ZhivotovskyLARosenbergNAFeldmanMW. Features of evolution and expansion of modern humans, inferred from genomewide microsatellite markers. Am J Hum Genet2003; 72(5): 1171–1186.
2.
HershkovitzIWeberGWQuamR, et al. The earliest modern humans outside Africa. Science2018; 359: 456–459.
3.
SayreAP. Africa. Minneapolis, MN: Twenty-First Century Books, 1999.
4.
HarperKNArmelagosGJ. Genomics, the origins of agriculture, and our changing microbe-scape: Time to revisit some old tales and tell some new ones. Am J Phys Anthropol2013; 152(Suppl. 57): 135–152.
5.
RonaldBKuzawaCWMcDadeT, et al. Emerging and re-emerging infectious diseases: The third epidemiologic transition. Annu Rev Anthropol1998; 27: 247–271.
6.
SpyrouMABosKIHerbigA, et al. Ancient pathogen genomics as an emerging tool for infectious disease research. Nat Rev Genet2019; 20(6): 323–340.
7.
KernerGNeehusALPhilippotQ, et al. Genetic adaptation to pathogens and increased risk of inflammatory disorders in post-Neolithic Europe. Cell Genom2023; 3: 100248.
8.
WaltonCKingRRechtmanL, et al. Rising prevalence of multiple sclerosis worldwide: Insights from the Atlas of MS, third edition. Mult Scler2020; 26(14): 1816–1821.
9.
CompstonA. ‘The marvellous harmony of the nervous parts’: The origins of multiple sclerosis. Clin Med2004; 4(4): 346–354.
10.
BarrieWYangYIrving-PeaseEK, et al. Elevated genetic risk for multiple sclerosis emerged in steppe pastoralist populations. Nature2024; 625(7994): 321–328.
11.
AllentoftMESikoraMRefoyo-MartinezA, et al. Population genomics of post-glacial western Eurasia. Nature2024; 625: 301–311.
12.
BjornevikKCorteseMHealyBC, et al. Longitudinal analysis reveals high prevalence of Epstein-Barr virus associated with multiple sclerosis. Science2022; 375: 296–301.
