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1. Genetic differentiation between upland and lowland populations shapes the Y-chromosomal landscape of West Asia

Author: Balanovsky, O., Chukhryaeva, M., Zaporozhchenko, V., Urasin, V., Zhabagin, M., Hovhannisyan, A., Agdzhoyan, A., Dibirova, K., Kuznetsova, M., Koshel, S., Pocheshkhova, E., Alborova, I., Skhalyakho, R., Utevska, O., Mustafin, Kh., Yepiskoposyan, L., Tyler-Smith, C., Balanovska, E., and The Genographic Consortium
Published: 2017
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2. Assessment of patrilineal gene pool of the Iranian Azeris

Author: Margaryan, A., Khachatryan, Z., Khudoyan, A., Andonian, L., and Yepiskoposyan, L.
Published: 2013
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3. Patrilocality and recent migrations have little impact on shaping patterns of genetic structure of the armenian population

Author: Harutyunyan, A., Khudoyan, A., and Yepiskoposyan, L.
Published: 2009
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4. Variation in Short Tandem Repeats of Human Y Chromosome

Author: Yepiskoposyan, L. M., Oganesyan, N. A., and Khudoyan, A. Ts.
Published: 2001
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5. Ancient DNA shows high faunal diversity in the Lesser Caucasus during the Late Pleistocene

Author: Antonosyan, M., Seersholm, Frederik, Grealy, Alicia, Barham, Milo, Werndly, Daniel, Margaryan, A., Cieślik, A., Stafford, T.W., Allentoft, M.E., Bunce, Michael, Yepiskoposyan, L., Antonosyan, M., Seersholm, Frederik, Grealy, Alicia, Barham, Milo, Werndly, Daniel, Margaryan, A., Cieślik, A., Stafford, T.W., Allentoft, M.E., Bunce, Michael, and Yepiskoposyan, L.
Abstract: © 2019 Elsevier Ltd In this study, we explore the Late Pleistocene (LP) vertebrate faunal diversity in south-eastern Lesser Caucasus based on morphological and genetic identification of fossil bones from Karin Tak cave. For the first time in this under-studied region, we used a bulk bone metabarcoding genetic approach to complement traditional morphology-based taxonomic identifications that are hampered by highly fragmented fossil bones. Excellent ancient DNA (aDNA) preservation allowed for a successful species identification of many bone remains and improved paleoenvironmental interpretations for the region. The aDNA identification of fossil bones revealed a high diversity of animal taxa inhabiting the region between ca. > 42,000 and 25,683–24,803 calibrated years before present (cal. BP).
Published: 2019

6. Characterizing the genetic history of admixture across inner Eurasia

Author: Jeong, C., Balanovsky, O., Lukianova, E., Kahbatkyzy, N., Flegontov, P., Zaporozhchenko, V., Immel, A., Wang, C., Ixan, O., Khussainova, E., Bekmanov, B., Zaibert, V., Lavryashina, M., Pocheshkhova, E., Yusupov, Y., Agdzhoyan, A., Sergey, K., Bukin, A., Nymadawa, P., Churnosov, M., Skhalyakho, R., Daragan, D., Bogunov, Y., Bogunova, A., Shtrunov, A., Dubova, N., Zhabagin, M., Yepiskoposyan, L., Churakov, V., Pislegin, N., Damba, L., Saroyants, L., Dibirova, K., Artamentova, L., Utevska, O., Idrisov, E., Kamenshchikova, E., Evseeva, I., Metspalu, M., Robbeets, M., Djansugurova, L., Balanovska, E., Schiffels, S., Haak, W., Reich, D., and Krause, J.
Abstract: The indigenous populations of inner Eurasia, a huge geographic region covering the central Eurasian steppe and the northern Eurasian taiga and tundra, harbor tremendous diversity in their genes, cultures and languages. In this study, we report novel genome-wide data for 763 individuals from Armenia, Georgia, Kazakhstan, Moldova, Mongolia, Russia, Tajikistan, Ukraine, and Uzbekistan. We furthermore report genome-wide data of two Eneolithic individuals (~5,400 years before present) associated with the Botai culture in northern Kazakhstan. We find that inner Eurasian populations are structured into three distinct admixture clines stretching between various western and eastern Eurasian ancestries. This genetic separation is well mirrored by geography. The ancient Botai genomes suggest yet another layer of admixture in inner Eurasia that involves Mesolithic hunter-gatherers in Europe, the Upper Paleolithic southern Siberians and East Asians. Admixture modeling of ancient and modern populations suggests an overwriting of this ancient structure in the Altai-Sayan region by migrations of western steppe herders, but partial retaining of this ancient North Eurasian-related cline further to the North. Finally, the genetic structure of Caucasus populations highlights a role of the Caucasus Mountains as a barrier to gene flow and suggests a post-Neolithic gene flow into North Caucasus populations from the steppe.
Published: 2018

7. Origin and spread of human mitochondrial DNA haplogroup U7

Author: Sahakyan, H. Kashani, B.H. Tamang, R. Kushniarevich, A. Francis, A. Costa, M.D. Pathak, A.K. Khachatryan, Z. Sharma, I. Van Oven, M. Parik, J. Hovhannisyan, H. Metspalu, E. Pennarun, E. Karmin, M. Tamm, E. Tambets, K. Bahmanimehr, A. Reisberg, T. Reidla, M. Achilli, A. Olivieri, A. Gandini, F. Perego, U.A. Al-Zahery, N. Houshmand, M. Sanati, M.H. Soares, P. Rai, E. Šarac, J. Šarić, T. Sharma, V. Pereira, L. Fernandes, V. Černý, V. Farjadian, S. Singh, D.P. Azakli, H. Üstek, D. Trofimova, N.E. Kutuev, I. Litvinov, S. Bermisheva, M. Khusnutdinova, E.K. Rai, N. Singh, M. Singh, V.K. Reddy, A.G. Tolk, H.-V. Cvjetan, S. Lauc, L.B. Rudan, P. Michalodimitrakis, E.N. Anagnou, N.P. Pappa, K.I. Golubenko, M.V. Orekhov, V. Borinskaya, S.A. Kaldma, K. Schauer, M.A. Simionescu, M. Gusar, V. Grechanina, E. Govindaraj, P. Voevoda, M. Damba, L. Sharma, S. Singh, L. Semino, O. Behar, D.M. Yepiskoposyan, L. Richards, M.B. Metspalu, M. Kivisild, T. Thangaraj, K. Endicott, P. Chaubey, G. Torroni, A. Villems, R.
Abstract: Human mitochondrial DNA haplogroup U is among the initial maternal founders in Southwest Asia and Europe and one that best indicates matrilineal genetic continuity between late Pleistocene hunter-gatherer groups and present-day populations of Europe. While most haplogroup U subclades are older than 30 thousand years, the comparatively recent coalescence time of the extant variation of haplogroup U7 (∼16-19 thousand years ago) suggests that its current distribution is the consequence of more recent dispersal events, despite its wide geographical range across Europe, the Near East and South Asia. Here we report 267 new U7 mitogenomes that - analysed alongside 100 published ones - enable us to discern at least two distinct temporal phases of dispersal, both of which most likely emanated from the Near East. The earlier one began prior to the Holocene (∼11.5 thousand years ago) towards South Asia, while the later dispersal took place more recently towards Mediterranean Europe during the Neolithic (∼8 thousand years ago). These findings imply that the carriers of haplogroup U7 spread to South Asia and Europe before the suggested Bronze Age expansion of Indo-European languages from the Pontic-Caspian Steppe region. © The Author(s) 2017.
Published: 2017

8. Origin and spread of mitochondrial DNA haplogroup U7

Author: Sahakyan, H, Kashani, BH, Tamang, R, Kushniarevich, A, Francis, A, Costa, MD, Pathak, AK, Khachatryan, Z, Sharma, I, van Oven, M, Parik, J, Hovhannisyan, H, Metspalu, E, Pennarun, E, Karmin, M, Tamm, E, Tambets, K, Bahmanimehr, A, Reisberg, T, Reidla, M, Achilli, A, Olivieri, A, Gandini, F, Perego, UA, Al-Zahery, N, Houshmand, M, Sanati, MH, Soares, P, Rai, E, Šarac, J, Šarić, T, Sharma, V, Pereira, L, Fernandes, V, Černý, V, Farjadian, S, Singh, DP, Azakli, H, Üstek, D, Ekomasova, NT, Kutuev, I, Litvinov, S, Bermisheva, M, Khusnutdinova, EK, Rai, N, Singh, M, Singh, VK, Reddy, AG, Tolk, HV, Cvjetan, S, Lauc, LB, Rudan, P, Michalodimitrakis, EN, Anagnou, NP, Pappa, KI, Golubenko, MV, Orekhov, V, Borinskaya, SA, Kaldma, K, Schauer, MA, Simionescu, M, Gusar, V, Grechanina, E, Govindaraj, P, Voevoda, M, Damba, L, Sharma, S, Singh, L, Semino, O, Behar, DM, Yepiskoposyan, L, Richards, MB, Metspalu, M, Kivisild, T, Thangaraj, K, Endicott, P, Chaubey, G, Torroni, A, Villems, R, and Instituto de Investigação e Inovação em Saúde
Subjects: Bronze Age, Europe, Mitochondrial haplogroup, Middle East, Steppe, Holocene, Human experiment, Neolithic, South Asia, Human, Language
Abstract: Human mitochondrial DNA haplogroup U is among the initial maternal founders in Southwest Asia and Europe and one that best indicates matrilineal genetic continuity between late Pleistocene huntergatherer groups and present-day populations of Europe. While most haplogroup U subclades are older than 30 thousand years, the comparatively recent coalescence time of the extant variation of haplogroup U7 (~16–19 thousand years ago) suggests that its current distribution is the consequence of more recent dispersal events, despite its wide geographical range across Europe, the Near East and South Asia. Here we report 267 new U7 mitogenomes that – analysed alongside 100 published ones – enable us to discern at least two distinct temporal phases of dispersal, both of which most likely emanated from the Near East. The earlier one began prior to the Holocene (~11.5 thousand years ago) towards South Asia, while the later dispersal took place more recently towards Mediterranean Europe during the Neolithic (~8 thousand years ago). These findings imply that the carriers of haplogroup U7 spread to South Asia and Europe before the suggested Bronze Age expansion of Indo-European languages from the Pontic-Caspian Steppe region.
Published: 2017

9. Coevolution of genes and languages and high levels of population structure among the highland populations of Daghestan

Author: Karafet, TM, Bulayeva, KB, Nichols, J, Bulayev, OA, Gurgenova, F, Omarova, J, Yepiskoposyan, L, Savina, OV, Rodrigue, BH, and Hammer, MF
Abstract: © 2016 The Japan Society of Human Genetics. All rights reserved. As a result of the combination of great linguistic and cultural diversity, the highland populations of Daghestan present an excellent opportunity to test the hypothesis of language-gene coevolution at a fine geographic scale. However, previous genetic studies generally have been restricted to uniparental markers and have not included many of the key populations of the region. To improve our understanding of the genetic structure of Daghestani populations and to investigate possible correlations between genetic and linguistic variation, we analyzed ∼550 000 autosomal single nucleotide polymorphisms, phylogenetically informative Y chromosome markers and mtDNA haplotypes in 21 ethnic Daghestani groups. We found high levels of population structure in Daghestan consistent with the hypothesis of long-term isolation among populations of the highland Caucasus. Highland Daghestani populations exhibit extremely high levels of between-population diversity for all genetic systems tested, leading to some of the highest F ST values observed for any region of the world. In addition, we find a significant positive correlation between gene and language diversity, suggesting that these two aspects of human diversity have coevolved as a result of historical patterns of social interaction among highland farmers at the community level. Finally, our data are consistent with the hypothesis that most Daghestanian-speaking groups descend from a common ancestral population (∼6000-6500 years ago) that spread to the Caucasus by demic diffusion followed by population fragmentation and low levels of gene flow.
Published: 2016
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10. Analysis of genetic variants associated with antipsychotic treatment efficacy in healthy Armenian individuals

Author: Zakharyan, R., primary, Chavushyan, A., additional, Hayrapetyan, V., additional, Hovhannisyan, A., additional, Khachatryan, Z., additional, Yepiskoposyan, L., additional, and Arakelyan, A., additional
Published: 2017
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11. A recent bottleneck of Y chromosome diversity coincides with a global change in culture

Author: Karmin M., Saag L., Vicente M., Wilson Sayres M., Järve M., Talas U., Rootsi S., Ilumäe A., Mägi R., Mitt M., Pagani L., Puurand T., Faltyskova Z., Clemente F., Cardona A., Metspalu E., Sahakyan H., Yunusbayev B., Hudjashov G., DeGiorgio M., Loogväli E., Eichstaedt C., Eelmets M., Chaubey G., Tambets K., Litvinov S., Mormina M., Xue Y., Ayub Q., Zoraqi G., Korneliussen T., Akhatova F., Lachance J., Tishkoff S., Momynaliev K., Ricaut F., Kusuma P., Razafindrazaka H., Pierron D., Cox M., Sultana G., Willerslev R., Muller C., Westaway M., Lambert D., Skaro V., Kovačević L., Turdikulova S., Dalimova D., Khusainova R., Trofimova N., Akhmetova V., Khidiyatova I., Lichman D., Isakova J., Pocheshkhova E., Sabitov Z., Barashkov N., Nymadawa P., Mihailov E., Seng J., Evseeva I., Migliano A., Abdullah S., Andriadze G., Primorac D., Atramentova L., Utevska O., Yepiskoposyan L., Marjanović D., Kushniarevich A., and Behar D.
Abstract: © 2015 Karmin et al. It is commonly thought that human genetic diversity in non-African populations was shaped primarily by an out-of-Africa dispersal 50-100 thousand yr ago (kya). Here, we present a study of 456 geographically diverse high-coverage Y chromosome sequences, including 299 newly reported samples. Applying ancient DNA calibration, we date the Y-chromosomal most recent common ancestor (MRCA) in Africa at 254 (95% CI 192-307) kya and detect a cluster of major non-African founder haplogroups in a narrow time interval at 47-52 kya, consistent with a rapid initial colonization model of Eurasia and Oceania after the out-of-Africa bottleneck. In contrast to demographic reconstructions based on mtDNA, we infer a second strong bottleneck in Y-chromosome lineages dating to the last 10 ky. We hypothesize that this bottleneck is caused by cultural changes affecting variance of reproductive success among males.
Published: 2015

12. Mapping genetic and cultural roots of Armenians

Author: Yepiskoposyan L., Nazaretyan M., Avagyan S., and Sokourenko E.
Published: 2015

13. Molecular Detection of Prostate Specific Antigen in Patients with Prostate Cancer or Benign Prostate Hyperplasia the First Investigation from Iran

Author: Andonian, L., Khorramizadeh, M. R., Farhud, D. D., Chaleshtori, M. H., Naieni, K. H., Razi, A., Sanadizadeh, J., Pourmand, G., Nouraie, M., Rezaie, S., farshid saadat, Yepiskoposyan, L., Norouzi, M., Soleimanpour, H., Berahme, A., and Aalizadeh, N.
Subjects: PSA, Prostate cancer, BPH, lcsh:Public aspects of medicine, lcsh:RA1-1270, urologic and male genital diseases
Abstract: Prostate cancer is the second common form of cancer in men. Detection of circulating Prostate Specific Antigen (PSA) transcripts has effectively been used for early diagnosis of prostate cancer cells. This investigation employed a reverse transcriptase polymerase chain reaction (RT-PCR) technique to distinguish the patients with either localized or metastatic prostate cancer (CaP) vs. Benign Prostate Hyperplasia (BPH) and control subjects, as compared with clinical and pathological records. With reservation of ethical issues, blood samples were collected from 60 cases. Based on pathological and clinical findings, 25 patients (20 with localized cancer, 5 with metastatic), 22 with BPH, and 13 healthy (including 3 females) subjects as negative controls, were selected from Shariati, Mehrad, Sina,, Khatam and Atie Hospitals in Tehran, Iran. RT-PCR for a 260 bp PSA transcript was then performed. Clinical and pathological records were used for the assessment and comparison of PSA RT-PCR results. None of the control subjects and BPH (with 7 exceptions) were found positive by RT-PCR (Relative specificity= 72.7%). In patients with prostate cancer, 21 out of 25 were found PSA positive (Relative sensitivity=83.4%) and the remaining 3 have been shown to be PSA negative (Positive predictive value= 83.4%). All of 5 metastatic patients (100%) revealed PSA positive results. Our data reflects the clinical relevance and significance of RT-PCR results as assessed with clinical and pathological examinations. PSA RT-PCR might be used as a powerful means for diagnosis, even when either pathological or clinical findings are negative, and could be employed for further molecular epidemiology surveys.
Published: 2005

14. The Simons Genome Diversity Project: 300 genomes from 142 diverse populations

Author: Mallick, S, Li, H, Lipson, M, Mathieson, I, Gymrek, M, Racimo, F, Zhao, M, Chennagiri, N, Nordenfelt, S, Tandon, A, Skoglund, P, Lazaridis, I, Sankararaman, S, Fu, Q, Rohland, N, Renaud, G, Erlich, Y, Willems, T, Gallo, C, Spence, JP, Song, YS, Poletti, G, Balloux, F, van Driem, G, de Knijff, P, Romero, IG, Jha, AR, Behar, DM, Bravi, CM, Capelli, C, Hervig, T, Moreno-Estrada, A, Posukh, OL, Balanovska, E, Balanovsky, O, Karachanak-Yankova, S, Sahakyan, H, Toncheva, D, Yepiskoposyan, L, Tyler-Smith, C, Xue, Y, Abdullah, MS, Ruiz-Linares, A, Beall, CM, Di Rienzo, A, Jeong, C, Starikovskaya, EB, Metspalu, E, Parik, J, Villems, R, Henn, BM, Hodoglugil, U, Mahley, R, Sajantila, A, Stamatoyannopoulos, G, Wee, JTS, Khusainova, R, Khusnutdinova, E, Litvinov, S, Ayodo, G, Comas, D, Hammer, MF, Kivisild, T, Klitz, W, Winkler, CA, Labuda, D, Bamshad, M, Jorde, LB, Tishkoff, SA, Watkins, WS, Metspalu, M, Dryomov, S, Sukernik, R, Singh, L, Thangaraj, K, Paeaebo, S, Kelso, J, Patterson, N, Reich, D, Mallick, S, Li, H, Lipson, M, Mathieson, I, Gymrek, M, Racimo, F, Zhao, M, Chennagiri, N, Nordenfelt, S, Tandon, A, Skoglund, P, Lazaridis, I, Sankararaman, S, Fu, Q, Rohland, N, Renaud, G, Erlich, Y, Willems, T, Gallo, C, Spence, JP, Song, YS, Poletti, G, Balloux, F, van Driem, G, de Knijff, P, Romero, IG, Jha, AR, Behar, DM, Bravi, CM, Capelli, C, Hervig, T, Moreno-Estrada, A, Posukh, OL, Balanovska, E, Balanovsky, O, Karachanak-Yankova, S, Sahakyan, H, Toncheva, D, Yepiskoposyan, L, Tyler-Smith, C, Xue, Y, Abdullah, MS, Ruiz-Linares, A, Beall, CM, Di Rienzo, A, Jeong, C, Starikovskaya, EB, Metspalu, E, Parik, J, Villems, R, Henn, BM, Hodoglugil, U, Mahley, R, Sajantila, A, Stamatoyannopoulos, G, Wee, JTS, Khusainova, R, Khusnutdinova, E, Litvinov, S, Ayodo, G, Comas, D, Hammer, MF, Kivisild, T, Klitz, W, Winkler, CA, Labuda, D, Bamshad, M, Jorde, LB, Tishkoff, SA, Watkins, WS, Metspalu, M, Dryomov, S, Sukernik, R, Singh, L, Thangaraj, K, Paeaebo, S, Kelso, J, Patterson, N, and Reich, D
Abstract: Here we report the Simons Genome Diversity Project data set: high quality genomes from 300 individuals from 142 diverse populations. These genomes include at least 5.8 million base pairs that are not present in the human reference genome. Our analysis reveals key features of the landscape of human genome variation, including that the rate of accumulation of mutations has accelerated by about 5% in non-Africans compared to Africans since divergence. We show that the ancestors of some pairs of present-day human populations were substantially separated by 100,000 years ago, well before the archaeologically attested onset of behavioural modernity. We also demonstrate that indigenous Australians, New Guineans and Andamanese do not derive substantial ancestry from an early dispersal of modern humans; instead, their modern human ancestry is consistent with coming from the same source as that of other non-Africans.
Published: 2016

15. A recent bottleneck of Y chromosome diversity coincides with a global change in culture

Author: Karmin, M., Saag, L., Vicente, M., Wilson Sayres, M.A., Jarve, M., Talas, U.G., Rootsi, S., Ilumae, A.M., Magi, R., Mitt, M., Pagani, L., Puurand, T., Faltyskova, Z., Clemente, F., Cardona, A., Metspalu, E., Sahakyan, H., Yunusbayev, B., Hudjashov, G., DeGiorgio, M., Loogvali, E.L., Eichstaedt, C., Eelmets, M., Chaubey, G., Tambets, K., Litvinov, S., Mormina, M., Xue, Y., Ayub, Q., Zoraqi, G., Korneliussen, T.S., Akhatova, F., Lachance, J., Tishkoff, S., Momynaliev, K., Ricaut, F.X., Kusuma, P., Razafindrazaka, H., Pierron, D., Cox, M.P., Sultana, G.N., Willerslev, R., Muller, C., Westaway, M., Lambert, D., Skaro, V., Kovacevic, L., Turdikulova, S., Dalimova, D., Khusainova, R., Trofimova, N., Akhmetova, V., Khidiyatova, I., Lichman, D.V., Isakova, J., Pocheshkhova, E., Sabitov, Z., Barashkov, N.A., Nymadawa, P., Mihailov, E., Seng, J.W., Evseeva, I., Migliano, A.B., Abdullah, S., Andriadze, G., Primorac, D., Atramentova, L., Utevska, O., Yepiskoposyan, L., Marjanovic, D., Kushniarevich, A., Behar, D.M., Gilissen, C., Vissers, L., Veltman, J.A., Balanovska, E., Derenko, M., Malyarchuk, B., Metspalu, A., Fedorova, S., Eriksson, A., Manica, A., Mendez, F.L., Karafet, T.M., Veeramah, K.R., Bradman, N., Hammer, M.F., Osipova, L.P., Balanovsky, O., Khusnutdinova, E.K., Johnsen, K., Remm, M., Thomas, M.G., Tyler-Smith, C., Underhill, P.A., Willerslev, E., Nielsen, R., Metspalu, M., Villems, R., Kivisild, T., Karmin, M., Saag, L., Vicente, M., Wilson Sayres, M.A., Jarve, M., Talas, U.G., Rootsi, S., Ilumae, A.M., Magi, R., Mitt, M., Pagani, L., Puurand, T., Faltyskova, Z., Clemente, F., Cardona, A., Metspalu, E., Sahakyan, H., Yunusbayev, B., Hudjashov, G., DeGiorgio, M., Loogvali, E.L., Eichstaedt, C., Eelmets, M., Chaubey, G., Tambets, K., Litvinov, S., Mormina, M., Xue, Y., Ayub, Q., Zoraqi, G., Korneliussen, T.S., Akhatova, F., Lachance, J., Tishkoff, S., Momynaliev, K., Ricaut, F.X., Kusuma, P., Razafindrazaka, H., Pierron, D., Cox, M.P., Sultana, G.N., Willerslev, R., Muller, C., Westaway, M., Lambert, D., Skaro, V., Kovacevic, L., Turdikulova, S., Dalimova, D., Khusainova, R., Trofimova, N., Akhmetova, V., Khidiyatova, I., Lichman, D.V., Isakova, J., Pocheshkhova, E., Sabitov, Z., Barashkov, N.A., Nymadawa, P., Mihailov, E., Seng, J.W., Evseeva, I., Migliano, A.B., Abdullah, S., Andriadze, G., Primorac, D., Atramentova, L., Utevska, O., Yepiskoposyan, L., Marjanovic, D., Kushniarevich, A., Behar, D.M., Gilissen, C., Vissers, L., Veltman, J.A., Balanovska, E., Derenko, M., Malyarchuk, B., Metspalu, A., Fedorova, S., Eriksson, A., Manica, A., Mendez, F.L., Karafet, T.M., Veeramah, K.R., Bradman, N., Hammer, M.F., Osipova, L.P., Balanovsky, O., Khusnutdinova, E.K., Johnsen, K., Remm, M., Thomas, M.G., Tyler-Smith, C., Underhill, P.A., Willerslev, E., Nielsen, R., Metspalu, M., Villems, R., and Kivisild, T.
Abstract: Contains fulltext : 153022.pdf (publisher's version ) (Open Access), It is commonly thought that human genetic diversity in non-African populations was shaped primarily by an out-of-Africa dispersal 50-100 thousand yr ago (kya). Here, we present a study of 456 geographically diverse high-coverage Y chromosome sequences, including 299 newly reported samples. Applying ancient DNA calibration, we date the Y-chromosomal most recent common ancestor (MRCA) in Africa at 254 (95% CI 192-307) kya and detect a cluster of major non-African founder haplogroups in a narrow time interval at 47-52 kya, consistent with a rapid initial colonization model of Eurasia and Oceania after the out-of-Africa bottleneck. In contrast to demographic reconstructions based on mtDNA, we infer a second strong bottleneck in Y-chromosome lineages dating to the last 10 ky. We hypothesize that this bottleneck is caused by cultural changes affecting variance of reproductive success among males.
Published: 2015

16. Iranian Azeri's Y-Chromosomal Diversity in the Context of Turkish-Speaking Populations of the Middle East

Author: Andonian, L., Rezaie, S., Margaryan, A., Farhud, D. D., Mohammad, K., Holakouie Naieni, K., Khorramizadeh, M. R., Mohammad Hossein sanati, Jamali, M., Bayatian, P., and Yepiskoposyan, L.
Subjects: Iranian Azersi, Y chromosome diversity, lcsh:Public aspects of medicine, Original Article, lcsh:RA1-1270, Iran, Iranian Azeris, Microsatellites, SNPs
Abstract: Background: The main goal of this study was to conduct a comparative population genetic study of Turkish speaking Iranian Azeris as being the biggest ethno-linguistic community, based on the polymorph markers on Y chromosome. Methods: One hundred Turkish-speaking Azeri males from north-west Iran (Tabriz, 2008-2009) were selected based on living 3 generations paternally in the same region and not having any relationship with each other. Samples were collected by mouth swabs, DNA extracted and multiplex PCR done, then 12 Single Nucleotide Polymorphisms (SNPs) and 6 Microsatellites (MS) were sequenced. Obtained data were statistically analyzed by Arlequin software. Results: SNPs and Microsatellites typing were compared with neighboring Turkish-speaking populations (from Turkey and Azerbaijan) and Turkmens representing a possible source group who imposed the Turkish language during 11-15th centuries AD. Azeris demonstrated high level of gene diversity compatible with patterns registered in the neighboring Turkish-speaking populations, whereas the Turkmens displayed significantly lower level of genetic variation. This rate of genetic affiliation depends primarily on the geographic proximity. Conclusion: The imposition of Turkish language to this region was realized predominantly by the process of elite dominance, i.e. by the limited number of invaders who left only weak patrilineal genetic trace in modern populations of the region.
Published: 2011

17. P87 – 2840: Establishment of rare diagnoses is possible in countries with limited resources

Author: Yepiskoposyan, L., primary and Sukhudyan, B., additional
Published: 2015
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18. Ancient human genomes suggest three ancestral populations for present-day Europeans

Author: Lazaridis, I, Patterson, N, Mittnik, A, Renaud, G, Mallick, S, Kirsanow, K, Sudmant, Ph, Schraiber, Jg, Castellano, S, Lipson, M, Berger, B, Economou, C, Bollongino, R, Fu, Q, Bos, Ki, Nordenfelt, S, Li, H, De Filippo, C, Prüfer, K, Sawyer, S, Posth, C, Haak, W, Hallgren, F, Fornander, E, Rohland, N, Delsate, D, Francken, M, Guinet, Jm, Wahl, J, Ayodo, G, Babiker, Ha, Bailliet, G, Balanovska, E, Balanovsky, O, Bedoya, G, Ben Ami, H, Bene, J, Berrada, F, Bravi, Cm, Brisighelli, Francesca, Busby, Gb, Cali, F, Churnosov, M, Cole, De, Corach, D, Damba, L, Van Driem, G, Dryomov, S, Fedorova, Sa, Gallego Romero, I, Gubina, M, Hammer, M, Henn, Bm, Hervig, T, Hodoglugil, U, Jha, Ar, Karachanak Yankova, S, Khusainova, R, Khusnutdinova, E, Kittles, R, Kivisild, T, Kučinskas, V, Kushniarevich, A, Laredj, L, Litvinov, S, Loukidis, T, Mahley, Rw, Melegh, B, Metspalu, E, Molina, J, Mountain, J, Näkkäläjärvi, K, Nesheva, D, Nyambo, T, Osipova, L, Platonov, F, Posukh, O, Romano, V, Rothhammer, F, Rudan, I, Ruizbakiev, R, Sahakyan, H, Sajantila, A, Salas, A, Starikovskaya, Eb, Tarekegn, A, Toncheva, D, Turdikulova, S, Utevska, O, Vasquez, R, Villena, M, Voevoda, M, Winkler, Ca, Yepiskoposyan, L, Zalloua, P, Zemunik, T, Cooper, A, Capelli, C, Ruiz Linares, A, Tishkoff, Sa Et Al, Brisighelli, Francesca (ORCID:0000-0001-5469-4413), Lazaridis, I, Patterson, N, Mittnik, A, Renaud, G, Mallick, S, Kirsanow, K, Sudmant, Ph, Schraiber, Jg, Castellano, S, Lipson, M, Berger, B, Economou, C, Bollongino, R, Fu, Q, Bos, Ki, Nordenfelt, S, Li, H, De Filippo, C, Prüfer, K, Sawyer, S, Posth, C, Haak, W, Hallgren, F, Fornander, E, Rohland, N, Delsate, D, Francken, M, Guinet, Jm, Wahl, J, Ayodo, G, Babiker, Ha, Bailliet, G, Balanovska, E, Balanovsky, O, Bedoya, G, Ben Ami, H, Bene, J, Berrada, F, Bravi, Cm, Brisighelli, Francesca, Busby, Gb, Cali, F, Churnosov, M, Cole, De, Corach, D, Damba, L, Van Driem, G, Dryomov, S, Fedorova, Sa, Gallego Romero, I, Gubina, M, Hammer, M, Henn, Bm, Hervig, T, Hodoglugil, U, Jha, Ar, Karachanak Yankova, S, Khusainova, R, Khusnutdinova, E, Kittles, R, Kivisild, T, Kučinskas, V, Kushniarevich, A, Laredj, L, Litvinov, S, Loukidis, T, Mahley, Rw, Melegh, B, Metspalu, E, Molina, J, Mountain, J, Näkkäläjärvi, K, Nesheva, D, Nyambo, T, Osipova, L, Platonov, F, Posukh, O, Romano, V, Rothhammer, F, Rudan, I, Ruizbakiev, R, Sahakyan, H, Sajantila, A, Salas, A, Starikovskaya, Eb, Tarekegn, A, Toncheva, D, Turdikulova, S, Utevska, O, Vasquez, R, Villena, M, Voevoda, M, Winkler, Ca, Yepiskoposyan, L, Zalloua, P, Zemunik, T, Cooper, A, Capelli, C, Ruiz Linares, A, Tishkoff, Sa Et Al, and Brisighelli, Francesca (ORCID:0000-0001-5469-4413)
Abstract: We sequenced the genomes of a ∼7,000-year-old farmer from Germany and eight ∼8,000-year-old hunter-gatherers from Luxembourg and Sweden. We analysed these and other ancient genomes with 2,345 contemporary humans to show that most present-day Europeans derive from at least three highly differentiated populations: west European hunter-gatherers, who contributed ancestry to all Europeans but not to Near Easterners; ancient north Eurasians related to Upper Palaeolithic Siberians, who contributed to both Europeans and Near Easterners; and early European farmers, who were mainly of Near Eastern origin but also harboured west European hunter-gatherer related ancestry. We model these populations' deep relationships and show that early European farmers had ∼44% ancestry from a 'basal Eurasian' population that split before the diversification of other non-African lineages.
Published: 2014

19. P.1.g.030 - Analysis of genetic variants associated with antipsychotic treatment efficacy in healthy Armenian individuals

Author: Zakharyan, R., Chavushyan, A., Hayrapetyan, V., Hovhannisyan, A., Khachatryan, Z., Yepiskoposyan, L., and Arakelyan, A.
Published: 2017
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20. The Azokh Cave complex: Middle Pleistocene to Holocene human occupation in the Caucasus

Author: Fernández-Jalvo, Yolanda, King, Tania, Andrews, Peter, Yepiskoposyan, L., Moloney, N., Murray, J., Domínguez Alonso, Patricio, Asryan, L., Ditchfield, P., Van der Made, Jan, Torres, Trinidad José de, Sevilla, Paloma, Nieto-Díaz, Manuel, Cáceres, Isabel, Allué, E., Marín Monfort, M. D., Sanz Martín, Teresa, Fernández-Jalvo, Yolanda, King, Tania, Andrews, Peter, Yepiskoposyan, L., Moloney, N., Murray, J., Domínguez Alonso, Patricio, Asryan, L., Ditchfield, P., Van der Made, Jan, Torres, Trinidad José de, Sevilla, Paloma, Nieto-Díaz, Manuel, Cáceres, Isabel, Allué, E., Marín Monfort, M. D., and Sanz Martín, Teresa
Abstract: Azokh Cave is located near the village of the same name in the Nagorno-Karabagh region of the south-eastern part of the Lesser Caucasus (3937.09’ N and 4659.19’ E, 962 metres –a.s.l.). Azokh Cave and other relevant Acheulian sites in the Caucasus (Fig. 1) were described by Lioubine (2002). Together with Mousterian sites (Klein, 1969, 1999; Hoffecker and Cleghorn, 2000; Hoffecker, 2002; Stringer and Andrews, 2005) and sites producing evidence of the Middle-Late Palaeolithic transition (Joris and Adler 2008), the Caucasus region has provided evidence of continuous human settlement of the area throughout the Pleistocene. The geographical location of these sites indicates the persistence of a natural corridor that Lioubine (2002) named the ‘Caucasus isthmus’ and which we describe as the Trans-Caucasian corridor. Based on a geological survey of Quaternary deposits in collaboration with the Armenian Academy of Sciences (Ferna´ndez-Jalvo et al., 2004; King et al., 2003), we observe that the topography of the area has changed considerably due to tectonic compression and periglacial isostasy. This is in agreement with estimations by GPS studies (Mosar, 2006, Mosar et al., 2007) and ESR (Gru¨n et al., 1999) that establishedan uplift rate of12 to14 mm/year or 0.8–1.0 cm/year, respectively. The corridor has changed greatly since the middle Pleistocene, with uplift and erosion altering the landscape, but it is likely that passage through the Caucasian mountains has always been possible. The Trans-Caucasian corridor and other routes via Turkey and towards Asia (Bar-Yosef and Belfer-Cohen, 2001) were migration pathways during the Pleistocene. Fossil humans in the Caucasian area are scarce. The site of Dmanisi in Georgia yielded the earliest known Eurasian hominins (1.7 Ma, Gabunia et al., 2000; Rightmire et al., 2006; Martino´ n- Torres et al., 2008). Late surviving Neanderthals are present at several sites: Mezmaiskaya Cave, in the Northern Caucasus of Russia (30 ka, Skinner et a
Published: 2010

21. Assessment of Patrilineal Gene Pool of the Iranian Azeris

Author: Margaryan, A., primary, Khachatryan, Z., additional, Khudoyan, A., additional, Andonian, L., additional, and Yepiskoposyan, L., additional
Published: 2013
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22. Mitochondrial Genetic Diversity in the Armenians: A Review.

Author: Hovhannisyan, H. and Yepiskoposyan, L.
Subjects: *MITOCHONDRIA, *GENETICS, *ARMENIANS, *ETHNIC groups, *EMIGRATION & immigration
Abstract: Armenians are the indigenous people of the Armenian Highland with strong and distinct ethnocultural charateristies. Being a crossroad linking Europe and Asia, the Armenian Highland has experienced numerous ancient and recent migrations of different tribes and ethnic groups. To describe the role of the Armenian plateau in these migrations and how the last influenced the ethnogenesis of the Armenian population, numerous population genetics studies have been recently performed on the Armenians. However, the matrilineal genetic legacy of the Armenian population, which is characterised by maternally transmitted mitochondrial DNA (mtDNA) is still poorly investigated. Here, we review the current state of genetic studies performed so far on the Armenian matrilineal genetic structure. [ABSTRACT FROM AUTHOR]
Published: 2016

23. The Caucasus as an Asymmetric Semipermeable Barrier to Ancient Human Migrations

Author: Yunusbayev, B., primary, Metspalu, M., additional, Jarve, M., additional, Kutuev, I., additional, Rootsi, S., additional, Metspalu, E., additional, Behar, D. M., additional, Varendi, K., additional, Sahakyan, H., additional, Khusainova, R., additional, Yepiskoposyan, L., additional, Khusnutdinova, E. K., additional, Underhill, P. A., additional, Kivisild, T., additional, and Villems, R., additional
Published: 2012
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24. The Caucasus as an Asymmetric Semipermeable Barrier to Ancient Human Migrations

Author: Yunusbayev, B., primary, Metspalu, M., additional, Jarve, M., additional, Kutuev, I., additional, Rootsi, S., additional, Metspalu, E., additional, Behar, D. M., additional, Varendi, K., additional, Sahakyan, H., additional, Khusainova, R., additional, Yepiskoposyan, L., additional, Khusnutdinova, E. K., additional, Underhill, P. A., additional, Kivisild, T., additional, and Villems, R., additional
Published: 2011
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25. The Azokh Cave complex: Middle Pleistocene to Holocene human occupation in the Caucasus

Author: Fernández-Jalvo, Y., primary, King, T., additional, Andrews, P., additional, Yepiskoposyan, L., additional, Moloney, N., additional, Murray, J., additional, Domínguez-Alonso, P., additional, Asryan, L., additional, Ditchfield, P., additional, van der Made, J., additional, Torres, T., additional, Sevilla, P., additional, Nieto Díaz, M., additional, Cáceres, I., additional, Allué, E., additional, Marín Monfort, M.D., additional, and Sanz Martín, T., additional
Published: 2010
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26. Role of the Armenian Highland in the Neolithic Migration of Homo sapiens from the Near East to Europe.

Author: Hovhannisyan A. and Yepiskoposyan L.
Subjects: *HUMAN beings, *FARMERS, *ANCIENT civilization, *NEOLITHIC Period
Abstract: The Armenian Highland is a landlocked mountainous plateau stretching from the Eastern Caucasus to Anatolia, and from the Black Sea to Mesopotamia. Holding a unique position at the crossroads of Europe and Asia, the region was a central point of connection, a route for interaction for the various ancient civilizations and a bridge for major waves of prehistoric and historic migrations. Here, we consider the role of the Armenian Highland in the spread of Neolithic farmers from the Near East to Europe (westward via Anatolia and northward via the Caucasus), based on archaeological and genetic evidence. [ABSTRACT FROM AUTHOR]
Published: 2014

27. The History of Human Population Genetics Studies in Armenia.

Author: Yepiskoposyan, L.
Subjects: *HUMAN population genetics, *PUBLICATIONS, *PALEOANTHROPOLOGY, *Y chromosome, *GENETIC markers
Abstract: Here is presented a brief history of human population genetics studies in Armenia which started in the early 1970s. Principal publications on this subject were based on the results of studies assessing the population structure of different geographic groups of Armenians using paleoanthropological, finger print (dermatoglyphics) and isoserological data, as well as paternally (Y-chromosomal), maternally (mtDNA) and biparentally (autosomal) inherited genetic markers. [ABSTRACT FROM AUTHOR]
Published: 2013

28. Newborns' physique in Armenia, 1980-2000

Author: Yepiskoposyan, L., Avagyan, T., and Hakobyan, M.
Subjects: Armenia -- Research, Social economics -- Research, Epidemiology -- Research, Infants (Newborn) -- Physiological aspects, Infants (Newborn) -- Research, Health, Social sciences
Published: 2004

29. Trends in infant mortality rate during the past decade in Armenia

Author: Hakobyan, M., Yepiskoposyan, L., and Avagyan, T.
Subjects: Armenia -- Research, Infants -- Patient outcomes, Infants -- Statistics, Infants -- Research, Health, Social sciences
Published: 2004

30. IRANIAN ARMENIANS IN THE ARMENIAN GENETIC LANDSCAPE.

Author: Andonian, L., Harutyunyan, A., Margaryan, A., Khachatryan, Z., and Yepiskoposyan, L.
Subjects: MICROSATELLITE repeats, GENETIC polymorphisms, GENETIC engineering, Y chromosome, ARMENIANS
Abstract: The place of modern Armenians living in Iran in the context of general Armenian population was clarified based on Y chromosomal single nucleotide (SNP) and microsatellite (MS) polymorphisms. 89 DNA samples in form of buccal swabs have been collected in ethnic Armenian males who are the direct descendants of Armenians forcibly moved to Iran in the beginning of 17th century AD. Twelve SNP and six MS markers have been typed to describe patrilineal genetic structure of the group studied and to compare with six geographic groups of Armenians representing different areas of Historical Armenia. The results indicate that modern Iranian Armenians are genetically closer to Western Armenians which is in agreement with historical records. Political and geographic isolation during the last four centuries had moderate influence on the genetic structure of the community that is expressed in lower diversity of their patrilineal genetic legacy. [ABSTRACT FROM AUTHOR]
Published: 2010

31. East Eurasian ancestry in the middle of Europe: Genetic footprints of Steppe nomads in the genomes of Belarusian Lipka Tatars

Author: Pankratov V., Litvinov S., Kassian A., Shulhin D., Tchebotarev L., Yunusbayev B., Möls M., Sahakyan H., Yepiskoposyan L., Rootsi S., Metspalu E., Golubenko M., Ekomasova N., Akhatova F., Khusnutdinova E., Heyer E., Endicott P., Derenko M., Malyarchuk B., Metspalu M., Davydenko O., Villems R., Kushniarevich A., Pankratov V., Litvinov S., Kassian A., Shulhin D., Tchebotarev L., Yunusbayev B., Möls M., Sahakyan H., Yepiskoposyan L., Rootsi S., Metspalu E., Golubenko M., Ekomasova N., Akhatova F., Khusnutdinova E., Heyer E., Endicott P., Derenko M., Malyarchuk B., Metspalu M., Davydenko O., Villems R., and Kushniarevich A.
Abstract: Medieval era encounters of nomadic groups of the Eurasian Steppe and largely sedentary East Europeans had a variety of demographic and cultural consequences. Amongst these outcomes was the emergence of the Lipka Tatars-a Slavic-speaking Sunni-Muslim minority residing in modern Belarus, Lithuania and Poland, whose ancestors arrived in these territories via several migration waves, mainly from the Golden Horde. Our results show that Belarusian Lipka Tatars share a substantial part of their gene pool with Europeans as indicated by their Y-chromosomal, mitochondrial and autosomal DNA variation. Nevertheless, Belarusian Lipkas still retain a strong genetic signal of their nomadic ancestry, witnessed by the presence of common Y-chromosomal and mitochondrial DNA variants as well as autosomal segments identical by descent between Lipkas and East Eurasians from temperate and northern regions. Hence, we document Lipka Tatars as a unique example of former Medieval migrants into Central Europe, who became sedentary, changed language to Slavic, yet preserved their faith and retained, both uni-and bi-parentally, a clear genetic echo of a complex population interplay throughout the Eurasian Steppe Belt, extending from Central Europe to northern China.

32. A recent bottleneck of Y chromosome diversity coincides with a global change in culture

Author: Karmin M., Saag L., Vicente M., Wilson Sayres M., Järve M., Talas U., Rootsi S., Ilumäe A., Mägi R., Mitt M., Pagani L., Puurand T., Faltyskova Z., Clemente F., Cardona A., Metspalu E., Sahakyan H., Yunusbayev B., Hudjashov G., DeGiorgio M., Loogväli E., Eichstaedt C., Eelmets M., Chaubey G., Tambets K., Litvinov S., Mormina M., Xue Y., Ayub Q., Zoraqi G., Korneliussen T., Akhatova F., Lachance J., Tishkoff S., Momynaliev K., Ricaut F., Kusuma P., Razafindrazaka H., Pierron D., Cox M., Sultana G., Willerslev R., Muller C., Westaway M., Lambert D., Skaro V., Kovačević L., Turdikulova S., Dalimova D., Khusainova R., Trofimova N., Akhmetova V., Khidiyatova I., Lichman D., Isakova J., Pocheshkhova E., Sabitov Z., Barashkov N., Nymadawa P., Mihailov E., Seng J., Evseeva I., Migliano A., Abdullah S., Andriadze G., Primorac D., Atramentova L., Utevska O., Yepiskoposyan L., Marjanović D., Kushniarevich A., Behar D., Karmin M., Saag L., Vicente M., Wilson Sayres M., Järve M., Talas U., Rootsi S., Ilumäe A., Mägi R., Mitt M., Pagani L., Puurand T., Faltyskova Z., Clemente F., Cardona A., Metspalu E., Sahakyan H., Yunusbayev B., Hudjashov G., DeGiorgio M., Loogväli E., Eichstaedt C., Eelmets M., Chaubey G., Tambets K., Litvinov S., Mormina M., Xue Y., Ayub Q., Zoraqi G., Korneliussen T., Akhatova F., Lachance J., Tishkoff S., Momynaliev K., Ricaut F., Kusuma P., Razafindrazaka H., Pierron D., Cox M., Sultana G., Willerslev R., Muller C., Westaway M., Lambert D., Skaro V., Kovačević L., Turdikulova S., Dalimova D., Khusainova R., Trofimova N., Akhmetova V., Khidiyatova I., Lichman D., Isakova J., Pocheshkhova E., Sabitov Z., Barashkov N., Nymadawa P., Mihailov E., Seng J., Evseeva I., Migliano A., Abdullah S., Andriadze G., Primorac D., Atramentova L., Utevska O., Yepiskoposyan L., Marjanović D., Kushniarevich A., and Behar D.
Abstract: © 2015 Karmin et al. It is commonly thought that human genetic diversity in non-African populations was shaped primarily by an out-of-Africa dispersal 50-100 thousand yr ago (kya). Here, we present a study of 456 geographically diverse high-coverage Y chromosome sequences, including 299 newly reported samples. Applying ancient DNA calibration, we date the Y-chromosomal most recent common ancestor (MRCA) in Africa at 254 (95% CI 192-307) kya and detect a cluster of major non-African founder haplogroups in a narrow time interval at 47-52 kya, consistent with a rapid initial colonization model of Eurasia and Oceania after the out-of-Africa bottleneck. In contrast to demographic reconstructions based on mtDNA, we infer a second strong bottleneck in Y-chromosome lineages dating to the last 10 ky. We hypothesize that this bottleneck is caused by cultural changes affecting variance of reproductive success among males.

33. East Eurasian ancestry in the middle of Europe: Genetic footprints of Steppe nomads in the genomes of Belarusian Lipka Tatars

Author: Pankratov V., Litvinov S., Kassian A., Shulhin D., Tchebotarev L., Yunusbayev B., Möls M., Sahakyan H., Yepiskoposyan L., Rootsi S., Metspalu E., Golubenko M., Ekomasova N., Akhatova F., Khusnutdinova E., Heyer E., Endicott P., Derenko M., Malyarchuk B., Metspalu M., Davydenko O., Villems R., Kushniarevich A., Pankratov V., Litvinov S., Kassian A., Shulhin D., Tchebotarev L., Yunusbayev B., Möls M., Sahakyan H., Yepiskoposyan L., Rootsi S., Metspalu E., Golubenko M., Ekomasova N., Akhatova F., Khusnutdinova E., Heyer E., Endicott P., Derenko M., Malyarchuk B., Metspalu M., Davydenko O., Villems R., and Kushniarevich A.
Abstract: Medieval era encounters of nomadic groups of the Eurasian Steppe and largely sedentary East Europeans had a variety of demographic and cultural consequences. Amongst these outcomes was the emergence of the Lipka Tatars-a Slavic-speaking Sunni-Muslim minority residing in modern Belarus, Lithuania and Poland, whose ancestors arrived in these territories via several migration waves, mainly from the Golden Horde. Our results show that Belarusian Lipka Tatars share a substantial part of their gene pool with Europeans as indicated by their Y-chromosomal, mitochondrial and autosomal DNA variation. Nevertheless, Belarusian Lipkas still retain a strong genetic signal of their nomadic ancestry, witnessed by the presence of common Y-chromosomal and mitochondrial DNA variants as well as autosomal segments identical by descent between Lipkas and East Eurasians from temperate and northern regions. Hence, we document Lipka Tatars as a unique example of former Medieval migrants into Central Europe, who became sedentary, changed language to Slavic, yet preserved their faith and retained, both uni-and bi-parentally, a clear genetic echo of a complex population interplay throughout the Eurasian Steppe Belt, extending from Central Europe to northern China.

34. A recent bottleneck of Y chromosome diversity coincides with a global change in culture

Author: Karmin M., Saag L., Vicente M., Wilson Sayres M., Järve M., Talas U., Rootsi S., Ilumäe A., Mägi R., Mitt M., Pagani L., Puurand T., Faltyskova Z., Clemente F., Cardona A., Metspalu E., Sahakyan H., Yunusbayev B., Hudjashov G., DeGiorgio M., Loogväli E., Eichstaedt C., Eelmets M., Chaubey G., Tambets K., Litvinov S., Mormina M., Xue Y., Ayub Q., Zoraqi G., Korneliussen T., Akhatova F., Lachance J., Tishkoff S., Momynaliev K., Ricaut F., Kusuma P., Razafindrazaka H., Pierron D., Cox M., Sultana G., Willerslev R., Muller C., Westaway M., Lambert D., Skaro V., Kovačević L., Turdikulova S., Dalimova D., Khusainova R., Trofimova N., Akhmetova V., Khidiyatova I., Lichman D., Isakova J., Pocheshkhova E., Sabitov Z., Barashkov N., Nymadawa P., Mihailov E., Seng J., Evseeva I., Migliano A., Abdullah S., Andriadze G., Primorac D., Atramentova L., Utevska O., Yepiskoposyan L., Marjanović D., Kushniarevich A., Behar D., Karmin M., Saag L., Vicente M., Wilson Sayres M., Järve M., Talas U., Rootsi S., Ilumäe A., Mägi R., Mitt M., Pagani L., Puurand T., Faltyskova Z., Clemente F., Cardona A., Metspalu E., Sahakyan H., Yunusbayev B., Hudjashov G., DeGiorgio M., Loogväli E., Eichstaedt C., Eelmets M., Chaubey G., Tambets K., Litvinov S., Mormina M., Xue Y., Ayub Q., Zoraqi G., Korneliussen T., Akhatova F., Lachance J., Tishkoff S., Momynaliev K., Ricaut F., Kusuma P., Razafindrazaka H., Pierron D., Cox M., Sultana G., Willerslev R., Muller C., Westaway M., Lambert D., Skaro V., Kovačević L., Turdikulova S., Dalimova D., Khusainova R., Trofimova N., Akhmetova V., Khidiyatova I., Lichman D., Isakova J., Pocheshkhova E., Sabitov Z., Barashkov N., Nymadawa P., Mihailov E., Seng J., Evseeva I., Migliano A., Abdullah S., Andriadze G., Primorac D., Atramentova L., Utevska O., Yepiskoposyan L., Marjanović D., Kushniarevich A., and Behar D.
Abstract: © 2015 Karmin et al. It is commonly thought that human genetic diversity in non-African populations was shaped primarily by an out-of-Africa dispersal 50-100 thousand yr ago (kya). Here, we present a study of 456 geographically diverse high-coverage Y chromosome sequences, including 299 newly reported samples. Applying ancient DNA calibration, we date the Y-chromosomal most recent common ancestor (MRCA) in Africa at 254 (95% CI 192-307) kya and detect a cluster of major non-African founder haplogroups in a narrow time interval at 47-52 kya, consistent with a rapid initial colonization model of Eurasia and Oceania after the out-of-Africa bottleneck. In contrast to demographic reconstructions based on mtDNA, we infer a second strong bottleneck in Y-chromosome lineages dating to the last 10 ky. We hypothesize that this bottleneck is caused by cultural changes affecting variance of reproductive success among males.

35. Ancient human genomes suggest three ancestral populations for present-day Europeans

Author: Joanna L. Mountain, Michael F. Hammer, Ruslan Ruizbakiev, Cesare de Filippo, Kumarasamy Thangaraj, David E. C. Cole, Haim Ben-Ami, Leila Laredj, Mark Lipson, Jüri Parik, Valentino Romano, Andres Ruiz-Linares, Fouad Berrada, Dominique Delsate, Ugur Hodoglugil, Antti Sajantila, Olga Utevska, Shahlo Turdikulova, Tor Hervig, Ludmila P. Osipova, Hovhannes Sahakyan, Robert W. Mahley, Ramiro Barrantes, Kirsten I. Bos, Stanislav Dryomov, Peter H. Sudmant, Nadin Rohland, Heng Li, Gabriel Renaud, Mikhail Voevoda, Claudio M. Bravi, Jean-Michel Guinet, Rem I. Sukernik, Joachim Wahl, Matthias Meyer, Christos Economou, Kay Prüfer, Graciela Bailliet, Mait Metspalu, Mikhail Churnosov, Iosif Lazaridis, Johannes Krause, Bonnie Berger, Levon Yepiskoposyan, Francesca Brisighelli, Francesco Calì, Irene Gallego Romero, Oleg Balanovsky, George Ayodo, Alan Cooper, Alissa Mittnik, Julio Molina, George van Driem, Jean-Michel Dugoujon, Larissa Damba, Fedor Platonov, Nick Patterson, David Reich, Thomas B. Nyambo, David Comas, Olga L. Posukh, Béla Melegh, Draga Toncheva, Alena Kushniarevich, Brenna M. Henn, Montgomery Slatkin, René Vasquez, Elena B. Starikovskaya, Joachim Burger, Ayele Tarekegn, Tatijana Zemunik, Ene Metspalu, Sena Karachanak-Yankova, Lalji Singh, Wolfgang Haak, Susanna Sawyer, Rick A. Kittles, Cheryl A. Winkler, Svante Pääbo, Francisco Rothhammer, Marina Gubina, Pierre Zalloua, Aashish R. Jha, Swapan Mallick, Sergi Castellano, Qiaomei Fu, Desislava Nesheva, Sergey Litvinov, Ingrida Uktveryte, Michael Francken, Cosimo Posth, Theologos Loukidis, Cristian Capelli, Janet Kelso, Sarah A. Tishkoff, Toomas Kivisild, Mark G. Thomas, Elin Fornander, Mercedes Villena, Fredrik Hallgren, Vaidutis Kučinskas, Daniel Corach, George B.J. Busby, Judit Bene, William Klitz, Hamza A. Babiker, Karola Kirsanow, Ruth Bollongino, Rita Khusainova, Evan E. Eichler, Sardana A. Fedorova, Klemetti Näkkäläjärvi, Igor Rudan, Susanne Nordenfelt, Joshua G. Schraiber, Elena Balanovska, Antonio Salas, Richard Villems, Gabriel Bedoya, Elza Khusnutdinova, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Massachusetts Institute of Technology. Department of Mathematics, Lipson, Mark, Berger Leighton, Bonnie, Lazaridis,I, Patterson,P, Mittnik,A, Renaud,G, Mallick,S, Kirsanow,K, Sudmant,PH, Schraiber,JG, Castellano,S, Lipson,M, Berger,B, Economou,C, Bollongino,R, Fu,Q, Bos,KI, Nordenfelt,S, Li,H, De Filippo,C, Pruefer,K, Sawyer, Posth,C, Haak1,H, Hallgren,F, Fornander,E, Rohland,N, Delsate,D, Francken,M, Guinet,JM, Wah,J, Ayodo,G, Babiker,HA, Bailliet,G, Balanovska,E, Balanovsky,O, Barrantes,R, Bedoya,G, Ben-Ami,H, Bene,J, Berrada,F, Bravi,CM, Brisighelli,F, Busby,GBJ, Cali,F, Churnosov,M, Cole,DEC, Corach,D, Damba,L, van Driem,G, Dryomov,S, Dugoujon,JM, Fedorova,SA, Gallego Romero,I, Gubina,M, Hammer,M, Henn,BM, Hervig,T, Hodoglugi,U, Jha,AR, Karachanak-Yankova,S, Khusainova,R, Khusnutdinova,E, Kittles,R:Kivisild,T, Klitz,W, Kucˇinskas,V, Kushniarevich,A, Laredj,L, Litvinov,S, Loukidis,T, Mahley,RW, Melegh,B, Metspalu,E, Molina,J, Mountain,J, Na¨kka¨la¨ja¨rvi,K, Nesheva,D, Nyambo,T, Osipova,L, Parik,J, Platonov,F, Posukh,O, Romano,V, Rothhammer,F, Rudan,I, Ruizbakiev,R, Sahakyan,H, Sajantila,A, Salas,A, Starikovskaya,EB, Tarekegn,A, Toncheva,D, Turdikulova,S, Uktveryte,I, Utevska,O, Vasquez,R, Villena,M, Voevoda,M, Winkler,CA, Yepiskoposyan,L, Zalloua,P, Zemunik,T, Cooper, Capelli,C, Thomas,MG, Ruiz-inares,A, Tishkoff,SA, Singh,L, Thangaraj,K, Villems,R, Comas,D, Sukernik,R, Metspalu,M, Meyer,M, Eichler,EE, Burger,J, Slatkin,M, Pa¨a¨bo,S, Kelso,J, Reich,D, and Krause,J
Subjects: History, Neanderthal, Biología, Population Dynamics, Present day, Genoma humà, Genome, purl.org/becyt/ford/1 [https], Basal (phylogenetics), Settore BIO/13 - Biologia Applicata, History, Ancient, Genetics, Principal Component Analysis, education.field_of_study, 0303 health sciences, Multidisciplinary, Ancient DNA, 030305 genetics & heredity, food and beverages, Agriculture, Genomics, 3. Good health, Europe, Workforce, CIENCIAS NATURALES Y EXACTAS, Human, Archaeogenetics, Asia, Lineage (genetic), EUROPE, Otras Ciencias Biológicas, European Continental Ancestry Group, Population, Settore BIO/08 - ANTROPOLOGIA, evolution, Europeans, Biology, Article, White People, Ancient, Genètica de poblacions humanes, Human origins, Ciencias Biológicas, 03 medical and health sciences, HUMAN ORIGINS, biology.animal, Humans, ANCIENT DNA, purl.org/becyt/ford/1.6 [https], education, Quantitative Biology - Populations and Evolution, Denisovan, 030304 developmental biology, Genetic diversity, ancient DNA, modern DNA, Europeans, prehistory, Genome, Human, Populations and Evolution (q-bio.PE), biology.organism_classification, Evolutionary biology, FOS: Biological sciences, Upper Paleolithic, Human genome, GENOMICS
Abstract: We sequenced the genomes of a ∼7,000-year-old farmer from Germany and eight ∼8,000-year-old hunter-gatherers from Luxembourg and Sweden. We analysed these and other ancient genomes1,2,3,4 with 2,345 contemporary humans to show that most present-day Europeans derive from at least three highly differentiated populations: west European hunter-gatherers, who contributed ancestry to all Europeans but not to Near Easterners; ancient north Eurasians related to Upper Palaeolithic Siberians3, who contributed to both Europeans and Near Easterners; and early European farmers, who were mainly of Near Eastern origin but also harboured west European hunter-gatherer related ancestry. We model these populations’ deep relationships and show that early European farmers had ∼44% ancestry from a ‘basal Eurasian’ population that split before the diversification of other non-African lineages., Instituto Multidisciplinario de Biología Celular
Published: 2014

36. Author Correction: Increasing obsidian diversity during the Chalcolithic Period at Yeghegis-1 Rockshelter (Armenia) reveals shifts in land use and social networks.

Author: Frahm E, Saribekyan M, Mkrtchyan S, Furquim L, Avagyan A, Sahakyan L, Azatyan K, Roberts P, Fernandes R, Yepiskoposyan L, Amano N, and Antonosyan M
Published: 2024
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37. Human Y chromosome haplogroup L1-M22 traces Neolithic expansion in West Asia and supports the Elamite and Dravidian connection.

Author: Pathak AK, Simonian H, Ibrahim IAA, Hrechdakian P, Behar DM, Ayub Q, Arsanov P, Metspalu E, Yepiskoposyan L, Rootsi S, Endicott P, Villems R, and Sahakyan H
Abstract: West and South Asian populations profoundly influenced Eurasian genetic and cultural diversity. We investigate the genetic history of the Y chromosome haplogroup L1-M22, which, while prevalent in these regions, lacks in-depth study. Robust Bayesian analyses of 165 high-coverage Y chromosomes favor a West Asian origin for L1-M22 ∼20.6 thousand years ago (kya). Moreover, this haplogroup parallels the genome-wide genetic ancestry of hunter-gatherers from the Iranian Plateau and the Caucasus. We characterized two L1-M22 harboring population groups during the Early Holocene. One expanded with the West Asian Neolithic transition. The other moved to South Asia ∼8-6 kya but showed no expansion. This group likely participated in the spread of Dravidian languages. These South Asian L1-M22 lineages expanded ∼4-3 kya, coinciding with the Steppe ancestry introduction. Our findings advance the current understanding of Eurasian historical dynamics, emphasizing L1-M22's West Asian origin, associated population movements, and possible linguistic impacts., Competing Interests: D.M.B. declares stock ownership at Gene by Gene, Ltd. All other authors declare no competing interests., (© 2024 The Author(s).)
Published: 2024
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38. Increasing obsidian diversity during the Chalcolithic Period at Yeghegis-1 Rockshelter (Armenia) reveals shifts in land use and social networks.

Author: Frahm E, Saribekyan M, Mkrtchyan S, Furquim L, Avagyan A, Sahakyan L, Azatyan K, Roberts P, Fernandes R, Yepiskoposyan L, Amano N, and Antonosyan M
Abstract: The newly excavated rockshelter of Yeghegis-1 in Armenia reflects an occupation of five centuries, as attested by radiocarbon dates from ∼ 4100 to 4000 cal BCE in the lowest layer to ∼ 3600-3500 cal BCE at the top. It is a partially collapsed cave in which pastoralists, we hypothesize, wintered with their herds. The stone tool assemblage is predominantly obsidian (92.1%), despite the shelter being > 60 km on foot from the nearest sources. We use obsidian sourcing to investigate two purported trends in the Southern Caucasus during the Chalcolithic Period: (1) occupation of more varied high-altitude environments and (2) more expansive social networks. Our data show both trends were dynamic phenomena. There was a greater balance in use of the nearest pasturelands over time, perhaps linked to risk management and/or resource sustainability. During later occupations, artifacts from distant sources reveal more extensive connections. This increase in connectivity likely played a central role in the shifts in societal complexity that gave rise to widely shared material culture throughout the Armenian Highlands around the start of the Early Bronze Age. In such a model, greater social connectivity becomes a key mechanism for, rather than a product of, the spread of cultural and/or technological innovations., (© 2024. The Author(s).)
Published: 2024
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39. Genotypes of the UCP1 gene polymorphisms and cardiometabolic diseases: A multifactorial study of association with disease probability.

Author: Pravednikova AE, Nikitich A, Witkowicz A, Karabon L, Flouris AD, Vliora M, Nintou E, Dinas PC, Szulińska M, Bogdański P, Metsios GS, Kerchev VV, Yepiskoposyan L, Bylino OV, Larina SN, Shulgin B, and Shidlovskii YV
Subjects: Humans, Uncoupling Protein 1 genetics, Genotype, Polymorphism, Single Nucleotide, Risk Factors, Alleles, Genetic Predisposition to Disease, Ion Channels genetics, Cardiovascular Diseases genetics
Abstract: Cardiometabolic diseases (CMDs) are complex disorders with a heterogenous phenotype, which are caused by multiple factors including genetic factors. Single nucleotide polymorphisms (SNPs) rs45539933 (p.Ala64Thr), rs10011540 (c.-112A>C), rs3811791 (c.-1766A>G), and rs1800592 (c.-3826A>G) in the UCP1 gene have been analyzed for association with CMDs in many studies providing controversial results. However, previous studies only considered individual UCP1 SNPs and did not evaluate them in an integrated manner, which is a more powerful approach to uncover genetic component of complex diseases. This study aimed to investigate associations between UCP1 genotype combinations and CMDs or CMD risk factors in the context of non-genetic factors. We performed multiple logistic regression analysis and proposed new methodology of testing different combinations of SNP genotypes. We found that probability of CMDs increased in presence of the three-SNP combination of genotypes with minor alleles of c.-3826A>G and p.Ala64Thr and wild allele of c.-112A>C, with increasing age, body mass index (BMI), body fat percentage (BF%) and may differ between sexes and between countries. The combination of genotypes with c.-3826A>G minor allele and wild homozygotes of c.-112A>C and p.Ala64Thr was associated with increased probability of diabetes. While combination of genotypes with minor alleles of all three SNPs reduced the CMD probability. The present results suggest that age, BMI, sex, and UCP1 three-SNP combinations of genotypes significantly contribute to CMD probability. Varying of c.-112A>C alleles in the genotype combination with minor alleles of c.-3826A>G and p.Ala64Thr markedly changes CMD probability., Competing Interests: Declaration of competing interest The authors have declared that no competing interests exist., (Copyright © 2023 Elsevier B.V. and Société Française de Biochimie et Biologie Moléculaire (SFBBM). All rights reserved.)
Published: 2024
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40. Publisher Correction: Population genomics of post-glacial western Eurasia.

Author: Allentoft ME, Sikora M, Refoyo-Martínez A, Irving-Pease EK, Fischer A, Barrie W, Ingason A, Stenderup J, Sjögren KG, Pearson A, Sousa da Mota B, Schulz Paulsson B, Halgren A, Macleod R, Jørkov MLS, Demeter F, Sørensen L, Nielsen PO, Henriksen RA, Vimala T, McColl H, Margaryan A, Ilardo M, Vaughn A, Fischer Mortensen M, Nielsen AB, Ulfeldt Hede M, Johannsen NN, Rasmussen P, Vinner L, Renaud G, Stern A, Jensen TZT, Scorrano G, Schroeder H, Lysdahl P, Ramsøe AD, Skorobogatov A, Schork AJ, Rosengren A, Ruter A, Outram A, Timoshenko AA, Buzhilova A, Coppa A, Zubova A, Silva AM, Hansen AJ, Gromov A, Logvin A, Gotfredsen AB, Henning Nielsen B, González-Rabanal B, Lalueza-Fox C, McKenzie CJ, Gaunitz C, Blasco C, Liesau C, Martinez-Labarga C, Pozdnyakov DV, Cuenca-Solana D, Lordkipanidze DO, En'shin D, Salazar-García DC, Price TD, Borić D, Kostyleva E, Veselovskaya EV, Usmanova ER, Cappellini E, Brinch Petersen E, Kannegaard E, Radina F, Eylem Yediay F, Duday H, Gutiérrez-Zugasti I, Merts I, Potekhina I, Shevnina I, Altinkaya I, Guilaine J, Hansen J, Aura Tortosa JE, Zilhão J, Vega J, Buck Pedersen K, Tunia K, Zhao L, Mylnikova LN, Larsson L, Metz L, Yepiskoposyan L, Pedersen L, Sarti L, Orlando L, Slimak L, Klassen L, Blank M, González-Morales M, Silvestrini M, Vretemark M, Nesterova MS, Rykun M, Rolfo MF, Szmyt M, Przybyła M, Calattini M, Sablin M, Dobisíková M, Meldgaard M, Johansen M, Berezina N, Card N, Saveliev NA, Poshekhonova O, Rickards O, Lozovskaya OV, Gábor O, Uldum OC, Aurino P, Kosintsev P, Courtaud P, Ríos P, Mortensen P, Lotz P, Persson P, Bangsgaard P, de Barros Damgaard P, Vang Petersen P, Martinez PP, Włodarczak P, Smolyaninov RV, Maring R, Menduiña R, Badalyan R, Iversen R, Turin R, Vasilyev S, Wåhlin S, Borutskaya S, Skochina S, Sørensen SA, Andersen SH, Jørgensen T, Serikov YB, Molodin VI, Smrcka V, Merts V, Appadurai V, Moiseyev V, Magnusson Y, Kjær KH, Lynnerup N, Lawson DJ, Sudmant PH, Rasmussen S, Korneliussen TS, Durbin R, Nielsen R, Delaneau O, Werge T, Racimo F, Kristiansen K, and Willerslev E
Published: 2024
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41. Population genomics of post-glacial western Eurasia.

Author: Allentoft ME, Sikora M, Refoyo-Martínez A, Irving-Pease EK, Fischer A, Barrie W, Ingason A, Stenderup J, Sjögren KG, Pearson A, Sousa da Mota B, Schulz Paulsson B, Halgren A, Macleod R, Jørkov MLS, Demeter F, Sørensen L, Nielsen PO, Henriksen RA, Vimala T, McColl H, Margaryan A, Ilardo M, Vaughn A, Fischer Mortensen M, Nielsen AB, Ulfeldt Hede M, Johannsen NN, Rasmussen P, Vinner L, Renaud G, Stern A, Jensen TZT, Scorrano G, Schroeder H, Lysdahl P, Ramsøe AD, Skorobogatov A, Schork AJ, Rosengren A, Ruter A, Outram A, Timoshenko AA, Buzhilova A, Coppa A, Zubova A, Silva AM, Hansen AJ, Gromov A, Logvin A, Gotfredsen AB, Henning Nielsen B, González-Rabanal B, Lalueza-Fox C, McKenzie CJ, Gaunitz C, Blasco C, Liesau C, Martinez-Labarga C, Pozdnyakov DV, Cuenca-Solana D, Lordkipanidze DO, En'shin D, Salazar-García DC, Price TD, Borić D, Kostyleva E, Veselovskaya EV, Usmanova ER, Cappellini E, Brinch Petersen E, Kannegaard E, Radina F, Eylem Yediay F, Duday H, Gutiérrez-Zugasti I, Merts I, Potekhina I, Shevnina I, Altinkaya I, Guilaine J, Hansen J, Aura Tortosa JE, Zilhão J, Vega J, Buck Pedersen K, Tunia K, Zhao L, Mylnikova LN, Larsson L, Metz L, Yepiskoposyan L, Pedersen L, Sarti L, Orlando L, Slimak L, Klassen L, Blank M, González-Morales M, Silvestrini M, Vretemark M, Nesterova MS, Rykun M, Rolfo MF, Szmyt M, Przybyła M, Calattini M, Sablin M, Dobisíková M, Meldgaard M, Johansen M, Berezina N, Card N, Saveliev NA, Poshekhonova O, Rickards O, Lozovskaya OV, Gábor O, Uldum OC, Aurino P, Kosintsev P, Courtaud P, Ríos P, Mortensen P, Lotz P, Persson P, Bangsgaard P, de Barros Damgaard P, Vang Petersen P, Martinez PP, Włodarczak P, Smolyaninov RV, Maring R, Menduiña R, Badalyan R, Iversen R, Turin R, Vasilyev S, Wåhlin S, Borutskaya S, Skochina S, Sørensen SA, Andersen SH, Jørgensen T, Serikov YB, Molodin VI, Smrcka V, Merts V, Appadurai V, Moiseyev V, Magnusson Y, Kjær KH, Lynnerup N, Lawson DJ, Sudmant PH, Rasmussen S, Korneliussen TS, Durbin R, Nielsen R, Delaneau O, Werge T, Racimo F, Kristiansen K, and Willerslev E
Subjects: Humans, Agriculture history, Asia, Western, Black Sea, Diploidy, Europe ethnology, Genotype, History, Ancient, Hunting history, Ice Cover, Genetics, Population, Genome, Human, Human Migration history, Metagenomics
Abstract: Western Eurasia witnessed several large-scale human migrations during the Holocene 1-5 . Here, to investigate the cross-continental effects of these migrations, we shotgun-sequenced 317 genomes-mainly from the Mesolithic and Neolithic periods-from across northern and western Eurasia. These were imputed alongside published data to obtain diploid genotypes from more than 1,600 ancient humans. Our analyses revealed a 'great divide' genomic boundary extending from the Black Sea to the Baltic. Mesolithic hunter-gatherers were highly genetically differentiated east and west of this zone, and the effect of the neolithization was equally disparate. Large-scale ancestry shifts occurred in the west as farming was introduced, including near-total replacement of hunter-gatherers in many areas, whereas no substantial ancestry shifts happened east of the zone during the same period. Similarly, relatedness decreased in the west from the Neolithic transition onwards, whereas, east of the Urals, relatedness remained high until around 4,000 BP, consistent with the persistence of localized groups of hunter-gatherers. The boundary dissolved when Yamnaya-related ancestry spread across western Eurasia around 5,000 BP, resulting in a second major turnover that reached most parts of Europe within a 1,000-year span. The genetic origin and fate of the Yamnaya have remained elusive, but we show that hunter-gatherers from the Middle Don region contributed ancestry to them. Yamnaya groups later admixed with individuals associated with the Globular Amphora culture before expanding into Europe. Similar turnovers occurred in western Siberia, where we report new genomic data from a 'Neolithic steppe' cline spanning the Siberian forest steppe to Lake Baikal. These prehistoric migrations had profound and lasting effects on the genetic diversity of Eurasian populations., (© 2024. The Author(s).)
Published: 2024
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42. Prevalence of uncoupling protein one genetic polymorphisms and their relationship with cardiovascular and metabolic health.

Author: Dinas PC, Nintou E, Vliora M, Pravednikova AE, Sakellariou P, Witkowicz A, Kachaev ZM, Kerchev VV, Larina SN, Cotton J, Kowalska A, Gkiata P, Bargiota A, Khachatryan ZA, Hovhannisyan AA, Antonosyan MA, Margaryan S, Partyka A, Bogdanski P, Szulinska M, Kregielska-Narozna M, Czepczyński R, Ruchała M, Tomkiewicz A, Yepiskoposyan L, Karabon L, Shidlovskii Y, Metsios GS, and Flouris AD
Subjects: Case-Control Studies, Cytidine Monophosphate, Genetic Predisposition to Disease, Humans, Prevalence, Cardiovascular Diseases genetics, Metabolic Diseases genetics, Polymorphism, Single Nucleotide, Uncoupling Protein 1 genetics
Abstract: Contribution of UCP1 single nucleotide polymorphisms (SNPs) to susceptibility for cardiometabolic pathologies (CMP) and their involvement in specific risk factors for these conditions varies across populations. We tested whether UCP1 SNPs A-3826G, A-1766G, Ala64Thr and A-112C are associated with common CMP and their risk factors across Armenia, Greece, Poland, Russia and United Kingdom. This case-control study included genotyping of these SNPs, from 2,283 Caucasians. Results were extended via systematic review and meta-analysis. In Armenia, GA genotype and A allele of Ala64Thr displayed ~2-fold higher risk for CMP compared to GG genotype and G allele, respectively (p<0.05). In Greece, A allele of Ala64Thr decreased risk of CMP by 39%. Healthy individuals with A-3826G GG genotype and carriers of mutant allele of A-112C and Ala64Thr had higher body mass index compared to those carrying other alleles. In healthy Polish, higher waist-to-hip ratio (WHR) was observed in heterozygotes A-3826G compared to AA homozygotes. Heterozygosity of A-112C and Ala64Thr SNPs was related to lower WHR in CMP individuals compared to wild type homozygotes (p<0.05). Meta-analysis showed no statistically significant odds-ratios across our SNPs (p>0.05). Concluding, the studied SNPs could be associated with the most common CMP and their risk factors in some populations., Competing Interests: The authors have declared that no competing interests exist.
Published: 2022
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43. HLA-C*04:01 Affects HLA Class I Heterozygosity and Predicted Affinity to SARS-CoV-2 Peptides, and in Combination With Age and Sex of Armenian Patients Contributes to COVID-19 Severity.

Author: Hovhannisyan A, Madelian V, Avagyan S, Nazaretyan M, Hyussyan A, Sirunyan A, Arakelyan R, Manukyan Z, Yepiskoposyan L, Mayilyan KR, and Jordan F
Subjects: Adult, Age Factors, Armenia, Female, Gene Frequency genetics, HLA-B51 Antigen immunology, HLA-C Antigens immunology, Heterozygote, Histocompatibility Antigens Class I genetics, Humans, Male, Middle Aged, Pandemics, Risk, Sex Factors, Viral Proteins immunology, COVID-19 pathology, HLA-B51 Antigen genetics, HLA-C Antigens genetics, SARS-CoV-2 immunology, Severity of Illness Index
Abstract: The novel SARS-CoV-2 coronavirus infection has become a global health concern, causing the COVID-19 pandemic. The disease symptoms and outcomes depend on the host immunity, in which the human leukocyte antigen (HLA) molecules play a distinct role. The HLA alleles have an inter-population variability, and understanding their link to the COVID-19 in an ethnically distinct population may contribute to personalized medicine. The present study aimed at detecting associations between common HLA alleles and COVID-19 susceptibility and severity in Armenians. In 299 COVID-19 patients (75 asymptomatic, 102 mild/moderate, 122 severe), the association between disease severity and classic HLA-I and II loci was examined. We found that the advanced age, male sex of patients, and sex and age interaction significantly contributed to the severity of the disease. We observed that an age-dependent effect of HLA-B*51:01 carriage [odds ratio (OR)=0.48 (0.28-0.80), P bonf <0.036] is protective against severe COVID-19. Contrary, the HLA-C*04:01 allele, in a dose-dependent manner, was associated with a significant increase in the disease severity [OR (95% CI) =1.73 (1.20-2.49), P bonf <0.021] and an advancing age (P<0.013). The link between HLA-C*04:01 and age was secondary to a stronger association between HLA-C*04:01 and disease severity. However, HLA-C*04:01 exerted a sex-dependent differential distribution between clinical subgroups [females: P<0.0012; males: P=0.48]. The comparison of HLA-C*04:01 frequency between subgroups and 2,781 Armenian controls revealed a significant incidence of HLA-C*04:01 deficiency in asymptomatic COVID-19. HLA-C*04:01 homozygous genotype in patients blueprinted a decrease in heterozygosity of HLA-B and HLA class-I loci. In HLA-C*04:01 carriers, these changes translated to the SARS-CoV-2 peptide presentation predicted inefficacy by HLA-C and HLA class-I molecules, simultaneously enhancing the appropriate HLA-B potency. In patients with clinical manifestation, due to the high prevalence of HLA-C*04:01, these effects provided a decrease of the HLA class-I heterozygosity and an ability to recognize SARS-CoV-2 peptides. Based on our observations, we developed a prediction model involving demographic variables and HLA-C*04:01 allele for the identification of potential cases with the risk of hospitalization (the area under the curve (AUC) = 86.2%) or severe COVID-19 (AUC =71%)., Competing Interests: RA and ZM declare that they work at the ClinSoft Armenia, Yerevan, Armenia, and ClinStat Group, Lexington, MA. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Hovhannisyan, Madelian, Avagyan, Nazaretyan, Hyussyan, Sirunyan, Arakelyan, Manukyan, Yepiskoposyan, Mayilyan and Jordan.)
Published: 2022
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44. Origin and diffusion of human Y chromosome haplogroup J1-M267.

Author: Sahakyan H, Margaryan A, Saag L, Karmin M, Flores R, Haber M, Kushniarevich A, Khachatryan Z, Bahmanimehr A, Parik J, Karafet T, Yunusbayev B, Reisberg T, Solnik A, Metspalu E, Hovhannisyan A, Khusnutdinova EK, Behar DM, Metspalu M, Yepiskoposyan L, Rootsi S, and Villems R
Subjects: Bayes Theorem, Evolution, Molecular, Genetics, Population, Humans, Phylogeny, Polymorphism, Single Nucleotide, Spatio-Temporal Analysis, Alleles, Chromosomes, Human, Y, Haplotypes
Abstract: Human Y chromosome haplogroup J1-M267 is a common male lineage in West Asia. One high-frequency region-encompassing the Arabian Peninsula, southern Mesopotamia, and the southern Levant-resides ~ 2000 km away from the other one found in the Caucasus. The region between them, although has a lower frequency, nevertheless demonstrates high genetic diversity. Studies associate this haplogroup with the spread of farming from the Fertile Crescent to Europe, the spread of mobile pastoralism in the desert regions of the Arabian Peninsula, the history of the Jews, and the spread of Islam. Here, we study past human male demography in West Asia with 172 high-coverage whole Y chromosome sequences and 889 genotyped samples of haplogroup J1-M267. We show that this haplogroup evolved ~ 20,000 years ago somewhere in northwestern Iran, the Caucasus, the Armenian Highland, and northern Mesopotamia. The major branch-J1a1a1-P58-evolved during the early Holocene ~ 9500 years ago somewhere in the Arabian Peninsula, the Levant, and southern Mesopotamia. Haplogroup J1-M267 expanded during the Chalcolithic, the Bronze Age, and the Iron Age. Most probably, the spread of Afro-Asiatic languages, the spread of mobile pastoralism in the arid zones, or both of these events together explain the distribution of haplogroup J1-M267 we see today in the southern regions of West Asia.
Published: 2021
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45. Insights into matrilineal genetic structure, differentiation and ancestry of Armenians based on complete mitogenome data.

Author: Derenko M, Denisova G, Malyarchuk B, Hovhannisyan A, Khachatryan Z, Hrechdakian P, Litvinov A, and Yepiskoposyan L
Subjects: Armenia, Asia, Central, Asia, Western, DNA, Mitochondrial chemistry, Europe, Genetic Variation, Haplotypes, Humans, Phylogeny, Phylogeography, Genome, Mitochondrial
Abstract: Distinctive peculiarities of Armenians such as their millennia-long genetic isolation and strong national identity attract a keen interest while studying the demographic history of the West Asia. Here, to examine their fine-scale matrilineal genetic structure, ancestry and relationships with neighboring populations, we analyzed 536 complete mitogenomes (141 of which are novel) from 8 geographically different Armenian populations, covering the whole stretch of historical Armenia. The observed patterns highlight a remarkable degree of matrilineal genetic heterogeneity and weak population structuring of Armenians. Moreover, our phylogeographic analysis reveals common ancestries for some mtDNA lineages shared by West Asians, Transcaucasians, Europeans, Central Asians and Armenians. About third of the mtDNA subhaplogroups found in Armenian gene pool might be considered as Armenian-specific, as these are virtually absent elsewhere in Europe, West Asia and Transcaucasia. Coalescence ages of most of these lineages do not exceed 3.1 kya and coincide well with the population size growth started around 1.8-2.8 kya detectable only in the Bayesian Skyline Plots based on the Armenian-specific mtDNA haplotypes.
Published: 2019
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46. The genetic history of admixture across inner Eurasia.

Author: Jeong C, Balanovsky O, Lukianova E, Kahbatkyzy N, Flegontov P, Zaporozhchenko V, Immel A, Wang CC, Ixan O, Khussainova E, Bekmanov B, Zaibert V, Lavryashina M, Pocheshkhova E, Yusupov Y, Agdzhoyan A, Koshel S, Bukin A, Nymadawa P, Turdikulova S, Dalimova D, Churnosov M, Skhalyakho R, Daragan D, Bogunov Y, Bogunova A, Shtrunov A, Dubova N, Zhabagin M, Yepiskoposyan L, Churakov V, Pislegin N, Damba L, Saroyants L, Dibirova K, Atramentova L, Utevska O, Idrisov E, Kamenshchikova E, Evseeva I, Metspalu M, Outram AK, Robbeets M, Djansugurova L, Balanovska E, Schiffels S, Haak W, Reich D, and Krause J
Subjects: Geography, Humans, Russia, Asian People, Gene Flow
Abstract: The indigenous populations of inner Eurasia-a huge geographic region covering the central Eurasian steppe and the northern Eurasian taiga and tundra-harbour tremendous diversity in their genes, cultures and languages. In this study, we report novel genome-wide data for 763 individuals from Armenia, Georgia, Kazakhstan, Moldova, Mongolia, Russia, Tajikistan, Ukraine and Uzbekistan. We furthermore report additional damage-reduced genome-wide data of two previously published individuals from the Eneolithic Botai culture in Kazakhstan (~5,400 BP). We find that present-day inner Eurasian populations are structured into three distinct admixture clines stretching between various western and eastern Eurasian ancestries, mirroring geography. The Botai and more recent ancient genomes from Siberia show a decrease in contributions from so-called 'ancient North Eurasian' ancestry over time, which is detectable only in the northern-most 'forest-tundra' cline. The intermediate 'steppe-forest' cline descends from the Late Bronze Age steppe ancestries, while the 'southern steppe' cline further to the south shows a strong West/South Asian influence. Ancient genomes suggest a northward spread of the southern steppe cline in Central Asia during the first millennium BC. Finally, the genetic structure of Caucasus populations highlights a role of the Caucasus Mountains as a barrier to gene flow and suggests a post-Neolithic gene flow into North Caucasus populations from the steppe.
Published: 2019
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47. Author Correction: 137 ancient human genomes from across the Eurasian steppes.

Author: de Barros Damgaard P, Marchi N, Rasmussen S, Peyrot M, Renaud G, Korneliussen T, Moreno-Mayar JV, Pedersen MW, Goldberg A, Usmanova E, Baimukhanov N, Loman V, Hedeager L, Pedersen AG, Nielsen K, Afanasiev G, Akmatov K, Aldashev A, Alpaslan A, Baimbetov G, Bazaliiskii VI, Beisenov A, Boldbaatar B, Boldgiv B, Dorzhu C, Ellingvag S, Erdenebaatar D, Dajani R, Dmitriev E, Evdokimov V, Frei KM, Gromov A, Goryachev A, Hakonarson H, Hegay T, Khachatryan Z, Khaskhanov R, Kitov E, Kolbina A, Kubatbek T, Kukushkin A, Kukushkin I, Lau N, Margaryan A, Merkyte I, Mertz IV, Mertz VK, Mijiddorj E, Moiyesev V, Mukhtarova G, Nurmukhanbetov B, Orozbekova Z, Panyushkina I, Pieta K, Smrčka V, Shevnina I, Logvin A, Sjogren KG, Štolcova T, Taravella AM, Tashbaeva K, Tkachev A, Tulegenov T, Voyakin D, Yepiskoposyan L, Undrakhbold S, Varfolomeev V, Weber A, Wilson Sayres MA, Kradin N, Allentoft ME, Orlando L, Nielsen R, Sikora M, Heyer E, Kristiansen K, and Willerslev E
Abstract: with In this Article, Angela M. Taravella and Melissa A. Wilson Sayres have been added to the author list (associated with: School of Life Sciences, Center for Evolution and Medicine, The Biodesign Institute, Arizona State University, Tempe, AZ, USA). The author list and Author Information section have been corrected online.
Published: 2018
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48. 137 ancient human genomes from across the Eurasian steppes.

Author: Damgaard PB, Marchi N, Rasmussen S, Peyrot M, Renaud G, Korneliussen T, Moreno-Mayar JV, Pedersen MW, Goldberg A, Usmanova E, Baimukhanov N, Loman V, Hedeager L, Pedersen AG, Nielsen K, Afanasiev G, Akmatov K, Aldashev A, Alpaslan A, Baimbetov G, Bazaliiskii VI, Beisenov A, Boldbaatar B, Boldgiv B, Dorzhu C, Ellingvag S, Erdenebaatar D, Dajani R, Dmitriev E, Evdokimov V, Frei KM, Gromov A, Goryachev A, Hakonarson H, Hegay T, Khachatryan Z, Khaskhanov R, Kitov E, Kolbina A, Kubatbek T, Kukushkin A, Kukushkin I, Lau N, Margaryan A, Merkyte I, Mertz IV, Mertz VK, Mijiddorj E, Moiyesev V, Mukhtarova G, Nurmukhanbetov B, Orozbekova Z, Panyushkina I, Pieta K, Smrčka V, Shevnina I, Logvin A, Sjögren KG, Štolcová T, Taravella AM, Tashbaeva K, Tkachev A, Tulegenov T, Voyakin D, Yepiskoposyan L, Undrakhbold S, Varfolomeev V, Weber A, Wilson Sayres MA, Kradin N, Allentoft ME, Orlando L, Nielsen R, Sikora M, Heyer E, Kristiansen K, and Willerslev E
Subjects: Asia ethnology, Europe ethnology, Farmers history, History, Ancient, Human Migration history, Humans, Asian People genetics, Genome, Human genetics, Grassland, Phylogeny, White People genetics
Abstract: For thousands of years the Eurasian steppes have been a centre of human migrations and cultural change. Here we sequence the genomes of 137 ancient humans (about 1× average coverage), covering a period of 4,000 years, to understand the population history of the Eurasian steppes after the Bronze Age migrations. We find that the genetics of the Scythian groups that dominated the Eurasian steppes throughout the Iron Age were highly structured, with diverse origins comprising Late Bronze Age herders, European farmers and southern Siberian hunter-gatherers. Later, Scythians admixed with the eastern steppe nomads who formed the Xiongnu confederations, and moved westward in about the second or third century BC, forming the Hun traditions in the fourth-fifth century AD, and carrying with them plague that was basal to the Justinian plague. These nomads were further admixed with East Asian groups during several short-term khanates in the Medieval period. These historical events transformed the Eurasian steppes from being inhabited by Indo-European speakers of largely West Eurasian ancestry to the mostly Turkic-speaking groups of the present day, who are primarily of East Asian ancestry.
Published: 2018
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49. Ancient pathogen DNA in human teeth and petrous bones.

Author: Margaryan A, Hansen HB, Rasmussen S, Sikora M, Moiseyev V, Khoklov A, Epimakhov A, Yepiskoposyan L, Kriiska A, Varul L, Saag L, Lynnerup N, Willerslev E, and Allentoft ME
Abstract: Recent ancient DNA (aDNA) studies of human pathogens have provided invaluable insights into their evolutionary history and prevalence in space and time. Most of these studies were based on DNA extracted from teeth or postcranial bones. In contrast, no pathogen DNA has been reported from the petrous bone which has become the most desired skeletal element in ancient DNA research due to its high endogenous DNA content. To compare the potential for pathogenic aDNA retrieval from teeth and petrous bones, we sampled these elements from five ancient skeletons, previously shown to be carrying Yersinia pestis . Based on shotgun sequencing data, four of these five plague victims showed clearly detectable levels of Y. pestis DNA in the teeth, whereas all the petrous bones failed to produce Y. pestis DNA above baseline levels. A broader comparative metagenomic analysis of teeth and petrous bones from 10 historical skeletons corroborated these results, showing a much higher microbial diversity in teeth than petrous bones, including pathogenic and oral microbial taxa. Our results imply that although petrous bones are highly valuable for ancient genomic analyses as an excellent source of endogenous DNA, the metagenomic potential of these dense skeletal elements is highly limited. This trade-off must be considered when designing the sampling strategy for an aDNA project.
Published: 2018
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50. The genetic variation in the R1a clade among the Ashkenazi Levites' Y chromosome.

Author: Behar DM, Saag L, Karmin M, Gover MG, Wexler JD, Sanchez LF, Greenspan E, Kushniarevich A, Davydenko O, Sahakyan H, Yepiskoposyan L, Boattini A, Sarno S, Pagani L, Carmi S, Tzur S, Metspalu E, Bormans C, Skorecki K, Metspalu M, Rootsi S, and Villems R
Subjects: Gene Frequency, Genetic Variation, Haplotypes, Humans, Male, Phylogeny, Chromosomes, Human, Y genetics, Evolution, Molecular, Jews genetics
Abstract: Approximately 300,000 men around the globe self-identify as Ashkenazi Levites, of whom two thirds were previously shown to descend from a single male. The paucity of whole Y-chromosome sequences precluded conclusive identification of this ancestor's age, geographic origin and migration patterns. Here, we report the variation of 486 Y-chromosomes within the Ashkenazi and non-Ashkenazi Levite R1a clade, other Ashkenazi Jewish paternal lineages, as well as non-Levite Jewish and non-Jewish R1a samples. Cumulatively, the emerging profile is of a Middle Eastern ancestor, self-affiliating as Levite, and carrying the highly resolved R1a-Y2619 lineage, which was likely a minor haplogroup among the Hebrews. A star-like phylogeny, coalescing similarly to other Ashkenazi paternal lineages, ~1,743 ybp, suggests it to be one of the Ashkenazi paternal founders; to have expanded as part of the overall Ashkenazi demographic expansion, without special relation to the Levite affiliation; and to have subsequently spread to non-Ashkenazi Levites.
Published: 2017
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