All mtDNA haplogroups considered native outside of Africa are descendants of either haplogroup M or its sibling haplogroup N.[14] Haplogroup M is relatively young, having a younger most recent common ancestor date than some subclades of haplogroup N such as haplogroup R.[15]
Origins
There is a debate concerning the geographical origins of Haplogroup M and its sibling haplogroup N. Both lineages are thought to have been the main surviving lineages involved in the out of Africa migration (or migrations) because all indigenous lineages found outside Africa belong to haplogroup M or haplogroup N. Scientists are unsure whether the mutations that define haplogroups M and N occurred in Africa before the exit from Africa or in Asia after the exit from Africa. Determining the origins of haplogroup M is further complicated by an early back-migration (from Asia to Africa) of bearers of M1.[5]
Its date of origin in absolute terms is only known with great uncertainty, as reconstruction has yielded different (but overlapping) ranges for the age of M in South Asia and East Asia. The same authors give an estimate for t of L3 as 71.6+15.0 −14.5kya,[16] later (2011) narrowed to the somewhat younger 65±5kya.[1] Thus, haplogroup M would have emerged around 10,000 or at most 20,000 years after L3, around or somewhat after the recent out-of-Africa migration event.
Haplogroup M1
Much discussion concerning the origins of haplogroup M has been related to its subclade haplogroup M1, which is the only variant of macro-haplogroup M found in Africa.[14] Two possibilities were being considered as potential explanations for the presence of M1 in Africa:
M was present in the ancient population which later gave rise to both M1 in Africa, and M more generally found in Eurasia.[17]
The presence of M1 in Africa is the result of a back-migration from Asia which occurred sometime after the Out of Africa migration.[5]
Haplogroup M23
In 2009, two independent publications reported a rare, deep-rooted subclade of haplogroup M, referred to as M23, that is present in Madagascar.[18][19]
The contemporary populations of Madagascar were formed in the last 2,000 years by the admixture of Bantu and Indonesian (Austronesian) populations. M23 seems to be restricted to Madagascar, as it has not been detected anywhere else. M23 could have been brought to Madagascar from Asia where most deep rooted subclades of Haplogroup M are found.
Asian origin hypothesis
According to this theory, anatomically modern humans carrying ancestral haplogroup L3 lineages were involved in the Out of Africa migration from East Africa into Asia. Somewhere in Asia, the ancestral L3 lineages gave rise to haplogroups M and N. The ancestral L3 lineages were then lost by genetic drift as they are infrequent outside Africa. The hypothesis that Asia is the origin of macrohaplogroup M is supported by the following:
The highest frequencies worldwide of macrohaplogroup M are observed in Asia, specifically in Bangladesh, China, India, Japan, Korea and Nepal where frequencies range from 60 to 80%. The total frequency of M subclades is even higher in some populations of Siberia or the Americas, but these small populations tend to exhibit strong genetic drift effects, and often their geographical neighbors exhibit very different frequencies.[3][20][21]
Deep time depth >50,000 years of western, central, southern and eastern Indian haplogroups M2, M38, M54, M58, M33, M6, M61, M62 and the distribution of macrohaplogroup M, do not rule out the possibility of macrohaplogroup M arising in Indian population.[22]
With the exception of the African specific M1, India has several M lineages that emerged directly from the root of haplogroup M.[3][21]
Only two subclades of haplogroup M, M1 and M23, are found in Africa, whereas numerous subclades are found outside Africa[3][5] (with some discussion possible only about sub-clade M1, concerning which see below).
Specifically concerning M1
Haplogroup M1 has a restricted geographic distribution in Africa, being found mainly in North Africans and East Africa at low or moderate frequencies. If M had originated in Africa around, or before, the Out of Africa migration, it would be expected to have a more widespread distribution [21]
According to Gonzalez et al. 2007, M1 appears to have expanded relatively recently. In this study M1 had a younger coalescence age than the Asian-exclusive M lineages.[5]
The geographic distribution of M1 in Africa is predominantly North African/supra-equatorial[5] and is largely confined to Afro-Asiatic speakers,[23] which is inconsistent with the Sub-Saharan distribution of sub-clades of haplogroups L3 and L2 that have similar time depths.[14]
One of the basal lineages of M1 lineages has been found in Northwest Africa and in the Near East but is absent in East Africa.[5]
M1 is not restricted to Africa. It is relatively common in the Mediterranean, peaking in Iberia. M1 also enjoys a well-established presence in the Middle East, from the South of the Arabian Peninsula to Anatolia and from the Levant to Iran. In addition, M1 haplotypes have occasionally been observed in the Caucasus and the Trans Caucasus, and without any accompanying L lineages.[5][14] M1 has also been detected in Central Asia, seemingly reaching as far as Tibet.[5]
The fact that the M1 sub-clade of macrohaplogroup M has a coalescence age which overlaps with that of haplogroup U6 (a Eurasian haplogroup whose presence in Africa is due to a back-migration from West Asia) and the distribution of U6 in Africa is also restricted to the same North African and Horn African populations as M1 supports the scenario that M1 and U6 were part of the same population expansion from Asia to Africa.[23]
The timing of the proposed migration of M1 and U6-carrying peoples from West Asia to Africa (between 40,000 to 45,000 ybp) is also supported by the fact that it coincides with changes in climatic conditions that reduced the desert areas of North Africa, thereby rendering the region more accessible to entry from the Levant. This climatic change also temporally overlaps with the peopling of Europe by populations bearing haplogroup U5, the European sister clade of haplogroup U6.[23]
African origin hypothesis
According to this theory, haplogroups M and N arose from L3 in an East African population ancestral to eurasians that had been isolated from other African populations before the OOA event. Members of this population were involved in the out Africa migration and may have only carried M and N lineages. With the possible exception of haplogroup M1, all other M and N clades in Africa were lost due to admixture with other African populations and genetic drift.[8][17]
The African origin of Haplogroup M is supported by the following arguments and evidence.
L3, the parent clade of haplogroup M, is found throughout Africa, but is rare outside Africa.[17] According to Toomas Kivisild (2003), "the lack of L3 lineages other than M and N in India and among non-African mitochondria in general suggests that the earliest migration(s) of modern humans already carried these two mtDNA ancestors, via a departure route over the Horn of Africa."[8]
Specifically concerning at least M1a:
This study provides evidence that M1, or its ancestor, had an Asiatic origin. The earliest M1 expansion into Africa occurred in northwestern instead of northeastern areas; this early spread reached the Iberian Peninsula even affecting the Basques. The majority of the M1a lineages found outside and inside Africa had a more recent eastern Africa origin. Both western and eastern M1 lineages participated in the Neolithic colonization of the Sahara. The striking parallelism between subclade ages and geographic distribution of M1 and its North African U6 counterpart strongly reinforces this scenario. Finally, a relevant fraction of M1a lineages present today in the European Continent and nearby islands possibly had a Jewish instead of the commonly proposed Arab/Berber maternal ascendance.[5]
Dispersal
Hypothesized map of human migration based on mitochondrial DNA
A number of studies have proposed that the ancestors of modern haplogroup M dispersed from Africa through the southern route across the Horn of Africa along the coastal regions of Asia onwards to New Guinea and Australia. These studies suggested that the migrations of haplogroups M and N occurred separately with haplogroup N heading northwards from East Africa to the Levant. However, the results of numerous recent studies indicate that there was only one migration out of Africa and that haplogroups M and N were part of the same migration. This is based on the analysis of a number of relict populations along the proposed beachcombing route from Africa to Australia, all of which possessed both haplogroups N and M.[4][24]
A 2008 study by Abu-Amero et al., suggests that the Arabian Peninsula may have been the main route out of Africa. However, as the region lacks of autochthonous clades of haplogroups M and N the authors suggest that the area has been a more recent receptor of human migrations than an ancient demographic expansion center along the southern coastal route as proposed under the single migration Out-of-Africa scenario of the African origin hypothesis.[6]
Distribution
M is the most common mtDNA haplogroup in Asia,[25]super-haplogroup M is distributed all over Asia, where it represents 60% of all maternal lineages.[26]
All Andamanese belong to Haplogroup M.[27] It peaks in the Malaysian aboriginal Negrito tribes at almost 100% but with mtDNA M21a representing Semang; 84% in Mendriq people, Batek people 48%, (almost all belong to the specific Malaysian Negrito haplogroup M21a, this subclade also found in the Orang Asli 21%, Thais 7.8% and Malay 4.6%)[28][29][30] It also peaks very high in Japan and Tibet, where it represents on average about 70% of the maternal lineages (160/216 = 74% Tibet,[31] 205/282 = 73% Tōkai,[32] 231/326 = 71% Okinawa,[32] 148/211 = 70% Japanese,[20] 50/72 = 69% Tibet,[31] 150/217 = 69% Hokkaidō,[33] 24/35 = 69% ZhongdianTibetan, 175/256 = 68% northern Kyūshū,[32] 38/56 = 68% QinghaiTibetan, 16/24 = 67% DiqingTibetan, 66/100 = 66% Miyazaki, 33/51 = 65% Ainu, 214/336 = 64% Tōhoku,[32] 75/118 = 64% Tokyo (JPT)[34]) and is ubiquitous in India[3][14][35] and South Korea,[32][36][37][38][39] where it has approximately 60% frequency. Among Chinese people both inside and outside of China, haplogroup M accounts for approximately 50% of all mtDNA on average, but the frequency varies from approximately 40% in Hans from Hunan and Fujian in southern China to approximately 60% in Shenyang, Liaoning in northeastern China.[31][32][34][37]
Haplogroup M accounts for approximately 42% of all mtDNA in Filipinos, among whom it is represented mainly by M7c3c and E.[40] In Vietnam, haplogroup M has been found in 37% (52/139) to 48% (20/42) of samples of Vietnamese and in 32% (54/168) of a sample of Chams from Bình Thuận Province.[37][41] Haplogroup M accounts for 43% (92/214) of all mtDNA in a sample of Laotians, with its subclade M7 (M7b, M7c, and M7e) alone accounting for a full third of all haplogroup M, or 14.5% (31/214) of the total sample.[42]
In Oceania, A 2008 study found Haplogroup M in 42% (60/144) of a pool of samples from nine language groups in the Admiralty Islands of Papua New Guinea.[43] M has been found in 35% (17/48) of a sample of Papua New Guinea highlanders from the Bundi area and in 28% (9/32) of a sample of Aboriginal Australians from Kalumburu in northwestern Australia.[44] In a study published in 2015, Haplogroup M was found in 21% (18/86) of a sample of Fijians, but it was not observed in a sample of 21 Rotumans.[45]
Haplogroup M is also relatively common in Northeast Africa, occurring especially among Somalis, Libyans and Oromos at frequencies over 20%.[46][47] Toward the northwest, the lineage is found at comparable frequencies among the Tuareg in Mali and Burkina Faso; particularly the M1a2 subclade (18.42%).[48]
Among the descendant lineages of haplogroup M are C, D, E, G, Q, and Z. Z and G are found in North Eurasian populations, C and D exists among North Eurasian and Native American populations, E is observed in Southeast Asian populations, and Q is common among Melanesian populations. The lineages M2, M3, M4, M5, M6, M18 and M25 are exclusive to South Asia, with M2 reported to be the oldest lineage on the Indian sub-continent with an age estimation of 60,000—75,000 years, and with M5 reported to be the most prevalent in historically Turco-Persian enclaves.[3][49][50]
In 2013, four ancient specimens dated to around 2,500 BC-500 AD, which were excavated from the Tell Ashara (Terqa) and Tell Masaikh (Kar-Assurnasirpal) archaeological sites in the Euphrates Valley, were found to belong to mtDNA haplotypes associated with the M4b1, M49 and/or M61 haplogroups. Since these clades are not found among the current inhabitants of the area, they are believed to have been brought at a more remote period from east of Mesopotamia; possibly by either merchants or the founders of the ancient Terqa population.[51]
In 2016, three Late Pleistocene European hunter-gatherers were also found to carry M lineages. Two of the specimens were from the Goyet archaeological site in Belgium and were dated to 34,000 and 35,000 years ago, respectively. The other ancient individual hailed from the La Rochette site in France, and was dated to 28,000 years ago.[52]
Ancient DNA analysis of Iberomaurusian skeletal remains at the Taforalt site in Morocco, which have been dated to between 15,100 and 13,900 ybp, observed the M1b subclade in one of the fossils (1/7; ~14%).[53] Ancient individuals belonging to the Late Iron Age settlement of Çemialo Sırtı in Batman, southeast Turkey were found to carry haplogroup M; specifically the M1a1 subclade (1/12; ~8.3%). Haplogroup M was also detected in ancient specimens from Southeast Anatolia (0.4%).[54] Additionally, M1 has been observed among ancient Egyptian mummies excavated at the Abusir el-Meleq archaeological site in Middle Egypt, which date from the Pre-Ptolemaic/late New Kingdom and Roman periods.[55] Fossils at the Early Neolithic site of Ifri n'Amr or Moussa in Morocco, which have been dated to around 5,000 BCE, have also been found to carry the M1b subclade. These ancient individuals bore an autochthonous Maghrebi genomic component that peaks among modern Berbers, indicating that they were ancestral to populations in the area.[56] The ancient Egyptian aristocrats Nakht-Ankh and Khnum-Nakht were also found to belong to the M1a1 subclade. The half-brothers lived during the 12th Dynasty, with their tomb located at the Deir Rifeh cemetery in Middle Egypt.[57]
Haplogroup M2 – found in South Asia, with highest concentrations in SE India and Bangladesh;[14] oldest haplogroup M lineage on the Indian sub-continent.[3] Also found with low frequency in southwestern China.[31]
M2a'b
M2a – India (Madhya Pradesh), Munda; most common in Bangladesh
M2a1 – Malpaharia
M2a1a – Uyghur, Sindhi, Hill Kolam, Thailand
M2a1a1 – Katkari
M2a1a1a – Nihal
M2a1a1a1 – Katkari
M2a1a1b – Nihal
M2a1a1b1 – Nihal
M2a1a2 – Madia
M2a1a2a – Madia
M2a1a2a1 – Kamar
M2a1a2a1a – Kamar
M2a1a3 – Mathakur
M2a1a3a – Kathakur, Mathakur
M2a1a3a1 – Kathakur
M2a1a3b – Kathakur
M2a1b – Dungri Bhil
M2a1c – Andh
M2b – Paudi Bhuiya; most common in SE India
M2b1 – Korku
M2b1a – Korku, Munda
M2b1b – Malpaharia
M2b2 – Hill Kolam, Jenu Kuruba
M2b3 – Betta Kurumba
M2b3a – Betta Kurumba
M2b4 – Korku
M2c – Myanmar, Thailand/Laos
Haplogroup M3 – Uyghur, Myanmar, New Delhi (Hindu), Paniya – found mainly in South Asia, with highest concentrations in west and NW India[14]
Haplogroup M4b – found among ancient specimens in the Euphrates valley
Haplogroup M65
Haplogroup M65a – found in India, Pakistan (Balochi, Sindhi), Sarikoli in Taxkorgan, Xinjiang, China,[50]Pamiri in Gorno-Badakhshan, Tajikistan,[50] Ladakh, Myanmar, China
Haplogroup M65b – found in India[50] and in Pakistan (Balochi)
Haplogroup M30 – mainly in India; also found in Nepal, Pakistan, Central Asia (Kyrgyz, Wakhi, and Sarikoli in Taxkorgan, Xinjiang, China and Tajiks in Dushanbe, Tajikistan[50]), the Middle East, and North Africa.
Haplogroup M5a – found in India (Jammu and Kashmir, Madhya Pradesh, Kathakur,[67]Gadaba[21]), Thailand (Mon in Ratchaburi Province and Lopburi Province[58]), Israel, Kyrgyz in Taxkorgan[50]
M5a1
M5a1a – India (incl. Jammu and Kashmir)
M5a1b – India (Jammu and Kashmir, Dongri Bhil, Nihal, Andh), Pakistan (Burusho), Russia,[68] Spain (Romani), USA (Georgia), USA (California)
M5a2 – India
M5a2a – Pakistan (Balochi), India (Nihal), Thailand (Tai Yuan in Uttaradit Province[58])
M5a2a1 – India (Hindus in New Delhi), Pakistan (Sindhi)
M5a2a1a – Saudi Arabia, Iran (Persian),[49] Kazakh, Pakistan (Balochi), India (Dongri Bhil, Korku, Lachungpa), Myanmar
Haplogroup M61 – found among ancient specimens in the Euphrates valley
Haplogroup M7 – found in East Asia and Southeast Asia, especially in Japan, southern China, Vietnam,[70]Laos,[42] and Thailand;[58] also found with low frequency in Central Asia and Siberia
Haplogroup M9 – found in East Asia and Central Asia, especially in Tibet. In the Nepalese populations, it is prevalent mainly in Sherpa (27.4%), Tharu-CI (19.6%), Tamang (15.5%), Magar (13.5%), and Tharu-CII.[77] Haplogroup M9* has additionally been found in ancient remains from the Red Deer Cave people in present-day Yunnan.[78]
Haplogroup M9a'b
Haplogroup M9a – Han (Guangdong, Guangxi, Yunnan, Sichuan, Hunan, Taiwan, Anhui, Shaanxi, Shandong, Hebei), Korean (South Korea), Tujia (Hunan), Kinh (Hue), Mongol (Hohhot), Japanese, Lhoba[61] [TMRCA 23,000 (95% CI 18,100 <-> 28,800) ybp[61]]
Haplogroup M9a1 – Han (Hunan) [TMRCA 19,500 (95% CI 13,800 <-> 26,700) ybp[61]]
Haplogroup M9a1a – Han (Hebei, Henan, Shaanxi, Anhui, Zhejiang, Hunan, Yunnan, Guangdong, Hong Kong, Taiwan), Manchu (Jilin), Korean (South Korea), Hui (Qinghai), Kazakh (Ili), Kyrgyz (Kyrgyzstan), Nepal [TMRCA 16,500 (95% CI 12,800 <-> 20,900) ybp[61]]
Haplogroup M9a1a1 – Han (Henan, Shaanxi, Guangdong, Guangxi, Sichuan, Yunnan), Taiwan, Thailand/Laos, Hui (Yuxi), Tibetan (Nyingchi), Uyghur, Japanese (Hokkaido) [TMRCA 13,900 (95% CI 10,800 <-> 17,600) ybp[61]]
Haplogroup M9a1a1a – Japanese, Korean (Seoul), Chinese (incl. a Henan Han), Khamnigan (Buryat Republic), Udege, Nivkh, Tibetan (Qinghai)
Haplogroup M9a1a1b – Japanese, Korean (South Korea), Mongol (Inner Mongolia), Han (Hunan)
Haplogroup M9a1a1c – Han (Gansu, Shaanxi, Henan, Liaoning, Zhejiang, Jiangxi, Hunan, Guangdong, Sichuan, Yunnan), Ainu, Japanese, Korean, Mongol (Hohhot), Uyghur (Ürümqi), Altaian, Tuvinian, Hui (Xinjiang, Kyrgyzstan), Tujia (Hunan), Bai (Yunnan), Yi (Yunnan)
Haplogroup M9a1a1c1 – Han (Henan)
Haplogroup M9a1a1c1a – Han (Henan, Anhui, Shandong, Liaoning, Sichuan, Yunnan, Xinjiang, Lanzhou[74]), Korea, Japanese, Mongol (New Barga Left Banner), Tibetan (Liangshan), Hui (Ili)
Haplogroup M9a1a1c1b – Tibetan (Gansu, Qinghai, Sichuan, Yunnan, Chamdo, Lhasa, Nagqu, Ngari, Nyingchi, Shannan, Shigatse), Monpa (Nyingchi), Dirang Monpa (Arunachal Pradesh), Lachungpa (Sikkim), Tu (Huzhu Tu Autonomous County), Dongxiang (Gansu), Buryat (Inner Mongolia, Buryat Republic), Han (Qinghai), Hui (Qinghai), Nepalese
Haplogroup M9a1a1d – Salar (Qinghai), Han (Yanting), Bai (Dali)
Haplogroup M9a1a2 – Tharu (Chitwan District, Uttar Pradesh), Tibetan (Nagqu, Yunnan, Qinghai, Shigatse), Lhoba (Nyingchi), Dhimal (West Bengal), Chin (Myanmar), Adi (Assam), Tu (Qinghai), Uyghur (Ürümqi), Mongol (Ili), Han (Hunan, Shanxi, Sichuan, Yunnan, Shandong, Ili), Yi (Yunnan), Bai (Dali), Nepalese [TMRCA 6,153.9 ± 5,443.2 ybp; CI=95%[79]]
Haplogroup M9a4a – Kinh (Hanoi), Han (Shaanxi, Shandong, Zhejiang, Taiwan, Sichuan, Guangdong), Li (Hainan), Mulam (Guangxi), Jino (Xishuangbanna), Dai (Xishuangbanna), Chiang Mai
Haplogroup M9b – Han (Luocheng, Dujiangyan, Shaanxi), Cham (Binh Thuan), Mulam (Luocheng), Bouyei (Guizhou), Yi (Hezhang), Bunu (Dahua), Hui (Ili), Thailand (Phuan from Sukhothai Province[58][61])
Haplogroup E – a subclade of M9 – found especially in Taiwan (Aboriginal peoples), Maritime Southeast Asia, and the Mariana Islands [TMRCA 23,695.4 ± 6,902.4 ybp; CI=95%[79]]
Haplogroup M10 – small clade found in East Asia, Southeast Asia, Bangladesh, Central Asia, Saudi Arabia, southern Siberia, Russia, Belarus, and Poland [TMRCA 23,600 (95% CI 17,100 <-> 31,700) ybp[61]]
Haplogroup M11 – small clade found especially among the Chinese and also in some Japanese, Koreans, Oroqen, Yi, Tibetans, Tajiks in Dushanbe, Tajikistan,[50] and Bangladeshis[31] [TMRCA 20,987.7 ± 5,740.8 ybp; CI=95%[79]]
Haplogroup M11b2 – Japanese (Hokkaido), China, Altai-Kizhi, Tajik (Dushanbe)
Haplogroup M11d – China, Teleut, Kyrgyz, Iran
Haplogroup M11c – Japan, Korea
Haplogroup M12'G
Haplogroup M12 – small clade found especially among the aborigines of Hainan Island as well as in other populations of China,[34] Japan, Korea, Pashtuns, Tibet, Myanmar, Thailand, Cambodia, and Vietnam [TMRCA 31,287.5 ± 5,731.2 ybp; CI=95%[79]]
Haplogroup M12a1a – Thailand (Htin in Phayao Province, Black Tai in Kanchanaburi Province, Mon in Kanchanaburi Province, Khon Mueang in Chiang Mai Province[58]), Laos (Lao in Luang Prabang[58]), Hainan
Haplogroup M12a1b – Tibet, Thailand (Blang in Chiang Rai Province, Khon Mueang in Chiang Rai Province, Palaung in Chiang Mai Province, Mon in Kanchanaburi Province[58]), Hainan, Vietnam
Haplogroup M12a2 – Thailand, Hainan, Myanmar
Haplogroup M12b – Thailand (Khmu in Nan Province[58])
Haplogroup M12b1a2 – Thailand (Soa in Sakon Nakhon Province[58])
Haplogroup M12b1a2a – Cambodia, Malaysia
Haplogroup M12b1a2b – Cambodia
Haplogroup M12b1b – Thailand (Suay in Surin Province, Khmer in Surin Province, Lao Isan in Roi Et Province, Black Tai in Loei Province[58]), Cambodia
Haplogroup M12b2 – Thailand, Hainan
Haplogroup M12b2a – Cambodia
Haplogroup G – found especially in Japan, Mongolia, and Tibet and in indigenous peoples of Kamchatka (Koryaks, Alyutors, Itelmens), with some isolated instances in diverse places of Asia [TMRCA 31,614.8 ± 5,193.6 ybp; CI=95%[79]]
Haplogroup G1 – Japan [TMRCA 21,492.9 ± 5,414.4 ybp; CI=95%[79]]
Haplogroup G1a – China (Uyghurs), Thailand (Black Lahu in Mae Hong Son Province[62]) [TMRCA 18,139.1 ± 5,462.4 ybp; CI=95%[79]] (TMRCA 18,800 [95% CI 12,600 <-> 26,900] ybp[61])
Haplogroup G1a1 – Korea, Vietnam (Dao), China (Sarikolis, Uyghurs, etc.), Tajikistan (Pamiris), Russia (Todzhin) [TMRCA 12,200 (95% CI 10,100 <-> 14,600) ybp][61]
Haplogroup G2a-T152C!-C16262T - ancient DNA from Irkutsk Oblast (Irk067 from the Novyj Kachug site at the left bank of the upper Lena River, cal BC 3755 to cal BC 3640[106][61])
Haplogroup G3a1c (C2389A) - skeletal remains of Bo people from Chang'an Township, Weixin County, Zhaotong, Yunnan, China and similar people from Yangxu Town, Youjiang District, Baise, Guangxi, China and Tham Lod rockshelter, Pang Mapha District, Mae Hong Son Province, Thailand[116]
Haplogroup D – found in Eastern Eurasia, Native Americans, Central Asia[140] and occasionally also in West Asia and Europe.
Subclades
Tree
This phylogenetic tree of haplogroup M subclades is based on the paper by Mannis van Oven and Manfred Kayser Updated comprehensive phylogenetic tree of global human mitochondrial DNA variation[13] and subsequent published research.
Haplogroup U is a human mitochondrial DNA haplogroup (mtDNA). The clade arose from haplogroup R, likely during the early Upper Paleolithic. Its various subclades are found widely distributed across Northern and Eastern Europe, Central, Western and South Asia, as well as North Africa, the Horn of Africa, and the Canary Islands.
Haplogroup R is a widely distributed human mitochondrial DNA (mtDNA) haplogroup. Haplogroup R is associated with the peopling of Eurasia after about 70,000 years ago, and is distributed in modern populations throughout the world outside of sub-Saharan Africa.
In human mitochondrial genetics, haplogroup B is a human mitochondrial DNA (mtDNA) haplogroup.
Haplogroup F is a human mitochondrial DNA (mtDNA) haplogroup. The clade is most common in East Asia and Southeast Asia. It has not been found among Native Americans.
Haplogroup N is a human mitochondrial DNA (mtDNA) clade. A macrohaplogroup, its descendant lineages are distributed across many continents. Like its sibling macrohaplogroup M, macrohaplogroup N is a descendant of the haplogroup L3.
In human mitochondrial genetics, Haplogroup A is a human mitochondrial DNA (mtDNA) haplogroup.
In human mitochondrial genetics, Haplogroup C is a human mitochondrial DNA (mtDNA) haplogroup.
In human mitochondrial genetics, Haplogroup D is a human mitochondrial DNA (mtDNA) haplogroup. It is a descendant haplogroup of haplogroup M, thought to have arisen somewhere in East Asia, between roughly 60,000 and 35,000 years ago.
In human mitochondrial genetics, Haplogroup Z is a human mitochondrial DNA (mtDNA) haplogroup.
Haplogroup N (M231) is a Y-chromosome DNA haplogroup defined by the presence of the single-nucleotide polymorphism (SNP) marker M231.
Haplogroup O-M122 is an Eastern Eurasian Y-chromosome haplogroup. The lineage ranges across Southeast Asia and East Asia, where it dominates the paternal lineages with extremely high frequencies. It is also significantly present in Central Asia, especially among the Naiman tribe of Kazakhs.
In human genetics, Haplogroup O-M119 is a Y-chromosome DNA haplogroup. Haplogroup O-M119 is a descendant branch of haplogroup O-F265 also known as O1a, one of two extant primary subclades of Haplogroup O-M175. The same clade previously has been labeled as O-MSY2.2.
Haplogroup C-M217, also known as C2, is a Y-chromosome DNA haplogroup. It is the most frequently occurring branch of the wider Haplogroup C (M130). It is found mostly in Central Asia, Eastern Siberia and significant frequencies in parts of East Asia and Southeast Asia including some populations in the Caucasus, Middle East, South Asia, East Europe. It is found in a much more widespread area with a low frequency of less than 2%.
In human mitochondrial genetics, Haplogroup Y is a human mitochondrial DNA (mtDNA) haplogroup.
In human mitochondrial genetics, Haplogroup G is a human mitochondrial DNA (mtDNA) haplogroup.
In human mitochondrial genetics, Haplogroup M30 is a human mitochondrial DNA (mtDNA) haplogroup.
The Barga are a subgroup of the Buryats which gave its name to the Baikal region – "Bargujin-Tukum" – "the land's end", according to the 13th-14th centuries Mongol people's conception.
In human mitochondrial genetics, haplogroup M18 is a human mitochondrial DNA (mtDNA) haplogroup. It is an India-specific lineage.
Haplogroup C-M48 also known as C2b1a2 is a Y-chromosome DNA haplogroup.
Haplogroup O2a2b1a1-M117 or Haplogroup O2a2b1a1-M117 is a subclade of O2a2b1-M134 that occurs frequently in China and in neighboring countries like Bhutan, Nepal, and Korea, also found among Sino-Tibetan language speaking people.
↑ Dubut, V; Cartault, F; Payet, C; Thionville, MD; Murail, P; etal. (2009). "Complete mitochondrial sequences for haplogroups M23 and M46: insights into the Asian ancestry of the Malagasy population". Human Biology. 81 (4): 495–500. doi:10.3378/027.081.0407. PMID20067372. S2CID31809306.
1 2 Maruyama, Sayaka; Minaguchi, Kiyoshi; Saitou, Naruya (2003). "Sequence polymorphisms of the mitochondrial DNA control region and phylogenetic analysis of mtDNA lineages in the Japanese population". Int J Legal Med. 117 (4): 218–225. doi:10.1007/s00414-003-0379-2. PMID12845447. S2CID1224295.
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↑ Beom Hong, Seung; Cheol Kim, Ki; Kim, Wook (2014). "Mitochondrial DNA haplogroups and homogeneity in the Korean population". Genes & Genomics. 36 (5): 583–590. doi:10.1007/s13258-014-0194-9. S2CID16827252.
↑ Cosimo Posth; Gabriel Renaud; Alissa Mittnik; Dorothée G. Drucker; Hélène Rougier; Christophe Cupillard; Frédérique Valentin; Corinne Thevenet; Anja Furtwängler; Christoph Wißing; Michael Francken; Maria Malina; Michael Bolus; Martina Lari; Elena Gigli; Giulia Capecchi; Isabelle Crevecoeur; Cédric Beauval; Damien Flas; Mietje Germonpré; Johannes van der Plicht; Richard Cottiaux; Bernard Gély; Annamaria Ronchitelli; Kurt Wehrberger; Dan Grigorescu; Jiří Svoboda; Patrick Semal; David Caramelli; Hervé Bocherens; Katerina Harvati; Nicholas J. Conard; Wolfgang Haak; Adam Powell (March 21, 2016). "Pleistocene Mitochondrial Genomes Suggest a Single Major Dispersal of Non-Africans and a Late Glacial Population Turnover in Europe". Current Biology. 26 (6): 827–833. doi:10.1016/j.cub.2016.01.037. hdl:2440/114930. PMID26853362. S2CID140098861.
↑ Reyhan Yaka. "Archaeogenetics of Late Iron Age Çemialo Sırtı, Batman: Investigating maternal genetic continuity in North Mesopotamia since the Neolithic". bioRxiv10.1101/172890.
↑ Fregel; etal. (2018). "Ancient genomes from North Africa evidence prehistoric migrations to the Maghreb from both the Levant and Europe". bioRxiv10.1101/191569.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 Wibhu Kutanan, Rasmi Shoocongdej, Metawee Srikummool, et al. (2020), "Cultural variation impacts paternal and maternal genetic lineages of the Hmong-Mien and Sino-Tibetan groups from Thailand." European Journal of Human Genetics. https://doi.org/10.1038/s41431-020-0693-x
↑ Kutanan,W., Kampuansai,J., Brunelli,A., Ghirotto,S., Pittayaporn,P., Ruangchai,S., Schroder,R., Macholdt,E., Srikummool,M., Kangwanpong,D., Hubner,A., Arias,L. and Stoneking,M., "New insights from Thailand into the maternal genetic history of Mainland Southeast Asia." Eur. J. Hum. Genet. (2018).
↑ Sukernik, Rem I.; Volodko, Natalia V.; Mazunin, Ilya O.; Eltsov, Nikolai P.; Dryomov, Stanislav V.; Starikovskaya, Elena B. (2012). "Mitochondrial Genome Diversity in the Tubalar, Even, and Ulchi: Contribution to Prehistory of Native Siberians and Their Affinities to Native Americans". American Journal of Physical Anthropology. 148 (1): 123–138. doi:10.1002/ajpa.22050. PMID22487888.
1 2 3 4 Hongbin Yao, Mengge Wang, Xing Zou, et al., "New insights into the fine-scale history of western-eastern admixture of the northwestern Chinese population in the Hexi Corridor via genome-wide genetic legacy." Mol Genet Genomics 2021 Mar 1. doi: 10.1007/s00438-021-01767-0.
↑ Chen J, He G, Ren Z, Wang Q, Liu Y, Zhang H, Yang M, Zhang H, Ji J, Zhao J, Guo J, Chen J, Zhu K, Yang X, Wang R, Ma H, Tao L, Liu Y, Shen Q, Yang W, Wang C-C, and Huang J (2022), "Fine-Scale Population Admixture Landscape of Tai–Kadai-Speaking Maonan in Southwest China Inferred From Genome-Wide SNP Data." Front. Genet. 13:815285. doi: 10.3389/fgene.2022.815285
↑ Basnet, Rajdip; Rai, Niraj; Tamang, Rakesh; Awasthi, Nagendra Prasad; Pradhan, Isha; Parajuli, Pawan; Kashyap, Deepak; Reddy, Alla Govardhan; Chaubey, Gyaneshwer; Das Manandhar, Krishna; Shrestha, Tilak Ram; Thangaraj, Kumarasamy (2022-10-15). "The matrilineal ancestry of Nepali populations". Human Genetics. 142 (2): 167–180. doi:10.1007/s00439-022-02488-z. ISSN0340-6717. PMID36242641. S2CID252904281.
↑ Hwan Young Lee, Ji-Eun Yoo, Myung Jin Park, Ukhee Chung, Chong-Youl Kim, and Kyoung-Jin Shin, "East Asian mtDNA haplogroup determination in Koreans: Haplogroup-level coding region SNP analysis and subhaplogroup-level control region sequence analysis." Electrophoresis (2006). DOI 10.1002/elps.200600151.
1 2 3 Dandan Yu, Xiaoyun Jia, A-Mei Zhang, Shiqiang Li, Yang Zou, Qingjiong Zhang, and Yong-Gang Yao (2010), "Mitochondrial DNA Sequence Variation and Haplogroup Distribution in Chinese Patients with LHON and m.14484T.C." PLoS ONE 5(10): e13426. doi:10.1371/journal.pone.0013426
↑ Yanli Ji, A-Mei Zhang, Xiaoyun Jia, et al. (2008), "Mitochondrial DNA Haplogroups M7b102 and M8a Affect Clinical Expression of Leber Hereditary Optic Neuropathy in Chinese Families with the m.11778G/A Mutation." The American Journal of Human Genetics 83, 760–768, December 12, 2008. DOI 10.1016/j.ajhg.2008.11.002.
1 2 3 4 5 6 7 8 Dan Zhao, Yingying Ding, Haijiang Lin, Xiaoxiao Chen, Weiwei Shen, Meiyang Gao, Qian Wei, Sujuan Zhou, Xing Liu, and Na He (2019), "Mitochondrial Haplogroups N9 and G Are Associated with Metabolic Syndrome Among Human Immunodeficiency Virus-Infected Patients in China." AIDS Research and Human Retroviruses, Jun 2019, 536-543. http://doi.org/10.1089/aid.2018.0151
↑ Dongsheng Lu, Haiyi Lou, Kai Yuan, et al. (2016), "Ancestral Origins and Genetic History of Tibetan Highlanders." The American Journal of Human Genetics 99, 580–594, September 1, 2016.
1 2 3 4 Monika Summerer, Jürgen Horst, Gertraud Erhart, et al. (2014), "Large-scale mitochondrial DNA analysis in Southeast Asia reveals evolutionary effects of cultural isolation in the multi-ethnic population of Myanmar." BMC Evolutionary Biology 2014, 14:17. http://www.biomedcentral.com/1471-2148/14/17
↑ Max Ingman and Ulf Gyllensten (2007), "Rate variation between mitochondrial domains and adaptive evolution in humans." Human Molecular Genetics, 2007, Vol. 16, No. 19, 2281–2287. doi:10.1093/hmg/ddm180
1 2 3 4 5 6 7 8 9 10 11 12 Pankratov, V., Litvinov, S., Kassian, A., et al., "East Eurasian ancestry in the middle of Europe: genetic footprints of Steppe nomads in the genomes of Belarusian Lipka Tatars." Sci Rep 6, 30197 (2016). https://doi.org/10.1038/srep30197
↑ Rebecca S. Just, Melissa K. Scheible, Spence A. Fast, et al. (2015), "Full mtGenome reference data: Development and characterization of 588 forensic-quality haplotypes representing three U.S. populations." Forensic Science International: Genetics 14 (2015) 141–155. http://dx.doi.org/10.1016/j.fsigen.2014.09.021
1 2 Qing-Peng Kong, Yong-Gang Yao, Chang Sun, et al. (2003), "Phylogeny of East Asian Mitochondrial DNA Lineages Inferred from Complete Sequences." Am. J. Hum. Genet. 73:671–676, 2003.
1 2 3 Duong,N.T., Macholdt,E., Ton,N.D., et al., "Complete human mtDNA genome sequences from Vietnam and the phylogeography of Mainland Southeast Asia." Sci Rep 8 (1), 11651 (2018).
↑ Yang Zou, Xiaoyun Jia, A-Mei Zhang, et al. (2010), "The MT-ND1 and MT-ND5 genes are mutational hotspots for Chinese families with clinical features of LHON but lacking the three primary mutations." Biochemical and Biophysical Research Communications Volume 399, Issue 2, 20 August 2010, Pages 179-185. https://doi.org/10.1016/j.bbrc.2010.07.051
1 2 3 4 5 6 7 8 Jiang,C., Cui,J., Liu,F., Gao,L., Luo,Y., Li,P., Guan,L. and Gao,Y., "Mitochondrial DNA 10609T Promotes Hypoxia-Induced Increase of Intracellular ROS and Is a Risk Factor of High Altitude Polycythemia." PLoS ONE 9 (1), E87775 (2014).
↑ Kong QP, Sun C, Wang HW, Zhao M, Wang WZ, Zhong L, Hao XD, Pan H, Wang SY, Cheng YT, Zhu CL, Wu SF, Liu LN, Jin JQ, Yao YG, Zhang YP. "Large-scale mtDNA screening reveals a surprising matrilineal complexity in east Asia and its implications to the peopling of the region." Mol Biol Evol. 2011 Jan;28(1):513-22. doi: 10.1093/molbev/msq219. Epub 2010 Aug 16. PMID 20713468.
1 2 3 4 Jia Liu, Li-Dong Wang, Yan-Bo Sun, et al. (2012), "Deciphering the Signature of Selective Constraints on Cancerous Mitochondrial Genome." Mol. Biol. Evol. 29(4):1255–1261. doi:10.1093/molbev/msr290
1 2 Boris Malyarchuk, Andrey Litvinov, Miroslava Derenko, et al. (2017), "Mitogenomic diversity in Russians and Poles." FSI Genetics Volume 30, p51-56, September 01, 2017. DOI:https://doi.org/10.1016/j.fsigen.2017.06.003
↑ Marchi N, Hegay T, Mennecier P, et al. (2017), "Sex-specific genetic diversity is shaped by cultural factors in Inner Asian human populations." American Journal of Physical Anthropology 2017 Apr;162(4):627-640. DOI: 10.1002/ajpa.23151.
1 2 Hua-Wei Wang, Xiaoyun Jia, Yanli Ji, et al. (2008), "Strikingly different penetrance of LHON in two Chinese families with primary mutation G11778A is independent of mtDNA haplogroup background and secondary mutation G13708A." Mutation Research 643 (2008) 48–53. doi:10.1016/j.mrfmmm.2008.06.004
1 2 Mielnik-Sikorska M, Daca P, Malyarchuk B, Derenko M, Skonieczna K, et al. (2013), "The History of Slavs Inferred from Complete Mitochondrial Genome Sequences." PLoS ONE 8(1): e54360. doi:10.1371/journal.pone.0054360
↑ Gülşah Merve Kılınç, Natalija Kashuba, Reyhan Yaka, et al. (2018), "Investigating Holocene human population history in North Asia using ancient mitogenomes." Scientific Reports (2018) 8:8969 | DOI:10.1038/s41598-018-27325-0
1 2 Boris Malyarchuk, Miroslava Derenko, Galina Denisova, and Olga Kravtsova (2010), "Mitogenomic Diversity in Tatars from the Volga-Ural Region of Russia." Mol. Biol. Evol. 27(10):2220–2226. doi:10.1093/molbev/msq065
↑ Jun-Hun Loo, Jean A Trejaut, Ju-Chen Yen, et al. (2014), "Mitochondrial DNA association study of type 2 diabetes with or without ischemic stroke in Taiwan." BMC Res Notes 2014; 7: 223. Published online 2014 Apr 9. doi: 10.1186/1756-0500-7-223
1 2 Dryomov SV, Nazhmidenova AM, Starikovskaya EB, Shalaurova SA, Rohland N, Mallick S, et al. (2021), "Mitochondrial genome diversity on the Central Siberian Plateau with particular reference to the prehistory of northernmost Eurasia." PLoS ONE 16(1):e0244228. https://doi.org/10.1371/journal. pone.0244228
1 2 Wang, C. Y., Li, H., Hao, X. D., Liu, J., Wang, J. X., Wang, W. Z., Kong, Q. P., & Zhang, Y. P. (2011). "Uncovering the profile of somatic mtDNA mutations in Chinese colorectal cancer patients." PloS one, 6(6), e21613. https://doi.org/10.1371/journal.pone.0021613
↑ A-Mei Zhang, Xiaoyun Jia, Yong-Gang Yao, and Qingjiong Zhang (2008), "Co-occurrence of A1555G and G11778A in a Chinese family with high penetrance of Leber’s hereditary optic neuropathy." Biochemical and Biophysical Research Communications 376 (2008) 221–224. doi:10.1016/j.bbrc.2008.08.128
↑ Choongwon Jeong, Ke Wang, Shevan Wilkin, William Timothy Treal Taylor, Bryan K. Miller, Jan H. Bemmann, Raphaela Stahl, Chelsea Chiovelli, Florian Knolle, Sodnom Ulziibayar, Dorjpurev Khatanbaatar, Diimaajav Erdenebaatar, Ulambayar Erdenebat, Ayudai Ochir, Ganbold Ankhsanaa, Chuluunkhuu Vanchigdash, Battuga Ochir, Chuluunbat Munkhbayar, Dashzeveg Tumen, Alexey Kovalev, Nikolay Kradin, Bilikto A. Bazarov, Denis A. Miyagashev, Prokopiy B. Konovalov, Elena Zhambaltarova, Alicia Ventresca Miller, Wolfgang Haak, Stephan Schiffels, Johannes Krause, Nicole Boivin, Myagmar Erdene, Jessica Hendy, and Christina Warinner, "A Dynamic 6,000-Year Genetic History of Eurasia’s Eastern Steppe." Cell, Volume 183, Issue 4, 2020, Pages 890-904.e29, ISSN 0092-8674, https://doi.org/10.1016/j.cell.2020.10.015.
1 2 Mian Zhao, Qing-Peng Kong, Hua-Wei Wang, et al. (2009), "Mitochondrial genome evidence reveals successful Late Paleolithic settlement on the Tibetan Plateau." PNAS, vol. 106, no. 50, 21230–21235. http://www.pnas.org/cgi/doi/10.1073/pnas.0907844106
↑ Longli Kang, Hong-Xiang Zheng, Feng Chen, et al. (2013), "mtDNA Lineage Expansions in Sherpa Population Suggest Adaptive Evolution in Tibetan Highlands." Molecular Biology and Evolution, Volume 30, Issue 12, December 2013, Pages 2579–2587, https://doi.org/10.1093/molbev/mst147.
↑ Xiaoming Zhang, Chunmei Li, Yanan Zhou, et al. (2020), "A Matrilineal Genetic Perspective of Hanging Coffin Custom in Southern China and Northern Thailand." iScience 23, 101032, April 24, 2020. https://doi.org/10.1016/j.isci.2020.101032
↑ Dryomov, S.V., Starikovskaya, E.B., Nazhmidenova, A.M. et al. Genetic legacy of cultures indigenous to the Northeast Asian coast in mitochondrial genomes of nearly extinct maritime tribes. BMC Evol Biol 20, 83 (2020). https://doi.org/10.1186/s12862-020-01652-1
↑ Cheng-Ye Wang and Zhong-Bao Zhao (2012), "Somatic mtDNA mutations in lung tissues of pesticide-exposed fruit growers." Toxicology 291 (2012) 51– 55. doi:10.1016/j.tox.2011.10.018
1 2 3 Scholes, Clarissa; Siddle, Katherine; Ducourneau, Axel; etal. (2011). "Genetic Diversity and Evidence for Population Admixture in Batak Negritos from Palawan". American Journal of Physical Anthropology. 146 (1): 62–72. doi:10.1002/ajpa.21544. PMID21796613.
↑ Zhang,X., Qi,X., Yang,Z., et al., "Analysis of mitochondrial genome diversity identifies new and ancient maternal lineages in Cambodian aborigines." Nat Commun 4, 2599 (2013).
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