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Genetic history of Europe

February 02, 2023

For a non-technical introduction to genetics in general, see Introduction to genetics.

The Genetic history of Europe deals with the formation, ethnogenesis, and other DNA-specific information about populations indigenous, or living in Europe.

The European genetic structure (based on 273,464 SNPs). Three levels of structure as revealed by PC analysis are shown: A) inter-continental; B) intra-continental; and C) inside a single country (Estonia), where median values of the PC1&2 are shown. D) European map illustrating the origin of sample and population size. CEU – Utah residents with ancestry from Northern and Western Europe, CHB – Han Chinese from Beijing, JPT – Japanese from Tokyo, and YRI – Yoruba from Ibadan, Nigeria.[1]

The most significant recent dispersal of modern humans from Africa gave rise to an undifferentiated "non-African" lineage by some 70–50 ka (70-50,000 years ago). By about 50–40 ka a West Eurasian lineage had emerged, as had a separate East Eurasian lineage.[2][3][4][5] Both East and West Eurasians acquired Neanderthal admixture in Europe and Asia.[6]

European early modern humans (EEMH) lineages between 40 and 26 ka (Aurignacian) were still part of a large Western Eurasian "meta-population", related to Central and Western Asian populations.[2] Divergence into genetically distinct sub-populations within Western Eurasia is a result of increased selection pressure and founder effects during the Last Glacial Maximum (LGM, Gravettian).[7] By the end of the LGM, after 20 ka, A Western European lineage, dubbed West European Hunter-Gatherer (WHG) emerges from the Solutrean refugium during the European Mesolithic.[8] These mesolithic hunter-gatherer cultures are substantially replaced in the Neolithic Revolution by the arrival of Early European Farmers (EEF) lineages derived from mesolithic populations of West Asia (Anatolia and the Caucasus).[9] In the European Bronze Age, there were again substantial population replacements in parts of Europe by the intrusion of Ancient North Eurasian (ANE) lineages from the Pontic–Caspian steppes, being deeply related to Mesolithic European hunter-gatherers. These Bronze Age population replacements are associated with the Bell Beaker and Corded Ware cultures archaeologically and with the Indo-European expansion linguistically.[10][11]

As a result of the population movements during the Mesolithic to Bronze Age, modern European populations are distinguished by differences in WHG, EEF and ANE ancestry.[12][13][14] 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%.[15] The contribution of EEF is more significant in Mediterranean Europe, and declines towards northern and northeastern Europe, where WHG ancestry is stronger; the Sardinians are considered to be the closest European group to the population of the EEF. ANE ancestry is found throughout Europe, with maxima of about 20% found in Baltic people and Finns.

Ethnogenesis of the modern ethnic groups of Europe in the historical period is associated with numerous admixture events, primarily those associated with the Roman, Germanic, Norse, Slavic, Berber, Arab and Turkish expansions.

Research into the genetic history of Europe became possible in the second half of the 20th century, but did not yield results with high resolution before the 1990s. In the 1990s, preliminary results became possible, but they remained mostly limited to studies of mitochondrial and Y-chromosomal lineages. Autosomal DNA became more easily accessible in the 2000s, and since the mid-2010s, results of previously unattainable resolution, many of them based on full-genome analysis of ancient DNA, have been published at an accelerated pace.[16][17]

Prehistory

 
Distribution of the Neanderthals, and main sites

Due to natural selection, the percentage of Neanderthal DNA in ancient Europeans gradually decreased over time. From 45,000 BP to 7,000 BP, the percentage dropped from around 3–6% to 2%.[17] The removal of Neanderthal-derived alleles occurred more frequently around genes than other parts of the genome.[17]

Palaeolithic

Further information: Peopling of Europe, Archaic human admixture with modern humans § Neanderthals, and Paleolithic Europe

Neanderthals inhabited much of Europe and western Asia from as far back as 130,000 years ago. They existed in Europe as late as 30,000 years ago. They were eventually replaced by anatomically modern humans (AMH; sometimes known as Cro-Magnons), who began to appear in Europe circa 40,000 years ago. Given that the two hominid species likely coexisted in Europe, anthropologists have long wondered whether the two interacted.[18] The question was resolved only in 2010, when it was established that Eurasian populations exhibit Neanderthal admixture, estimated at 1.5–2.1% on average.[19] The question now became whether this admixture had taken place in Europe, or rather in the Levant, prior to AMH migration into Europe.

There has also been speculation about the inheritance of specific genes from Neanderthals. For example, one MAPT locus 17q21.3 which is split into deep genetic lineages H1 and H2. Since the H2 lineage seems restricted to European populations, several authors had argued for inheritance from Neanderthals beginning in 2005.[20][21][22][23][24] However the preliminary results from the sequencing of the full Neanderthal Genome at that time (2009), failed to uncover evidence of interbreeding between Neanderthals and modern humans.[25][26] By 2010, findings by Svante Pääbo (Max Planck Institute for Evolutionary Anthropology at Leipzig, Germany), Richard E. Green (University of California, Santa Cruz), and David Reich (Harvard Medical School), comparing the genetic material from the bones of three Neanderthals with that from five modern humans, did show a relationship between Neanderthals and modern people outside Africa.

Upper Paleolithic

Main articles: Upper Paleolithic and Early European modern humans
 
Replacement of Neanderthals by early modern humans

It is thought that modern humans began to inhabit Europe during the Upper Paleolithic about 40,000 years ago. Some evidence shows the spread of the Aurignacian culture.[27]: 59 

From a purely patrilineal, Y-chromosome perspective, it is possible that the old Haplogroup C1a2, F and/or E may be those with the oldest presence in Europe. They have been found in some very old human remains in Europe. However, other haplogroups are far more common among living European males because of later demographic changes.

Haplogroup I (M170), which is now relatively common and widespread within Europe, may represent a Palaeolithic marker – its age has been estimated at ~ 22,000 BP. While it is now concentrated in Europe, it probably arose in a male from the Middle East or Caucasus, or their near descendants, c. 20–25,000 years BP, when it diverged from its immediate ancestor, haplogroup IJ. At about this time, an Upper Palaeolithic culture also appeared, known as the Gravettian.[28]

Earlier research into Y-DNA had instead focused on haplogroup R1 (M173): the most populous lineage among living European males; R1 was also believed to have emerged ~ 40,000 BP in Central Asia.[28][29] However, it is now estimated that R1 emerged substantially more recently: a 2008 study dated the most recent common ancestor of haplogroup IJ to 38,500 and haplogroup R1 to 18,000 BP. This suggested that haplogroup IJ colonists formed the first wave and haplogroup R1 arrived much later.[30]

Thus the genetic data suggests that, at least from the perspective of patrilineal ancestry, separate groups of modern humans took two routes into Europe: from the Middle East via the Balkans and another from Central Asia via the Eurasian Steppe, to the north of the Black Sea.

Martin Richards et al. found that 15–40% of extant mtDNA lineages trace back to the Palaeolithic migrations (depending on whether one allows for multiple founder events).[31] MtDNA haplogroup U5, dated to be ~ 40–50 kYa, arrived during the first early upper Palaeolithic colonisation. Individually, it accounts for 5–15% of total mtDNA lineages. Middle U.P. movements are marked by the haplogroups HV, I and U4. HV split into Pre-V (around 26,000 years old) and the larger branch H, both of which spread over Europe, possibly via Gravettian contacts.[28][32]

Haplogroup H accounts for about half the gene lines in Europe, with many subgroups. The above mtDNA lineages or their precursors, are most likely to have arrived into Europe via the Middle East. This contrasts with Y DNA evidence, whereby some 50%-plus of male lineages are characterised by the R1 superfamily, which is of possible central Asian origin.[citation needed] Ornella Semino postulates that these differences "may be due in part to the apparent more recent molecular age of Y chromosomes relative to other loci, suggesting more rapid replacement of previous Y chromosomes. Gender-based differential migratory demographic behaviors will also influence the observed patterns of mtDNA and Y variation"[citation needed].

Last Glacial Maximum

Main article: Early European modern humans
Further information: Last Glacial Maximum and Last Glacial Maximum refugia
 
European LGM refuges, 20 kya
  Solutrean and Proto-Solutrean Cultures
  Epi-Gravettian Culture

The Last Glacial Maximum ("LGM") started c. 30 ka BCE, at the end of MIS 3, leading to a depopulation of Northern Europe. According to the classical model, people took refuge in climatic sanctuaries (or refugia) as follows:

  • Northern Iberia and Southwest France, together making up the "Franco-Cantabrian" refugium
  • The Balkans
  • Ukraine and more generally the northern coast of the Black Sea[28]
  • Italy.[33]

This event decreased the overall genetic diversity in Europe, a "result of drift, consistent with an inferred population bottleneck during the Last Glacial Maximum".[29] As the glaciers receded from about 16,000–13,000 years ago, Europe began to be slowly repopulated by people from refugia, leaving genetic signatures.[28]

Some Y haplogroup I clades appear to have diverged from their parental haplogroups sometime during or shortly after the LGM.[34] Haplogroup I2 is prevalent in the western Balkans, as well as the rest of southeastern and central-eastern Europe in more moderate frequencies. Its frequency drops rapidly in central Europe, suggesting that the survivors bearing I2 lineages expanded predominantly through south-eastern and central-eastern Europe.[35]

Cinnioglu sees evidence for the existence of an Anatolian refuge, which also harboured Hg R1b1b2.[36] Today, R1b dominates the y chromosome landscape of western Europe, including the British Isles, suggesting that there could have been large population composition changes based on migrations after the LGM.

Semino, Passarino and Pericic place the origins of haplogroup R1a within the Ukrainian ice-age refuge. Its current distribution in eastern Europe and parts of Scandinavia are in part reflective of a re-peopling of Europe from the southern Russian/Ukrainian steppes after the Late Glacial Maximum.[35][37][28]

From an mtDNA perspective, Richards et al. found that the majority of mtDNA diversity in Europe is accounted for by post-glacial re-expansions during the late upper Palaeolithic/ Mesolithic. "The regional analyses lend some support to the suggestion that much of western and central Europe was repopulated largely from the southwest when the climate improved. The lineages involved include much of the most common haplogroup, H, as well as much of K, T, W, and X." The study could not determine whether there were new migrations of mtDNA lineages from the near east during this period; a significant input was deemed unlikely.[31]

The alternative model of more refugees was discussed by Bilton et al.[38]

From a study of 51 individuals, researchers were able to identify five separate genetic clusters of ancient Eurasians during the LGM: the Věstonice Cluster (34,000–26,000 years ago), associated with the Gravettian culture; the Mal'ta Cluster (24,000–17,000), associated with the Mal'ta-Buret' culture, the El Mirón Cluster (19,000–14,000 years ago), associated with the Magdalenian culture; the Villabruna Cluster (14,000–7,000 years ago) and the Satsurblia Cluster (13,000 to 10,000 years ago).[17]

From around 37,000 years ago, all ancient Europeans began to share some ancestry with modern Europeans.[17] This founding population is represented by GoyetQ116-1, a 35,000 year old specimen from Belgium.[17] This lineage disappears from the record and is not found again until 19,000 BP in Spain at El Mirón, which shows strong affinities to GoyetQ116-1.[17] During this interval, the distinct Věstonice Cluster is predominant in Europe, even at Goyet.[17] The re-expansion of the El Mirón Cluster coincided with warming temperatures following the retreat of the glaciers during the Last Glacial Maximum.[17] From 37,000 to 14,000 years ago, the population of Europe consisted of an isolated population descended from a founding population that didn't interbreed significantly with other populations.[39]

Mesolithic

Further information: Mesolithic Europe, Western Hunter-Gatherer, and Caucasian Hunter-Gatherer

Mesolithic (post-LGM) populations had diverged significantly due to their relative isolation over several millennia, to the harsh selection pressures during the LGM, and to the founder effects caused by the rapid expansion from LGM refugia in the beginning Mesolithic.[7] By the end of the LGM, around 19 to 11 ka, the familiar varieties of Eurasian phenotypes had emerged. However, the lineage of Mesolithic hunter-gatherers of Western Europe (WHG) does not survive as a majority contribution in any modern population. They were most likely blue eyed, and retained the dark skin pigmentation of pre-LGM EEMH.[40] The HERC2 and OCA2 variations for blue eyes are derived from the WHG lineage were also found in the Yamnaya people.[40][contradictory]

Around 14,000 years ago, the Villabruna Cluster shifted away from GoyetQ116-1 affinity and started to show more affinity with the Near East, a shift which coincided with the warming temperatures of the Bølling-Allerød interstadial.[17] This genetic shift shows that Near East populations had probably already begun moving into Europe during the end of the Upper Paleolithic, about 6,000 years earlier than previously thought, before the introduction of farming.[39] A few specimens from the Villabruna Cluster also show genetic affinities for East Asians that are derived from gene flow.[17][39] The HERC2 variation for blue eyes first appears around 13,000 to 14,000 years ago in Italy and the Caucasus.[17] The light skin pigmentation characteristic of modern Europeans is estimated to have spread across Europe in a "selective sweep" during the Mesolithic (19 to 11 ka). The associated TYRP1 SLC24A5 and SLC45A2 alleles emerge around 19 ka, still during the LGM, most likely in the Caucasus.[7][8]

Neolithic

Further information: Neolithic Europe, Neolithic Revolution, Early European Farmers, and Holocene
 
Simplified model for the demographic history of Europeans during the Neolithic period in the introduction of agriculture[41]
 
Ancient European Neolithic farmers were genetically closest to modern Near-Eastern/ Anatolian populations. Genetic matrilineal distances between European Neolithic Linear Pottery Culture populations (5,500–4,900 calibrated BC) and modern Western Eurasian populations.[42]

A big cline in genetic variation that has long been recognised in Europe seems to show important dispersals from the direction of the Middle East. This has often been linked to the spread of farming technology during the Neolithic, which has been argued to be one of the most important periods in determining modern European genetic diversity.

The Neolithic started with the introduction of farming, beginning in SE Europe approximately 10,000–3000 BCE, and extending into NW Europe between 4500 and 1700 BCE. During this era, the Neolithic revolution led to drastic economic as well as socio-cultural changes in Europe and this is also thought to have had a big effect on Europe's genetic diversity, especially concerning genetic lineages entering Europe from the Middle East into the Balkans. There were several phases of this period:

  • In a late European Mesolithic prelude to the Neolithic, it appears that Near Eastern peoples from areas that already had farming, and who also had sea-faring technology, had a transient presence in Greece (for example at Franchthi Cave).[43][44]
  • There is consensus that agricultural technology and the main breeds of animals and plants which are farmed entered Europe from somewhere in the area of the Fertile Crescent and specifically the Levant region from the Sinai to Southern Anatolia.[27]: 1143, 1150 [45] (Less certainly, this agricultural revolution is sometimes argued to have in turn been partly triggered by movements of people and technology coming across the Sinai from Africa.) For more see Fertile Crescent: Cosmopolitan diffusion.
  • A later stage of the Neolithic, the so-called Pottery Neolithic, saw an introduction of pottery into the Levant, Balkans and Southern Italy (it had been present in the area of modern Sudan for some time before it is found in the Eastern Mediterranean, but it is thought to have developed independently), and this may have also been a period of cultural transfer from the Levant into the Balkans.

An important issue regarding the genetic impact of neolithic technologies in Europe is the manner by which they were transferred into Europe. Farming was introduced by a significant migration of farmers from the Near East (Cavalli-Sforza's biological demic diffusion model) or a "cultural diffusion" or a combination of the two, and population geneticists have tried to clarify whether any genetic signatures of Near Eastern origin correspond to the expansion routes postulated by the archaeological evidence.[27]: 146 

Martin Richards estimated that only 11% of European mtDNA is due to immigration in this period, suggesting that farming was spread primarily due to being adopted by indigenous Mesolithic populations, rather than due to immigration from Near East. Gene flow from SE to NW Europe seems to have continued in the Neolithic, the percentage significantly declining towards the British Isles. Classical genetics also suggested that the largest admixture to the European Paleolithic/Mesolithic stock was due to the Neolithic revolution of the 7th to 5th millennia BCE.[46] Three main mtDNA gene groups have been identified as contributing Neolithic entrants into Europe: J, T1 and U3 (in that order of importance). With others, they amount up to around 20% of the gene pool.[31]

In 2000, Semino's study on Y DNA revealed the presence of haplotypes belonging to the large clade E1b1b1 (E-M35). These were predominantly found in the southern Balkans, southern Italy and parts of Iberia. Semino connected this pattern, along with J haplogroup subclades, to be the Y-DNA component of Cavalli-Sforza's Neolithic demic-diffusion of farmers from the Near East.[28]: Here, the clade E-M35 is referred to as "Eu 4"  Rosser et al. rather saw it as a (direct) 'North African component' in European genealogy, although they did not propose a timing and mechanism to account for it.[47][48] also described E1b1b as representing a late-Pleistocene migration from Africa to Europe over the Sinai Peninsula in Egypt, evidence for which does not show up in mitochondrial DNA.[49]

Concerning timing the distribution and diversity of V13 however, Battaglia[50] proposed an earlier movement whereby the E-M78* lineage ancestral to all modern E-V13 men moved rapidly out of a Southern Egyptian homeland and arrived in Europe with only Mesolithic technologies. They then suggest that the E-V13 sub-clade of E-M78 only expanded subsequently as native Balkan 'foragers-cum-farmers' adopted Neolithic technologies from the Near East. They propose that the first major dispersal of E-V13 from the Balkans may have been in the direction of the Adriatic Sea with the Neolithic Impressed Ware culture often referred to as Impressa or Cardial,[35] rather propose that the main route of E-V13 spread was along the Vardar-Morava-Danube river 'highway' system.

In contrast to Battaglia, Cruciani[51] tentatively suggested (i) a different point where the V13 mutation happened on its way from Egypt to the Balkans via the Middle East, and (ii) a later dispersal time. The authors proposed that the V13 mutation first appeared in western Asia, where it is found in low but significant frequencies, whence it entered the Balkans sometime after 11 kYa. It later experienced a rapid dispersal which he dated to c. 5300 years ago in Europe, coinciding with the Balkan Bronze Age. Like Peričic et al. they consider that "the dispersion of the E-V13 and J-M12 haplogroups seems to have mainly followed the river waterways connecting the southern Balkans to north-central Europe".

More recently, Lacan[52] announced that a 7000-year-old skeleton in a Neolithic context in a Spanish funeral cave, was an E-V13 man. (The other specimens tested from the same site were in haplogroup G2a, which has been found in Neolithic contexts throughout Europe.) Using 7 STR markers, this specimen was identified as being similar to modern individuals tested in Albania, Bosnia, Greece, Corsica, and Provence. The authors therefore proposed that, whether or not the modern distribution of E-V13 of today is a result of more recent events, E-V13 was already in Europe within the Neolithic, carried by early farmers from the Eastern Mediterranean to the Western Mediterranean, much earlier than the Bronze Age. This supports the proposals of Battaglia et al. rather than Cruciani et al. at least concerning earliest European dispersals, but E-V13 may have dispersed more than once. Even more recent than the Bronze Age, it has also been proposed that modern E-V13's modern distribution in Europe is at least partly caused by Roman era movements of people.[53] (See below.)

The migration of Neolithic farmers into Europe brought along several new adaptations.[40] The variation for light skin colour was introduced to Europe by the neolithic farmers.[40] After the arrival of the neolithic farmers, a SLC22A4 mutation was selected for, a mutation which probably arose to deal with ergothioneine deficiency but increases the risk of ulcerative colitis, coeliac disease, and irritable bowel syndrome.

Bronze Age

Further information: Bronze Age Europe

The Bronze Age saw the development of long-distance trading networks, particularly along the Atlantic Coast and in the Danube valley. There was migration from Norway to Orkney and Shetland in this period (and to a lesser extent to mainland Scotland and Ireland). There was also migration from Germany to eastern England. Martin Richards estimated that there was about 4% mtDNA immigration to Europe in the Bronze Age.

 
Scheme of Indo-European migrations from ca. 4000 to 1000 BC according to the Kurgan hypothesis

Another theory about the origin of the Indo-European language centres around a hypothetical Proto-Indo-European people, who, according to the Kurgan hypothesis, can be traced to north of the Black and Caspian Seas at about 4500 BCE.[54] They domesticated the horse and possibly invented the wooden disk wheel, and are considered to have spread their culture and genes across Europe.[55] The Y haplogroup R1a is a proposed marker of these "Kurgan" genes, as is the Y Haplogroup R1b, although these haplogroups as a whole may be much older than the language family.[56]

In the far north, carriers of the Y-haplogroup N arrived to Europe from Siberia, eventually expanding as far as Finland, though the specific timing of their arrival is uncertain. The most common North European subclade N1c1 is estimated to be around 8,000 years old. There is evidence of human settlement in Finland dating back to 8500 BCE, linked with the Kunda culture and its putative ancestor, the Swiderian culture, but the latter is thought to have a European origin. The geographical spread of haplogroup N in Europe is well aligned with the Pit–Comb Ware culture, whose emergence is commonly dated c. 4200 BCE, and with the distribution of Uralic languages. Mitochondrial DNA studies of Sami people, haplogroup U5 are consistent with multiple migrations to Scandinavia from Volga-Ural region, starting 6,000 to 7,000 years before present.[57]

The relationship between roles of European and Asian colonists in the prehistory of Finland is a point of some contention, and some scholars insist that Finns are "predominantly Eastern European and made up of people who trekked north from the Ukrainian refuge during the Ice Age".[58] Farther east, the issue is less contentious. Haplogroup N carriers account for a significant part of all non-Slavic ethnic groups in northern Russia, including 37% of Karelians, 35% of Komi people (65% according to another study[59]), 67% of Mari people, as many as 98% of Nenets people, 94% of Nganasans, and 86% to 94% of Yakuts.[60]

The Yamnaya component contains partial ancestry from an Ancient North Eurasian component, a Paleolithic Siberian lineage but closely related to European hunter-gatherers, first identified in Mal'ta.[61][62] According to Iosif Lazaridis, "the Ancient North Eurasian ancestry is proportionally the smallest component everywhere in Europe, never more than 20 percent, but we find it in nearly every European group we’ve studied."[63] This genetic component does not come directly from the Mal'ta lineage itself, but a related lineage that separated from the Mal'ta lineage.[17]

Up to a half of the Yamnaya component may have come from a Caucasus hunter-gatherer strand.[61] On November 16, 2015, in a study published in the journal Nature Communications,[61] geneticists announced that they had found a new fourth ancestral "tribe" or "strand" which had contributed to the modern European gene pool. They analysed genomes from two hunter-gatherers from Georgia which were 13,300 and 9,700 years old, and found that these Caucasus hunter-gatherers were probably the source of the farmer-like DNA in the Yamna. According to co-author Dr Andrea Manica of the University of Cambridge: "The question of where the Yamnaya come from has been something of a mystery up to now....we can now answer that as we've found that their genetic make-up is a mix of Eastern European Hunter-Gatherers and a population from this pocket of Caucasus hunter-gatherers who weathered much of the last Ice Age in apparent isolation."[64]

According to Lazaridis et al. (2016), a population related to the people of the Chalcolithic Iran contributed to roughly half of the ancestry of Yamnaya populations of the Pontic–Caspian steppe. These Iranian Chalcolithic people were a mixture of "the Neolithic people of western Iran, the Levant, and Caucasus Hunter Gatherers."[65]

The genetic variations for lactase persistence and greater height came with the Yamnaya people.[40] The derived allele of the KITLG gene (SNP rs12821256) that is associated with – and likely causal for – blond hair in Europeans is found in populations with Eastern but not Western Hunter-Gatherers ancestry, suggesting that its origin is in the Ancient North Eurasian (ANE) population and may have been spread in Europe by individuals with steppe ancestry. Consistent with this, the earliest known individual with the derived allele is an ANE individual from the Late Upper Paleolithic Afontova Gora archaeological complex in central Siberia.[66]

Recent history

Further information: History of Europe
Further information: Demography of the Roman Empire, Migration period, Viking expansion, Slavic expansion, Magyar migration, Umayyad conquest of Hispania, Turkic expansion, African admixture in Europe, Ottoman wars in Europe, Ostsiedlung, World War II evacuation and expulsion, Population transfer in the Soviet Union, and Immigration to Europe
 
Overview map of recent (1st to 17th centuries AD) admixture events in Europe[67]

During the period of the Roman Empire, historical sources show that there were many movements of people around Europe, both within and outside the Empire. Historic sources sometimes cite instances of genocide inflicted by the Romans upon rebellious provincial tribes. If this did in fact occur, it would have been limited given that modern populations show considerable genetic continuity in their respective regions.[citation needed] The process of 'Romanisation' appears to have been accomplished by the colonisation of provinces by a few Latin speaking administrators, military personnel, settled veterans, and private citizens (merchants, traders) who emanated from the Empire's various regions (and not merely from Roman Italy). They served as a nucleus for the acculturation of local notables.[68]

Given their small numbers and varied origins, Romanization does not appear to have left distinct genetic signatures in Europe. Indeed, Romance-speaking populations in the Balkans, like Romanians, Aromanians, Moldovans, etc. have been found to genetically resemble neighbouring Greek and South Slavic-speaking peoples rather than modern Italians.[69][70] Steven Bird has speculated that E1b1b1a was spread during the Roman era through Thracian and Dacian populations from the Balkans into the rest of Europe.[53]

Concerning the late Roman period of (not only) Germanic "Völkerwanderung", some suggestions have been made, at least for Britain, with Y haplogroup I1a being associated with Anglo-Saxon immigration in eastern England, and R1a being associated with Norse immigration in northern Scotland.[71]

Genetics of modern European populations

Further information: Ethnic groups in Europe

Patrilineal studies

There are four main Y-chromosome DNA haplogroups that account for most of Europe's patrilineal descent.[28]

  • Haplogroup R1b is common in Europe, particularly in Western Europe, with the R1b1a1a2 being the most common among Western Europeans.[72][73][74] Nearly all of this R1b in Europe is in the form of the R1b1a2 (2011 name) (R-M269) sub-clade, specifically within the R-L23 sub-sub-clade whereas R1b found in Central Asia, western Asia and Africa tends to be in other clades. It has also been pointed out that outlier types are present in Europe and are particularly notable in some areas such as Sardinia and Armenia.[75] Haplogroup R1b frequencies vary from highs in western Europe in a steadily decreasing cline with growing distance from the Atlantic: 80–90% (Welsh, Basque, Irish, Scots, Bretons) around 70–80% in Spain, Britain and France and around 40–60% in parts of eastern Germany, and northern Italy. It drops outside this area and is around 30% or less in areas such as southern Italy, Poland, the Balkans and Cyprus. R1b remains the most common clade as one moves east to Germany, while farther east, in Poland, R1a is more common (see below).[76] In southeastern Europe, R1b drops behind R1a in the area in and around Hungary and Serbia but is more common both to the south and north of this region.[35] R1b in Western Europe is dominated by at least two sub-clades, R-U106, which is distributed from the east side of the Rhine into northern and central Europe (with a strong presence in England) and R-P312, which is most common west of the Rhine, including the British Isles.[73][74]
  • Haplogroup R1a, almost entirely in the R1a1a sub-clade, is prevalent in much of Eastern and Central Europe (also in South and Central Asia). For example, there is a sharp increase in R1a1 and decrease in R1b1b2 as one goes east from Germany to Poland.[76] It also has a substantial presence in Scandinavia (particularly Norway).[77][78] In the Baltic countries R1a frequencies decrease from Lithuania (45%) to Estonia (around 30%).[79]
  • Haplogroup I is found in the form of various sub-clades throughout Europe and is found at highest frequencies in the Nordic countries as I1 (Norway, Denmark, Sweden, Finland) and in the Balkan Peninsula as I2a (Bosnia and Herzegovina 65%,[59] Croatia and Serbia). I1 is also frequent in Germany, Great Britain and Netherlands, while I2a is frequent also in Sardinia, Romania/Moldova, Bulgaria and Ukraine. This clade is found at its highest expression by far in Europe and may have been there since before the LGM.[34]
  • Haplogroup E1b1b (formerly known as E3b) was part of a migration of Neolithic farmers from the Middle East, which carried E1b1b at low to medium frequency and was introduced into Neolithic Middle Easterners throughout genetic drift from a migration from Africa into the Middle East associated with the Afroasiatic languages. It is believed to have first appeared in Northeast Africa approximately 26,000 years ago and dispersed to North Africa and the Near East during the late Paleolithic and Mesolithic periods. E1b1b lineages are closely linked to the diffusion of Afroasiatic languages. Although present throughout Europe, it peaks in the western Balkan region amongst Albanians and their neighbors. It is also common in Italy and the Iberian peninsula at lower frequency. Haplogroup E1b1b1, mainly in the form of its E1b1b1a2 (E-V13) sub-clade, reaches frequencies above 47% around the area of Kosovo.[35] This clade is thought to have arrived in Europe from western Asia either in the later Mesolithic,[50] or the Neolithic.[80] North Africa subclade E-M81 is also present in Sicily and Andalusia.

Putting aside small enclaves, there are also several haplogroups apart from the above four that are less prominent or most common only in certain areas of Europe.

  • Haplogroup G, the original Neolithic Europeans (Caucasians), is common in most parts of Europe at a low frequency, reaching peaks above 70% around Georgia and among the Madjars (although living in Asia they border the eastern perimeter of Europe), up to 10% in Sardinia, 12% in Corsica and Uppsala (Sweden), 11% in the Balkans and Portugal, 10% in Spain and 9% in European Russia. This clade is also found in the Near East.
  • Haplogroup N, is common only in the northeast of Europe and in the form of its N1c1 sub-clade reaches frequencies of approximately 60% among Finns and approximately 40% among Estonians, Latvians, and Lithuanians.
  • Haplogroup J2, in various sub-clades (J2a, J2b), is found in levels of around 15–30% in the Balkans (particularly Greece) and Italy. Haplogroup J2 is frequent in Western Asia and the Eastern Mediterranean.[81]

Matrilineal studies

There have been a number of studies about the mitochondrial DNA haplogroups (mtDNA) in Europe. In contrast to Y DNA haplogroups, mtDNA haplogroups did not show as much geographical patterning, but were more evenly ubiquitous. Apart from the outlying Saami, all Europeans are characterised by the predominance of haplogroups H, U and T. The lack of observable geographic structuring of mtDNA may be due to socio-cultural factors, namely the phenomena of polygyny and patrilocality.[47]

Genetic studies suggest some maternal gene flow to eastern Europe from eastern Asia or southern Siberia 13,000 – 6,600 years BP.[82] Analysis of Neolithic skeletons in the Great Hungarian Plain found a high frequency of eastern Asian mtDNA haplogroups, some of which survive in modern eastern European populations.[82] Maternal gene flow to Europe from sub-Saharan Africa began as early as 11,000 years BP, although the majority of lineages, approximately 65%, are estimated to have arrived more recently, including during the Romanization period, the Arab conquests of southern Europe, and during the Atlantic slave trade.[83]

European population sub-structure

Genetically, Europe is relatively homogeneous, but distinct sub-population patterns of various types of genetic markers have been found,[84] particularly along a southeast–northwest cline.[85] For example, Cavalli-Sforza's principal component analyses revealed five major clinal patterns throughout Europe, and similar patterns have continued to be found in more recent studies.[84]: 291–296 

  1. A cline of genes with highest frequencies in the Middle East, spreading to lowest levels northwest. Cavalli-Sforza originally described this as faithfully reflecting the spread of agriculture in Neolithic times. This has been the general tendency in interpretation of all genes with this pattern.
  2. A cline of genes with highest frequencies among Finnish and Sami in the extreme north east, and spreading to lowest frequencies in the south west.
  3. A cline of genes with highest frequencies in the area of the lower Don and Volga rivers in southern Russia, and spreading to lowest frequencies in Spain, Southern Italy, Greece and the areas inhabited by Saami speakers in the extreme north of Scandinavia. Cavalli-Sforza associated this with the spread of Indo-European languages, which he links in turn to a "secondary expansion" after the spread of agriculture, associated with animal grazing.
  4. A cline of genes with highest frequencies in the Balkans and Southern Italy, spreading to lowest levels in Britain and the Basque country. Cavalli-Sforza associates this with "the Greek expansion, which reached its peak in historical times around 1000 and 500 BCE but which certainly began earlier".
  5. A cline of genes with highest frequencies in the Basque country, and lower levels beyond the area of Iberia and Southern France. In perhaps the most well-known conclusion from Cavalli-Sforza, this weakest of the five patterns was described as isolated remnants of the pre-Neolithic population of Europe, "who at least partially withstood the expansion of the cultivators". It corresponds roughly to the geographical spread of rhesus negative blood types. In particular, the conclusion that the Basques are a genetic isolate has become widely discussed, but also a controversial conclusion.

He also created a phylogenetic tree to analyse the internal relationships among Europeans. He found four major 'outliers'- Basques, Sami, Sardinians and Icelanders;[86] a result he attributed to their relative isolation (note: the Icelanders and the Sardinians speak Indo-European languages, while the other two groups do not). Greeks and Yugoslavs represented a second group of less extreme outliers. The remaining populations clustered into several groups : "Celtic", "Germanic", "south-western Europeans", "Scandinavians" and "eastern Europeans".[84]: 268 

A study in May 2009[87] of 19 populations from Europe using 270,000 SNPs highlighted the genetic diversity of European populations corresponding to the northwest to southeast gradient and distinguished "four several distinct regions" within Europe:

In this study, barrier analysis revealed "genetic barriers" between Finland, Italy and other countries and that barriers could also be demonstrated within Finland (between Helsinki and Kuusamo) and Italy (between northern and southern part, Fst=0.0050). Fst (Fixation index) was found to correlate considerably with geographic distances ranging from ≤0.0010 for neighbouring populations to 0.0200–0.0230 for Southern Italy and Finland. For comparisons, pair-wise Fst of non-European samples were as follows: Europeans – Africans (Yoruba) 0.1530; Europeans – Chinese 0.1100; Africans (Yoruba) – Chinese 0.1900.[88]

A study by Chao Tian in August 2009 extended the analysis of European population genetic structure to include additional southern European groups and Arab populations (Palestinians, Druzes...) from the Near-East. This study determined autosomal Fst between 18 population groups and concluded that, in general, genetic distances corresponded to geographical relationships with smaller values between population groups with origins in neighbouring countries/regions (for example, Greeks/Tuscans: Fst=0.0010, Greeks/Palestinians: Fst=0.0057) compared with those from very different regions in Europe (for example Greeks/Swedish: Fst=0.0087, Greeks/Russians: Fst=0.0108).[89]

Autosomal DNA

Seldin (2006) used over 5,000 autosomal SNPs. It showed "a consistent and reproducible distinction between ‘northern’ and ‘southern’ European population groups". Most individual participants with southern European ancestry (Italians, Greeks, Portuguese, Spaniards), and Ashkenazi Jews have >85% membership in the southern population; and most northern, western, central, and eastern Europeans (Swedes, English, Irish, Germans, and Ukrainians) have >90% in the northern population group. Many of the participants in this study were American citizens who self-identified with different European ethnicities based on self-reported familial pedigree.[90]

A similar study in 2007 using samples predominantly from Europe found that the most important genetic differentiation in Europe occurs on a line from the north to the south-east (northern Europe to the Balkans), with another east–west axis of differentiation across Europe. Its findings were consistent with earlier results based on mtDNA and Y-chromosomal DNA that support the theory that modern Iberians (Spanish and Portuguese) hold the most ancient European genetic ancestry, as well as separating Basques and Sami from other European populations.[91]

It suggested that the English and Irish cluster with other Northern and Eastern Europeans such as Germans and Poles, while some Basque and Italian individuals also clustered with Northern Europeans. Despite these stratifications, it noted that "there is low apparent diversity in Europe with the entire continent-wide samples only marginally more dispersed than single population samples elsewhere in the world".[91]

In 2008, two international research teams published analyses of large-scale genotyping of large samples of Europeans, using over 300,000 autosomal SNPs. With the exception of usual isolates such as Basques, Finns and Sardinians, the European population lacked sharp discontinuities (clustering) as previous studies have found (see Seldin et al. 2006 and Bauchet et al. 2007[91]), although there was a discernible south to north gradient. Overall, they found only a low level of genetic differentiation between subpopulations, and differences which did exist were characterised by a strong continent-wide correlation between geographic and genetic distance. In addition, they found that diversity was greatest in southern Europe due a larger effective population size and/or population expansion from southern to northern Europe.[85] The researchers take this observation to imply that genetically, Europeans are not distributed into discrete populations.[92][85]

Two whole-genome studies of the two Eastern European populations in Ukraine (Ukrainians from Ukraine) and Russia (Russians from Russia) showed genomic diversity from this region has not been represented in the previous genomic surveys, as studies in Europe are mostly biased towards the populations in the western part of the continent.[93][94] Within Russia, Komi people that live in the north eastern part of the country, and are part of the Uralic language family that also includes Finns, form a pole of genetic diversity that is distinct from other populations, and characterized by a higher European hunter-gatherer (WHG) and Ancient North Eurasian ancestry.[95][96]

According to geneticist David Reich, based on ancient human genomes that his laboratory sequenced in 2016, Europeans descend from a mixture of four West-Eurasian ancestral components, namely WHG (Western Hunter-gatherers), EHG (Eastern Hunter-gatherers), Neolithic farmers from the Levant/Anatolia as well as from Neolithic farmers from Iran (often summarized as "EEF"; Early European farmers), in varying degrees.[97][98]

Siberian geneflow is found among several Uralic-speaking European ethnic groups. This Siberian component is itself a composition of Ancient North Eurasian and East Asian-related ancestry from Eastern Siberia, maximized among Evenks and Evens or Nganasans. The spread of this ancestry is linked by some geneticists to the dispersal of Uralic languages, others however maintain that the Uralic languages spreaded prior to the arrival of Siberian geneflow, which is a secondary source of diversity within Uralic-speaking populations.[99][100] Genetic data points to a Western Siberian hunter-gatherer origin of the observed Siberian geneflow among Uralic-speaking groups, which are best represented by the modern Khanty. Historical Western Siberian hunter-gatherers were characterized by high Ancient North Eurasian ancestry and lower amounts of Eastern Siberian admixture. Genetic data on Volga Tatars or Chuvash, found among "Western Turkic speakers, like Chuvash and Volga Tatar, the East Asian component was detected only in low amounts (~ 5%)".[101][102] East Asian ancestry is furthermore found at low frequency among other Europeans: Germans and French people (CEU) ~1%, Britons (GBR) 2.5%–3.8%, Russians and Finns ~13%, associated with the Turco-Mongol expansion,[103] and higher among the Lipka Tatars, a Turkic minority in Belarus ~30%. East Asian ancestry is suggested to have largely arrived indirectly through previous admixed historical Steppe nomads from Central Asia, such as the Huns, Pannonian Avars, and the Golden Horde, which got absorbed by the European majority population. European-related ancestry to East Asians was similarly contributed indirectly through Central Asian groups, specifically into Northern Han Chinese (2.8%), Southern Han Chinese (1.7%), Japanese people (2.2%), and Koreans (1.6%). Northeast Asians had inherited significantly higher European-related ancestry: Mongolians (10.9%), Oroqens (9.6%) Daur people (8%), and Hezhen (6.8%), which also included earlier West-Eurasian ancestry through Ancient North Eurasians, representing the earliest layer within Siberia.[104][105][106]

Modern Europeans are genetically rather homogeneous and derive their ancestry - predominantly to exclusively - from up to five West-Eurasian lineages, in varying degrees. Modern Europeans show affinity and continuity to ancient European hunter-gatherers (Western European Hunter-Gatherers, Scandinavian Hunter-Gatherers, and Eastern European Hunter-Gatherers), yet modern Europeans are significantly closer to Middle Easterners than ancient ones, largely explained through the more recent Neolithic Expansion of farmers from Anatolia towards Europe. Europeans, compared to Middle Easterners, have less "basal" ancestry (ancestry inferred to have diverged before the diverging of Mesolithic European hunter-gatherers and Ancient North Eurasians, therefore representing deep substructure among West-Eurasians), which is inferred to have arrived with Early European farmers (EEF). Europeans contrary have higher Ancient North Eurasian affinity, which is inferred to have arrived with Bronze and Iron Age migrations from Western Siberia. Overall, Europeans cluster closely together with Middle Eastern and South-Central Asian populations, followed by Northern African and South Asian populations, while being most distant from Sub-Saharan African (specifically Central/West African) and Eastern Asian populations.[107]

Autosomal genetic distances (Fst) based on SNPs (2009)

The genetic distance between populations is often measured by Fixation index (Fst), based on genetic polymorphism data, such as single-nucleotide polymorphisms (SNPs) or microsatellites. Fst is a special case of F-statistics, the concept developed in the 1920s by Sewall Wright. Fst is simply the correlation of randomly chosen alleles within the same sub-population relative to that found in the entire population. It is often expressed as the proportion of genetic diversity due to allele frequency differences among populations.

The values range from 0 to 1. A zero value implies that the two populations are panmictic, that they are interbreeding freely. A value of one would imply that the two populations are completely separate. The greater the Fst value, the greater the genetic distance. Essentially, these low Fst values suggest that the majority of genetic variation is at the level of individuals within the same population group (~ 85%); whilst belonging to a different population group within same ‘race’/ continent, and even to different racial/ continental groups added a much smaller degree of variation (3–8%; 6–11%, respectively).

Intra-European/Mediterranean Autosomal genetic distances (Fst) based on 3,500 SNPs using the Weir and Cockerham algorithm[89]
Italian Americans Palestinians Swedes Druzes Spaniards Germans Russians Irish Greek Americans Ashkenazi Jews Circassians
Italian Americans 0.0064 0.0064 0.0057 0.0010 0.0029 0.0088 0.0048 0.0000 0.0040 0.0067
Palestinians 0.0064 0.0191 0.0064 0.0101 0.0136 0.0202 0.0170 0.0057 0.0093 0.0108
Swedes 0.0064 0.0191 0.0167 0.0040 0.0007 0.0030 0.0020 0.0084 0.0120 0.0117
Druzes 0.0057 0.0064 0.0167 0.0096 0.0121 0.0194 0.0154 0.0052 0.0088 0.0092
Spaniards 0.0010 0.0101 0.0040 0.0096 0.0015 0.0070 0.0037 0.0035 0.0056 0.0090
Germans 0.0029 0.0136 0.0007 0.0121 0.0015 0.0030 0.0010 0.0039 0.0072 0.0089
Russians 0.0088 0.0202 0.0030 0.0194 0.0070 0.0030 0.0038 0.0108 0.0137 0.0120
Irish 0.0048 0.0170 0.0020 0.0154 0.0037 0.0010 0.0038 0.0067 0.0109 0.0110
Greek Americans 0.0000 0.0057 0.0084 0.0052 0.0035 0.0039 0.0108 0.0067 0.0042 0.0054
Ashkenazi Jews 0.0040 0.0093 0.0120 0.0088 0.0056 0.0072 0.0137 0.0109 0.0042 0.0107
Circassians 0.0067 0.0108 0.0117 0.0092 0.0090 0.0089 0.0120 0.0110 0.0054 0.0107
European Population Genetic Substructure based on SNPs[108][1]
Austria Bulgaria Czech Republic Estonia Finland (Helsinki) Finland (Kuusamo) France Northern Germany Southern Germany Hungary Northern Italy Southern Italy Latvia Lithuania Poland Russia Spain Sweden Switzerland CEU
Austria 1.14 1.08 1.58 2.24 3.30 1.16 1.10 1.04 1.04 1.49 1.79 1.85 1.70 1.19 1.47 1.41 1.21 1.19 1.12 Austria
Bulgaria 1.14 1.21 1.70 2.19 2.91 1.22 1.32 1.19 1.10 1.32 1.38 1.86 1.73 1.29 1.53 1.30 1.47 1.13 1.29 Bulgaria
Czech Republic 1.08 1.21 1.42 2.20 3.26 1.35 1.15 1.16 1.06 1.69 2.04 1.62 1.48 1.09 1.27 1.63 1.26 1.37 1.21 Czech Republic
Estonia 1.58 1.70 1.42 1.71 2.80 2.08 1.53 1.70 1.41 2.42 2.93 1.24 1.28 1.17 1.21 2.54 1.49 2.16 1.59 Estonia
Finland (Helsinki) 2.24 2.19 2.20 1.71 1.86 2.69 2.17 2.35 1.87 2.82 3.37 2.31 2.33 1.75 2.10 3.14 1.89 2.77 1.99 Finland (Helsinki)
Finland (Kuusamo) 3.30 2.91 3.26 2.80 1.86 3.72 3.27 3.46 2.68 3.64 4.18 3.33 3.37 2.49 3.16 4.21 2.87 3.83 2.89 Finland (Kuusamo)
France 1.16 1.22 1.35 2.08 2.69 3.72 1.25 1.12 1.16 1.38 1.68 2.40 2.20 1.44 1.94 1.13 1.38 1.10 1.13 France
Northern Germany 1.10 1.32 1.15 1.53 2.17 3.27 1.25 1.08 1.11 1.72 2.14 1.84 1.66 1.18 1.49 1.62 1.12 1.36 1.06 Northern Germany
Southern Germany 1.04 1.19 1.16 1.70 2.35 3.46 1.12 1.08 1.08 1.53 1.85 1.20 1.84 1.23 1.58 1.40 1.21 1.17 1.07 Southern Germany
Hungary 1.04 1.10 1.06 1.41 1.87 2.68 1.16 1.11 1.08 1.42 1.63 1.58 1.46 1.14 1.28 1.32 1.22 1.16 1.13 Hungary
Northern Italy 1.49 1.32 1.69 2.42 2.82 3.64 1.38 1.72 1.53 1.42 1.54 2.64 2.48 1.75 2.24 1.42 1.86 1.36 1.56 Northern Italy
Southern Italy 1.79 1.38 2.04 2.93 3.37 4.18 1.68 2.14 1.85 1.63 1.54 3.14 2.96 1.99 2.68 1.67 2.28 1.54 1.84 Southern Italy
Latvia 1.85 1.86 1.62 1.24 2.31 3.33 2.40 1.84 1.20 1.58 2.64 3.14 1.20 1.26 1.84 2.82 1.89 2.52 1.87 Latvia
Lithuania 1.70 1.73 1.48 1.28 2.33 3.37 2.20 1.66 1.84 1.46 2.48 2.96 1.20 1.20 1.26 2.62 1.74 2.29 1.74 Lithuania
Poland 1.19 1.29 1.09 1.17 1.75 2.49 1.44 1.18 1.23 1.14 1.75 1.99 1.26 1.20 1.18 1.66 1.30 1.46 1.28 Poland
Russia 1.47 1.53 1.27 1.21 2.10 3.16 1.94 1.49 1.58 1.28 2.24 2.68 1.84 1.26 1.18 2.32 1.59 1.20 1.56 Russia
Spain 1.41 1.30 1.63 2.54 3.14 4.21 1.13 1.62 1.40 1.32 1.42 1.67 2.82 2.62 1.66 2.32 1.73 1.16 1.34 Spain
Sweden 1.21 1.47 1.26 1.49 1.89 2.87 1.38 1.12 1.21 1.22 1.86 2.28 1.89 1.74 1.30 1.59 1.73 1.50 1.09 Sweden
Switzerland 1.19 1.13 1.37 2.16 2.77 3.83 1.10 1.36 1.17 1.16 1.36 1.54 2.52 2.29 1.46 1.20 1.16 1.50 1.21 Switzerland
CEU 1.12 1.29 1.21 1.59 1.99 2.89 1.13 1.06 1.07 1.13 1.56 1.84 1.87 1.74 1.28 1.56 1.34 1.09 1.21 CEU
Austria Bulgaria Czech Republic Estonia Finland (Helsinki) Finland (Kuusamo) France Northern Germany Southern Germany Hungary Northern Italy Southern Italy Latvia Lithuania Poland Russia Spain Sweden Switzerland CEU

CEU – Utah residents with ancestry from Northern and Western Europe.

History of research

Further information: Population genetics

Classical genetic markers (by proxy)

One of the first scholars to perform genetic studies was Luigi Luca Cavalli-Sforza. He used classical genetic markers to analyse DNA by proxy. This method studies differences in the frequencies of particular allelic traits, namely polymorphisms from proteins found within human blood (such as the ABO blood groups, Rhesus blood antigens, HLA loci, immunoglobulins, G6PD isoenzymes, among others). Subsequently, his team calculated genetic distance between populations, based on the principle that two populations that share similar frequencies of a trait are more closely related than populations that have more divergent frequencies of the trait.[84]: 51 

From this, he constructed phylogenetic trees that showed genetic distances diagrammatically. His team also performed principal component analyses, which is good at analysing multivariate data with minimal loss of information. The information that is lost can be partly restored by generating a second principal component, and so on.[84]: 39  In turn, the information from each individual principal component (PC) can be presented graphically in synthetic maps. These maps show peaks and troughs, which represent populations whose gene frequencies take extreme values compared to others in the studied area.[84]: 51 

Peaks and troughs usually connected by smooth gradients are called clines. Genetic clines can be generated by adaptation to environment (natural selection), continuous gene flow between two initially different populations or a demographic expansion into a scarcely populated environment, with little initial admixture with existing populations.[109]: 390  Cavalli-Sforza connected these gradients with postulated pre-historic population movements, based on archaeological and linguistic theories. However, given that the time depths of such patterns are not known, "associating them with particular demographic events is usually speculative".[47]

Direct DNA analysis

Further information: Genetic drift, Founder effect, and Population bottleneck

Studies using direct DNA analysis are now abundant and may use mitochondrial DNA (mtDNA), the non-recombining portion of the Y chromosome (NRY), or even autosomal DNA. MtDNA and NRY DNA share some similar features, which have made them particularly useful in genetic anthropology. These properties include the direct, unaltered inheritance of mtDNA and NRY DNA from mother to offspring and father to son, respectively, without the 'scrambling' effects of genetic recombination. We also presume that these genetic loci are not affected by natural selection and that the major process responsible for changes in base pairs has been mutation (which can be calculated).[27]: 58 

The smaller effective population size of the NRY and mtDNA enhances the consequences of drift and founder effect, relative to the autosomes, making NRY and mtDNA variation a potentially sensitive index of population composition.[47][31][28] These biologically plausible assumptions are not concrete; Rosser suggests that climatic conditions may affect the fertility of certain lineages.[47]

The underlying mutation rate used by the geneticists is more questionable. They often use different mutation rates and studies frequently arrive at vastly different conclusions.[47] NRY and mtDNA may be so susceptible to drift that some ancient patterns may have become obscured. Another assumption is that population genealogies are approximated by allele genealogies. Guido Barbujani points out that this only holds if population groups develop from a genetically monomorphic set of founders. Barbujani argues that there is no reason to believe that Europe was colonised by monomorphic populations. This would result in an overestimation of haplogroup age, thus falsely extending the demographic history of Europe into the Late Paleolithic rather than the Neolithic era.[110] Greater certainty about chronology may be obtained from studies of ancient DNA (see below), but so far these have been comparatively few.

Whereas Y-DNA and mtDNA haplogroups represent but a small component of a person's DNA pool, autosomal DNA has the advantage of containing hundreds of thousands of examinable genetic loci, thus giving a more complete picture of genetic composition. Descent relationships can only be determined on a statistical basis, because autosomal DNA undergoes recombination. A single chromosome can record a history for each gene. Autosomal studies are much more reliable for showing the relationships between existing populations, but do not offer the possibilities for unravelling their histories in the same way as mtDNA and NRY DNA studies promise, despite their many complications.

Genetic studies operate on numerous assumptions and suffer from methodological limitations, such as selection bias and confounding phenomena like genetic drift, foundation and bottleneck effects cause large errors, particularly in haplogroup studies. No matter how accurate the methodology, conclusions derived from such studies are compiled on the basis of how the author envisages their data fits with established archaeological or linguistic theories.[citation needed]

See also

General
Genetics by European group

References

Inline citations

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Further reading

  • Rodríguez-Varela, Ricardo et al. "The genetic history of Scandinavia from the Roman Iron Age to the present". In: Cell. Volume 186, Issue 1, 5 January 2023, Pages 32-46.e19. doi:10.1016/j.cell.2022.11.024
  • Skourtanioti, E., Ringbauer, H., Gnecchi Ruscone, G.A. et al. "Ancient DNA reveals admixture history and endogamy in the prehistoric Aegean". In: Nature Ecology & Evolution (2023). https://doi.org/10.1038/s41559-022-01952-3

External links

 
Wikimedia Commons has media related to Genetic studies on European populations.
  • "A genetic atlas of human admixture history". 2014.

February 02, 2023
genetic, history, europe, technical, introduction, genetics, general, introduction, genetics, this, article, multiple, issues, please, help, improve, discuss, these, issues, talk, page, learn, when, remove, these, template, messages, this, article, factual, ac. For a non technical introduction to genetics in general see Introduction to genetics This article has multiple issues Please help improve it or discuss these issues on the talk page Learn how and when to remove these template messages This article s factual accuracy may be compromised due to out of date information Please help update this article to reflect recent events or newly available information December 2022 This article may need to be rewritten to comply with Wikipedia s quality standards You can help The talk page may contain suggestions January 2018 Learn how and when to remove this template message The Genetic history of Europe deals with the formation ethnogenesis and other DNA specific information about populations indigenous or living in Europe The European genetic structure based on 273 464 SNPs Three levels of structure as revealed by PC analysis are shown A inter continental B intra continental and C inside a single country Estonia where median values of the PC1 amp 2 are shown D European map illustrating the origin of sample and population size CEU Utah residents with ancestry from Northern and Western Europe CHB Han Chinese from Beijing JPT Japanese from Tokyo and YRI Yoruba from Ibadan Nigeria 1 The most significant recent dispersal of modern humans from Africa gave rise to an undifferentiated non African lineage by some 70 50 ka 70 50 000 years ago By about 50 40 ka a West Eurasian lineage had emerged as had a separate East Eurasian lineage 2 3 4 5 Both East and West Eurasians acquired Neanderthal admixture in Europe and Asia 6 European early modern humans EEMH lineages between 40 and 26 ka Aurignacian were still part of a large Western Eurasian meta population related to Central and Western Asian populations 2 Divergence into genetically distinct sub populations within Western Eurasia is a result of increased selection pressure and founder effects during the Last Glacial Maximum LGM Gravettian 7 By the end of the LGM after 20 ka A Western European lineage dubbed West European Hunter Gatherer WHG emerges from the Solutrean refugium during the European Mesolithic 8 These mesolithic hunter gatherer cultures are substantially replaced in the Neolithic Revolution by the arrival of Early European Farmers EEF lineages derived from mesolithic populations of West Asia Anatolia and the Caucasus 9 In the European Bronze Age there were again substantial population replacements in parts of Europe by the intrusion of Ancient North Eurasian ANE lineages from the Pontic Caspian steppes being deeply related to Mesolithic European hunter gatherers These Bronze Age population replacements are associated with the Bell Beaker and Corded Ware cultures archaeologically and with the Indo European expansion linguistically 10 11 As a result of the population movements during the Mesolithic to Bronze Age modern European populations are distinguished by differences in WHG EEF and ANE ancestry 12 13 14 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 15 The contribution of EEF is more significant in Mediterranean Europe and declines towards northern and northeastern Europe where WHG ancestry is stronger the Sardinians are considered to be the closest European group to the population of the EEF ANE ancestry is found throughout Europe with maxima of about 20 found in Baltic people and Finns Ethnogenesis of the modern ethnic groups of Europe in the historical period is associated with numerous admixture events primarily those associated with the Roman Germanic Norse Slavic Berber Arab and Turkish expansions Research into the genetic history of Europe became possible in the second half of the 20th century but did not yield results with high resolution before the 1990s In the 1990s preliminary results became possible but they remained mostly limited to studies of mitochondrial and Y chromosomal lineages Autosomal DNA became more easily accessible in the 2000s and since the mid 2010s results of previously unattainable resolution many of them based on full genome analysis of ancient DNA have been published at an accelerated pace 16 17 Contents 1 Prehistory 1 1 Palaeolithic 1 1 1 Upper Paleolithic 1 1 2 Last Glacial Maximum 1 2 Mesolithic 1 3 Neolithic 1 4 Bronze Age 1 5 Recent history 2 Genetics of modern European populations 2 1 Patrilineal studies 2 2 Matrilineal studies 2 3 European population sub structure 2 3 1 Autosomal DNA 2 3 2 Autosomal genetic distances Fst based on SNPs 2009 3 History of research 3 1 Classical genetic markers by proxy 3 2 Direct DNA analysis 4 See also 5 References 5 1 Inline citations 5 2 Sources referenced 6 Further reading 7 External linksPrehistory Edit Distribution of the Neanderthals and main sites Due to natural selection the percentage of Neanderthal DNA in ancient Europeans gradually decreased over time From 45 000 BP to 7 000 BP the percentage dropped from around 3 6 to 2 17 The removal of Neanderthal derived alleles occurred more frequently around genes than other parts of the genome 17 Palaeolithic Edit Further information Peopling of Europe Archaic human admixture with modern humans Neanderthals and Paleolithic Europe Neanderthals inhabited much of Europe and western Asia from as far back as 130 000 years ago They existed in Europe as late as 30 000 years ago They were eventually replaced by anatomically modern humans AMH sometimes known as Cro Magnons who began to appear in Europe circa 40 000 years ago Given that the two hominid species likely coexisted in Europe anthropologists have long wondered whether the two interacted 18 The question was resolved only in 2010 when it was established that Eurasian populations exhibit Neanderthal admixture estimated at 1 5 2 1 on average 19 The question now became whether this admixture had taken place in Europe or rather in the Levant prior to AMH migration into Europe There has also been speculation about the inheritance of specific genes from Neanderthals For example one MAPT locus 17q21 3 which is split into deep genetic lineages H1 and H2 Since the H2 lineage seems restricted to European populations several authors had argued for inheritance from Neanderthals beginning in 2005 20 21 22 23 24 However the preliminary results from the sequencing of the full Neanderthal Genome at that time 2009 failed to uncover evidence of interbreeding between Neanderthals and modern humans 25 26 By 2010 findings by Svante Paabo Max Planck Institute for Evolutionary Anthropology at Leipzig Germany Richard E Green University of California Santa Cruz and David Reich Harvard Medical School comparing the genetic material from the bones of three Neanderthals with that from five modern humans did show a relationship between Neanderthals and modern people outside Africa Upper Paleolithic Edit Main articles Upper Paleolithic and Early European modern humans Replacement of Neanderthals by early modern humans It is thought that modern humans began to inhabit Europe during the Upper Paleolithic about 40 000 years ago Some evidence shows the spread of the Aurignacian culture 27 59 From a purely patrilineal Y chromosome perspective it is possible that the old Haplogroup C1a2 F and or E may be those with the oldest presence in Europe They have been found in some very old human remains in Europe However other haplogroups are far more common among living European males because of later demographic changes Haplogroup I M170 which is now relatively common and widespread within Europe may represent a Palaeolithic marker its age has been estimated at 22 000 BP While it is now concentrated in Europe it probably arose in a male from the Middle East or Caucasus or their near descendants c 20 25 000 years BP when it diverged from its immediate ancestor haplogroup IJ At about this time an Upper Palaeolithic culture also appeared known as the Gravettian 28 Earlier research into Y DNA had instead focused on haplogroup R1 M173 the most populous lineage among living European males R1 was also believed to have emerged 40 000 BP in Central Asia 28 29 However it is now estimated that R1 emerged substantially more recently a 2008 study dated the most recent common ancestor of haplogroup IJ to 38 500 and haplogroup R1 to 18 000 BP This suggested that haplogroup IJ colonists formed the first wave and haplogroup R1 arrived much later 30 Thus the genetic data suggests that at least from the perspective of patrilineal ancestry separate groups of modern humans took two routes into Europe from the Middle East via the Balkans and another from Central Asia via the Eurasian Steppe to the north of the Black Sea Martin Richards et al found that 15 40 of extant mtDNA lineages trace back to the Palaeolithic migrations depending on whether one allows for multiple founder events 31 MtDNA haplogroup U5 dated to be 40 50 kYa arrived during the first early upper Palaeolithic colonisation Individually it accounts for 5 15 of total mtDNA lineages Middle U P movements are marked by the haplogroups HV I and U4 HV split into Pre V around 26 000 years old and the larger branch H both of which spread over Europe possibly via Gravettian contacts 28 32 Haplogroup H accounts for about half the gene lines in Europe with many subgroups The above mtDNA lineages or their precursors are most likely to have arrived into Europe via the Middle East This contrasts with Y DNA evidence whereby some 50 plus of male lineages are characterised by the R1 superfamily which is of possible central Asian origin citation needed Ornella Semino postulates that these differences may be due in part to the apparent more recent molecular age of Y chromosomes relative to other loci suggesting more rapid replacement of previous Y chromosomes Gender based differential migratory demographic behaviors will also influence the observed patterns of mtDNA and Y variation citation needed Last Glacial Maximum Edit Main article Early European modern humans Further information Last Glacial Maximum and Last Glacial Maximum refugia European LGM refuges 20 kya Solutrean and Proto Solutrean Cultures Epi Gravettian Culture The Last Glacial Maximum LGM started c 30 ka BCE at the end of MIS 3 leading to a depopulation of Northern Europe According to the classical model people took refuge in climatic sanctuaries or refugia as follows Northern Iberia and Southwest France together making up the Franco Cantabrian refugium The Balkans Ukraine and more generally the northern coast of the Black Sea 28 Italy 33 This event decreased the overall genetic diversity in Europe a result of drift consistent with an inferred population bottleneck during the Last Glacial Maximum 29 As the glaciers receded from about 16 000 13 000 years ago Europe began to be slowly repopulated by people from refugia leaving genetic signatures 28 Some Y haplogroup I clades appear to have diverged from their parental haplogroups sometime during or shortly after the LGM 34 Haplogroup I2 is prevalent in the western Balkans as well as the rest of southeastern and central eastern Europe in more moderate frequencies Its frequency drops rapidly in central Europe suggesting that the survivors bearing I2 lineages expanded predominantly through south eastern and central eastern Europe 35 Cinnioglu sees evidence for the existence of an Anatolian refuge which also harboured Hg R1b1b2 36 Today R1b dominates the y chromosome landscape of western Europe including the British Isles suggesting that there could have been large population composition changes based on migrations after the LGM Semino Passarino and Pericic place the origins of haplogroup R1a within the Ukrainian ice age refuge Its current distribution in eastern Europe and parts of Scandinavia are in part reflective of a re peopling of Europe from the southern Russian Ukrainian steppes after the Late Glacial Maximum 35 37 28 From an mtDNA perspective Richards et al found that the majority of mtDNA diversity in Europe is accounted for by post glacial re expansions during the late upper Palaeolithic Mesolithic The regional analyses lend some support to the suggestion that much of western and central Europe was repopulated largely from the southwest when the climate improved The lineages involved include much of the most common haplogroup H as well as much of K T W and X The study could not determine whether there were new migrations of mtDNA lineages from the near east during this period a significant input was deemed unlikely 31 The alternative model of more refugees was discussed by Bilton et al 38 From a study of 51 individuals researchers were able to identify five separate genetic clusters of ancient Eurasians during the LGM the Vestonice Cluster 34 000 26 000 years ago associated with the Gravettian culture the Mal ta Cluster 24 000 17 000 associated with the Mal ta Buret culture the El Miron Cluster 19 000 14 000 years ago associated with the Magdalenian culture the Villabruna Cluster 14 000 7 000 years ago and the Satsurblia Cluster 13 000 to 10 000 years ago 17 From around 37 000 years ago all ancient Europeans began to share some ancestry with modern Europeans 17 This founding population is represented by GoyetQ116 1 a 35 000 year old specimen from Belgium 17 This lineage disappears from the record and is not found again until 19 000 BP in Spain at El Miron which shows strong affinities to GoyetQ116 1 17 During this interval the distinct Vestonice Cluster is predominant in Europe even at Goyet 17 The re expansion of the El Miron Cluster coincided with warming temperatures following the retreat of the glaciers during the Last Glacial Maximum 17 From 37 000 to 14 000 years ago the population of Europe consisted of an isolated population descended from a founding population that didn t interbreed significantly with other populations 39 Mesolithic Edit Further information Mesolithic Europe Western Hunter Gatherer and Caucasian Hunter Gatherer Mesolithic post LGM populations had diverged significantly due to their relative isolation over several millennia to the harsh selection pressures during the LGM and to the founder effects caused by the rapid expansion from LGM refugia in the beginning Mesolithic 7 By the end of the LGM around 19 to 11 ka the familiar varieties of Eurasian phenotypes had emerged However the lineage of Mesolithic hunter gatherers of Western Europe WHG does not survive as a majority contribution in any modern population They were most likely blue eyed and retained the dark skin pigmentation of pre LGM EEMH 40 The HERC2 and OCA2 variations for blue eyes are derived from the WHG lineage were also found in the Yamnaya people 40 contradictory Around 14 000 years ago the Villabruna Cluster shifted away from GoyetQ116 1 affinity and started to show more affinity with the Near East a shift which coincided with the warming temperatures of the Bolling Allerod interstadial 17 This genetic shift shows that Near East populations had probably already begun moving into Europe during the end of the Upper Paleolithic about 6 000 years earlier than previously thought before the introduction of farming 39 A few specimens from the Villabruna Cluster also show genetic affinities for East Asians that are derived from gene flow 17 39 The HERC2 variation for blue eyes first appears around 13 000 to 14 000 years ago in Italy and the Caucasus 17 The light skin pigmentation characteristic of modern Europeans is estimated to have spread across Europe in a selective sweep during the Mesolithic 19 to 11 ka The associated TYRP1 SLC24A5 and SLC45A2 alleles emerge around 19 ka still during the LGM most likely in the Caucasus 7 8 Neolithic Edit Further information Neolithic Europe Neolithic Revolution Early European Farmers and Holocene Simplified model for the demographic history of Europeans during the Neolithic period in the introduction of agriculture 41 Ancient European Neolithic farmers were genetically closest to modern Near Eastern Anatolian populations Genetic matrilineal distances between European Neolithic Linear Pottery Culture populations 5 500 4 900 calibrated BC and modern Western Eurasian populations 42 A big cline in genetic variation that has long been recognised in Europe seems to show important dispersals from the direction of the Middle East This has often been linked to the spread of farming technology during the Neolithic which has been argued to be one of the most important periods in determining modern European genetic diversity The Neolithic started with the introduction of farming beginning in SE Europe approximately 10 000 3000 BCE and extending into NW Europe between 4500 and 1700 BCE During this era the Neolithic revolution led to drastic economic as well as socio cultural changes in Europe and this is also thought to have had a big effect on Europe s genetic diversity especially concerning genetic lineages entering Europe from the Middle East into the Balkans There were several phases of this period In a late European Mesolithic prelude to the Neolithic it appears that Near Eastern peoples from areas that already had farming and who also had sea faring technology had a transient presence in Greece for example at Franchthi Cave 43 44 There is consensus that agricultural technology and the main breeds of animals and plants which are farmed entered Europe from somewhere in the area of the Fertile Crescent and specifically the Levant region from the Sinai to Southern Anatolia 27 1143 1150 45 Less certainly this agricultural revolution is sometimes argued to have in turn been partly triggered by movements of people and technology coming across the Sinai from Africa For more see Fertile Crescent Cosmopolitan diffusion A later stage of the Neolithic the so called Pottery Neolithic saw an introduction of pottery into the Levant Balkans and Southern Italy it had been present in the area of modern Sudan for some time before it is found in the Eastern Mediterranean but it is thought to have developed independently and this may have also been a period of cultural transfer from the Levant into the Balkans An important issue regarding the genetic impact of neolithic technologies in Europe is the manner by which they were transferred into Europe Farming was introduced by a significant migration of farmers from the Near East Cavalli Sforza s biological demic diffusion model or a cultural diffusion or a combination of the two and population geneticists have tried to clarify whether any genetic signatures of Near Eastern origin correspond to the expansion routes postulated by the archaeological evidence 27 146 Martin Richards estimated that only 11 of European mtDNA is due to immigration in this period suggesting that farming was spread primarily due to being adopted by indigenous Mesolithic populations rather than due to immigration from Near East Gene flow from SE to NW Europe seems to have continued in the Neolithic the percentage significantly declining towards the British Isles Classical genetics also suggested that the largest admixture to the European Paleolithic Mesolithic stock was due to the Neolithic revolution of the 7th to 5th millennia BCE 46 Three main mtDNA gene groups have been identified as contributing Neolithic entrants into Europe J T1 and U3 in that order of importance With others they amount up to around 20 of the gene pool 31 In 2000 Semino s study on Y DNA revealed the presence of haplotypes belonging to the large clade E1b1b1 E M35 These were predominantly found in the southern Balkans southern Italy and parts of Iberia Semino connected this pattern along with J haplogroup subclades to be the Y DNA component of Cavalli Sforza s Neolithic demic diffusion of farmers from the Near East 28 Here the clade E M35 is referred to as Eu 4 Rosser et al rather saw it as a direct North African component in European genealogy although they did not propose a timing and mechanism to account for it 47 48 also described E1b1b as representing a late Pleistocene migration from Africa to Europe over the Sinai Peninsula in Egypt evidence for which does not show up in mitochondrial DNA 49 Concerning timing the distribution and diversity of V13 however Battaglia 50 proposed an earlier movement whereby the E M78 lineage ancestral to all modern E V13 men moved rapidly out of a Southern Egyptian homeland and arrived in Europe with only Mesolithic technologies They then suggest that the E V13 sub clade of E M78 only expanded subsequently as native Balkan foragers cum farmers adopted Neolithic technologies from the Near East They propose that the first major dispersal of E V13 from the Balkans may have been in the direction of the Adriatic Sea with the Neolithic Impressed Ware culture often referred to as Impressa or Cardial 35 rather propose that the main route of E V13 spread was along the Vardar Morava Danube river highway system In contrast to Battaglia Cruciani 51 tentatively suggested i a different point where the V13 mutation happened on its way from Egypt to the Balkans via the Middle East and ii a later dispersal time The authors proposed that the V13 mutation first appeared in western Asia where it is found in low but significant frequencies whence it entered the Balkans sometime after 11 kYa It later experienced a rapid dispersal which he dated to c 5300 years ago in Europe coinciding with the Balkan Bronze Age Like Pericic et al they consider that the dispersion of the E V13 and J M12 haplogroups seems to have mainly followed the river waterways connecting the southern Balkans to north central Europe More recently Lacan 52 announced that a 7000 year old skeleton in a Neolithic context in a Spanish funeral cave was an E V13 man The other specimens tested from the same site were in haplogroup G2a which has been found in Neolithic contexts throughout Europe Using 7 STR markers this specimen was identified as being similar to modern individuals tested in Albania Bosnia Greece Corsica and Provence The authors therefore proposed that whether or not the modern distribution of E V13 of today is a result of more recent events E V13 was already in Europe within the Neolithic carried by early farmers from the Eastern Mediterranean to the Western Mediterranean much earlier than the Bronze Age This supports the proposals of Battaglia et al rather than Cruciani et al at least concerning earliest European dispersals but E V13 may have dispersed more than once Even more recent than the Bronze Age it has also been proposed that modern E V13 s modern distribution in Europe is at least partly caused by Roman era movements of people 53 See below The migration of Neolithic farmers into Europe brought along several new adaptations 40 The variation for light skin colour was introduced to Europe by the neolithic farmers 40 After the arrival of the neolithic farmers a SLC22A4 mutation was selected for a mutation which probably arose to deal with ergothioneine deficiency but increases the risk of ulcerative colitis coeliac disease and irritable bowel syndrome Bronze Age Edit Further information Bronze Age Europe The Bronze Age saw the development of long distance trading networks particularly along the Atlantic Coast and in the Danube valley There was migration from Norway to Orkney and Shetland in this period and to a lesser extent to mainland Scotland and Ireland There was also migration from Germany to eastern England Martin Richards estimated that there was about 4 mtDNA immigration to Europe in the Bronze Age Scheme of Indo European migrations from ca 4000 to 1000 BC according to the Kurgan hypothesis Another theory about the origin of the Indo European language centres around a hypothetical Proto Indo European people who according to the Kurgan hypothesis can be traced to north of the Black and Caspian Seas at about 4500 BCE 54 They domesticated the horse and possibly invented the wooden disk wheel and are considered to have spread their culture and genes across Europe 55 The Y haplogroup R1a is a proposed marker of these Kurgan genes as is the Y Haplogroup R1b although these haplogroups as a whole may be much older than the language family 56 In the far north carriers of the Y haplogroup N arrived to Europe from Siberia eventually expanding as far as Finland though the specific timing of their arrival is uncertain The most common North European subclade N1c1 is estimated to be around 8 000 years old There is evidence of human settlement in Finland dating back to 8500 BCE linked with the Kunda culture and its putative ancestor the Swiderian culture but the latter is thought to have a European origin The geographical spread of haplogroup N in Europe is well aligned with the Pit Comb Ware culture whose emergence is commonly dated c 4200 BCE and with the distribution of Uralic languages Mitochondrial DNA studies of Sami people haplogroup U5 are consistent with multiple migrations to Scandinavia from Volga Ural region starting 6 000 to 7 000 years before present 57 The relationship between roles of European and Asian colonists in the prehistory of Finland is a point of some contention and some scholars insist that Finns are predominantly Eastern European and made up of people who trekked north from the Ukrainian refuge during the Ice Age 58 Farther east the issue is less contentious Haplogroup N carriers account for a significant part of all non Slavic ethnic groups in northern Russia including 37 of Karelians 35 of Komi people 65 according to another study 59 67 of Mari people as many as 98 of Nenets people 94 of Nganasans and 86 to 94 of Yakuts 60 The Yamnaya component contains partial ancestry from an Ancient North Eurasian component a Paleolithic Siberian lineage but closely related to European hunter gatherers first identified in Mal ta 61 62 According to Iosif Lazaridis the Ancient North Eurasian ancestry is proportionally the smallest component everywhere in Europe never more than 20 percent but we find it in nearly every European group we ve studied 63 This genetic component does not come directly from the Mal ta lineage itself but a related lineage that separated from the Mal ta lineage 17 Up to a half of the Yamnaya component may have come from a Caucasus hunter gatherer strand 61 On November 16 2015 in a study published in the journal Nature Communications 61 geneticists announced that they had found a new fourth ancestral tribe or strand which had contributed to the modern European gene pool They analysed genomes from two hunter gatherers from Georgia which were 13 300 and 9 700 years old and found that these Caucasus hunter gatherers were probably the source of the farmer like DNA in the Yamna According to co author Dr Andrea Manica of the University of Cambridge The question of where the Yamnaya come from has been something of a mystery up to now we can now answer that as we ve found that their genetic make up is a mix of Eastern European Hunter Gatherers and a population from this pocket of Caucasus hunter gatherers who weathered much of the last Ice Age in apparent isolation 64 According to Lazaridis et al 2016 a population related to the people of the Chalcolithic Iran contributed to roughly half of the ancestry of Yamnaya populations of the Pontic Caspian steppe These Iranian Chalcolithic people were a mixture of the Neolithic people of western Iran the Levant and Caucasus Hunter Gatherers 65 The genetic variations for lactase persistence and greater height came with the Yamnaya people 40 The derived allele of the KITLG gene SNP rs12821256 that is associated with and likely causal for blond hair in Europeans is found in populations with Eastern but not Western Hunter Gatherers ancestry suggesting that its origin is in the Ancient North Eurasian ANE population and may have been spread in Europe by individuals with steppe ancestry Consistent with this the earliest known individual with the derived allele is an ANE individual from the Late Upper Paleolithic Afontova Gora archaeological complex in central Siberia 66 Recent history Edit Further information History of Europe Further information Demography of the Roman Empire Migration period Viking expansion Slavic expansion Magyar migration Umayyad conquest of Hispania Turkic expansion African admixture in Europe Ottoman wars in Europe Ostsiedlung World War II evacuation and expulsion Population transfer in the Soviet Union and Immigration to Europe Overview map of recent 1st to 17th centuries AD admixture events in Europe 67 During the period of the Roman Empire historical sources show that there were many movements of people around Europe both within and outside the Empire Historic sources sometimes cite instances of genocide inflicted by the Romans upon rebellious provincial tribes If this did in fact occur it would have been limited given that modern populations show considerable genetic continuity in their respective regions citation needed The process of Romanisation appears to have been accomplished by the colonisation of provinces by a few Latin speaking administrators military personnel settled veterans and private citizens merchants traders who emanated from the Empire s various regions and not merely from Roman Italy They served as a nucleus for the acculturation of local notables 68 Given their small numbers and varied origins Romanization does not appear to have left distinct genetic signatures in Europe Indeed Romance speaking populations in the Balkans like Romanians Aromanians Moldovans etc have been found to genetically resemble neighbouring Greek and South Slavic speaking peoples rather than modern Italians 69 70 Steven Bird has speculated that E1b1b1a was spread during the Roman era through Thracian and Dacian populations from the Balkans into the rest of Europe 53 Concerning the late Roman period of not only Germanic Volkerwanderung some suggestions have been made at least for Britain with Y haplogroup I1a being associated with Anglo Saxon immigration in eastern England and R1a being associated with Norse immigration in northern Scotland 71 Genetics of modern European populations EditFurther information Ethnic groups in Europe Patrilineal studies Edit There are four main Y chromosome DNA haplogroups that account for most of Europe s patrilineal descent 28 Haplogroup R1b is common in Europe particularly in Western Europe with the R1b1a1a2 being the most common among Western Europeans 72 73 74 Nearly all of this R1b in Europe is in the form of the R1b1a2 2011 name R M269 sub clade specifically within the R L23 sub sub clade whereas R1b found in Central Asia western Asia and Africa tends to be in other clades It has also been pointed out that outlier types are present in Europe and are particularly notable in some areas such as Sardinia and Armenia 75 Haplogroup R1b frequencies vary from highs in western Europe in a steadily decreasing cline with growing distance from the Atlantic 80 90 Welsh Basque Irish Scots Bretons around 70 80 in Spain Britain and France and around 40 60 in parts of eastern Germany and northern Italy It drops outside this area and is around 30 or less in areas such as southern Italy Poland the Balkans and Cyprus R1b remains the most common clade as one moves east to Germany while farther east in Poland R1a is more common see below 76 In southeastern Europe R1b drops behind R1a in the area in and around Hungary and Serbia but is more common both to the south and north of this region 35 R1b in Western Europe is dominated by at least two sub clades R U106 which is distributed from the east side of the Rhine into northern and central Europe with a strong presence in England and R P312 which is most common west of the Rhine including the British Isles 73 74 Haplogroup R1a almost entirely in the R1a1a sub clade is prevalent in much of Eastern and Central Europe also in South and Central Asia For example there is a sharp increase in R1a1 and decrease in R1b1b2 as one goes east from Germany to Poland 76 It also has a substantial presence in Scandinavia particularly Norway 77 78 In the Baltic countries R1a frequencies decrease from Lithuania 45 to Estonia around 30 79 Haplogroup I is found in the form of various sub clades throughout Europe and is found at highest frequencies in the Nordic countries as I1 Norway Denmark Sweden Finland and in the Balkan Peninsula as I2a Bosnia and Herzegovina 65 59 Croatia and Serbia I1 is also frequent in Germany Great Britain and Netherlands while I2a is frequent also in Sardinia Romania Moldova Bulgaria and Ukraine This clade is found at its highest expression by far in Europe and may have been there since before the LGM 34 Haplogroup E1b1b formerly known as E3b was part of a migration of Neolithic farmers from the Middle East which carried E1b1b at low to medium frequency and was introduced into Neolithic Middle Easterners throughout genetic drift from a migration from Africa into the Middle East associated with the Afroasiatic languages It is believed to have first appeared in Northeast Africa approximately 26 000 years ago and dispersed to North Africa and the Near East during the late Paleolithic and Mesolithic periods E1b1b lineages are closely linked to the diffusion of Afroasiatic languages Although present throughout Europe it peaks in the western Balkan region amongst Albanians and their neighbors It is also common in Italy and the Iberian peninsula at lower frequency Haplogroup E1b1b1 mainly in the form of its E1b1b1a2 E V13 sub clade reaches frequencies above 47 around the area of Kosovo 35 This clade is thought to have arrived in Europe from western Asia either in the later Mesolithic 50 or the Neolithic 80 North Africa subclade E M81 is also present in Sicily and Andalusia Putting aside small enclaves there are also several haplogroups apart from the above four that are less prominent or most common only in certain areas of Europe Haplogroup G the original Neolithic Europeans Caucasians is common in most parts of Europe at a low frequency reaching peaks above 70 around Georgia and among the Madjars although living in Asia they border the eastern perimeter of Europe up to 10 in Sardinia 12 in Corsica and Uppsala Sweden 11 in the Balkans and Portugal 10 in Spain and 9 in European Russia This clade is also found in the Near East Haplogroup N is common only in the northeast of Europe and in the form of its N1c1 sub clade reaches frequencies of approximately 60 among Finns and approximately 40 among Estonians Latvians and Lithuanians Haplogroup J2 in various sub clades J2a J2b is found in levels of around 15 30 in the Balkans particularly Greece and Italy Haplogroup J2 is frequent in Western Asia and the Eastern Mediterranean 81 Matrilineal studies Edit There have been a number of studies about the mitochondrial DNA haplogroups mtDNA in Europe In contrast to Y DNA haplogroups mtDNA haplogroups did not show as much geographical patterning but were more evenly ubiquitous Apart from the outlying Saami all Europeans are characterised by the predominance of haplogroups H U and T The lack of observable geographic structuring of mtDNA may be due to socio cultural factors namely the phenomena of polygyny and patrilocality 47 Genetic studies suggest some maternal gene flow to eastern Europe from eastern Asia or southern Siberia 13 000 6 600 years BP 82 Analysis of Neolithic skeletons in the Great Hungarian Plain found a high frequency of eastern Asian mtDNA haplogroups some of which survive in modern eastern European populations 82 Maternal gene flow to Europe from sub Saharan Africa began as early as 11 000 years BP although the majority of lineages approximately 65 are estimated to have arrived more recently including during the Romanization period the Arab conquests of southern Europe and during the Atlantic slave trade 83 European population sub structure Edit Genetically Europe is relatively homogeneous but distinct sub population patterns of various types of genetic markers have been found 84 particularly along a southeast northwest cline 85 For example Cavalli Sforza s principal component analyses revealed five major clinal patterns throughout Europe and similar patterns have continued to be found in more recent studies 84 291 296 A cline of genes with highest frequencies in the Middle East spreading to lowest levels northwest Cavalli Sforza originally described this as faithfully reflecting the spread of agriculture in Neolithic times This has been the general tendency in interpretation of all genes with this pattern A cline of genes with highest frequencies among Finnish and Sami in the extreme north east and spreading to lowest frequencies in the south west A cline of genes with highest frequencies in the area of the lower Don and Volga rivers in southern Russia and spreading to lowest frequencies in Spain Southern Italy Greece and the areas inhabited by Saami speakers in the extreme north of Scandinavia Cavalli Sforza associated this with the spread of Indo European languages which he links in turn to a secondary expansion after the spread of agriculture associated with animal grazing A cline of genes with highest frequencies in the Balkans and Southern Italy spreading to lowest levels in Britain and the Basque country Cavalli Sforza associates this with the Greek expansion which reached its peak in historical times around 1000 and 500 BCE but which certainly began earlier A cline of genes with highest frequencies in the Basque country and lower levels beyond the area of Iberia and Southern France In perhaps the most well known conclusion from Cavalli Sforza this weakest of the five patterns was described as isolated remnants of the pre Neolithic population of Europe who at least partially withstood the expansion of the cultivators It corresponds roughly to the geographical spread of rhesus negative blood types In particular the conclusion that the Basques are a genetic isolate has become widely discussed but also a controversial conclusion He also created a phylogenetic tree to analyse the internal relationships among Europeans He found four major outliers Basques Sami Sardinians and Icelanders 86 a result he attributed to their relative isolation note the Icelanders and the Sardinians speak Indo European languages while the other two groups do not Greeks and Yugoslavs represented a second group of less extreme outliers The remaining populations clustered into several groups Celtic Germanic south western Europeans Scandinavians and eastern Europeans 84 268 A study in May 2009 87 of 19 populations from Europe using 270 000 SNPs highlighted the genetic diversity of European populations corresponding to the northwest to southeast gradient and distinguished four several distinct regions within Europe Finland showing the greatest distance to the rest of Europeans the Baltic region Estonia Latvia and Lithuania western Russia and eastern Poland Central and Western Europe Italy due to the alps acting as a great genetic barrier In this study barrier analysis revealed genetic barriers between Finland Italy and other countries and that barriers could also be demonstrated within Finland between Helsinki and Kuusamo and Italy between northern and southern part Fst 0 0050 Fst Fixation index was found to correlate considerably with geographic distances ranging from 0 0010 for neighbouring populations to 0 0200 0 0230 for Southern Italy and Finland For comparisons pair wise Fst of non European samples were as follows Europeans Africans Yoruba 0 1530 Europeans Chinese 0 1100 Africans Yoruba Chinese 0 1900 88 A study by Chao Tian in August 2009 extended the analysis of European population genetic structure to include additional southern European groups and Arab populations Palestinians Druzes from the Near East This study determined autosomal Fst between 18 population groups and concluded that in general genetic distances corresponded to geographical relationships with smaller values between population groups with origins in neighbouring countries regions for example Greeks Tuscans Fst 0 0010 Greeks Palestinians Fst 0 0057 compared with those from very different regions in Europe for example Greeks Swedish Fst 0 0087 Greeks Russians Fst 0 0108 89 Autosomal DNA Edit Seldin 2006 used over 5 000 autosomal SNPs It showed a consistent and reproducible distinction between northern and southern European population groups Most individual participants with southern European ancestry Italians Greeks Portuguese Spaniards and Ashkenazi Jews have gt 85 membership in the southern population and most northern western central and eastern Europeans Swedes English Irish Germans and Ukrainians have gt 90 in the northern population group Many of the participants in this study were American citizens who self identified with different European ethnicities based on self reported familial pedigree 90 A similar study in 2007 using samples predominantly from Europe found that the most important genetic differentiation in Europe occurs on a line from the north to the south east northern Europe to the Balkans with another east west axis of differentiation across Europe Its findings were consistent with earlier results based on mtDNA and Y chromosomal DNA that support the theory that modern Iberians Spanish and Portuguese hold the most ancient European genetic ancestry as well as separating Basques and Sami from other European populations 91 It suggested that the English and Irish cluster with other Northern and Eastern Europeans such as Germans and Poles while some Basque and Italian individuals also clustered with Northern Europeans Despite these stratifications it noted that there is low apparent diversity in Europe with the entire continent wide samples only marginally more dispersed than single population samples elsewhere in the world 91 In 2008 two international research teams published analyses of large scale genotyping of large samples of Europeans using over 300 000 autosomal SNPs With the exception of usual isolates such as Basques Finns and Sardinians the European population lacked sharp discontinuities clustering as previous studies have found see Seldin et al 2006 and Bauchet et al 2007 91 although there was a discernible south to north gradient Overall they found only a low level of genetic differentiation between subpopulations and differences which did exist were characterised by a strong continent wide correlation between geographic and genetic distance In addition they found that diversity was greatest in southern Europe due a larger effective population size and or population expansion from southern to northern Europe 85 The researchers take this observation to imply that genetically Europeans are not distributed into discrete populations 92 85 Two whole genome studies of the two Eastern European populations in Ukraine Ukrainians from Ukraine and Russia Russians from Russia showed genomic diversity from this region has not been represented in the previous genomic surveys as studies in Europe are mostly biased towards the populations in the western part of the continent 93 94 Within Russia Komi people that live in the north eastern part of the country and are part of the Uralic language family that also includes Finns form a pole of genetic diversity that is distinct from other populations and characterized by a higher European hunter gatherer WHG and Ancient North Eurasian ancestry 95 96 According to geneticist David Reich based on ancient human genomes that his laboratory sequenced in 2016 Europeans descend from a mixture of four West Eurasian ancestral components namely WHG Western Hunter gatherers EHG Eastern Hunter gatherers Neolithic farmers from the Levant Anatolia as well as from Neolithic farmers from Iran often summarized as EEF Early European farmers in varying degrees 97 98 Siberian geneflow is found among several Uralic speaking European ethnic groups This Siberian component is itself a composition of Ancient North Eurasian and East Asian related ancestry from Eastern Siberia maximized among Evenks and Evens or Nganasans The spread of this ancestry is linked by some geneticists to the dispersal of Uralic languages others however maintain that the Uralic languages spreaded prior to the arrival of Siberian geneflow which is a secondary source of diversity within Uralic speaking populations 99 100 Genetic data points to a Western Siberian hunter gatherer origin of the observed Siberian geneflow among Uralic speaking groups which are best represented by the modern Khanty Historical Western Siberian hunter gatherers were characterized by high Ancient North Eurasian ancestry and lower amounts of Eastern Siberian admixture Genetic data on Volga Tatars or Chuvash found among Western Turkic speakers like Chuvash and Volga Tatar the East Asian component was detected only in low amounts 5 101 102 East Asian ancestry is furthermore found at low frequency among other Europeans Germans and French people CEU 1 Britons GBR 2 5 3 8 Russians and Finns 13 associated with the Turco Mongol expansion 103 and higher among the Lipka Tatars a Turkic minority in Belarus 30 East Asian ancestry is suggested to have largely arrived indirectly through previous admixed historical Steppe nomads from Central Asia such as the Huns Pannonian Avars and the Golden Horde which got absorbed by the European majority population European related ancestry to East Asians was similarly contributed indirectly through Central Asian groups specifically into Northern Han Chinese 2 8 Southern Han Chinese 1 7 Japanese people 2 2 and Koreans 1 6 Northeast Asians had inherited significantly higher European related ancestry Mongolians 10 9 Oroqens 9 6 Daur people 8 and Hezhen 6 8 which also included earlier West Eurasian ancestry through Ancient North Eurasians representing the earliest layer within Siberia 104 105 106 Modern Europeans are genetically rather homogeneous and derive their ancestry predominantly to exclusively from up to five West Eurasian lineages in varying degrees Modern Europeans show affinity and continuity to ancient European hunter gatherers Western European Hunter Gatherers Scandinavian Hunter Gatherers and Eastern European Hunter Gatherers yet modern Europeans are significantly closer to Middle Easterners than ancient ones largely explained through the more recent Neolithic Expansion of farmers from Anatolia towards Europe Europeans compared to Middle Easterners have less basal ancestry ancestry inferred to have diverged before the diverging of Mesolithic European hunter gatherers and Ancient North Eurasians therefore representing deep substructure among West Eurasians which is inferred to have arrived with Early European farmers EEF Europeans contrary have higher Ancient North Eurasian affinity which is inferred to have arrived with Bronze and Iron Age migrations from Western Siberia Overall Europeans cluster closely together with Middle Eastern and South Central Asian populations followed by Northern African and South Asian populations while being most distant from Sub Saharan African specifically Central West African and Eastern Asian populations 107 Autosomal genetic distances Fst based on SNPs 2009 Edit The genetic distance between populations is often measured by Fixation index Fst based on genetic polymorphism data such as single nucleotide polymorphisms SNPs or microsatellites Fst is a special case of F statistics the concept developed in the 1920s by Sewall Wright Fst is simply the correlation of randomly chosen alleles within the same sub population relative to that found in the entire population It is often expressed as the proportion of genetic diversity due to allele frequency differences among populations The values range from 0 to 1 A zero value implies that the two populations are panmictic that they are interbreeding freely A value of one would imply that the two populations are completely separate The greater the Fst value the greater the genetic distance Essentially these low Fst values suggest that the majority of genetic variation is at the level of individuals within the same population group 85 whilst belonging to a different population group within same race continent and even to different racial continental groups added a much smaller degree of variation 3 8 6 11 respectively Intra European Mediterranean Autosomal genetic distances Fst based on 3 500 SNPs using the Weir and Cockerham algorithm 89 Italian Americans Palestinians Swedes Druzes Spaniards Germans Russians Irish Greek Americans Ashkenazi Jews CircassiansItalian Americans 0 0064 0 0064 0 0057 0 0010 0 0029 0 0088 0 0048 0 0000 0 0040 0 0067Palestinians 0 0064 0 0191 0 0064 0 0101 0 0136 0 0202 0 0170 0 0057 0 0093 0 0108Swedes 0 0064 0 0191 0 0167 0 0040 0 0007 0 0030 0 0020 0 0084 0 0120 0 0117Druzes 0 0057 0 0064 0 0167 0 0096 0 0121 0 0194 0 0154 0 0052 0 0088 0 0092Spaniards 0 0010 0 0101 0 0040 0 0096 0 0015 0 0070 0 0037 0 0035 0 0056 0 0090Germans 0 0029 0 0136 0 0007 0 0121 0 0015 0 0030 0 0010 0 0039 0 0072 0 0089Russians 0 0088 0 0202 0 0030 0 0194 0 0070 0 0030 0 0038 0 0108 0 0137 0 0120Irish 0 0048 0 0170 0 0020 0 0154 0 0037 0 0010 0 0038 0 0067 0 0109 0 0110Greek Americans 0 0000 0 0057 0 0084 0 0052 0 0035 0 0039 0 0108 0 0067 0 0042 0 0054Ashkenazi Jews 0 0040 0 0093 0 0120 0 0088 0 0056 0 0072 0 0137 0 0109 0 0042 0 0107Circassians 0 0067 0 0108 0 0117 0 0092 0 0090 0 0089 0 0120 0 0110 0 0054 0 0107European Population Genetic Substructure based on SNPs 108 1 Austria Bulgaria Czech Republic Estonia Finland Helsinki Finland Kuusamo France Northern Germany Southern Germany Hungary Northern Italy Southern Italy Latvia Lithuania Poland Russia Spain Sweden Switzerland CEUAustria 1 14 1 08 1 58 2 24 3 30 1 16 1 10 1 04 1 04 1 49 1 79 1 85 1 70 1 19 1 47 1 41 1 21 1 19 1 12 AustriaBulgaria 1 14 1 21 1 70 2 19 2 91 1 22 1 32 1 19 1 10 1 32 1 38 1 86 1 73 1 29 1 53 1 30 1 47 1 13 1 29 BulgariaCzech Republic 1 08 1 21 1 42 2 20 3 26 1 35 1 15 1 16 1 06 1 69 2 04 1 62 1 48 1 09 1 27 1 63 1 26 1 37 1 21 Czech RepublicEstonia 1 58 1 70 1 42 1 71 2 80 2 08 1 53 1 70 1 41 2 42 2 93 1 24 1 28 1 17 1 21 2 54 1 49 2 16 1 59 EstoniaFinland Helsinki 2 24 2 19 2 20 1 71 1 86 2 69 2 17 2 35 1 87 2 82 3 37 2 31 2 33 1 75 2 10 3 14 1 89 2 77 1 99 Finland Helsinki Finland Kuusamo 3 30 2 91 3 26 2 80 1 86 3 72 3 27 3 46 2 68 3 64 4 18 3 33 3 37 2 49 3 16 4 21 2 87 3 83 2 89 Finland Kuusamo France 1 16 1 22 1 35 2 08 2 69 3 72 1 25 1 12 1 16 1 38 1 68 2 40 2 20 1 44 1 94 1 13 1 38 1 10 1 13 FranceNorthern Germany 1 10 1 32 1 15 1 53 2 17 3 27 1 25 1 08 1 11 1 72 2 14 1 84 1 66 1 18 1 49 1 62 1 12 1 36 1 06 Northern GermanySouthern Germany 1 04 1 19 1 16 1 70 2 35 3 46 1 12 1 08 1 08 1 53 1 85 1 20 1 84 1 23 1 58 1 40 1 21 1 17 1 07 Southern GermanyHungary 1 04 1 10 1 06 1 41 1 87 2 68 1 16 1 11 1 08 1 42 1 63 1 58 1 46 1 14 1 28 1 32 1 22 1 16 1 13 HungaryNorthern Italy 1 49 1 32 1 69 2 42 2 82 3 64 1 38 1 72 1 53 1 42 1 54 2 64 2 48 1 75 2 24 1 42 1 86 1 36 1 56 Northern ItalySouthern Italy 1 79 1 38 2 04 2 93 3 37 4 18 1 68 2 14 1 85 1 63 1 54 3 14 2 96 1 99 2 68 1 67 2 28 1 54 1 84 Southern ItalyLatvia 1 85 1 86 1 62 1 24 2 31 3 33 2 40 1 84 1 20 1 58 2 64 3 14 1 20 1 26 1 84 2 82 1 89 2 52 1 87 LatviaLithuania 1 70 1 73 1 48 1 28 2 33 3 37 2 20 1 66 1 84 1 46 2 48 2 96 1 20 1 20 1 26 2 62 1 74 2 29 1 74 LithuaniaPoland 1 19 1 29 1 09 1 17 1 75 2 49 1 44 1 18 1 23 1 14 1 75 1 99 1 26 1 20 1 18 1 66 1 30 1 46 1 28 PolandRussia 1 47 1 53 1 27 1 21 2 10 3 16 1 94 1 49 1 58 1 28 2 24 2 68 1 84 1 26 1 18 2 32 1 59 1 20 1 56 RussiaSpain 1 41 1 30 1 63 2 54 3 14 4 21 1 13 1 62 1 40 1 32 1 42 1 67 2 82 2 62 1 66 2 32 1 73 1 16 1 34 SpainSweden 1 21 1 47 1 26 1 49 1 89 2 87 1 38 1 12 1 21 1 22 1 86 2 28 1 89 1 74 1 30 1 59 1 73 1 50 1 09 SwedenSwitzerland 1 19 1 13 1 37 2 16 2 77 3 83 1 10 1 36 1 17 1 16 1 36 1 54 2 52 2 29 1 46 1 20 1 16 1 50 1 21 SwitzerlandCEU 1 12 1 29 1 21 1 59 1 99 2 89 1 13 1 06 1 07 1 13 1 56 1 84 1 87 1 74 1 28 1 56 1 34 1 09 1 21 CEUAustria Bulgaria Czech Republic Estonia Finland Helsinki Finland Kuusamo France Northern Germany Southern Germany Hungary Northern Italy Southern Italy Latvia Lithuania Poland Russia Spain Sweden Switzerland CEUCEU Utah residents with ancestry from Northern and Western Europe History of research EditFurther information Population genetics Classical genetic markers by proxy Edit One of the first scholars to perform genetic studies was Luigi Luca Cavalli Sforza He used classical genetic markers to analyse DNA by proxy This method studies differences in the frequencies of particular allelic traits namely polymorphisms from proteins found within human blood such as the ABO blood groups Rhesus blood antigens HLA loci immunoglobulins G6PD isoenzymes among others Subsequently his team calculated genetic distance between populations based on the principle that two populations that share similar frequencies of a trait are more closely related than populations that have more divergent frequencies of the trait 84 51 From this he constructed phylogenetic trees that showed genetic distances diagrammatically His team also performed principal component analyses which is good at analysing multivariate data with minimal loss of information The information that is lost can be partly restored by generating a second principal component and so on 84 39 In turn the information from each individual principal component PC can be presented graphically in synthetic maps These maps show peaks and troughs which represent populations whose gene frequencies take extreme values compared to others in the studied area 84 51 Peaks and troughs usually connected by smooth gradients are called clines Genetic clines can be generated by adaptation to environment natural selection continuous gene flow between two initially different populations or a demographic expansion into a scarcely populated environment with little initial admixture with existing populations 109 390 Cavalli Sforza connected these gradients with postulated pre historic population movements based on archaeological and linguistic theories However given that the time depths of such patterns are not known associating them with particular demographic events is usually speculative 47 Direct DNA analysis Edit Further information Genetic drift Founder effect and Population bottleneck Studies using direct DNA analysis are now abundant and may use mitochondrial DNA mtDNA the non recombining portion of the Y chromosome NRY or even autosomal DNA MtDNA and NRY DNA share some similar features which have made them particularly useful in genetic anthropology These properties include the direct unaltered inheritance of mtDNA and NRY DNA from mother to offspring and father to son respectively without the scrambling effects of genetic recombination We also presume that these genetic loci are not affected by natural selection and that the major process responsible for changes in base pairs has been mutation which can be calculated 27 58 The smaller effective population size of the NRY and mtDNA enhances the consequences of drift and founder effect relative to the autosomes making NRY and mtDNA variation a potentially sensitive index of population composition 47 31 28 These biologically plausible assumptions are not concrete Rosser suggests that climatic conditions may affect the fertility of certain lineages 47 The underlying mutation rate used by the geneticists is more questionable They often use different mutation rates and studies frequently arrive at vastly different conclusions 47 NRY and mtDNA may be so susceptible to drift that some ancient patterns may have become obscured Another assumption is that population genealogies are approximated by allele genealogies Guido Barbujani points out that this only holds if population groups develop from a genetically monomorphic set of founders Barbujani argues that there is no reason to believe that Europe was colonised by monomorphic populations This would result in an overestimation of haplogroup age thus falsely extending the demographic history of Europe into the Late Paleolithic rather than the Neolithic era 110 Greater certainty about chronology may be obtained from studies of ancient DNA see below but so far these have been comparatively few Whereas Y DNA and mtDNA haplogroups represent but a small component of a person s DNA pool autosomal DNA has the advantage of containing hundreds of thousands of examinable genetic loci thus giving a more complete picture of genetic composition Descent relationships can only be determined on a statistical basis because autosomal DNA undergoes recombination A single chromosome can record a history for each gene Autosomal studies are much more reliable for showing the relationships between existing populations but do not offer the possibilities for unravelling their histories in the same way as mtDNA and NRY DNA studies promise despite their many complications Genetic studies operate on numerous assumptions and suffer from methodological limitations such as selection bias and confounding phenomena like genetic drift foundation and bottleneck effects cause large errors particularly in haplogroup studies No matter how accurate the methodology conclusions derived from such studies are compiled on the basis of how the author envisages their data fits with established archaeological or linguistic theories citation needed See also Edit Europe portal Evolutionary biology portal History portalGeneralArchaeogenetics Ethnic groups in Europe European studies Genetic history of North Africa Genetic history of the Middle East Genetics and archaeogenetics of South Asia History of Europe Human genetic variation Y DNA haplogroups in populations of Europe Romani people Genetic evidenceGenetics by European groupGenetic history of Italy Genetic history of the British Isles Genetic history of the Iberian Peninsula Genetic studies on Bosniaks Genetic studies on Bulgarians Genetic studies on Croats Genetic studies on Jews Genetic studies on Russians Genetic studies on Sami Genetic studies on Serbs Genetic studies on Turkish peopleReferences EditInline citations Edit a b Nelis M Esko T Magi R Zimprich F Zimprich A Toncheva D et al 2009 Genetic structure of Europeans a view from the North East PLOS ONE 4 5 e5472 Bibcode 2009PLoSO 4 5472N doi 10 1371 journal pone 0005472 PMC 2675054 PMID 19424496 a b Seguin Orlando A Korneliussen TS Sikora M Malaspinas AS Manica A Moltke I et al November 2014 Paleogenomics Genomic structure in Europeans dating back at least 36 200 years Science 346 6213 1113 1118 Bibcode 2014Sci 346 1113S doi 10 1126 science aaa0114 PMID 25378462 S2CID 206632421 Posth C Renaud G Mittnik A Drucker DG Rougier H Cupillard C et al March 2016 Pleistocene Mitochondrial Genomes Suggest a Single Major Dispersal of Non Africans and a Late Glacial Population 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Mittnik Alissa Banffy Eszter Economou Christos Francken Michael 2015 Massive migration from the steppe was a source for Indo European languages in Europe Nature 522 7555 207 211 doi 10 1038 nature14317 ISSN 1476 4687 PMC 5048219 PMID 25731166 Lazaridis I Patterson N Mittnik A Renaud G Mallick S Kirsanow K et al September 2014 Ancient human genomes suggest three ancestral populations for present day Europeans Nature 513 7518 409 413 arXiv 1312 6639 Bibcode 2014Natur 513 409L doi 10 1038 nature13673 PMC 4170574 PMID 25230663 Since Lazaridis et al 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 EEF WHG 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 BCE rather than a single admixture event on initial contact Lipson M Szecsenyi Nagy A Mallick S Posa A Stegmar B Keerl V et al November 2017 Parallel palaeogenomic transects reveal complex genetic history of early European farmers Nature 551 7680 368 372 Bibcode 2017Natur 551 368L doi 10 1038 nature24476 PMC 5973800 PMID 29144465 There s no such thing as a pure European or anyone else Science AAAS May 15 2017 Curry A 2019 Genetic testing reveals that Europe is a melting pot made of immigrants National Geographic Lipson et al 2017 Fig 2 Dutchen S November 23 2015 Farming s in Their DNA Harvard Medical School Retrieved 25 November 2015 a b c d e f g h i j k l m Fu Q Posth C Hajdinjak M Petr M Mallick S Fernandes D et al June 2016 The genetic history of Ice Age Europe Nature 534 7606 200 205 Bibcode 2016Natur 534 200F doi 10 1038 nature17993 PMC 4943878 PMID 27135931 Even before the advent of genetic studies some anthropologists believed they had discovered skeletons representing Neanderthal modern human hybrids These results were deemed ambiguous Archaeological evidence points to an abrupt change from Neanderthal artefacts to those related to AMH during the Upper Palaeolithic Klein RG March 2003 Paleoanthropology Whither the Neanderthals Science 299 5612 1525 1527 doi 10 1126 science 1082025 PMID 12624250 S2CID 161836323 Prufer K Racimo F Patterson N Jay F Sankararaman S Sawyer S et al January 2014 Online 2013 The complete genome sequence of a Neanderthal from the Altai Mountains Nature 505 7481 43 49 Bibcode 2014Natur 505 43P doi 10 1038 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2023 Pages 32 46 e19 doi 10 1016 j cell 2022 11 024 Skourtanioti E Ringbauer H Gnecchi Ruscone G A et al Ancient DNA reveals admixture history and endogamy in the prehistoric Aegean In Nature Ecology amp Evolution 2023 https doi org 10 1038 s41559 022 01952 3External links Edit Wikimedia Commons has media related to Genetic studies on European populations A genetic atlas of human admixture history 2014 Retrieved from https en wikipedia org w index php title Genetic history of Europe amp oldid 1136121363, wikipedia, wiki, book, books, library,

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