez A, et al. Diversity and scale: genetic architecture of 2068 traits in the VA million veteran program. Science. 2024;385:eadj1182.

38. Yang Q, Sun Y, Duan S, et al. High-quality Population-specific Haplotype-resolved Reference Panel in the Genomic and Pangenomic Eras. Genom Proteom Bioinform. 2025;23:qzaf022.

39. Wang Z, Liu K, Yuan H, et al. YanHuang paternal genomic resource suggested a weakly-differentiated multi-source admixture model for the formation of Han’s founding ancestral lineages. Genom Proteom Bioinform. 2025;23:qzaf049.

40. Wang M, Duan S, Sun Q, et al. Genomic insights into population structure, adaptation, and archaic introgression at the Himalayan-East Asian crossroads. J Genet Genomics. 2026;53:414-32.

41. Ioannidis AG, Blanco-Portillo J, Sandoval K, et al. Paths and timings of the peopling of Polynesia inferred from genomic networks. Nature. 2021;597:522-6.

42. Ioannidis AG, Blanco-Portillo J, Sandoval K, et al. Native American gene flow into Polynesia predating Easter Island settlement. Nature. 2020;583:572-7.

43. Malaspinas AS, Westaway MC, Muller C, et al. A genomic history of Aboriginal Australia. Nature. 2016;538:207-14.

44. Fan S, Spence JP, Feng Y, et al. Whole-genome sequencing reveals a complex African population demographic history and signatures of local adaptation. Cell. 2023;186:923-939.e14.

45. Gurdasani D, Carstensen T, Fatumo S, et al. Uganda genome resource enables insights into population history and genomic discovery in Africa. Cell. 2019;179:984-1002.e36.

46. Lachance J, Vernot B, Elbers CC, et al. Evolutionary history and adaptation from high-coverage whole-genome sequences of diverse African hunter-gatherers. Cell. 2012;150:457-69.

47. Skoglund P, Thompson JC, Prendergast ME, et al. Reconstructing prehistoric African population structure. Cell. 2017;171:59-71.e21.

48. Joshi E, Biddanda A, Popoola J, et al. ; 54gene Team, NCD-GHS Consortium. Whole-genome sequencing across 449 samples spanning 47 ethnolinguistic groups provides insights into genetic diversity in Nigeria. Cell Genom. 2023;3:100378.

49. Choudhury A, Aron S, Botigué LR, et al. ; TrypanoGEN Research Group, H3Africa Consortium. High-depth African genomes inform human migration and health. Nature. 2020;586:741-8.

50. Fortes-Lima CA, Burgarella C, Hammarén R, et al. The genetic legacy of the expansion of Bantu-speaking peoples in Africa. Nature. 2024;625:540-7.

51. Gurdasani D, Carstensen T, Tekola-Ayele F, et al. The African Genome Variation Project shapes medical genetics in Africa. Nature. 2015;517:327-32.

52. Lipson M, Ribot I, Mallick S, et al. Ancient West African foragers in the context of African population history. Nature. 2020;577:665-70.

53. Lipson M, Sawchuk EA, Thompson JC, et al. Ancient DNA and deep population structure in sub-Saharan African foragers. Nature. 2022;603:290-6.

54. Hanotte O, Bradley DG, Ochieng JW, Verjee Y, Hill EW, Rege JE. African pastoralism: genetic imprints of origins and migrations. Science. 2002;296:336-9.

55. Patin E, Lopez M, Grollemund R, et al. Dispersals and genetic adaptation of Bantu-speaking populations in Africa and North America. Science. 2017;356:543-6.

56. Prendergast ME, Lipson M, Sawchuk EA, et al. Ancient DNA reveals a multistep spread of the first herders into sub-Saharan Africa. Science. 2019;365:eaaw6275.

57. Zhang P, Luo H, Li Y, et al. ; Han100K Initiative. NyuWa Genome resource: a deep whole-genome sequencing-based variation profile and reference panel for the Chinese population. Cell Rep. 2021;37:110017.

58. Cao Y, Li L, Xu M, et al. ; ChinaMAP Consortium. The ChinaMAP analytics of deep whole genome sequences in 10,588 individuals. Cell Res. 2020;30:717-31.

59. Yang MY, Zhong JD, Li X, et al. SEAD reference panel with 22,134 haplotypes boosts rare variant imputation and genome-wide association analysis in Asian populations. Nat Commun. 2024;15:10839.

60. Zhou D, Wu M, Tan Q, et al. Non-coding genetic elements of lung cancer identified using whole genome sequencing in 13,722 Chinese. Nat Commun. 2025;16:7365.

61. Jiang T, Guo H, Liu Y, et al. A comprehensive genetic variant reference for the Chinese population. Sci Bull. 2024;69:3820-5.

62. Lipson M, Cheronet O, Mallick S, et al. Ancient genomes document multiple waves of migration in Southeast Asian prehistory. Science. 2018;361:92-5.

63. McColl H, Racimo F, Vinner L, et al. The prehistoric peopling of Southeast Asia. Science. 2018;361:88-92.

64. Sun Y, Wang M, Sun Q, et al. Distinguished biological adaptation architecture aggravated population differentiation of Tibeto-Burman-speaking people. J Genet Genomics. 2024;51:517-30.

65. Huang Y, Wang M, Wang Z, et al. Short tandem repeats in populations of the Qinghai-Tibet Plateau and adjacent regions provide insights into high-altitude adaptation. Sci Adv. 2025;11:eadx1590.

66. Lin X, Liu Y, Zhang J, et al. Genomic resources from the Yunnan-Guizhou Plateau reveal the linguistic‐linked demographic history and insights into human adaptation and disease of multi‐ancestry populations. J Syst Evol. 2025;63:1370-89.

67. He G, Sun Y, Duan S, et al. Ancient genomes give insight into 160,000 years of East Asian population dynamics and biological adaptation. Genome Biol. 2025;26:420.

68. Robbeets M, Bouckaert R, Conte M, et al. Triangulation supports agricultural spread of the Transeurasian languages. Nature. 2021;599:616-21.

69. Ma H, Zhou Y, Wang R, et al. Ancient genomes shed light on the long-term genetic stability in the Central Plain of China. Sci Bull. 2025;70:333-7.

70. Yang T, He J, Li C, et al. Ancient DNA reveals the population interactions and a Neolithic patrilineal community in Northern Yangtze Region. Nat Commun. 2025;16:8728.

71. Yang MA, Fan X, Sun B, et al. Ancient DNA indicates human population shifts and admixture in northern and southern China. Science. 2020;369:282-8.

72. Zhang D, Sun B, Li F, et al. Neolithic genomes reveal long distance interactions in agropastoral border zone of Yan Mountain Region. Sci Bull 2026;71:148-58.

73. Xiong J, Xu Y, Chen G, et al. The genomic history of East Asian Middle Neolithic millet- and rice-agricultural populations. Cell Genom. 2025;5:100976.

74. Zou Y, Tan J, Zhou J, et al. Ancient genomes from the Yellow River Bend reveal long-distance population interactions between the Central Plains, Steppe, and southern China. Cell Rep. 2025;44:116034.

75. Liu J, Liu Y, Zhao Y, et al. East Asian Gene flow bridged by northern coastal populations over past 6000 years. Nat Commun. 2025;16:1322.

76. Damgaard PB, Marchi N, Rasmussen S, et al. 137 ancient human genomes from across the Eurasian steppes. Nature. 2018;557:369-74.

77. Flegontov P, Altınışık NE, Changmai P, et al. Palaeo-Eskimo genetic ancestry and the peopling of Chukotka and North America. Nature. 2019;570:236-40.

78. Sikora M, Pitulko VV, Sousa VC, et al. The population history of northeastern Siberia since the Pleistocene. Nature. 2019;570:182-8.

79. Luo L, Wang M, Liu Y, et al. Sequencing and characterizing human mitochondrial genomes in the biobank-based genomic research paradigm. Sci China Life Sci. 2025;68:1610-25.

80. Moltke I, Grarup N, Jørgensen ME, et al. A common Greenlandic TBC1D4 variant confers muscle insulin resistance and type 2 diabetes. Nature. 2014;512:190-3.

81. Skoglund P, Mallick S, Bortolini MC, et al. Genetic evidence for two founding populations of the Americas. Nature. 2015;525:104-8.

82. Sohail M, Palma-Martínez MJ, Chong AY, et al. Mexican Biobank advances population and medical genomics of diverse ancestries. Nature. 2023;622:775-83.

83. Stæger FF, Andersen MK, Li Z, et al. Genetic architecture in Greenland is shaped by demography, structure and selection. Nature. 2025;639:404-10.

84. Ziyatdinov A, Torres J, Alegre-Díaz J, et al. ; Regeneron Genetics Center, Mexico City Prospective Study. Genotyping, sequencing and analysis of 140,000 adults from Mexico City. Nature. 2023;622:784-93.

85. Gusareva ES, Ghosh AG, Kharkov VN, et al. From North Asia to South America: Tracing the longest human migration through genomic sequencing. Science. 2025;388:eadk5081.

86. Nunes K, Araújo Castro E Silva M, Rodrigues MR, et al. Admixture’s impact on Brazilian population evolution and health. Science. 2025;388:eadl3564.