Haplogroup R-M269 is the sub-clade of human Y-chromosome haplogroup R1b that is defined by the SNP marker M269. According to ISOGG 2020 it is phylogenetically classified as R1b1a1b. It underwent intensive research and was previously classified as R1b1a2 (2003 to 2005), R1b1c (2005 to 2008), R1b1b2 (2008 to 2011) and R1b1a1a2 (2011 to 2020).[6]

Haplogroup R-M269
Projected spatial frequency distribution for haplogroup R-M269 in Europe.[1]
Possible time of origin4,000–10,000 BP[2][3]
Possible place of originEastern Europe, associated with Indo-European migrations[4][5]
AncestorR1b1a1a (R-P297)
DescendantsL23; L51/M412, L151/P310; Z2103
Defining mutationsM269

R-M269 is of particular interest for the genetic history of Western Europe, being the most common European haplogroup. It increases in frequency on an east to west gradient (its prevalence in Poland estimated at 22.7%, compared to Wales at 92.3%). It is carried by approximately 110 million European men (2010 estimate).[3] The age of the mutation M269 is estimated at 4,000 to 10,000 years ago.[2][3]

Origin

edit

R-M269 had formerly been dated to the Upper Paleolithic,[7] but by about 2010 it was thought to have formed near the beginning of the Neolithic Revolution, about 10,000 years ago.[8][9][10] More recent archaeogenetics studies since 2015, however, strongly suggest an origin among Eneolithic hunter-gatherers from eastern Europe.[4][11]

Balaresque et al. (2010) based on the pattern of Y-STR diversity argued for a single source in the Near East and introduction to Europe via Anatolia in the Neolithic Revolution. In this scenario, Mesolithic hunter-gatherers in Europe would have been nearly replaced by the incoming farmers. By contrast, Busby et al. (2012) could not confirm the results of Balaresque et al. (2010) and could not make credible estimates of the age of R-M269 based on Y-STR diversity.[3][12] Furthermore, more recent studies have found that the Y-DNA of Early European Farmers is typically haplogroup G2a.[13]

According to a 2015 study,[4] a hunter-gatherer from Samara (dated 5640-5555 cal BCE) belonging to haplogroup R1b1(*) was ancestral for both haplogroups R-M269 and R-M478. According to the authors, the occurrence of basal forms of R1b in eastern European hunter-gatherers provides a "geographically plausible source" for haplogroup R-M269. Subclades of R-M269, such as R-Z2103, have been found to be prevalent in ancient DNA found in individuals associated with the Yamnaya culture and related populations,[4][14] and the dispersal of this haplogroup is associated with the spread of so-called "steppe ancestry" and at least some of the Indo-European languages.[4][15]

According to Lazaridis et al. (2022), "the most likely hypothesis" is that the entire R-M269 clade originated "in the North Caucasus and steppe to the north".[16]

The subclade R-P311 is substantially confined to Western Europe in modern populations. R-P311 is absent from Neolithic-era ancient DNA found in Western Europe, strongly suggesting that its current distribution is due to population movements within Europe taking place after the end of the Neolithic. The three major subclades of P311 are U106 (S21), L21 (M529, S145), and U152 (S28). These show a clear articulation within Western Europe, with centers in the Low Countries, the British Isles and the Alps, respectively.[17] These lineages are associated with the non-Iberian steppe-related groups of the Bell Beaker culture, and demonstrate the relationship between steppe-related ancestry and R1b-M269 subclades,[14] which are "the major lineage associated with the arrival of Steppe ancestry in western Europe after 2500 BC".[18]

Distribution

edit

European R1b is dominated by R-M269. It has been found at generally low frequencies throughout central Eurasia,[19] but with relatively high frequency among the Bashkirs of the Perm region (84.0%) and Baymaksky District (81.0%).[20] This marker is present in China and India at frequencies of less than one percent. The table below lists in more detail the frequencies of M269 in regions in Asia, Europe, and Africa.

Distribution of R-M269 in Europe increases in frequency from east to west. It peaks at the national level in Wales at a rate of 92%, at 82% in Ireland, 70% in Scotland, 68% in Spain, 60% in France (76% in Normandy), about 60% in Portugal,[21] 50% in Germany, 50% in the Netherlands, 47% in Italy,[22] 45% in Eastern England, 43% in Denmark and 42% in Iceland. It is as high as 95% in parts of Ireland. It is also found in some areas of North Africa, where its frequency peaks at 10% in some parts of Algeria.[23] M269 has likewise been observed among 8% of the Herero in Namibia.[24] The R-M269 subclade has been found in ancient Guanche (Bimbapes) fossils excavated in Punta Azul, El Hierro, Canary Islands, which are dated to the 10th century (~44%).[25] In western Asia, R-M269 has been reported in 29.2% of Assyrian males from Iran.[26] Haplogroup R1b1 and its subclades in Asia.[27] M269* (xL23) is found at highest frequency in the central Balkans notably Kosovo with 7.9%, North Macedonia 5.1% and Serbia 4.4%.[21] Kosovo is notable in having a high percentage of descendant L23* or L23(xM412) at 11.4% unlike most other areas with significant percentages of M269* and L23* except for Poland with 2.4% and 9.5% and the Bashkirs of southeast Bashkortostan with 2.4% and 32.2% respectively.[21] Notably this Bashkir population also has a high percentage of M269 sister branch M73 at 23.4%.[21] Five individuals out of 110 tested in the Ararat Valley, Armenia belonged to R1b1a2* and 36 to L23*, with none belonging to known subclades of L23.[28] Trofimova et al. (2015) found a surprising high frequency of R1b-L23 (Z2105/2103) among the peoples of the Idel-Ural. 21 out of 58 (36.2%) of Burzyansky District Bashkirs, 11 out of 52 (21.2%) of Udmurts, 4 out of 50 (8%) of Komi, 4 out of 59 (6.8%) of Mordvins, 2 out of 53 (3.8%) of Besermyan and 1 out of 43 (2.3%) of Chuvash were R1b-L23 (Z2105/2103),[29] the type of R1b found in the recently analyzed Yamna remains of the Samara Oblast and Orenburg Oblast.[30]

Especially Western European R1b is dominated by specific sub-clades of R-M269 (with some small amounts of other types found in areas such as Sardinia[21][31]). Within Europe, R-M269 is dominated by R-M412, also known as R-L51, which according to Myres et al. (2010) is "virtually absent in the Near East, the Caucasus and West Asia." This Western European population is further divided between R-P312/S116 and R-U106/S21, which appear to spread from the western and eastern Rhine river basin respectively. Myres et al. note further that concerning its closest relatives, in R-L23*, it is "instructive" that these are often more than 10% of the population in the Caucasus, Turkey, and some southeast European and circum-Uralic populations.

In Western Europe it is present but in generally much lower levels apart from "an instance of 27% in Switzerland's Upper Rhone Valley."[21] In addition, the sub-clade distribution map, Figure 1h titled "L11(xU106,S116)", in Myres et al. shows that R-P310/L11* (or as yet undefined subclades of R-P310/L11) occurs only in frequencies greater than 10% in Central England with surrounding areas of England and Wales having lower frequencies.[21] This R-P310/L11* is almost non-existent in the rest of Eurasia and North Africa with the exception of coastal lands fringing the western and southern Baltic (reaching 10% in Eastern Denmark and 6% in northern Poland) and in Eastern Switzerland and surrounds.[21]

M269 (R1b1a1a2)[32]

R-M269*

L23 (R1b1a1a2a)

R-L23*: Caucasus, Turkey, circum-Uralic; Upper Rhone Valley

L51/M412 (R1b1a1a2a1)

R-L51*/R-M412*: Central France

L151/P310/P311 (R1b1a1a2a1a)

R-P310/L11*: Central England

U106 (R1b1a1a2a1a1)

R-U106: Netherlands, England, Norway; Germanic Europe

P312/S116 (R1b1a1a2a1a2)

S116*: Iberian Peninsula

U152 (R1b1a1a2a1a2b)

U152: Corsica, Sardinia; Northern Italy, Central Italy, Switzerland, Central France, Russia (Perm region, Ghaeynae bashkirs)

L21_M529_S145 (R1b1a1a2a1a2c1)

M529: Brittany, Ireland, Scotland, Wales

CTS4528 (R1b1a1a2a1a3a)

R-CTS4528

Z2103 (R1b1a1a2a2)

Z2103: Balkans and Turkey, Samara (Russia, Yamnaya a.c.), South Ural (burjan bashkirs)

In 2009, DNA extracted from the femur bones of 6 skeletons in an early-medieval burial place in Ergolding (Bavaria, Germany) dated to around c. 670 yielded the following results: 4 were found to be haplogroup R1b with the closest matches in modern populations of Germany, Ireland and the USA while 2 were in Haplogroup G2a.[33]

Population studies which test for M269 have become more common in recent years, while in earlier studies men in this haplogroup are only visible in the data by extrapolation of what is likely. The following gives a summary of most of the studies which specifically tested for M269, showing its distribution (as a percentage of total population) in Europe, North Africa, the Middle East and Central Asia as far as China and Nepal.

Country Sampling sample R-M269 Source
Wales National 65 92.3% Balaresque et al. (2009)[3]
Spain Basques 116 87.1% Balaresque et al. (2009)[3]
Ireland National 796 85.4% Moore et al. (2006)[34]
Spain Catalonia 80 81.3% Balaresque et al. (2009)[3]
Italy Lombardy 78 80.8% Grugni et al.[22]
France Ille-et-Vilaine 82 80.5% Balaresque et al. (2009)[3]
France Haute-Garonne 57 78.9% Balaresque et al. (2009)[3]
England Cornwall 64 78.1% Balaresque et al. (2009)[3]
France Loire-Atlantique 48 77.1% Balaresque et al. (2009)[3]
Italy Tuscany 42 76.2% Di Giacomo et al. (2003)[35]
France Finistère 75 76.0% Balaresque et al. (2009)[3]
France Basques 61 75.4% Balaresque et al. (2009)[3]
Italy North East 30 73.5% Di Giacomo et al. (2003)[35]
Spain East Andalucia 95 72.0% Balaresque et al. (2009)[3]
Spain Castilla La Mancha 63 72.0% Balaresque et al. (2009)[3]
France Vendée 50 68.0% Balaresque et al. (2009)[3]
Dominican Republic National 26 65.4% Bryc et al. (2010)[36]
France Baie de Somme 43 62.8% Balaresque et al. (2009)[3]
England Leicestershire 43 62.0% Balaresque et al. (2009)[3]
Italy North-East (Ladin) 79 60.8% Balaresque et al. (2009)[3]
Portugal National 657 59.9% Beleza et al. (2006)[37]
Italy Emilia 29 58.5% Boattini et al. (2013)[38]
Spain Galicia 88 58.0% Balaresque et al. (2009)[3]
Spain West Andalucia 72 55.0% Balaresque et al. (2009)[3]
Portugal South 78 46.2% Balaresque et al. (2009)[3]
Italy North-West 99 45.0% Balaresque et al. (2009)[3]
Denmark National 56 42.9% Balaresque et al. (2009)[3]
Netherlands National 84 42.0% Balaresque et al. (2009)[3]
Armenia Ararat Valley 41 37.3% Herrera et al. (2012)[28]
Russia Bashkirs 471 34.40% Lobov (2009)[20]
Italy East Sicily 246 34.14% Tofanelli et al. (2015)[39]
Italy West Sicily 68 33.0% Tofanelli et al. (2015)[39]
Germany Bavaria 80 32.3% Balaresque et al. (2009)[3]
Turkey Lake Van Armenians 33 32.0% Herrera et al. (2012) [28]
Armenia Gardman 30 31.3% Herrera et al. (2012) [28]
Iran Assyrians 48 29.2% Grugni,Viola et al. (2012)[26]
Poland National 110 22.7% Myres et al. (2007)[40]
Slovenia National 75 21.3% Battaglia et al. (2008)[41]
Kosovo Albanians National 114 21.1% Pericic2005[42]
Slovenia National 70 20.6% Balaresque et al. (2009)[3]
Turkey Central 152 19.1% Cinnioğlu et al. (2004)[43]
Albanians in North Macedonia National 64 18.8% Battaglia et al. (2008)[41]
Albanians National 55 18.2% Battaglia et al. (2008)[41]
Crete National 193 17.0% King et al. (2008)[44]
Italy Sardinia 930 17.0% Contu et al. (2008)[45]
Turkey Sasun Armenians 16 15.4% Herrera et al. (2012) [28]
Iran North 33 15.2% Regueiro et al. (2006)[46]
Moldova 268 14.6% Varzari (2006)[47]
Greece National 171 13.5% King et al. (2008)[44]
Turkey West 163 13.5% Cinnioğlu et al. (2004)[43]
Romania National 54 13.0% Varzari (2006)[47]
Croatia National 89 12.4% Battaglia et al. (2008)[41]
Turkey East 208 12.0% Cinnioğlu et al. (2004)[43]
Algeria Northwest (Oran area) 102 11.8% Robino et al. (2008)[48]
Russia Roslavl (Smolensk Oblast) 107 11.2% Balanovsky et al. (2008)[49]
Iraq National 139 10.8% Al-Zahery et al. (2003)[50]
Nepal Newar 66 10.6% Gayden et al. (2007)[51]
Bulgaria National 808 10.5% Karachanak et al. (2013)[52]
Serbia National 100 10.0% Belaresque et al. (2009)[3]
Lebanon National 914 7.3% Zalloua et al. (2008)[53]
Tunisia National 601 0.3% Bekada et al. (2013)[54]
Tunisia Tunis 139 7.2% Adams et al. (2008)[55]
Morocco National 760 3.5% Bekada et al. (2013)[54]
Libya National 83 0.0% Bekada et al. (2013)[54]
Egypt National 360 2.9% Bekada et al. (2013)[54]
Algeria National 156 7.0% Bekada et al. (2013)[54]
Algeria Algiers, Tizi Ouzou 46 6.5% Adams et al. (2008)[55]
Bosnia-Herzegovina Serbs 81 6.2% Marjanovic et al. (2005)[56]
Iran South 117 6.0% Regueiro et al. (2006)[46]
Russia Repyevka (Voronezh Oblast) 96 5.2% Balanovsky et al. (2008)[49]
UAE 164 3.7% Cadenas et al. (2007)[57]
Bosnia-Herzegovina Bosniaks 85 3.5% Marjanovic et al. (2005)[56]
Pakistan 176 2.8% Sengupta et al. (2006)[58]
Russia Belgorod 143 2.8% Balanovsky et al. (2008)[49]
Russia Ostrov (Pskov Oblast) 75 2.7% Balanovsky et al. (2008)[49]
Russia Pristen (Kursk Oblast) 45 2.2% Balanovsky et al. (2008)[49]
Bosnia-Herzegovina Croats 90 2.2% Marjanovic et al. (2005)[56]
Qatar 72 1.4% Cadenas et al. (2007)[57]
China 128 0.8% Sengupta et al. (2006)[58]
India various 728 0.5% Sengupta et al. (2006)[58]
Croatia Osijek 29 0.0% Battaglia et al. (2008)[41]
Yemen 62 0.0% Cadenas et al. (2007)[57]
Tibet 156 0.0% Gayden et al. (2007)[51]
Nepal Tamang 45 0.0% Gayden et al. (2007)[51]
Nepal Kathmandu 77 0.0% Gayden et al. (2007)[51]
Japan 23 0.0% Sengupta et al. (2006)[58]

Sub-clades

edit

R1b1a1a2a (R-L23)

edit

R-L23* (R1b1a1a2a*) is now most commonly found in Europe, Anatolia, the Caucasus.

R1b1a1a2a1 (R-L51)

edit

R-L51* (R1b1a1a2a1*) is now concentrated in a geographical cluster centred on southern France and northern Italy.

R1b1a1a2a1a (R-L151)

edit

R-L151 (L151/PF6542, CTS7650/FGC44/PF6544/S1164, L11, L52/PF6541, P310/PF6546/S129, P311/PF6545/S128) also known as R1b1a1a2a1, and its subclades, include most males with R1b in Western Europe.

R1b1a1a2a1a1 (R-U106)

edit

This subclade is defined by the presence of the SNP U106, also known as S21 and M405.[8][59] It appears to represent over 25% of R1b in Europe.[8] In terms of percentage of total population, its epicenter is Friesland, where it makes up 44% of the population.[60] In terms of total population numbers, its epicenter is Central Europe, where it comprises 60% of R1 combined.[60] See also Haplogroup R-Z18

U106/S21/M405
un‑defined

R-U106* (R-U106-*)

FGC3861

R-FGC3861 (R1b1a2a1a1a)

Z18

R-Z18 (R1b1a2a1a1b)

Z381
S264

R-S264 (R1b1a2a1a1c1)

S499

R-S499 (R1b1a2a1a1c2)

M1994

R-M1994 (R1b1a2a1a1c3)

FGC396

R-FGC396 (R1b1a2a1a1d)

S12025

R-S12025 (R1b1a2a1a1e)

While this sub-clade of R1b is frequently discussed amongst genetic genealogists, the following table represents the peer-reviewed findings published so far in the 2007 articles of Myres et al. and Sims et al.[40][59]

Population Sample size R-M269 R-U106 R-U106-1
Austria[40] 22 27% 23% 0.0%
Central/South America[40] 33 0.0% 0.0% 0.0%
Czech Republic[40] 36 28% 14% 0.0%
Denmark[40] 113 34% 17% 0.9%
Eastern Europe[40] 44 5% 0.0% 0.0%
England[40] 138 57% 20% 1.4%
France[40] 56 52% 7% 0.0%
Germany[40] 332 43% 19% 1.8%
Ireland[40] 102 80% 6% 0.0%
Italy[21] 34 53% 6% 0.0%
Jordan[40] 76 0.0% 0.0% 0.0%
Middle-East[40] 43 0.0% 0.0% 0.0%
Netherlands[40] 94 54% 35% 2.1%
Oceania[40] 43 0.0% 0.0% 0.0%
Oman[40] 29 0.0% 0.0% 0.0%
Pakistan[40] 177 3% 0.0% 0.0%
Palestine[40] 47 0.0% 0.0% 0.0%
Poland[40] 110 23% 8% 0.0%
Russia[40] 56 21% 5.4% 1.8%
Slovenia[40] 105 17% 4% 0.0%
Switzerland[40] 90 58% 13% 0.0%
Turkey[40] 523 14% 0.4% 0.0%
Ukraine[40] 32 25% 9% 0.0%
United States (European)[59] 125 46% 15% 0.8%
United States (Afroamerican)[59] 118 14% 2.5% 0.8%

R-P312

edit

R1b1a1a2a1a2, better known as R-P312 (or R-S116) is one of the most common types of R-M269 in Europe, alongside R-U106. Myres et al. described it as originating in and spreading from the west of the Rhine basin.[21]

R-P312 has been the subject of significant, ongoing study concerning its complex internal structure.

P312

R-P312*

DF27

R-S227/Z196

R-Z2552

R-L881

R-A431

U152

R-L2

R-S206

R-Z56

L21

R-A7905

R-A5846

R-DF63 (R-S522)

R-DF13 (R-CTS241/R-S521)

R-L238

R-DF19

R-DF99

R-DF27

edit

R-M153

R-M153 is a subclade of R-DF27 that has been found mostly in Basques and Gascons, among whom it represents a sizeable fraction of the Y-DNA pool,[55][61] though is also found occasionally among Iberians in general. The first time it was located (Bosch 2001[62]) it was described as H102 and included seven Basques and one Andalusian.

R-M167

R-M167 is a subclade of R-DF27 defined by the presence of the marker M167. The first author to test for this marker (long before current haplogroup nomenclature existed) was Hurles in 1999, who tested 1158 men in various populations.[63] He found it relatively common among Basques (13/117: 11%) and Catalans (7/32: 22%). Other occurrences were found among other French, British, Spaniards, Béarnais, and Germans.

In 2000 Rosser et al., in a study which tested 3616 men in various populations[64] also tested for that same marker, naming the haplogroup Hg22, and again it was found mainly among Basques (19%), in lower frequencies among French (5%), Bavarians (3%), Spaniards (2%), Southern Portuguese (2%), and in single occurrences among Romanians, Slovenians, Dutch, Belgians and English.::In 2001 Bosch described this marker as H103, in 5 Basques and 5 Catalans.[62] Further regional studies have located it in significant amounts in Asturias, Cantabria and Galicia, as well as again among Basques.[62] Cases in the Azores have been reported.[citation needed] In 2008 two research papers by López-Parra[61] and Adams,[55] respectively, confirmed a strong association with all or most of the Pyrenees and Eastern Iberia.

In a larger study of Portugal in 2006, with 657 men tested, Beleza et al. confirmed similar low levels in all the major regions, from 1.5%–3.5%.[37]

R-L165

This subclade is defined by the presence of the marker S68, also known as L165. It is found in England, Scandinavia, and Scotland (in this country it is mostly found in the Northern Isles and Outer Hebrides). It has been suggested, therefore, that it arrived in the British Isles with Vikings.[65]

R-U152

edit

R-U152 is defined by the presence of the marker U152, also called S28.[8] Its existence was confirmed by Sims et al. (2007).[59] Myres et al. report this clade "is most frequent (20–44%) in Switzerland, Italy, France and Western Poland, with additional instances exceeding 15% in some regions of England and Germany."[40] Similarly Cruciani et al. (2010)[66] reported frequency peaks in Northern and Central Italy and France. Out of a sample of 135 men in Tyrol, Austria, 9 tested positive for U152/S28.[67] Far removed from this apparent core area, Myres et al. also mention a sub-population in north Bashkortostan, where 71% of 70 men tested belong to R-U152. They propose this to be the result of an isolated founder effect.[21] King et al. (2014) reported four living descendants of Henry Somerset, 5th Duke of Beaufort in the male line tested positive for U-152.[68] Ancient samples from the central European Bell Beaker, Hallstatt and Tumulus cultures belonged to this subclade.[14][69][70] Analyzed Iron Age Latins and Etruscans dating between 1000 and 100 BCE belonged primarily to haplogroup R1b-U152 (including the clades L2, Z56 and Z193).[71][72]

R-L21

edit

R-L21, also known as R-M529 and R-S145,[8] is most common in Ireland, Scotland and Wales (i.e. at least 25–50% of their male populations.[21] R-L21 has two primary subclades: R-A5846 and R-S552.

R-DF13
A primary subclade of R-S552, R-DF13 – also known as R-S521, R-Z2542 and R-CTS8221 – is one of the most common subclades of R-L21. At least one study estimated that R-DF13 would be found among more than 50% of living Irish males. The following are among the most common subclades within R-DF13.

  • R-DF21, a primary subclade of R-DF13, defined by the presence of the marker DF21 a.k.a. S192. R-DF21 makes up about 10% of all L21 men and is circa 3000 years old.[73]
  • R-L159.2 is a subclade of R-DF13, defined by the marker L159/S169. It is known as R-L159.2 because of an unrelated parallel mutation (L159.1), found within haplogroup I2a1a1a (a.k.a. I-L158 or I-M26). Consequently, some Y-DNA trees exclude L159/S169 completely, on the basis that it may be an unreliable marker. For instance, as of 2024, Yfull refers to an equivalent subclade as R-FGC80001 (i.e. R-L21 > R-S552 > R-DF13 > R-Z255 > R-FGC80001).[74] R-L159.2 appears to be associated with the Laigin, an ethno-tribal group, after whom the Kingdom of Leinster was named. It is common in males from coastal areas surrounding the Irish Sea, including western Wales, the Isle of Man and the Hebrides; R-L159.2 has also been found at significant levels in Norway, western and southern Scottish mainland, parts of England, northwest France, and northern Denmark.[75]
  • R-L193: this subclade within R-DF13 is defined by the presence of the marker L193. Many surnames with this marker are associated geographically with the western "Border Region" of Scotland. A few other surnames have a Highland association. R-L193 is a relatively young subclade likely born within the last 2000 years.
  • R-L226, under R-DF13, is defined by the presence of the marker L226, also known as S168. Commonly referred to as Irish Type III, it is concentrated in central western Ireland and associated with the Dál gCais kindred.[76]
  • R-L371: a subclade within R-DF13 defined by the presence of the marker L371 – sometimes referred to as the "Welsh modal haplotype". It is associated with ancient Welsh kings and princes.[77][78][79]

See also

edit

References

edit
  1. ^ Balaresque et al. (2010), figure 1B: "Geographical distribution of haplogroup frequency of hgR1b1b2, shown as an interpolated spatial frequency surface. Filled circles indicate populations for which microsatellite data and TMRCA estimates are available. Unfilled circles indicate populations included to illustrate R1b1b2 frequency only. Population codes are defined in Table 1."
  2. ^ a b "Mean estimates for individual populations vary (Table 2), but the oldest value is in Central Turkey (7,989 y [95% confidence interval (CI): 5,661–11,014]), and the youngest in Cornwall (5,460 y [3,764–7,777]). The mean estimate for the entire dataset is 6,512 y (95% CI: 4,577–9,063 years), with a growth rate of 1.95% (1.02%–3.30%). Thus, we see clear evidence of rapid expansion, which cannot have begun before the Neolithic period." Balaresque et al. (2010).
  3. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab Balaresque P, Bowden GR, Adams SM, Leung HY, King TE, Rosser ZH, et al. (January 2010). Penny D (ed.). "A predominantly neolithic origin for European paternal lineages". PLOS Biology. 8 (1): e1000285. doi:10.1371/journal.pbio.1000285. PMC 2799514. PMID 20087410.
  4. ^ a b c d e Haak W, Lazaridis I, Patterson N, Rohland N, Mallick S, Llamas B, et al. (June 2015). "Massive migration from the steppe was a source for Indo-European languages in Europe". Nature. 522 (7555): 207–11. arXiv:1502.02783. Bibcode:2015Natur.522..207H. doi:10.1038/nature14317. PMC 5048219. PMID 25731166.
  5. ^ Lazaridis, Iosif; et al. (2022). "The genetic history of the Southern Arc: a bridge between West Asia and Europe". Science. 377 (6609): Supplementary material, p.332. doi:10.1126/science.abm4247. PMC 10064553. PMID 36007055. Given that within the phylogeny of R-M269 (R-PF7562, (R-L51, R-Z2103 is meant) both R-PF7562 and R-Z2103 have their earliest examples in the North Caucasus and steppe to the north, the most likely hypothesis is that the entire R-M269 clade originated there as well, with R-L51 representing a lineage that eventually became highly successful in mainland Europe, R-PF7562 a lineage that did not achieve the prominence of its relatives, and R-Z2103 became highly successful (briefly) as part of the Yamnaya culture and its offshoots
  6. ^ dates according to the ISOGG trees for each respective year.
  7. ^ Semino O, Passarino G, Oefner PJ, Lin AA, Arbuzova S, Beckman LE, et al. (November 2000). "The genetic legacy of Paleolithic Homo sapiens sapiens in extant Europeans: a Y chromosome perspective". Science. 290 (5494): 1155–9. Bibcode:2000Sci...290.1155S. doi:10.1126/science.290.5494.1155. PMID 11073453.
  8. ^ a b c d e International Society of Genetic Genealogy (ISOGG) – Y-DNA Haplogroup R and its Subclades
  9. ^ Arredi B, Poloni ES, Tyler-Smith C (2007). "The peopling of Europe". In Crawford, Michael H. (ed.). Anthropological genetics: theory, methods and applications. Cambridge, UK: Cambridge University Press. p. 394. ISBN 978-0-521-54697-3.
  10. ^ Cruciani F, Trombetta B, Antonelli C, Pascone R, Valesini G, Scalzi V, et al. (June 2011). "Strong intra- and inter-continental differentiation revealed by Y chromosome SNPs M269, U106 and U152". Forensic Science International. Genetics. 5 (3): e49–52. doi:10.1016/j.fsigen.2010.07.006. PMID 20732840.
  11. ^ Allentoft ME, Sikora M, Sjögren KG, Rasmussen S, Rasmussen M, Stenderup J, et al. (June 2015). "Population genomics of Bronze Age Eurasia". Nature. 522 (7555): 167–172. Bibcode:2015Natur.522..167A. doi:10.1038/nature14507. PMID 26062507. S2CID 4399103.
  12. ^ Busby GB, Brisighelli F, Sánchez-Diz P, Ramos-Luis E, Martinez-Cadenas C, Thomas MG, et al. (March 2012). "The peopling of Europe and the cautionary tale of Y chromosome lineage R-M269". Proceedings. Biological Sciences. 279 (1730): 884–892. doi:10.1098/rspb.2011.1044. PMC 3259916. PMID 21865258.
  13. ^ Mathieson I, Lazaridis I, Rohland N, Mallick S, Patterson N, Roodenberg SA, et al. (December 2015). "Genome-wide patterns of selection in 230 ancient Eurasians". Nature. 528 (7583): 499–503. Bibcode:2015Natur.528..499M. doi:10.1038/nature16152. PMC 4918750. PMID 26595274.
  14. ^ a b c Olalde I, Brace S, Allentoft ME, Armit I, Kristiansen K, Booth T, et al. (March 2018). "The Beaker phenomenon and the genomic transformation of northwest Europe". Nature. 555 (7695): 190–196. Bibcode:2018Natur.555..190O. doi:10.1038/nature25738. PMC 5973796. PMID 29466337.
  15. ^ Anthony DW (2019-12-06). "Ancient DNA, Mating Networks, and the Anatolian Split". In Serangeli M, Olander T (eds.). Dispersals and Diversification. BRILL. pp. 21–53. doi:10.1163/9789004416192_003. ISBN 978-90-04-41619-2. S2CID 213909442.
  16. ^ Lazaridis, Iosif; et al. (2022). "The genetic history of the Southern Arc: a bridge between West Asia and Europe". Science. 377 (6609): Supplementary material, p.332. doi:10.1126/science.abm4247. PMC 10064553. PMID 36007055. Given that within the phylogeny of R-M269 (R-PF7562, (R-L51, R-Z2103 is meant) both R-PF7562 and R-Z2103 have their earliest examples in the North Caucasus and steppe to the north, the most likely hypothesis is that the entire R-M269 clade originated there as well, with R-L51 representing a lineage that eventually became highly successful in mainland Europe, R-PF7562 a lineage that did not achieve the prominence of its relatives, and R-Z2103 became highly successful (briefly) as part of the Yamnaya culture and its offshoots
  17. ^ Hammer M (2013). Origins of R-M269 Diversity in Europe. FamilyTreeDNA 9th Annual Conference.
  18. ^ Sjögren KG, Olalde I, Carver S, Allentoft ME, Knowles T, Kroonen G, et al. (2019-12-11). "Kinship and social organization in Copper Age Europe. A cross-disciplinary analysis of archaeology, DNA, isotopes, and anthropology from two Bell Beaker cemeteries". PLOS ONE. 15 (11): e0241278. bioRxiv 10.1101/863944. doi:10.1371/journal.pone.0241278. hdl:10261/236801. PMC 7668604. PMID 33196640. S2CID 212833639.
  19. ^ Underhill PA, Shen P, Lin AA, Jin L, Passarino G, Yang WH, et al. (November 2000). "Y chromosome sequence variation and the history of human populations". Nature Genetics. 26 (3): 358–61. doi:10.1038/81685. PMID 11062480. S2CID 12893406.
  20. ^ a b Lobov AS, et al. (2009). "Structure of the Gene Pool of Bashkir Subpopulations" (PDF) (in Russian). Archived from the original (PDF) on 2011-08-16.
  21. ^ a b c d e f g h i j k l Myres NM, Rootsi S, Lin AA, Järve M, King RJ, Kutuev I, et al. (January 2011). "A major Y-chromosome haplogroup R1b Holocene era founder effect in Central and Western Europe". European Journal of Human Genetics. 19 (1): 95–101. doi:10.1038/ejhg.2010.146. PMC 3039512. PMID 20736979.
  22. ^ a b Grugni V, Raveane A, Mattioli F, Battaglia V, Sala C, Toniolo D, et al. (February 2018). "Reconstructing the genetic history of Italians: new insights from a male (Y-chromosome) perspective". Annals of Human Biology. 45 (1): 44–56. doi:10.1080/03014460.2017.1409801. PMID 29382284. S2CID 43501209.
  23. ^ Robino C, Crobu F, Di Gaetano C, Bekada A, Benhamamouch S, Cerutti N, et al. (May 2008). "Analysis of Y-chromosomal SNP haplogroups and STR haplotypes in an Algerian population sample". International Journal of Legal Medicine. 122 (3): 251–255. doi:10.1007/s00414-007-0203-5. PMID 17909833. S2CID 11556974.
  24. ^ Wood ET, Stover DA, Ehret C, Destro-Bisol G, Spedini G, McLeod H, et al. (July 2005). "Contrasting patterns of Y chromosome and mtDNA variation in Africa: evidence for sex-biased demographic processes". European Journal of Human Genetics. 13 (7): 867–876. doi:10.1038/sj.ejhg.5201408. PMID 15856073. S2CID 20279122.
  25. ^ Ordóñez AC, Fregel R, Trujillo-Mederos A, Hervella M, de-la-Rúa C, Arnay-de-la-Rosa M (2017). "Genetic studies on the prehispanic population buried in Punta Azul cave (El Hierro, Canary Islands)". Journal of Archaeological Science. 78: 20–28. Bibcode:2017JArSc..78...20O. doi:10.1016/j.jas.2016.11.004.
  26. ^ a b Grugni V, Battaglia V, Hooshiar Kashani B, Parolo S, Al-Zahery N, Achilli A, et al. (2012). "Ancient migratory events in the Middle East: new clues from the Y-chromosome variation of modern Iranians". PLOS ONE. 7 (7): e41252. Bibcode:2012PLoSO...741252G. doi:10.1371/journal.pone.0041252. PMC 3399854. PMID 22815981.
  27. ^ Proceedings of the Russian Academy of DNA Genealogy, 3, 1676–1695 (in Russian).
  28. ^ a b c d e Herrera KJ, Lowery RK, Hadden L, Calderon S, Chiou C, Yepiskoposyan L, Regueiro M, Underhill PA, Herrera RJ (March 2012). "Neolithic patrilineal signals indicate that the Armenian plateau was repopulated by agriculturalists". European Journal of Human Genetics. 20 (3): 313–20. doi:10.1038/ejhg.2011.192. PMC 3286660. PMID 22085901.
  29. ^ Трофимова Натал'я Вадимовна (Feb. 2015), "Изменчивость Митохондриальной ДНК и Y-Хромосомы в Популяциях Волго-Уральского Региона" Archived 2017-04-02 at the Wayback Machine ("Mitochondrial DNA variation and the Y-chromosome in the population of the Volga-Ural Region"). Автореферат. диссертации на соискание ученой степени кандидата биологических наук. Уфа – 2015.
  30. ^ Haak W, Lazaridis I, Patterson N, Rohland N, Mallick S, Llamas B, et al. (June 2015). "Massive migration from the steppe was a source for Indo-European languages in Europe". Nature. 522 (7555): 207–11. arXiv:1502.02783. Bibcode:2015Natur.522..207H. bioRxiv 10.1101/013433. doi:10.1038/nature14317. PMC 5048219. PMID 25731166.
  31. ^ Morelli L, Contu D, Santoni F, Whalen MB, Francalacci P, Cucca F (April 2010). Lalueza-Fox C (ed.). "A comparison of Y-chromosome variation in Sardinia and Anatolia is more consistent with cultural rather than demic diffusion of agriculture". PLOS ONE. 5 (4): e10419. Bibcode:2010PLoSO...510419M. doi:10.1371/journal.pone.0010419. PMC 2861676. PMID 20454687.
  32. ^ ISOGG tree as of 2017 (isogg.org)
  33. ^ Vanek D, Saskova L, Koch H (June 2009). "Kinship and Y-chromosome analysis of 7th century human remains: novel DNA extraction and typing procedure for ancient material". Croatian Medical Journal. 3. 50 (3): 286–95. doi:10.3325/cmj.2009.50.286. PMC 2702742. PMID 19480023.
  34. ^ Moore LT, McEvoy B, Cape E, Simms K, Bradley DG (February 2006). "A Y-chromosome signature of hegemony in Gaelic Ireland". American Journal of Human Genetics. 78 (2): 334–8. doi:10.1086/500055. PMC 1380239. PMID 16358217.
  35. ^ a b Di Giacomo F, Luca F, Anagnou N, Ciavarella G, Corbo RM, Cresta M, et al. (September 2003). "Clinal patterns of human Y chromosomal diversity in continental Italy and Greece are dominated by drift and founder effects". Molecular Phylogenetics and Evolution. 28 (3): 387–395. Bibcode:2003MolPE..28..387D. CiteSeerX 10.1.1.553.5711. doi:10.1016/s1055-7903(03)00016-2. PMID 12927125.
  36. ^ Bryc K, Velez C, Karafet T, Moreno-Estrada A, Reynolds A, Auton A, et al. (May 2010). "Colloquium paper: genome-wide patterns of population structure and admixture among Hispanic/Latino populations". Proceedings of the National Academy of Sciences of the United States of America. 107 (Suppl 2): 8954–61. Bibcode:2010PNAS..107.8954B. doi:10.1073/pnas.0914618107. PMC 3024022. PMID 20445096.
  37. ^ a b Beleza S, Gusmão L, Lopes A, Alves C, Gomes I, Giouzeli M, et al. (March 2006). "Micro-phylogeographic and demographic history of Portuguese male lineages". Annals of Human Genetics. 70 (Pt 2): 181–94. doi:10.1111/j.1529-8817.2005.00221.x. PMID 16626329. S2CID 4652154. 395/657
  38. ^ Boattini A, Martinez-Cruz B, Sarno S, Harmant C, Useli A, Sanz P, Yang-Yao D, Manry J, Ciani G, Luiselli D, Quintana-Murci L, Comas D, Pettener D (2013). "Uniparental markers in Italy reveal a sex-biased genetic structure and different historical strata". PLOS ONE. 8 (5): e65441. Bibcode:2013PLoSO...865441B. doi:10.1371/journal.pone.0065441. PMC 3666984. PMID 23734255.
  39. ^ a b Tofanelli S, Brisighelli F, Anagnostou P, Busby GB, Ferri G, Thomas MG, Taglioli L, Rudan I, Zemunik T, Hayward C, Bolnick D, Romano V, Cali F, Luiselli D, Shepherd GB, Tusa S, Facella A, Capelli C (March 2016). "The Greeks in the West: genetic signatures of the Hellenic colonisation in southern Italy and Sicily". European Journal of Human Genetics. 24 (3): 429–36. doi:10.1038/ejhg.2015.124. PMC 4757772. PMID 26173964.
  40. ^ a b c d e f g h i j k l m n o p q r s t u v w x y Myres NM, Ekins JE, Lin AA, Cavalli-Sforza LL, Woodward SR, Underhill PA (August 2007). "Y-chromosome short tandem repeat DYS458.2 non-consensus alleles occur independently in both binary haplogroups J1-M267 and R1b3-M405". Croatian Medical Journal. 48 (4): 450–9. PMC 2080563. PMID 17696299.
  41. ^ a b c d e Battaglia V, Fornarino S, Al-Zahery N, Olivieri A, Pala M, Myres NM, et al. (June 2009). "Y-chromosomal evidence of the cultural diffusion of agriculture in Southeast Europe". European Journal of Human Genetics. 17 (6): 820–30. doi:10.1038/ejhg.2008.249. PMC 2947100. PMID 19107149.
  42. ^ Pericić M, Lauc LB, Klarić IM, Rootsi S, Janićijevic B, Rudan I, et al. (October 2005). "High-resolution phylogenetic analysis of southeastern Europe traces major episodes of paternal gene flow among Slavic populations". Molecular Biology and Evolution. 22 (10): 1964–75. doi:10.1093/molbev/msi185. PMID 15944443.
  43. ^ a b c Cinnioğlu C, King R, Kivisild T, Kalfoğlu E, Atasoy S, Cavalleri GL, et al. (January 2004). "Excavating Y-chromosome haplotype strata in Anatolia" (PDF). Human Genetics. 114 (2): 127–48. doi:10.1007/s00439-003-1031-4. PMID 14586639. S2CID 10763736. Archived from the original (PDF) on 2006-06-19.
  44. ^ a b King RJ, Ozcan SS, Carter T, Kalfoğlu E, Atasoy S, Triantaphyllidis C, et al. (March 2008). "Differential Y-chromosome Anatolian influences on the Greek and Cretan Neolithic". Annals of Human Genetics. 72 (Pt 2): 205–14. doi:10.1111/j.1469-1809.2007.00414.x. PMID 18269686. S2CID 22406638.
  45. ^ Contu D, Morelli L, Santoni F, Foster JW, Francalacci P, Cucca F (January 2008). Hawks J (ed.). "Y-chromosome based evidence for pre-neolithic origin of the genetically homogeneous but diverse Sardinian population: inference for association scans". PLOS ONE. 3 (1): e1430. Bibcode:2008PLoSO...3.1430C. doi:10.1371/journal.pone.0001430. PMC 2174525. PMID 18183308. 174/930
  46. ^ a b Regueiro M, Cadenas AM, Gayden T, Underhill PA, Herrera RJ (2006). "Iran: tricontinental nexus for Y-chromosome driven migration". Human Heredity. 61 (3): 132–43. doi:10.1159/000093774. PMID 16770078. S2CID 7017701.
  47. ^ a b Varzari A (2006). Population History of the Dniester-Carpathians: Evidence from Alu Insertion and Y-Chromosome Polymorphisms (PDF) (Dissertation). Ludwig-Maximilians-Universität München.
  48. ^ Robino C, Crobu F, Di Gaetano C, Bekada A, Benhamamouch S, Cerutti N, et al. (May 2008). "Analysis of Y-chromosomal SNP haplogroups and STR haplotypes in an Algerian population sample". International Journal of Legal Medicine. 122 (3): 251–5. doi:10.1007/s00414-007-0203-5. PMID 17909833. S2CID 11556974.
  49. ^ a b c d e Balanovsky O, Rootsi S, Pshenichnov A, Kivisild T, Churnosov M, Evseeva I, et al. (January 2008). "Two sources of the Russian patrilineal heritage in their Eurasian context". American Journal of Human Genetics. 82 (1): 236–50. doi:10.1016/j.ajhg.2007.09.019. PMC 2253976. PMID 18179905.
  50. ^ Al-Zahery N, Semino O, Benuzzi G, Magri C, Passarino G, Torroni A, Santachiara-Benerecetti AS (September 2003). "Y-chromosome and mtDNA polymorphisms in Iraq, a crossroad of the early human dispersal and of post-Neolithic migrations" (PDF). Molecular Phylogenetics and Evolution. 28 (3): 458–72. Bibcode:2003MolPE..28..458A. doi:10.1016/S1055-7903(03)00039-3. PMID 12927131. Archived from the original (PDF) on 2017-01-20. Retrieved 2017-03-17. 16/139
  51. ^ a b c d Gayden T, Cadenas AM, Regueiro M, Singh NB, Zhivotovsky LA, Underhill PA, Cavalli-Sforza LL, Herrera RJ (May 2007). "The Himalayas as a directional barrier to gene flow". American Journal of Human Genetics. 80 (5): 884–94. doi:10.1086/516757. PMC 1852741. PMID 17436243.
  52. ^ Karachanak S, Grugni V, Fornarino S, Nesheva D, Al-Zahery N, Battaglia V, Carossa V, Yordanov Y, Torroni A, Galabov AS, Toncheva D, Semino O (2013). "Y-chromosome diversity in modern Bulgarians: new clues about their ancestry". PLOS ONE. 8 (3): e56779. Bibcode:2013PLoSO...856779K. doi:10.1371/journal.pone.0056779. PMC 3590186. PMID 23483890.
  53. ^ Zalloua PA, Xue Y, Khalife J, Makhoul N, Debiane L, Platt DE, Royyuru AK, Herrera RJ, Hernanz DF, Blue-Smith J, Wells RS, Comas D, Bertranpetit J, Tyler-Smith C (April 2008). "Y-chromosomal diversity in Lebanon is structured by recent historical events". American Journal of Human Genetics. 82 (4): 873–82. doi:10.1016/j.ajhg.2008.01.020. PMC 2427286. PMID 18374297.
  54. ^ a b c d e Bekada A, Fregel R, Cabrera VM, Larruga JM, Pestano J, Benhamamouch S, González AM (2013-02-19). "Introducing the Algerian mitochondrial DNA and Y-chromosome profiles into the North African landscape". PLOS ONE. 8 (2): e56775. Bibcode:2013PLoSO...856775B. doi:10.1371/journal.pone.0056775. PMC 3576335. PMID 23431392.
  55. ^ a b c d Adams SM, Bosch E, Balaresque PL, Ballereau SJ, Lee AC, Arroyo E, et al. (December 2008). "The genetic legacy of religious diversity and intolerance: paternal lineages of Christians, Jews, and Muslims in the Iberian Peninsula". American Journal of Human Genetics. 83 (6): 725–36. doi:10.1016/j.ajhg.2008.11.007. PMC 2668061. PMID 19061982.
  56. ^ a b c Marjanovic D, Fornarino S, Montagna S, Primorac D, Hadziselimovic R, Vidovic S, Pojskic N, Battaglia V, Achilli A, Drobnic K, Andjelinovic S, Torroni A, Santachiara-Benerecetti AS, Semino O (November 2005). "The peopling of modern Bosnia-Herzegovina: Y-chromosome haplogroups in the three main ethnic groups". Annals of Human Genetics. 69 (Pt 6): 757–63. doi:10.1111/j.1529-8817.2005.00190.x. PMID 16266413. S2CID 36632274.
  57. ^ a b c Cadenas AM, Zhivotovsky LA, Cavalli-Sforza LL, Underhill PA, Herrera RJ (March 2008). "Y-chromosome diversity characterizes the Gulf of Oman". European Journal of Human Genetics. 16 (3): 374–86. doi:10.1038/sj.ejhg.5201934. PMID 17928816.
  58. ^ a b c d Sengupta S, Zhivotovsky LA, King R, Mehdi SQ, Edmonds CA, Chow CE, et al. (February 2006). "Polarity and temporality of high-resolution y-chromosome distributions in India identify both indigenous and exogenous expansions and reveal minor genetic influence of Central Asian pastoralists". American Journal of Human Genetics. 78 (2): 202–21. doi:10.1086/499411. PMC 1380230. PMID 16400607. 8/176 R-M73 and 5/176 R-M269 for a total of 13/176 R1b in Pakistan and 4/728 R-M269 in India
  59. ^ a b c d e Sims LM, Garvey D, Ballantyne J (January 2007). "Sub-populations within the major European and African derived haplogroups R1b3 and E3a are differentiated by previously phylogenetically undefined Y-SNPs". Human Mutation. 28 (1): 97. doi:10.1002/humu.9469. PMID 17154278. S2CID 34556775.
  60. ^ a b "Origins of R-M269 Diversity in Europe" (PDF).
  61. ^ a b López-Parra AM, Gusmão L, Tavares L, Baeza C, Amorim A, Mesa MS, Prata MJ, Arroyo-Pardo E (January 2009). "In search of the pre- and post-neolithic genetic substrates in Iberia: evidence from Y-chromosome in Pyrenean populations". Annals of Human Genetics. 73 (1): 42–53. doi:10.1111/j.1469-1809.2008.00478.x. PMID 18803634. S2CID 43273988.
  62. ^ a b c Bosch E, Calafell F, Comas D, Oefner PJ, Underhill PA, Bertranpetit J (April 2001). "High-resolution analysis of human Y-chromosome variation shows a sharp discontinuity and limited gene flow between northwestern Africa and the Iberian Peninsula". American Journal of Human Genetics. 68 (4): 1019–29. doi:10.1086/319521. PMC 1275654. PMID 11254456.
  63. ^ Hurles ME, Veitia R, Arroyo E, Armenteros M, Bertranpetit J, Pérez-Lezaun A, et al. (November 1999). "Recent male-mediated gene flow over a linguistic barrier in Iberia, suggested by analysis of a Y-chromosomal DNA polymorphism". American Journal of Human Genetics. 65 (5): 1437–48. doi:10.1086/302617. PMC 1288297. PMID 10521311.
  64. ^ Rosser ZH, Zerjal T, Hurles ME, Adojaan M, Alavantic D, Amorim A, et al. (December 2000). "Y-chromosomal diversity in Europe is clinal and influenced primarily by geography, rather than by language". American Journal of Human Genetics. 67 (6): 1526–43. doi:10.1086/316890. PMC 1287948. PMID 11078479.
  65. ^ Moffat A, Wilson JF (2011). The Scots: a genetic journey. Birlinn. pp. 181–182, 192. ISBN 978-0-85790-020-3.
  66. ^ Cruciani F, Trombetta B, Antonelli C, Pascone R, Valesini G, Scalzi V, Vona G, Melegh B, Zagradisnik B, Assum G, Efremov GD, Sellitto D, Scozzari R (June 2011). "Strong intra- and inter-continental differentiation revealed by Y chromosome SNPs M269, U106 and U152". Forensic Science International. Genetics. 5 (3): e49–52. doi:10.1016/j.fsigen.2010.07.006. PMID 20732840.
  67. ^ Niederstätter H, Berger B, Erhart D, Parson W (August 2008). "Recently introduced Y-SNPs improve the resolution within Y-chromosome haplogroup R1b in a central European population sample (Tyrol, Austria)". Forensic Science International: Genetics Supplement Series. 1: 226–227. doi:10.1016/j.fsigss.2007.10.158.
  68. ^ Henry Somerset was in turn descended in the patrilineal line from John of Gaunt (1340–1399), a son of King Edward III (1312–1377). In the context of the analysis of the remains of Richard III, which proved to belong to haplogroup G2, the possibility of a false-paternity event, most likely between Edward III and Henry Somerset, was discussed; possibly confirming rumors to the effect that John of Gaunt was illegitimate (Jonathan Sumption, Divided Houses: The Hundred Years War III, 2009, p. 274). King TE, Fortes GG, Balaresque P, Thomas MG, Balding D, Maisano Delser P, Neumann R, Parson W, Knapp M, Walsh S, Tonasso L, Holt J, Kayser M, Appleby J, Forster P, Ekserdjian D, Hofreiter M, Schürer K (December 2014). "Identification of the remains of King Richard III". Nature Communications. 5 (5631): 5631. Bibcode:2014NatCo...5.5631K. doi:10.1038/ncomms6631. PMC 4268703. PMID 25463651. "Y-chromosome haplotypes from male-line relatives and the remains do not match, which could be attributed to a false-paternity event occurring in any of the intervening generations."
  69. ^ Allentoft ME, Sikora M, Sjögren KG, Rasmussen S, Rasmussen M, Stenderup J, et al. (June 2015). "Population genomics of Bronze Age Eurasia". Nature. 522 (7555): 167–72. Bibcode:2015Natur.522..167A. doi:10.1038/nature14507. PMID 26062507. S2CID 4399103.
  70. ^ Damgaard PB, Marchi N, Rasmussen S, Peyrot M, Renaud G, Korneliussen T, et al. (May 2018). "137 ancient human genomes from across the Eurasian steppes". Nature. 557 (7705): 369–374. Bibcode:2018Natur.557..369D. doi:10.1038/s41586-018-0094-2. hdl:1887/3202709. PMID 29743675. S2CID 13670282.
  71. ^ Antonio ML, Gao Z, Moots HM, Lucci M, Candilio F, Sawyer S, et al. (November 2019). "Ancient Rome: A genetic crossroads of Europe and the Mediterranean". Science. 366 (6466): 708–714. Bibcode:2019Sci...366..708A. doi:10.1126/science.aay6826. PMC 7093155. PMID 31699931.
  72. ^ Posth C, Zaro V, Spyrou MA, Vai S, Gnecchi-Ruscone GA, Modi A, et al. (September 2021). "The origin and legacy of the Etruscans through a 2000-year archeogenomic time transect". Science Advances. 7 (39). American Association for the Advancement of Science: eabi7673. Bibcode:2021SciA....7.7673P. doi:10.1126/sciadv.abi7673. PMC 8462907. PMID 34559560.
  73. ^ "R-DF21 and Subclades Project".
  74. ^ Yfull, 2012–24, R-FGC80001(Access: 9 April 2024.)
  75. ^ "R-L159 Project Goals".
  76. ^ Wright DM (2009). "A Set of Distinctive Marker Values Defines a Y-STR Signature for Gaelic Dalcassian Families". Journal of Genetic Genealogy. Archived from the original on 2012-08-24. Retrieved 2017-03-17.
  77. ^ Bevan N (2014-09-25). "Dafydd Iwan's rare genetic roots unveiled in new project". walesonline. Retrieved 2018-04-05.
  78. ^ Bodden T (2014-09-26). "Dafydd Iwan 'descended from Welsh kings' who ruled in England". northwales. Retrieved 2018-04-05.
  79. ^ "Family Tree DNA - My FamilyTree DNA Project Website Title". www.familytreedna.com. Retrieved 2018-04-05.
  NODES
eth 7
orte 5
see 6
Story 7