Haplogroup E-V68

Haplogroup E-V68, also known as E1b1b1a, is a major human Y-chromosome DNA haplogroup found in North Africa, the Horn of Africa, Western Asia and Europe. It is a subclade of the larger and older haplogroup, known as E1b1b or E-M215 (also roughly equivalent to E-M35). The E1b1b1a lineage is identified by the presence of a single nucleotide polymorphism (SNP) mutation on the Y chromosome, which is known as V68. It is a subject of discussion and study in genetics as well as genetic genealogy, archaeology, and historical linguistics.

Haplogroup E-V68
Possible time of originc. 24,000 years BP[1]
Coalescence agec. 19,900 years BP[1]
Possible place of originEgypt/Libya[2] or southern Egypt/northern Sudan[3]
AncestorE-M215-M35[4]
DescendantsE-M78,[4] E-V1039
Defining mutationsV68, L539, PF2203[4]

E-V68 is dominated by its longer-known subclade E-M78. In various publications, both E-V68 and E-M78 have been referred to by other names, especially phylogenetic nomenclature such as "E3b1a" which are designed to show their place on the family tree of all human males. These various names change as new discoveries are made and are discussed below.

Origins

The Nile River and its main tributaries: a probable corridor of ancient human migrations, including those involving the Y DNA lineages E-M243, E-M78, E-V12, and E-V22.

E-M78, like its parent clade E-V68, is thought to have an African origin. Based on genetic STR variance data, Cruciani et al. (2007) suggests that this subclade originated in "Northeastern Africa", which in the study refers specifically to the region of Egypt and Libya.[5]

Prior to Cruciani et al. (2007), Semino et al. (2004) had proposed a place of origin for E-M78 further south in East Africa. This was because of the high frequency and diversity of E-M78 lineages in the region of Ethiopia. However, Cruciani et al. (2007) were able to study more data, and concluded that the E-M78 lineages in the Horn of Africa were dominated by relatively recent branches (see E-V32 below). They concluded that the region of Egypt was the likely place of origin of E-M78 based on "the peripheral geographic distribution of the most derived subhaplogroups with respect to northeastern Africa, as well as the results of quantitative analysis of UEP and microsatellite diversity".

Cruciani et al. (2007) also note this as evidence for "a corridor for bidirectional migrations" between Northeast Africa (Egypt and Libya in their data) on the one hand and East Africa on the other. Because Cruciani et al. (2007) also proposed that E-M35, the parent clade of E-M78, originated in East Africa during the Palaeolithic and subsequently spread to the region of Egypt. E-M78 in East Africa, is therefore the result of a back migration. The authors believe there were "at least 2 episodes between 23.9–17.3 ky and 18.0–5.9 ky ago".

Another probable migration to the south from Egypt was noted by Hassan et al. (2008) based upon their survey of Sudan. Specifically E-V12 and E-V22, "might have been brought to Sudan from North Africa after the progressive desertification of the Sahara around 6,000-8,000 years ago".

Northwards from Egypt and Libya, E-M78 migrated into the Middle East, but additionally Trombetta et al. (2011) proposed that the earlier E-V68 carrying population may have migrated by sea directly from Africa to southwestern Europe, because they observed cases of E-V68* (without the M78 mutation) only in Sardinia, and not in the Middle Eastern samples. Concerning E-M78, like other forms of E-V68 there is evidence of multiple routes of expansion out of an African homeland.

On the other hand, while there were apparently direct migrations from North Africa to Iberia and Southern Italy (of people carrying E-V68*, E-V12, E-V22, and E-V65), the majority of E-M78 lineages found in Europe belong to the E-V13 subclade which appears to have entered Europe at some time undetermined from the Near East, where it apparently originated, via the Balkans.

Coming to similar conclusions as the Cruciani and Trombetta team, Battaglia et al. (2008), writing prior to the discovery of E-V68, describe Egypt as "a hub for the distribution of the various geographically localized M78-related sub-clades" and, based on archaeological data, they propose that the point of origin of E-M78 (as opposed to later dispersals from Egypt) may have been in a refugium which "existed on the border of present-day Sudan and Egypt, near Lake Nubia, until the onset of a humid phase around 8500 BC. The northward-moving rainfall belts during this period could have also spurred a rapid migration of Mesolithic foragers northwards in Africa, the Levant and ultimately onwards to Asia Minor and Europe, where they each eventually differentiated into their regionally distinctive branches".

The division of E-V68 into sub-clades such as E-V12, E-V13, etc. has largely been the work of an Italian team including Fulvio Cruciani, Beniamino Trombetta, Rosario Scozzari and others. They started on the basis of STR studies in 2004, and then in 2006 they announced the discoveries of single nucleotide polymorphism (SNP) mutations which could define most of the main branches with better clarity, which was then discussed further in 2007.[2][6][7] These articles were the basis of the updated phylogenies found in Karafet (2008), and ISOGG, which is in turn the basis of the phylogeny given below.

Loosdrecht et al. (2018) analysed genome-wide data from seven ancient Iberomaurusian individuals from the Grotte des Pigeons near Taforalt in eastern Morocco. The fossils were directly dated to between 15,100 and 13,900 calibrated years before present. The scientists found that all the male specimens with sufficient nuclear DNA preservation belonged to the E1b1b1a1 (M78) subclade, with one skeleton bearing the E1b1b1a1b1 parent lineage to E-V13.[8]

Age

Battaglia et al. (2007) estimated that E-M78 (called E1b1b1a1 in that paper) has been in Europe longer than 10,000 years. And more recently, Lacan et al. (2011) found that human remains excavated in a Spanish funeral cave dated to approximately 7000 years ago were in the E-V13 branch of E-M78.

In June 2015, the M78 mutation and the consequent beginning of the E-M78 and E-V68 family trees was dated by Trombetta et al. to approximately 20,300-14,800 years ago.[9]

Family tree

This phylogenetic tree of haplogroup subclades is based on the ISOGG 2019 tree.

V68

E-V68* (E1b1b1a*)

M78

E-M78* (E1b1b1a1*) (Gurna Oasis) in Egypt, Morocco and Mediterranean.[2]

V12

E-V12* (E1b1b1a1a*) Found in Egypt, French Basques, Sudan, and other places.

E-M224 (E1b1b1a1a1)

E-V32 (E1b1b1a1a1b) Found in Somalia.

V13
V13

E-V13*(E1b1b1a1b1a*) The majority of E-V13, and more generally of E-M78 in Europe.

V27

()

P65

()

L17

(E1b1b1a1b1a1)

L143

(E1b1b1a1b1a2a)

M35.2

(E1b1b1a1a1b1a3) In this small branch, the M35 mutation has been reversed and lost.

L241

()

L250, L251, L252

(E1b1b1a1b1a4)

L540

(E1b1b1a1b1a5a1)

V22
V22

E-V22* (E1b1b1a1b2*) Found in Egypt, the Middle East and other places.

M148

(E1b1b1a1b2a1)

V19

()

V65

(E1b1b1a1a2) Associated with the Maghreb, but also found in Italy and Spain.

M521

(E1b1b1a1c) Found in two individuals in Greece by Battaglia et al. 2008

Distribution

So far, three individuals who are in E-V68 but not E-M78 have been reported in Sardinia, by Trombetta et al. (2010), when announcing the discovery of V68.

E-M78 is widely distributed in North Africa, Horn of Africa, West Asia (stretching as far as Southern Asia), and Europe.[2][7]

The most basal and rare E-M78* paragroup has been found at its highest frequencies in Egyptians from the Gurna Oasis (5.88%), with lower frequencies also observed in Moroccan Arabs, Sardinians, the Balkans, and Andalusians from Huelva.[2][3][10]

The highest frequencies of all the defined E-M78 sub-clades is primarily found amongst Afroasiatic-speaking populations in the large area stretching from the haplogroup's putative place of origin in Upper Egypt to the Sudan and the Horn of Africa.[6]

Outside of this core area of distribution (North Africa and the Horn of Africa), E-V68 is also observed in other parts of the continent at lower frequencies due to more recent dispersals. It is thus found today in pockets of the African Great Lakes and Southern Africa owing to early Afro-Asiatic-speaking settlers from the Horn region,[9] and as far west as Guinea-Bissau, where its presence has been tentatively attributed to trans-Saharan movements of people from North Africa.[11]

The distribution of E-V68 in Europe is dominated by its E-V13 subclade, except in Iberia. E-V13 has a frequency peak centered in parts of the Balkans (approximately 20% in southern areas; up to almost 50% is some particular places and populations[12][13]) and Italy. It today has lower frequencies toward the western, central and northeastern areas, though E-V13 has been found in a Neolithic burial in Catalonia. This is discussed in more detail below.

RegionPopulationnE-M78E-M78*E-V12*E-V13E-V22E-V32E-V65Study
Europe    Albanians5525.46% = (14/55)1.82% = (1/55)23.64% = (13/55)[14]
Europe    Macedonian Albanians6435.94% = (23/64)1.56% = (1/64)34.38% = (22/64)[14]
Europe    Albanians+
Macedonian Albanians
55+
64=
119
31.09% = (37/119)1.68% = (2/119)29.41% = (35/119)[14]
Europe    Kosovar Albanians11445.61% = (52/114)1.75% = (2/114)43.86% = (50/114)Peričic et al. (2005)
Europe    Albanians9632.29% = (31/96)32.29% = (31/96)Cruciani et al. (2007)
Europe    Kosovar Albanians+
Macedonian Albanians+
Albanians
119+
114+
96=
329
36.47% = (120/329)1.22% = (4/329)35.26% = (116/329)
[14]
Peričic et al. (2005)
Cruciani et al. (2007)
Europe    Macedonian Arumanians5729.8229.82Peričic et al. (2005)
Europe    Serbians11320.351.7718.58Peričic et al. (2005)
Europe    Croatians1085.605.60Peričic et al. (2005)
Europe    Crete1936.7% = 13/1936.7% = 13/193King et al. (2008)
Europe    Greeks from Nea Nikomedeia5715.8% = 9/571.8% = 1/5714.0% = 8/57King et al. (2008)
Europe    Greeks from Sesklo/Dimini5738.6% = 22/573.5% = 2/5735.1% = 20/57King et al. (2008)
Europe    Greeks from Lerna/Franchthi5735.1% = 20/5735.1% = 20/57King et al. (2008)
Europe    Greeks from Crete+
Greeks from Nea Nikomedeia
Greeks from Sesklo/Dimini
from Lerna/Franchthi
193+
57+
57+
57=
364
17.58% = 64/3640.82% = 3/36416.76% = 61/364King et al. (2008)
Europe    Continental Greeks14719.05% = 28/14717.69% = 26/1470.68% = 1/1470.68% = 1/147Cruciani et al. (2007)
Europe    Greeks from Crete2156.51% = 14/2150.93% = 2/2155.58% = 12/215Cruciani et al. (2007)
Europe    Greeks from Aegean Islands7116.9% = 12/7115.49% = 11/711.41% = 1/71Cruciani et al. (2007)
Europe    Continental Greeks
Greeks from Crete
Greeks from Aegean Islands
147+
215+
71=
433
12.47% = 54/4330.46% = 2/43311.32% = 49/4330.46% = 2/4330.23% = 1/433Cruciani et al. (2007)
Europe    Greeks from Crete+
Greeks from Nea Nikomedeia
Greeks from Sesklo/Dimini
from Lerna/Franchthi
Continental Greeks
Greeks from Crete
Greeks from Aegean Islands
364+
433=
797
14.81% = 118/7970.38% = 3/7970.25% = 2/79713.8% = 110/7970.25% = 2/7970.13% = 1/797King et al. (2008)
Cruciani et al. (2007)
Europe    Sicilians23611.431.275.933.810.42Di Gaetano et al. (2008)
Europe    Huelva Andalusians1676.591.204.190.600.60Ambrosio et al. (2010)
Europe    Macedonians9918.1817.171.01Cruciani et al. (2007)
Europe    Bulgarians20416.670.4916.18Cruciani et al. (2007)
Europe    Sicilians15313.070.657.194.580.65Cruciani et al. (2007)
Europe    Northern Italians947.455.322.13Cruciani et al. (2007)
Europe    Central Italians3567.870.285.341.970.28Cruciani et al. (2007)
Europe    Southern Italians14110.640.718.511.42Cruciani et al. (2007)
Europe    Sardinians3743.480.270.271.070.81.07Cruciani et al. (2007)
Europe    Northern Portuguese5044Cruciani et al. (2007)
Europe    Southern Portuguese494.084.08Cruciani et al. (2007)
Europe    Pasiegos from Cantabria56Cruciani et al. (2007)
Europe    Asturians90105.564.44Cruciani et al. (2007)
Europe    Southern Spaniards623.233.23Cruciani et al. (2007)
Europe    Spanish Basques55Cruciani et al. (2007)
Europe    French Basques166.256.25Cruciani et al. (2007)
Europe    French2254.440.444Cruciani et al. (2007)
Europe    English28Cruciani et al. (2007)
Europe    Danish352.862.86Cruciani et al. (2007)
Europe    Germans773.93.9Cruciani et al. (2007)
Europe    Polish402.52.5Cruciani et al. (2007)
Europe    Czechs2684.854.85Cruciani et al. (2007)
Europe    Slovaks248.338.33Cruciani et al. (2007)
Europe    Slovenians1042.882.88Cruciani et al. (2007)
Europe    Estonians744.054.05Cruciani et al. (2007)
Europe    Belarusians40Cruciani et al. (2007)
Europe    Northern Russians823.663.66Cruciani et al. (2007)
Europe    Southern Russians922.172.17Cruciani et al. (2007)
Europe    Ukrainians119.099.09Cruciani et al. (2007)
Europe    Moldovians777.797.79Cruciani et al. (2007)
Europe    Hungarians1069.439.43Cruciani et al. (2007)
Europe    Rumanians2657.557.170.38Cruciani et al. (2007)
Northwestern Africa    Moroccan Arabs55403.647.2729.09Cruciani et al. (2007)
Northwestern Africa    Asni Berbers543.73.7Cruciani et al. (2007)
Northwestern Africa    Bouhria Berbers671.491.49Cruciani et al. (2007)
Northwestern Africa    Moyen Atlas Berbers6910.1410.14Cruciani et al. (2007)
Northwestern Africa    Marrakech Berbers296.93.453.45Cruciani et al. (2007)
Northwestern Africa    Moroccan Jews5012228Cruciani et al. (2007)
Northwestern Africa    Mozabite Berbers20Cruciani et al. (2007)
Northeastern Africa    Libyan Jews25844Cruciani et al. (2007)
Northeastern Africa    Libyan Arabs102020Cruciani et al. (2007)
Northeastern Africa    Northern Egyptians (Delta)7223.615.561.3913.892.78Cruciani et al. (2007)
Northeastern Africa    Egyptian Berbers936.452.154.3Cruciani et al. (2007)
Northeastern Africa    Egyptians from Bahari4141.4614.632.4421.952.44Cruciani et al. (2007)
Northeastern Africa    Egyptians from Gurna Oasis3417.655.888.822.94Cruciani et al. (2007)
Northeastern Africa    Egyptians707979Trombetta (2015)
Northeastern Africa    Southern Egyptians7950.6344.31.273.81.27Cruciani et al. (2007)
Eastern Africa    Dinka2615.383.8511.54Hassan et al. (2008)
Eastern Africa    Shilluk1513.3313.33Hassan et al. (2008)
Eastern Africa    Nuer1216.6716.67Hassan et al. (2008)
Eastern Africa    Borgu2615.383.8511.54Hassan et al. (2008)
Eastern Africa    Nuba28253.573.577.1410.71Hassan et al. (2008)
Eastern Africa    Masalit3271.883.1315.6353.13Hassan et al. (2008)
Eastern Africa    Fur3259.3818.7540.63Hassan et al. (2008)
Eastern Africa    Nubians3915.3812.822.56Hassan et al. (2008)
Eastern Africa    Fulani from Sudan2634.6230.773.85Hassan et al. (2008)
Eastern Africa    Hausa from Sudan323.133.13Hassan et al. (2008)
Eastern Africa    Egyptian Copts from Sudan3315.1515.15Hassan et al. (2008)
Eastern Africa    Beja4235.714.7630.95Hassan et al. (2008)
Eastern Africa    Gaalien5018.006.006.006.00Hassan et al. (2008)
Eastern Africa    Meseria2814.293.5710.71Hassan et al. (2008)
Eastern Africa    Arakien2416.678.334.174.17Hassan et al. (2008)
Eastern Africa    Amhara348.828.82Cruciani et al. (2007)
Eastern Africa    Ethiopian Jews229.099.09Cruciani et al. (2007)
Eastern Africa    Mixed Ethiopians1233.33258.33Cruciani et al. (2007)
Eastern Africa    Borana/Oromo (Kenya/Ethiopia)3240.6340.63Cruciani et al. (2007)
Eastern Africa    Wolayta1216.678.338.33Cruciani et al. (2007)
Eastern Africa    Saho from Eritrea9488.388.3Trombetta (2015)
Eastern Africa    Somali from Ethiopia1233.38.325Trombetta (2015)
Eastern Africa    Somali from Somalia58080Trombetta (2015)
Eastern Africa    Somali from Kenya68080Trombetta (2015)
Eastern Africa    Nilotic from Kenya1811.1111.11Cruciani et al. (2007)
Eastern Africa    Bantu from Kenya283.573.57Cruciani et al. (2007)
Eastern Africa    Western Africa1230.810.81Cruciani et al. (2007)
Eastern Africa    Central Africa1500.670.67Cruciani et al. (2007)
Eastern Africa    Southern Afric105Cruciani et al. (2007)
Western Asia    Istanbul Turkish358.572.865.71Cruciani et al. (2007)
Western Asia    Southwestern Turkish402.52.5Cruciani et al. (2007)
Western Asia    Northeastern Turkish41Cruciani et al. (2007)
Western Asia    Southeastern Turkish244.174.17Cruciani et al. (2007)
Western Asia    Erzurum Turkish2544Cruciani et al. (2007)
Western Asia    Central Anatolian616.561.644.92Cruciani et al. (2007)
Western Asia    Turkish Cypriots4613.0410.872.17Cruciani et al. (2007)
Western Asia    Sephardi Turkish19Cruciani et al. (2007)
Western Asia    Palestinians2910.343.456.9Cruciani et al. (2007)
Western Asia    Druze Arabs2810.7110.71Cruciani et al. (2007)
Western Asia    Bedouin283.573.57Cruciani et al. (2007)
Western Asia    Syrians10022Cruciani et al. (2007)
Western Asia    Kurds from Iraq20Cruciani et al. (2007)
Western Asia    Arabs from United Arab Emirates402.52.5Cruciani et al. (2007)
Western Asia    Omanite1060.940.94Cruciani et al. (2007)
Western Asia    Adygei18Cruciani et al. (2007)
Western Asia    Azeri972.062.06Cruciani et al. (2007)

Subclades of M78

Interpolated frequency distribution of haplogroup E-M78.[15]

Listed here are the main subclades of M78 as of June 2015. Within the E-M78 subclade, Trombetta et al. 2015 allocated most of the former E-M78* chromosomes to three new distinct branches: E-V1083*, E-V1477 and E-V259. The first is a paragroup sister to clades E-V22 and E-V13. The mutation V1477 defines a new basal branch observed only in one northern African sample. Finally, a sister clade of E-V12, defined by V264, includes E-V65 and a new central African lineage defined by V259.[9] The rare M78 subhaplogroup E1b1b1a1-PF2186 has been found at highest frequencies among the Toubou population inhabiting Chad (21%).[16]

  • E-M78 (E1b1b1a1) North Africa, Horn of Africa, West Asia, Europe (formerly E1b1b1a).
    • E-M78*
    • E-V1477 Found in Tunisian Jews.
    • E-V1083
    • PF2186 Found among Toubou in Lake Chad area.
      • E-V1083* Found only in Eritrea (1.1%) and Sardinia (0.3%).
      • E-V13 (E1b1b1a1b)
      • E-V22
    • E-V1129
      • E-V12
        • E-V12*
        • E-V32
      • E-V264
        • E-V259 Found in Chadic (Afro-Asiatic) speakers from Northern Cameroon.
        • E-V65

E-V12

Interpolated frequency distribution of haplogroup E-V12.[15]

This subclade of E-M78 is the one which appears to have split from the others first (it arose c. 13.7-15.2 kya[17]). According to Cruciani et al. (2007), the E-V12 sublineage likely originated in North Africa.

Undifferentiated E-V12* lineages

Undifferentiated E-V12* lineages (not E-V32 or E-M224, so therefore named "E-V12*") peak in frequency among Southern Egyptians (up to 74.5%).[18] The subclades are also scattered widely in small amounts in both Northern Africa and Europe, but with very little sign in Western Asia, apart from Turkey.[2] These E-V12* lineages were formerly included (along with many E-V22* lineages[Note 1]) in Cruciani et al.'s original (2004) "delta cluster", which he had defined using Y-STR profiles. With the discovery of the defining SNP, Cruciani et al. (2007) reported that V12* was found in its highest concentrations in Egypt, especially Southern Egypt. Hassan et al. (2008) report a significant presence of E-V12* in neighboring Sudan, including 5/33 Copts and 5/39 Nubians. E-V12* made up approximately 20% of the Sudanese E-M78. They propose that the E-V12 and E-V22 sub-clades of E-M78 might have been brought to Sudan from their place of origin in North Africa after the progressive desertification of the Sahara around 6,000–8,000 years ago. Sudden climate change might have forced several Neolithic cultures/people to migrate northward to the Mediterranean and southward to the Sahel and the Nile Valley.[19] The E-V12* paragroup is also observed in Europe (e.g. amongst French Basques) and Eastern Anatolia (e.g. Erzurum Turks).[2]

The non-basal subhaplogroup E1b1b-V12/E3b1a1 has been found at highest frequencies among various Afroasiatic-speaking populations in eastern Africa, including Garreh (74.1%), Gabra (58.6%), Wata (55.6%), Borana (50.0%), Sanye (41.7%), Beja (33.3%) and Rendille (29.0%).[20]

E-M224

E-M224 has been found in Israel among Yemeni population (5%) and appears to be a minor subclade.

Its discovery was announced in Underhill et al. (2001) and Shen et al. (2004) found 1 out of their 20 Yemeni Israelis they tested. Cruciani et al. (2006) called M224 "rare and rather uninformative" and they found no exemplars.

E-V32
The distribution of V-32 in Africa

Cruciani et al. (2007) suggest that this subclade of E-V12 originated in North Africa, and then subsequently expanded further south into the Horn of Africa, where it is now prevalent.[Note 2] Before the discovery of V32, Cruciani et al. (2004) referred to the same lineages as the "gamma cluster", which was estimated to have arisen about 8,500 years ago. They stated that "the highest frequencies in the three Cushitic-speaking groups: the Borana from Kenya (71.4%), the Oromo from Ethiopia (32.0%), and the Somali (52.2%). Outside of eastern Africa, it was found only in two subjects from Egypt (3.6%) and in one Arab from Morocco". Sanchez et al. (2005) found it extremely prominent in Somali men and stated that "the male Somali population is a branch of the Horn African population – closely related to the Oromos in Ethiopia and North Kenya (Boranas)" and that their gamma cluster lineages "probably were introduced into the Somali population 4000–5000 years ago". More recently, Tillmar et al. (2009) typed 147 males from Somalia for 12 Y-STR loci, and observed that 77% (113/147) had typical E-V32 haplotypes. This is currently the highest frequency of E-V32 found in any single sample population. Similarly, Hassan et al. (2008) in their study observed this to be the most common of the sub-clades of E-M78 found in Sudan, especially among the Beja, Masalit and Fur. The Beja, like Somalis and Oromos, speak an Afro-Asiatic language and live along the "corridor" from the Horn of Africa to Egypt. Hassan et al. (2008) interpret this as reinforcing the "strong correlation between linguistic and genetic diversity" and signs of relatedness between the Beja and the peoples of the Horn of Africa such as the Amhara and Oromo. On the other hand, the Masalit and Fur live in Darfur and speak a Nilo-Saharan language. The authors observed in their study that "the Masalit possesses by far the highest frequency of the E-M78 and of the E-V32 haplogroup", which they believe suggests "either a recent bottleneck in the population or a proximity to the origin of the haplogroup." However, More recently, Tillmar et al. (2009) typed 147 males from Somalia for 12 Y-STR loci, and observed that 77% (113/147) had typical E-V32 haplotypes. This is the highest frequency of E-V32 found in any single sample population.

The STR data from Cruciani et al. (2007) concerning E-V12 can be summarized as follows.

Haplotype description YCAIIa YCAIIb DYS413a DYS413b DYS19 DYS391 DYS393 DYS439 DYS460 DYS461 A10
E-V12*modal192222221310131111913
min18212021111012118811
max1922222315121413121014
number4040404040404040404040
E-V32modal1921222311101312101013
min19192021119121191011
max2022222411111313121114
number3535353535353535353535
All E-V12modal1922222311101311111013
min1819202111912118811
max2022222415121413121114
number7575757575757575757575

E-V13

The distribution of E-V13 according to the dataset of Cruciani (2007) et al. listed above

The E-V13 clade is equivalent to the "alpha cluster" of E-M78 reported in Cruciani et al. (2004), and was first defined by the SNP V13 in Cruciani et al. (2006). Another SNP is known for this clade, V36, reported in Cruciani et al. (2007). All known positive tests for V13 are also positive for V36. So E-V13 is currently considered "phylogenetically equivalent" to E-V36.

Haplogroup E-V13 is the only lineage that reaches the highest frequencies out of Africa. In fact, it represents about 85% of the European E-M78 chromosomes with a clinal pattern of frequency distribution from the southern Balkan peninsula (19.6%) to western Europe (2.5%). The same haplogroup is also present at lower frequencies in Anatolia (3.8%), the Near East (2.0%), and the Caucasus (1.8%). In Africa, haplogroup E-V13 is rare, being observed only in northern Africa at a low frequency (0.9%).

According to some authors E-V13 appears to have originated in Greece or the southern Balkans and its presence in the rest of the Mediterranean is likely a consequence of Greek colonization.[21][22][23] Within Europe, E-V13 is especially common in the Balkans and some parts of Italy. In different studies, particularly high frequencies have been observed in Kosovo Albanians (45.6%[24]), Macedonian Albanians (34.4%[14]), Albanians (32.29%Cruciani et al. (2007)) , and in some parts of Greece (ca. 35%[25]).[26] More generally, high frequencies have also been found in other areas of Greece, and amongst Bulgarians, Romanians, Macedonians and Serbs.[6][13][27][28]

Within Italy, frequencies tend to be higher in Southern Italy,[2] with particularly high results sometimes seen in particular areas; for example, in Santa Ninfa and Piazza Armerina in Sicily.[29] High frequencies appear to exist also in some northern areas[Note 3] for example around Venice,[Note 4] Genoa[30] and Rimini,[31] as well as on the island of Corsica [32] and the region of Provence in south France,[23] and is also found in scattered and small amounts in Libyan Jews and Egypt, but this is most likely a result of migration from Europe or the Near East.[2]

Among ancient specimens, Loosdrecht et al. (2018) found one E-M78-carrying fossil at the Grotte des Pigeons near Taforalt in eastern Morocco. The skeleton has been directly dated to between 15,100 and 13,900 calibrated years before present.[8]

E-V13 and ancient migrations

The apparent movement of E-M78 lineages from the Near East to Europe, and their subsequent rapid expansion, make its E-V13 subclade a particularly interesting subject for speculation about ancient human migrations.

It was concluded that northeastern Africa, rather than eastern Africa, was where the E-M78 chromosomes began dispersing to other regions.[33] The most plausible scenario is that E-V13 originated in Western Asia.[34] A hypothesis is that E-M78 carriers devoid of V13 mutation left Africa and that the coalescence occurred later in the Near East/Anatolia.[34] Data suggests that Western Asian carriers of V13 expanded in Europe at earliest 5300 years ago.[34] The TMRCA of European V13 is 4700–4000 years ago.[34] Phylogenetic analysis suggest that the European v13 spread through Europe from the Balkans in a "rapid demographic expansion".[34]

Before then, the SNP mutation, V13 apparently first arose in West Asia around 10 thousand years ago, and although not widespread there, it is for example found in high levels (>10% of the male population) in Turkish Cypriot and Druze Arab lineages.[2] The Druze are considered a genetically isolated community, and are therefore of particular interest.[35] The STR DNA signature of some of the E-V13 men amongst them was actually originally classified in the delta cluster in Cruciani et al. (2004). This means that Druze E-V13 clustered together with most E-V12 and E-V22, and not with European E-V13, which was mostly in the alpha cluster.

haplotype description YCAIIa YCAIIb DYS413a DYS413b DYS19 DYS391 DYS393 DYS439 DYS460 DYS461 A10
All E-V13modal192123241310131291013
Druze V131192123231310131311912
Druze V132192123231310131311913
All E-V22modal1922222314101312111012
All E-V12*modal192222221310131111913
Early migration from the Middle East to Europe

The distribution and diversity of V13 are often thought to represent the introduction of early farming technologies, during the Neolithic expansion, into Europe by way of the Balkans.[12] The haplogroup J2b (J-M12) has also frequently been discussed in connection with V13, as a haplogroup with a seemingly very similar distribution and pre-history.[3][6][12] (There is no consensus regarding the circumstances or timing of its evolution.)

Cruciani et al. (2007) says there were at least four major demographic events which have been envisioned for this geographic area:

The last two seem within the timespan possible for V13 given its STR age of arise putatively in the Middle East. In favor of the agricultural connection, human remains excavated in a Spanish funeral cave dating from approximately 7000 years ago were shown to be in this haplogroup.[36]

However, earlier entry into Europe is also possible. Battaglia et al. (2008), for example, propose that the E-M78* lineage ancestral to all modern E-V13 men moved rapidly out of a Southern Egyptian homeland, in the wetter conditions of the early Holocene; arrived in the Balkans with only Mesolithic technologies and then only subsequently integrated with Neolithic cultures which arrived later in the Balkans.

E-V13 is in any case often described in population genetics as one of the components of the European genetic composition which shows a relatively recent link of populations from the Middle East, entering Europe and presumably associated with bringing new technologies.[37][38][39] As such, it is also sometimes remarked that it is a relatively recent genetic movement out of Africa into Eurasia, and has been described as "a signal for a separate late-Pleistocene migration from Africa to Europe over the Sinai ... which is not manifested in mtDNA haplogroup distributions".[40]

After its initial entry in Europe, there was then a dispersal from the Balkans into the rest of Europe. Also for this movement, a wide range of possibilities exists. Battaglia et al. (2008) suggest that the E-V13 subclade of E-M78 originated in situ in Europe, and 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. The above-mentioned find of archaic E-V13 in Spain supports this suggestion.

In contrast, Cruciani et al. (2007) suggest that the movement out of the Balkans may have been more recent than 5300 years ago. The authors suggest that for the most part, modern E-V13 descends from a population which remained in the Balkans until the Balkan Bronze Age. 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". Peričic et al. (2005) propose the Vardar-Morava-Danube rivers as a possible route of Neolithic dispersal into central Europe. Bird (2007) proposes a still more recent dispersal out of the Balkans, around the time of the Roman empire.

According to Lacan et al. (2011), Neolithic skeletons (~7,000 years old) that were excavated from the Avellaner cave in Catalonia, northeastern Spain included a male specimen, which carried haplogroup E1b1b. This fossil belonged to the E1b1b1a1b (V13) subclade, and possessed identical haplotypes as found in modern European individuals (five Albanians, two Provence French, two Corsicans, two Bosnians, one Italian, one Sicilian, and one Greek). The presence of this haplogroup in Neolithic Spain suggests that it is associated with the Neolithic agricultural package. The ancient farmer also bore the U5 mtDNA clade, an early European maternal haplogroup. His autosomal STR markers were likewise most typical of Europe. Additionally, the specimen was homozygous C/C for the LP-13910-C/T lactase persistence SNP, indicating that he was lactose intolerant.

Greek soldiers in Pakistan

Both E-M78 and J-M12 have also been used in studies seeking to find evidence of a remaining Greek presence in Afghanistan and Pakistan, going back to the time of Alexander the Great.

An extensive analysis of Y diversity within Greeks and three Pakistani populations – the Burusho, Kalash and Pathan – who claim descent from Greek soldiers allowed us to compare Y lineages within these populations and re-evaluate their suggested Greek origins. This study as a whole seems to exclude a large Greek contribution to any Pakistani population, confirming previous observations. However, it provides strong evidence in support of the Greek origins for a small proportion of Pathans, as demonstrated by the clade E network and the low pairwise genetic distances between these two populations.

Firasat et al. (2006)

This study however tested only for M78, and not V13, the typical type of M78 from the Balkans. More recent and detailed analyses of E-V13 in this region have however concluded that this hypothesis is incorrect, and that the variants found there are not the types typical of the Balkans.[41] Instead "Afghanistan's lineages are correlated with Middle Easterners and Iranians but not with populations from the Balkans"[42]

Ancient Britain

Significant frequencies of E-V13 have also been observed in towns in Wales, around Chester (ancient Deva Victrix) in England, and Scotland. The old trading town of Abergele on the northern coast of Wales in particular showed 7 out of 18 local people tested were in this lineage (approximately 40%), as reported in Weale et al. (2002).

Some scholars (e.g. Steven Bird (2007) have attributed the presence of E-V13 in Great Britain, especially in areas of high frequency, to Roman settlement during the 1st through 4th centuries CE. The Roman Army including men of Balkan ancestry, including Thracians, Illyrians and Dacians. In particular, Steven Bird proposes a connection to a modern region encompassing Kosovo, southern Serbia, northern Macedonia, and extreme northwestern Bulgaria – a region corresponding to the Roman province of Moesia Superior, which was identified by Peričic et al. (2005) as harboring the highest frequency worldwide of this subclade.[Note 5]

It is also notable that E-V13 appears to be absent in modern central England, especially the West Midlands and South Midlands.[Note 6] Bird (2007) notes that the collective genetic profile of the English Midlands is similar to that of the Dutch province of Friesland, which was not colonised by Rome, but was, like England, subject to Anglo-Saxon settlement. The so-called "E3b hole" in Central England, according to Steven Bird, may reflect a population replacement – of Romano-British people by Anglo-Saxons.[Note 7] Thomas et al. (2006) raises the possibility of "apartheid"-type, elite dominance social structures in Anglo-Saxon England. Bird (2007) concurs: "The 'E3b hole' suggests that either (a) a massive displacement of the ... Romano-British population by invasion or, (b) the substantial genetic replacement of Romano-British Y-DNA through an elite dominance ("apartheid") model... Regardless of the mechanism, the Central England region ... with its lack of E3b haplotypes, is the area having the most "striking similarity in the distribution of Y-chromosomes" with Friesland."

Sub-clades of E-V13

Although most E-V13 individuals do not show any known downstream SNP mutations, and are therefore categorized as E-V13* there are several recognized sub-clades, all of which may be very small. These are one of two cases where Karafet et al. (2008) remarked that at the time of that article, it was not certain that the two clades were truly separate ("the positions of these mutations have not been resolved because of a lack of a DNA sample containing the derived state at V27").

  • E-V27. Defined by V27. Cruciani et al. (2007) found one case in Sicily.
  • E-P65. Defined by P65.
  • E-L17. Defined by L17.
  • E-L143. Defined by L143.
  • E-M35.2. Defined by M35.2.
  • E-L241. Defined by L241.
  • E-L250. Defined by L250, L251, and L252.

E-V22

Interpolated frequency distribution of haplogroup E-V22.[15]

This clade comprises most of those classified in the "delta cluster" of Cruciani et al. (2004). Cruciani et al. (2006) later noted that "E-V22 and E-V12* chromosomes are intermingled and not clearly differentiated by their microsatellite haplotypes".

This subclade of E-M78 is "relatively common"[2] in the Horn of Africa and Egypt, with higher microsatellite variance (0.35 vs. 0.46, respectively) in Egypt. In the article announcing this first information, Cruciani et al. (2007) described it as uncommon in Western Asia and they proposed Northeast Africa and/or East Africa as this subclade's likely place of origin.

The highest frequency of E-V22 has thus far been observed in the Cushitic-speaking Saho population of central Eritrea at a rate of 88%.[9] The Saho are known to be organized in strict patrilineal and patrilocal clans. It has been hypothesized that this kind of social structure can explain patterns of variability characterized by low Y-chromosome diversity within groups and large difference between groups.[43]

Hassan et al. (2008) also reported a significant presence in neighboring Sudan, making up about 30% of the diverse range of the country's E-M78 lineages in their study, including 8 out of 26 Fulani (about 31%), a widely-dispersed pastoral people.[Note 8] E-V22 was also present in much smaller frequencies amongst the Shilluk (2 of 15 samples, 13%) and Dinka (3 of 26, 11.5%) Nilotes of Southern Sudan. Hassan et al. suggest that E-V22, like E-V12, might have entered Sudan from North Africa "after the progressive desertification of the Sahara around 6,000–8,000 years ago". They add that the gene flow to Sudan "is not only recent (Holocene onward) but also largely of focal nature", and that "most speakers of Nilo-Saharan languages, the major linguistic family spoken in the country, show very little evidence of gene flow and demonstrate low migration rate, with exception of the Nubians, who appear to have sustained considerable gene flow from Asia and Europe together with the Beja."

Other frequencies reported by Cruciani et al. (2007) include Asturians (4.44% out of 90 people), Sicilians (4.58% out of 153 people), Moroccan Arabs (7.27%, 55 people), Moroccan Jews (8%, 50 people), Istanbul Turkish (5.71% out of 35 people), and Palestinians (6.9% out of 29 people). Cadenas et al. (2007) found a 6.7% presence in the UAE.

Sub-clades of E-V22

There are two recognized sub-clades, which are apparently separate, although Karafet (2008) remarked that at the time of that article, "the positions of these mutations have not been resolved because of a lack of a DNA sample containing the derived state at [...] V19".

E-V65

This subclade, equivalent to the previously classified "beta cluster", is found in high levels in the Maghreb regions of far northern Africa. Cruciani et al. (2007) report levels of about 20% amongst Libyan Arab lineages, and about 30% amongst Moroccan Arabs. It appears to be less common amongst Berbers, but still present in levels of >10%. The authors suggest a North African origin for this lineage. In Europe, only a few individuals were found in Italy and Greece. The results from the article can be summarized as follows...

E-V65 YCAIIa YCAIIb DYS413a DYS413b DYS19 DYS391 DYS393 DYS439 DYS460 DYS461 A10
modal1921212313101310101113
min19202022111013109912
max2121222314111411111213
number3838383838383838383838

Capelli et al. (2009) studied the beta cluster in Europe. They found small amounts in Southern Italy, but also traces in Cantabria, Portugal and Galicia, with Cantabria having the highest level in Europe in their study, at 3.1% (5 out of 161 people).

E-M521

This subclade's discovery was announced in Battaglia et al. (2008) They found 2 out of 92 Greeks to have this mutation.

Phylogenetics

Phylogenetic history

Prior to 2002, there were in academic literature at least seven naming systems for the Y-Chromosome Phylogenetic tree. This led to considerable confusion. In 2002, the major research groups came together and formed the Y-Chromosome Consortium (YCC). They published a joint paper that created a single new tree that all agreed to use. Later, a group of citizen scientists with an interest in population genetics and genetic genealogy formed a working group to create an amateur tree aiming at being above all timely. The table below brings together all of these works at the point of the landmark 2002 YCC Tree. This allows a researcher reviewing older published literature to quickly move between nomenclatures.

YCC 2002/2008 (Shorthand) (α) (β) (γ) (δ) (ε) (ζ) (η) YCC 2002 (Longhand) YCC 2005 (Longhand) YCC 2008 (Longhand) YCC 2010r (Longhand) ISOGG 2006 ISOGG 2007 ISOGG 2008 ISOGG 2009 ISOGG 2010 ISOGG 2011 ISOGG 2012
E-P2921III3A13Eu3H2BE*EEEEEEEEEE
E-M3321III3A13Eu3H2BE1*E1E1aE1aE1E1E1aE1aE1aE1aE1a
E-M4421III3A13Eu3H2BE1aE1aE1a1E1a1E1aE1aE1a1E1a1E1a1E1a1E1a1
E-M7521III3A13Eu3H2BE2aE2E2E2E2E2E2E2E2E2E2
E-M5421III3A13Eu3H2BE2bE2bE2bE2b1-------
E-P225III414Eu3H2BE3*E3E1bE1b1E3E3E1b1E1b1E1b1E1b1E1b1
E-M28III515Eu2H2BE3a*E3aE1b1E1b1aE3aE3aE1b1aE1b1aE1b1aE1b1a1E1b1a1
E-M588III515Eu2H2BE3a1E3a1E1b1a1E1b1a1E3a1E3a1E1b1a1E1b1a1E1b1a1E1b1a1a1aE1b1a1a1a
E-M116.28III515Eu2H2BE3a2E3a2E1b1a2E1b1a2E3a2E3a2E1b1a2E1b1a2E1ba12removedremoved
E-M1498III515Eu2H2BE3a3E3a3E1b1a3E1b1a3E3a3E3a3E1b1a3E1b1a3E1b1a3E1b1a1a1cE1b1a1a1c
E-M1548III515Eu2H2BE3a4E3a4E1b1a4E1b1a4E3a4E3a4E1b1a4E1b1a4E1b1a4E1b1a1a1g1cE1b1a1a1g1c
E-M1558III515Eu2H2BE3a5E3a5E1b1a5E1b1a5E3a5E3a5E1b1a5E1b1a5E1b1a5E1b1a1a1dE1b1a1a1d
E-M108III515Eu2H2BE3a6E3a6E1b1a6E1b1a6E3a6E3a6E1b1a6E1b1a6E1b1a6E1b1a1a1eE1b1a1a1e
E-M3525III414Eu4H2BE3b*E3bE1b1b1E1b1b1E3b1E3b1E1b1b1E1b1b1E1b1b1removedremoved
E-M7825III414Eu4H2BE3b1*E3b1E1b1b1aE1b1b1a1E3b1aE3b1aE1b1b1aE1b1b1aE1b1b1aE1b1b1a1E1b1b1a1
E-M14825III414Eu4H2BE3b1aE3b1aE1b1b1a3aE1b1b1a1c1E3b1a3aE3b1a3aE1b1b1a3aE1b1b1a3aE1b1b1a3aE1b1b1a1c1E1b1b1a1c1
E-M8125III414Eu4H2BE3b2*E3b2E1b1b1bE1b1b1b1E3b1bE3b1bE1b1b1bE1b1b1bE1b1b1bE1b1b1b1E1b1b1b1a
E-M10725III414Eu4H2BE3b2aE3b2aE1b1b1b1E1b1b1b1aE3b1b1E3b1b1E1b1b1b1E1b1b1b1E1b1b1b1E1b1b1b1aE1b1b1b1a1
E-M16525III414Eu4H2BE3b2bE3b2bE1b1b1b2E1b1b1b1b1E3b1b2E3b1b2E1b1b1b2aE1b1b1b2aE1b1b1b2aE1b1b1b2aE1b1b1b1a2a
E-M12325III414Eu4H2BE3b3*E3b3E1b1b1cE1b1b1cE3b1cE3b1cE1b1b1cE1b1b1cE1b1b1cE1b1b1cE1b1b1b2a
E-M3425III414Eu4H2BE3b3a*E3b3aE1b1b1c1E1b1b1c1E3b1c1E3b1c1E1b1b1c1E1b1b1c1E1b1b1c1E1b1b1c1E1b1b1b2a1
E-M13625III414Eu4H2BE3ba1E3b3a1E1b1b1c1aE1b1b1c1a1E3b1c1aE3b1c1aE1b1b1c1a1E1b1b1c1a1E1b1b1c1a1E1b1b1c1a1E1b1b1b2a1a1

Research publications

The following research teams per their publications were represented in the creation of the YCC tree.

  • α Jobling and Tyler-Smith 2000 and Kaladjieva 2001
  • β Underhill 2000
  • γ Hammer 2001
  • δ Karafet 2001
  • ε Semino 2000
  • ζ Su 1999
  • η Capelli 2001

See also

Genetics

Y-DNA E subclades

Y-DNA backbone tree

Phylogenetic tree of human Y-chromosome DNA haplogroups [χ 1][χ 2]
"Y-chromosomal Adam"
A00 A0-T [χ 3]
A0 A1 [χ 4]
A1a A1b
A1b1 BT
B CT
DE CF
D E C F
F1  F2  F3  GHIJK
G HIJK
IJK H
IJ K
I   J     LT [χ 5]       K2 [χ 6]
L     T    K2a [χ 7]        K2b [χ 8]     K2c     K2d K2e [χ 9]  
K-M2313 [χ 10]     K2b1 [χ 11] P [χ 12]
NO   S [χ 13]  M [χ 14]    P1     P2
N O Q R

Notes

  1. Cruciani et al. (2004): "E-V22 and E-V12* chromosomes are intermingled and not clearly differentiated by their microsatellite haplotypes". In Cruciani et al. (2007) the same authors show that a branch of E-V13 found amongst the Druze Arabs is also in the delta cluster. (Contrast the data tables of Cruciani et al. (2007) and Cruciani et al. (2004).)
  2. Cruciani et al. (2007): Fig. 2/C
  3. Genetic surveys do not all test the same markers.
  4. Scozzari et al. 2001. See clade 25.1. The same data set was later used in Cruciani et al. (2004) and Cruciani et al. (2007).
  5. Doubts about this line of reasoning have been expressed because: (a.) new data appearing in King et al. (2008) indicates that there were also high concentrations of E-V13 in Greece and (b.) the data in Peričic et al. (2005) show that the area with the highest frequency does not have the highest diversity, implying that V13 arrived there more recently than in Greece.
  6. Bird uses three sources: Weale et al. (2002), Capelli et al. (2003) and Sykes (2006). Neither Capelli nor Weale have data from the area in the English Midlands where Bird suggests that there is a lack of E1b1b [editor E-M243]. In 2006 Bird mentioned that there were 193 Central English haplotypes in Sykes.
  7. However, in the E3b distribution maps published in Bird's own paper – the Norfolk area is shown as having a high percentage of E3b. Norfolk is part of the epicentre of the supposed Anglian invasion.
  8. Rosa et al. (2007) in a study of Guinea Bissau, showed that the Fulani there are about 10% E-M78. Note that this study did not test specifically for V12 or V22, so the E-M78 may have a different exact breakdown of diversity as well as a lower frequency.
  1. "E-L539 YTree".
  2. Cruciani et al. (2007)
  3. Battaglia et al. (2008)
  4. ISOGG, Copyright 2016 by. "ISOGG 2017 Y-DNA Haplogroup E". isogg.org. Retrieved 2019-01-07.
  5. Cruciani et al. (2007) Table 1
  6. Cruciani et al. (2004)
  7. Cruciani et al. (2006)
  8. Loosdrecht; et al. (2018). "Pleistocene North African genomes link Near Eastern and sub-Saharan African human populations". Science. 360 (6388): 548–552. Bibcode:2018Sci...360..548V. doi:10.1126/science.aar8380. PMID 29545507.
  9. Trombetta (2015)
  10. Ambrosio et al. (2010)
  11. Rosa et al. (2007)
  12. Semino et al. (2004)
  13. Peričic (2005)
  14. Battaglia et al. 2008.
  15. D'Atanasio E, Trombetta B, Bonito M, Finocchio A, Di Vito G, Seghizzi M; et al. (2018). "The peopling of the last Green Sahara revealed by high-coverage resequencing of trans-Saharan patrilineages". Genome Biol. 19 (1): 20. doi:10.1186/s13059-018-1393-5. PMC 5809971. PMID 29433568.CS1 maint: multiple names: authors list (link)
  16. Haber, Marc; et al. (2016). "Chad Genetic Diversity Reveals an African History Marked by Multiple Holocene Eurasian Migrations". American Journal of Human Genetics. 99 (6): 1316–1324. doi:10.1016/j.ajhg.2016.10.012. PMC 5142112. PMID 27889059. - Y-chromosomal haplogroup frequencies on Table S.4
  17. See Figure 1.
  18. Beniamino Trombetta (2015). "Phylogeographic refinement and large scale genotyping of human Y chromosome haplogroup E provide new insights into the dispersal of early pastoralists in the African continent". Genome Biology and Evolution. 7 (7): 1940–1950. doi:10.1093/gbe/evv118. PMC 4524485. PMID 26108492.
  19. Hassan et al. (2008)
  20. Hirbo, Jibril Boru. "Complex Genetic History of East African Human Populations" (PDF). University of Maryland, College Park. Retrieved 13 July 2017.
  21. Sarno, Stefania; et al. (2014). "An Ancient Mediterranean Melting Pot: Investigating the Uniparental Genetic Structure and Population History of Sicily and Southern Italy". PLOS ONE. 9 (4): e96074. Bibcode:2014PLoSO...996074S. doi:10.1371/journal.pone.0096074. PMC 4005757. PMID 24788788.
  22. Primorac, Dragan; et al. (2011). "Croatian genetic heritage: Y-chromosome story". Croat Med J. 52 (3): 225–234. doi:10.3325/cmj.2011.52.225. PMC 3118711. PMID 21674820.
  23. King, Roy J.; et al. (2011). "The coming of the Greeks to Provence and Corsica: Y-chromosome models of archaic Greek colonization of the western Mediterranean". BMC Evolutionary Biology. 11: 69. doi:10.1186/1471-2148-11-69. PMC 3068964. PMID 21401952.
  24. Peričic et al. 2005.
  25. King et al. 2008.
  26. Semino et al. (2004) suggest that there might be levels of E-M78 in the Peloponnese above 40%. They found 17 out of 36 there (47%), but justified drawing conclusions from this small sample by referring also to Di Giacomo et al. (2003).
  27. Rosser et al. 2000
  28. King et al. (2008)
  29. Di Gaetano et al. (2008)
  30. Di Giacomo et al. (2003)
  31. Pelotti et al. 2007
  32. Francalacci et al. 2003
  33. Cruciani et al. 2007, "Locating the Origin of Haplogroup E-M78".
  34. Cruciani et al. 2007, "The Haplogroup E-V13: Migrations and Demographic Expansions in Western Eurasia".
  35. Shlush et al. (2008)
  36. Lacan et al. (2011)
  37. Semino et al. (2000)
  38. King and Underhill (2002)
  39. Underhill (2002)
  40. Underhill and Kivisild (2007)
  41. Lacau et al. (2012)
  42. Haber et al. (2012)
  43. Iacovacci, Giuseppe; et al. (2017). "Forensic data and microvariant sequence characterization of 27 Y-STR loci analyzed in four Eastern African countries". Forensic Science International: Genetics. 27: 123–131. doi:10.1016/j.fsigen.2016.12.015. PMID 28068531. Retrieved 23 September 2018.

References

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