Western hunter-gatherer explained

Western hunter-gatherer

In archaeogenetics, western hunter-gatherer (WHG, also known as west European hunter-gatherer, western European hunter-gatherer or Oberkassel cluster) is a distinct ancestral component of modern Europeans, representing descent from a population of Mesolithic hunter-gatherers who scattered over western, southern and central Europe, from the British Isles in the west to the Carpathians in the east, following the retreat of the ice sheet of the Last Glacial Maximum. It is closely associated and sometimes considered synonymous with the concept of the Villabruna cluster, named after Ripari Villabruna cave in Italy, known from the terminal Pleistocene of Europe, which is largely ancestral to later WHG populations.

WHGs share a closer genetic relationship to ancient and modern peoples in the Middle East and the Caucasus than earlier European hunter-gatherers. WHGs are thought to have migrated into Europe around the end of the Last Glacial Maximum, expanding across Western Europe at the end of the Pleistocene, largely replacing earlier Cro-Magnon groups like the Magdalenians.

Along with the Scandinavian hunter-gatherers (SHG) and eastern hunter-gatherers (EHG), the WHGs constituted one of the three main genetic groups in the postglacial period of early Holocene Europe. The border between WHGs and EHGs ran roughly from the lower Danube, northward along the western forests of the Dnieper towards the western Baltic Sea. EHGs primarily consisted of a mixture of WHG-related and Ancient North Eurasian (ANE) ancestry, while SHGs were a mixture between WHG and EHG. In the Iberian Peninsula, early Holocene hunter-gathers consisted of a mixture of WHG and Magdalenian Cro-Magnon (GoyetQ2) ancestry.[1]

Once the main population throughout Europe, the WHGs were largely replaced by successive expansions of Early European Farmers (EEFs) of Anatolian origin during the early Neolithic, who generally carried a minor amount of WHG ancestry due to admixture with WHG groups during their European expansion. Among modern-day populations, WHG ancestry is most common among populations of the eastern Baltic region.[2]

Research

Western hunter-gatherers (WHG) are recognised as a distinct ancestral component contributing to the ancestry of most modern Europeans. Most Europeans can be modeled as a mixture of WHG, EEF, and WSH from the Pontic–Caspian steppe. WHGs also contributed ancestry to other ancient groups such as Early European Farmers (EEF), who were, however, mostly of Anatolian descent. With the Neolithic expansion, EEF came to dominate the gene pool in most parts of Europe, although WHG ancestry had a resurgence in Western Europe from the Early Neolithic to the Middle Neolithic.

Origin and expansion into continental Europe

WHGs represent a major population shift within Europe at the end of the Ice Age, probably a population expansion into continental Europe, from Southeastern European or West Asian refugia.[3] It is thought that their ancestors separated from eastern Eurasians around 40,000 BP, and from Ancient North Eurasians (ANE) prior to 24,000 BP (the estimated age date of the Mal'ta boy). This date was subsequently put further back in time by the findings of the Yana Rhinoceros Horn Site to around 38kya, shortly after the divergence of West-Eurasian and East-Eurasian lineages.[4] Vallini et al. 2022 argues that the dispersal and split patterns of West Eurasian lineages was not earlier than c. 38,000 years ago, with older Initial Upper Paleolithic European specimens, such as Zlaty Kun, Peștera cu Oase and Bacho Kiro, being unrelated to Western hunter-gatherers but closer to Ancient East Eurasians or basal to both.[5]

Genetic evidence suggests that the ancestors of the WHG population genetically diverged from hunter-gatherers in the Middle East and the Caucasus around 26,000 years ago, during the Last Glacial Maximum.[6] WHG genomes display higher affinity for ancient and modern Middle Eastern populations when compared against earlier Paleolithic Europeans such as Gravettians. The affinity for ancient Middle Eastern populations in Europe increased after the Last Glacial Maximum, correlating with the expansion of WHG (Villabruna or Oberkassel) ancestry. There is also evidence for bi-directional geneflow between WHG and Middle Eastern populations as early as 15,000 years ago. WHG associated remains belonged primarily to the human Y-chromosome haplogroups I-M170 with a lower frequency of C-F3393 (specifically the clade C-V20/C1a2), which has been found commonly among earlier Paleolithic European remains such as Kostenki-14 and Sungir. The paternal haplogroup C-V20 can still be found in men living in modern Spain, attesting to this lineage's longstanding presence in Western Europe. Their mitochondrial chromosomes belonged primarily to haplogroup U5.[7] The earliest known individuals of predominantly WHG/Villabruna ancestry in Europe are known from Italy, dating to around 17,000 years ago,[8] though an individual from El Mirón cave in northern Spain with 43% Villabruna ancestry is known from 19,000 years ago. Early WHG/Villabruna populations are associated with the Epigravettian archaeological culture, which largely replaced populations associated with the Magdalenian culture about 14,000 years ago (the ancestors of the Magdalenian-associated individuals were the populations associated with the western Gravettian, Solutrean and Aurignacian cultures).[9] [10] WHG ancestry is first found north of the Alps in two 14,000 year-old individuals at Oberkassel, Germany who can be modeled as an admixture of Villabruna ancestry (itself modeled as an admixture between a lineage related to the Věstonice cluster and a lineage ancestral to the Kostenki-14 and Goyet Q116-1 individuals), and Goyet-Q2 ancestry related to individuals found in Europe prior to the Last Glacial Maximum. The study states that all of the individuals of the Oberkassel cluster could be modeled as c. 75% Villabruna and 25% Goyet-Q2 ancestry or, alternatively, as c. 90% Villabruna and 10% Fournol ancestry, a newly identified cluster described as a sister lineage of the Goyet Q116-1 ancestry found in individuals associated with the Gravettian culture of southwestern Europe.[9] The study suggests that Oberkassel ancestry was mostly already formed before expanding, possibly around the west side of the Alps, to Western and Central Europe and Britain, where sampled WHG individuals are genetically homogeneous. This is in contrast to the arrival of Villabruna and Oberkassel ancestry to Iberia, which seems to have involved repeated admixture events with local populations carrying high levels of Goyet-Q2 ancestry. This, and the survival of specific Y-DNA haplogroup C1 clades previously observed among early European hunter-gatherers, suggests relatively higher genetic continuity in southwest Europe during this period.[9]

There are indications that the WHG carried "risk alleles for diabetes and Alzheimer's disease".[11]

Interaction with other populations

The WHG were also found to have contributed ancestry to populations on the borders of Europe such as early Anatolian farmers and Ancient Northwestern Africans,[12] as well as other European groups such as eastern hunter-gatherers.[13] The relationship of WHGs to the EHGs remains inconclusive.[13] EHGs are modeled to derive varying degrees of ancestry from a WHG-related lineage, ranging from merely 25% to up to 91%, with the remainder being linked to geneflow from Paleolithic Siberians (ANE) and perhaps Caucasus hunter-gatherers. Another lineage known as the Scandinavian hunter-gatherers (SHGs) were found to be a mix of EHGs and WHGs.[14] [15]

People of the Mesolithic Kunda culture and the Narva culture of the eastern Baltic were a mix of WHG and EHG, showing the closest affinity with WHG. Samples from the Ukrainian Mesolithic and Neolithic were found to cluster tightly together between WHG and EHG, suggesting genetic continuity in the Dnieper Rapids for a period of 4,000 years. The Ukrainian samples belonged exclusively to the maternal haplogroup U, which is found in around 80% of all European hunter-gatherer samples.

People of the Pit–Comb Ware culture (CCC) of the eastern Baltic were closely related to EHG. Unlike most WHGs, the WHGs of the eastern Baltic did not receive European farmer admixture during the Neolithic. Modern populations of the eastern Baltic thus harbor a larger amount of WHG ancestry than any other population in Europe.

SHGs have been found to contain a mix of WHG components who had likely migrated into Scandinavia from the south, and EHGs who had later migrated into Scandinavia from the northeast along the Norwegian coast. This hypothesis is supported by evidence that SHGs from western and northern Scandinavia had less WHG ancestry (ca 51%) than individuals from eastern Scandinavia (ca. 62%). The WHGs who entered Scandinavia are believed to have belonged to the Ahrensburg culture. EHGs and WHGs displayed lower allele frequencies of SLC45A2 and SLC24A5, which cause depigmentation, and OCA/Herc2, which causes light eye color, than SHGs.

The DNA of eleven WHGs from the Upper Palaeolithic and Mesolithic in Western Europe, Central Europe and the Balkans was analyzed, with regards to their Y-DNA haplogroups and mtDNA haplogroups. The analysis suggested that WHGs were once widely distributed from the Atlantic coast in the West, to Sicily in the South, to the Balkans in the Southeast, for more than six thousand years. The study also included an analysis of a large number of individuals of prehistoric Eastern Europe. Thirty-seven samples were collected from Mesolithic and Neolithic Ukraine (9500-6000 BC). These were determined to be an intermediate between EHG and SHG, although WHG ancestry in this population increased during the Neolithic. Samples of Y-DNA extracted from these individuals belonged exclusively to R haplotypes (particularly subclades of R1b1) and I haplotypes (particularly subclades of I2). mtDNA belonged almost exclusively to U (particularly subclades of U5 and U4). A large number of individuals from the Zvejnieki burial ground, which mostly belonged to the Kunda culture and Narva culture in the eastern Baltic, were analyzed. These individuals were mostly of WHG descent in the earlier phases, but over time EHG ancestry became predominant. The Y-DNA of this site belonged almost exclusively to haplotypes of haplogroup R1b1a1a and I2a1. The mtDNA belonged exclusively to haplogroup U (particularly subclades of U2, U4 and U5). Forty individuals from three sites of the Iron Gates Mesolithic in the Balkans were also analyzed. These individuals were estimated to be of 85% WHG and 15% EHG descent. The males at these sites carried exclusively haplogroup R1b1a and I (mostly subclades of I2a) haplotypes. mtDNA belonged mostly to U (particularly subclades of U5 and U4). People of the Balkan Neolithic were found to harbor 98% Anatolian ancestry and 2% WHG ancestry. By the Chalcolithic, people of the Cucuteni–Trypillia culture were found to harbor about 20% hunter-gatherer ancestry, which was intermediate between EHG and WHG. People of the Globular Amphora culture were found to harbor ca. 25% WHG ancestry, which is significantly higher than Middle Neolithic groups of Central Europe.

Replacement by Neolithic farmers

See also: Neolithic Europe and Genetic history of Europe. A seminal 2014 study first identified the contribution of three main components to modern European lineages: the Western Hunter Gatherers (WHG, in proportions of up to 50% in Northern Europeans), the Ancient North Eurasians (ANE, Upper Palaeolithic Siberians later associated with the later Indo-European expansion, present in proportions up to 20%), and finally the Early European Farmers (EEF, agriculturists of mainly Near Eastern origin who migrated to Europe from circa 8,000 BP, now present in proportions from around 30% in the Baltic region to around 90% in the Mediterranean). The Early European Farmer (EEF) component was identified based on the genome of a woman buried c. 7,000 years ago in a Linear Pottery culture grave in Stuttgart, Germany.[16]

This 2014 study found evidence for genetic mixing between WHG and EEF throughout Europe, with the largest contribution of EEF in Mediterranean Europe (especially in Sardinia, Sicily, Malta and among Ashkenazi Jews), and the largest contribution of WHG in Northern Europe and among Basque people.[17]

Since 2014, further studies have refined the picture of interbreeding between EEF and WHG. In a 2017 analysis of 180 ancient DNA datasets of the Chalcolithic and Neolithic periods from Hungary, Germany and Spain, evidence was found of a prolonged period of interbreeding. Admixture took place regionally, from local hunter-gatherer populations, so that populations from the three regions (Germany, Iberia and Hungary) were genetically distinguishable at all stages of the Neolithic period, with a gradually increasing ratio of WHG ancestry of farming populations over time. This suggests that after the initial expansion of early farmers, there were no further long-range migrations substantial enough to homogenize the farming population, and that farming and hunter-gatherer populations existed side by side for many centuries, with ongoing gradual admixture throughout the 5th to 4th millennia BC (rather than a single admixture event on initial contact).[18] Admixture rates varied geographically; in the late Neolithic, WHG ancestry in farmers in Hungary was at around 10%, in Germany around 25% and in Iberia as high as 50%.[19]

Analysis of remains from the Grotta Continenza in Italy showed that out of six remains, three buried between belonged to I2a-P214; and two-times the maternal haplogroups U5b1 and one U5b3. Around 6000 BC, the WHGs of Italy were almost completely genetically replaced by EEFs (two G2a2) and one Haplogroup R1b, although WHG ancestry slightly increased in subsequent millennia.

Neolithic individuals in the British Isles were close to Iberian and Central European Early and Middle Neolithic populations, modeled as having about 75% ancestry from EEF with the rest coming from WHG in continental Europe. They subsequently replaced most of the WHG population in the British Isles without mixing much with them.[20]

The WHG are estimated to have contributed between 20-30% ancestry to Neolithic EEF groups throughout Europe. Specific adaptions against local pathogens may have been introduced via the Mesolithic WHG admixture into Neolithic EEF populations.[21]

A study on Mesolithic hunter-gatherers from Denmark found that they were related to contemporary Western hunter-gatherers, and are associated with the Maglemose, Kongemose and Ertebølle cultures. They displayed "genetic homogeneity from around 10,500 to 5,900 calibrated years before present", until "Neolithic farmers with Anatolian-derived ancestry arrived". The transition to the Neolithic period was "very abrupt and resulted in a population turnover with limited genetic contribution from local hunter-gatherers. The succeeding Neolithic population has been associated with the Funnelbeaker culture.[22]

Physical appearance

According to David Reich, DNA analysis has shown that Western Hunter Gatherers were typically dark skinned, dark haired, and blue eyed.[23] The dark skin was due to their Out-of-Africa origin (all Homo sapiens populations having had initially dark skin), while the blue eyes were the result of a variation in their OCA2 gene, which caused iris depigmentation.

Archaeologist Graeme Warren has said that their skin color ranged from olive to black, and speculated that they may have had some regional variety of eye and hair colors.[24] This is strikingly different from the distantly related eastern hunter-gatherers (EHG)—who have been suggested to be light-skinned, brown-eyed or blue eyed and dark-haired or light-haired.

Two WHG skeletons with incomplete SNPs, La Braña and Cheddar Man, are predicted to have had dark or dark to black skin, whereas two other WHG skeletons with complete SNPs, "Sven" and Loschbour man, are predicted to have had dark or intermediate-to-dark and intermediate skin, respectively.[25] Spanish biologist Carles Lalueza-Fox said the La Braña-1 individual had dark skin, "although we cannot know the exact shade."[26]

According to a 2020 study, the arrival of Early European Farmers (EEFs) from western Anatolia from 8500 to 5000 years ago, along with Western Steppe Herders during the Bronze Age, caused a rapid evolution of European populations towards lighter skin and hair. Admixture between hunter-gatherer and agriculturist populations was apparently occasional, but not extensive.[27]

Some authors have expressed caution regarding skin pigmentation reconstructions: Quillen et al. (2019) acknowledge studies that generally show that "lighter skin color was uncommon across much of Europe during the Mesolithic", including studies regarding the “dark or dark to black” predictions for the Cheddar Man, but warn that "reconstructions of Mesolithic and Neolithic pigmentation phenotype using loci common in modern populations should be interpreted with some caution, as it is possible that other as yet unexamined loci may have also influenced phenotype."[28]

Geneticist Susan Walsh at Indiana University–Purdue University Indianapolis, who worked on Cheddar Man project, said that "we simply don't know his skin colour".[29] German biochemist Johannes Krause stated that we do not know whether the skin color of Western European hunter-gatherers was more similar to the skin color of people from present-day Central Africa or people from the Arab region. It is only certain that they did not carry any known mutation responsible for the light skin in subsequent populations of Europeans.[30]

A 2024 research into the genomic ancestry and social dynamics of the last hunter-gatherers of Atlantic France has stated that "phenotypically, we find some diversity during the Late Mesolithic in France", at which two of the WHG's sequenced in the study "likely had pale to intermediate skin pigmentation", but "most individuals carry the dark skin and blue eyes characteristic of WHGs" of the studied samples.[31]

Bibliography

Further reading

Notes and References

  1. Villalba-Mouco . Vanessa . van de Loosdrecht . Marieke S. . Posth . Cosimo . Mora . Rafael . Martínez-Moreno . Jorge . Rojo-Guerra . Manuel . Salazar-García . Domingo C. . Royo-Guillén . José I. . Kunst . Michael . Rougier . Hélène . Crevecoeur . Isabelle . Arcusa-Magallón . Héctor . Tejedor-Rodríguez . Cristina . García-Martínez de Lagrán . Iñigo . Garrido-Pena . Rafael . April 2019 . Survival of Late Pleistocene Hunter-Gatherer Ancestry in the Iberian Peninsula . Current Biology . en . 29 . 7 . 1169–1177.e7 . 10.1016/j.cub.2019.02.006. 10261/208851 . free .
  2. Davy . Tom . Ju . Dan . Mathieson . Iain . Skoglund . Pontus . April 2023 . Hunter-gatherer admixture facilitated natural selection in Neolithic European farmers . Current Biology . 33 . 7 . 1365–1371.e3 . 10.1016/j.cub.2023.02.049 . 0960-9822 . 10153476 . 36963383. 2023CBio...33E1365D .
  3. Fu . Qiaomei . The genetic history of Ice Age Europe . Nature . 2016 . 534 . 7606 . 200–205 . 10.1038/nature17993 . 27135931 . 4943878 . 2016Natur.534..200F . "Beginning with the Villabruna Cluster at least ~14,000 years ago, all European individuals analyzed show an affinity to the Near East. This correlates in time to the Bølling-Allerød interstadial, the first significant warming period after the Ice Age. Archaeologically, it correlates with cultural transitions within the Epigravettian in Southern Europe and the Magdalenian-to-Azilian transition in Western Europe. Thus, the appearance of the Villabruna Cluster may reflect migrations or population shifts within Europe at the end of the Ice Age, an observation that is also consistent with the evidence of turnover of mitochondrial DNA sequences at this time. One scenario that could explain these patterns is a population expansion from southeastern European or west Asian refugia after the Ice Age, drawing together the genetic ancestry of Europe and the Near East. Sixth, within the Villabruna Cluster, some, but not all, individuals have affinity to East Asians. An important direction for future work is to generate similar ancient DNA data from southeastern Europe and the Near East to arrive at a more complete picture of the Upper Paleolithic population history of western Eurasia".
  4. Sikora . Martin . Pitulko . Vladimir V. . Sousa . Vitor C. . Allentoft . Morten E. . Vinner . Lasse . Rasmussen . Simon . Margaryan . Ashot . de Barros Damgaard . Peter . de la Fuente . Constanza . Renaud . Gabriel . Yang . Melinda A. . Fu . Qiaomei . Dupanloup . Isabelle . Giampoudakis . Konstantinos . Nogués-Bravo . David . June 2019 . The population history of northeastern Siberia since the Pleistocene . Nature . en . 570 . 7760 . 182–188 . 10.1038/s41586-019-1279-z . 31168093 . 2019Natur.570..182S . 174809069 . 1476-4687. 1887/3198847 . free .
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  10. News: Scientists Sequence Genomes of Prehistoric Hunter-Gatherers from Different Eurasian Cultures . Sci.News . 2 March 2023.
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  12. Simões . Luciana G. . Günther . Torsten . Martínez-Sánchez . Rafael M. . Vera-Rodríguez . Juan Carlos . Iriarte . Eneko . Rodríguez-Varela . Ricardo . Bokbot . Youssef . Valdiosera . Cristina . Jakobsson . Mattias . 7 June 2023 . Northwest African Neolithic initiated by migrants from Iberia and Levant . Nature . 618 . 7965 . en . 550–556 . 10.1038/s41586-023-06166-6 . 37286608 . 10266975 . 2023Natur.618..550S . 1476-4687.
  13. Lazaridis . Iosif . 1 December 2018 . The evolutionary history of human populations in Europe . Current Opinion in Genetics & Development . Genetics of Human Origins . en . 53 . 21–27 . 10.1016/j.gde.2018.06.007 . 29960127 . 1805.01579 . 19158377 . 0959-437X.
  14. Haak . Wolfgang . Lazaridis . Iosif . Patterson . Nick . Rohland . Nadin . Mallick . Swapan . Llamas . Bastien . Brandt . Guido . Nordenfelt . Susanne . Harney . Eadaoin . Stewardson . Kristin . Fu . Qiaomei . Mittnik . Alissa . Bánffy . Eszter . Economou . Christos . Francken . Michael . June 2015 . Massive migration from the steppe was a source for Indo-European languages in Europe . Nature . en . 522 . 7555 . 207–211 . 10.1038/nature14317 . 25731166 . 5048219 . 1502.02783 . 2015Natur.522..207H . 1476-4687.
  15. Sikora . Martin . Pitulko . Vladimir V. . Sousa . Vitor C. . Allentoft . Morten E. . Vinner . Lasse . Rasmussen . Simon . Margaryan . Ashot . de Barros Damgaard . Peter . de la Fuente . Constanza . Renaud . Gabriel . Yang . Melinda A. . Fu . Qiaomei . Dupanloup . Isabelle . Giampoudakis . Konstantinos . Nogués-Bravo . David . June 2019 . The population history of northeastern Siberia since the Pleistocene . Nature . en . 570 . 7760 . 182–188 . 10.1038/s41586-019-1279-z . 31168093 . 2019Natur.570..182S . 174809069 . 1476-4687. 1887/3198847 . free .
  16. Lazaridis . Iosif . Patterson . Nick . Mittnik . Alissa . Ancient human genomes suggest three ancestral populations for present-day Europeans . Nature . September 2014 . 513 . 7518 . 409–413 . 10.1038/nature13673 . 25230663 . 4170574 . 1312.6639 . 2014Natur.513..409L . en . 1476-4687. Most present-day Europeans derive from at least three highly differentiated populations: west European hunter-gatherers, who contributed ancestry to all Europeans but not to Near Easterners; ancient north Eurasians related to Upper Palaeolithic Siberians, who contributed to both Europeans and Near Easterners; and early European farmers, who were mainly of Near Eastern origin but also harboured west European hunter-gatherer related ancestry..
  17. Lazaridis et al. (2014), Supplementary Information, p. 113.
  18. Lipson et al., "Parallel palaeogenomic transects reveal complex genetic history of early European farmers", Nature 551, 368–372 (16 November 2017) .
  19. Lipson et al. (2017), Fig 2.
  20. Brace . Selina . Diekmann . Yoan . Booth . Thomas J. . van Dorp . Lucy . Faltyskova . Zuzana . Rohland . Nadin . Mallick . Swapan . Olalde . Iñigo . Ferry . Matthew. Michel. Megan . Oppenheimer . Jonas . Broomandkhoshbacht . Nasreen . Stewardson . Kristin . Martiniano . Rui . Walsh . Susan . Kayser . Manfred . Charlton . Sophy . Hellenthal . Garrett . Armit . Ian. Schulting. Rick . Craig . Oliver E. . Sheridan . Alison . Parker Pearson . Mike . Stringer . Chris . Reich . David . Thomas . Mark G. . Barnes . Ian . Ancient genomes indicate population replacement in Early Neolithic Britain . Nature Ecology & Evolution . 3 . 5 . 2019 . 765–771 . 2397-334X . 10.1038/s41559-019-0871-9 . 30988490 . 6520225. 2019NatEE...3..765B .
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  23. Book: Reich . David . Who We Are and How We Hot Here : Ancient DNA and the New Science of the Human Past . 2018 . Knopf Doubleday Publishing Group . New York . 978-1101870334 . First . "Analysis of ancient DNA data shows that the hunter-gatherers of Western Europe some eight thousand years ago had blue eyes but dark skin and dark hair, a combination that is rare today."
  24. Book: Warren . Graeme . Hunter-Gatherer Ireland: making connections in an island world . 2021 . Oxbow Books . 978-1789256840 . "WHGs for example, had skin pigmentation ranging from olive to brown to black, with blue or blue-green eyes. In some parts of Europe this may also have been associated with blond hair."
  25. Supplementary Material. Page 22: "Two WHGs (Cheddar Man and La Braña from northern Spain) are predicted to have had dark or dark-to-black skin, whereas one (Loschbour44from Luxembourg) is predicted to have had intermediate skin suggesting but we find potential temporal and/or geographical variation in pigmentation characteristics, suggesting that diverse skin pigmentation levels coexisted in WHGs by at least ca.8 kBP. Sven was predicted to have had dark to intermediate to dark skin in line with the current hypothesis that alleles commonly associated with lighter skin in Europeans were introduced to north-western Europe by ANFs."
  26. News: Dark Skin, Blue Eyes: Genes Paint 7,000-Year-Old European's Picture . NBC News . 26 January 2014.
  27. Callaway . Ewen . Ancient DNA maps 'dawn of farming' . Nature . 12 May 2022 . 10.1038/d41586-022-01322-w . 35552521 . 248765487 . "Once established in Anatolia, Excoffier’s team found, early farming populations moved west into Europe in a stepping-stone-like fashion, beginning around 8,000 years ago. They mixed occasionally — but not extensively — with local hunter-gatherers." .
  28. American Journal of Biological Anthropology . 168 . S67 . 2019 . Shades of complexity: New perspectives on the evolution and genetic architecture of human skin . Quillen . Ellen . 4–26. 10.1002/ajpa.23737. 30408154 . 53237190 . "Their analyses suggest that the skin color of both individuals was likely dark, with that of Mesolithic Cheddar Man predicted to be “dark or dark to black”. These findings suggest that lighter skin color was uncommon across much of Europe during the Mesolithic. This is not, however, in conflict with the date estimates of <20 kya above, which addresses the onset of selection and not time of fixation of favored alleles (Beleza et al., 2013; Beleza, Johnson, et al., 2013). While ancient genome studies predict generally darker skin color among Mesolithic Europeans, derived alleles at rs1426654 and rs16891982 were segregating in European populations during the Mesolithic (González-Fortes et al., 2017; Günther et al., 2018; Mittnik et al., 2018), suggesting that phenotypic variation due to these loci was likely present by this time. However, reconstructions of Mesolithic and Neolithic pigmentation phenotype using loci common in modern populations should be interpreted with some caution, as it is possible that other as yet unexamined loci may have also influenced phenotype.". free .
  29. Web site: 21 February 2018 . Ancient 'dark skinned' Cheddar man find may not be true . .
  30. Book: Krause . Johannes . A Short History of Humanity A New History of Old Europe . 2021 . l: Random House Publishing Group . 9780593229446.
  31. Simões . Luciana G. . Peyroteo-Stjerna . Rita . Marchand . Grégor . Bernhardsson . Carolina . Vialet . Amélie . Chetty . Darshan . Alaçamlı . Erkin . Edlund . Hanna . Bouquin . Denis . Dina . Christian . Garmond . Nicolas . Günther . Torsten . Jakobsson . Mattias . 5 March 2024 . Genomic ancestry and social dynamics of the last hunter-gatherers of Atlantic France . Proceedings of the National Academy of Sciences . en . 121 . 10 . e2310545121 . 10.1073/pnas.2310545121 . 0027-8424 . 10927518 . 38408241. 2024PNAS..12110545S .