Reconstructing migration trajectories using ancient DNA

doi:10.1017/9781316686942.011

10 - Reconstructing migration trajectories using ancient DNA

from IV - Complexity: Species Movements in the Holocene

Published online by Cambridge University Press: 04 May 2017

Edited by

Rémy Crassard and

Greger Larson: Affiliation:
University of Colorado
Nicole Boivin: Affiliation:
Max Planck Institute for the Science of Human History, Jena
Rémy Crassard: Affiliation:
Centre National de la Recherche Scientifique (CNRS), Lyon
Michael Petraglia: Affiliation:
Max Planck Institute for the Science of Human History, Jena

Book contents

Get access

Summary

Abstract

Revealing the temporal and geographic pattern of human and animal dispersal and migration has been a major goal within anthropology, archaeology, and palaeontology. Here, I focus on the use of ancient DNA to delve beneath the migration palimpsests. More specifically, I firstly describe the use of ancient DNA derived from archaeological pig remains as a proxy to understand the initial dispersal of farmers into Europe, the back migration into Anatolia, and the spread of people into the Pacific. I then show how ancient DNA from foxes in the northern and southern hemisphere has been used to understand their dispersal onto islands in the absence of landbridges. These case studies highlight the value of DNA derived from long-dead organisms to detail the pattern and process of ancient dispersals.

Keywords: Domestication, pigs, Arctic fox, long-distance dispersal, Lapita dispersal

INTRODUCTION

Tracing the timing and trajectories of human and animal migratory patterns has been a significant anthropological, archaeological, and palaeontological endeavour. In order to piece together the palimpsest of migrations, scientists have employed a range of proxies including not only genetic signatures and fossil and sub-fossils evidence, but also, in the case of people, linguistics and material culture (see Boivin, Introductory chapter). More recently, the ability to extract and sequence DNA from ancient organismal remains has allowed researchers to directly observe molecular patterns of variation in time and space, thus adding an important temporal perspective to migration-related questions.

Ancient DNA (aDNA) refers to the retrieval and amplification of DNA fragments from organisms that are no longer alive. Like the organism itself, the DNA contained within it begins degrading as soon as it dies. Inevitably, the DNA disappears completely, though the rate at which this occurs can be slow enough to allow for its retrieval and sequencing depending on the preservation conditions (Allentoft et al., 2012). Because each individual cell of any organism contains a full copy of that individual's entire genome, and several thousand copies of the individual's mitochondrial genome, aDNA has been retrieved not just from the obvious remains such as bones, teeth, and tissue, but also from less obvious sources such as hair, coprolites, and even frozen mud, where DNA remained despite the lack of any physical remains (Shapiro and Hofreiter, 2012).

Type: Chapter
Information: Human Dispersal and Species Movement
From Prehistory to the Present
, pp. 237 - 260

DOI: https://doi.org/10.1017/9781316686942.011 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2017

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Book purchase

Temporarily unavailable

References

Albarella, U., Dobney, K., and Rowley-Conwy, P. 2009. Size and shape of the Eurasian wild boar (Sus scrofa), with a view to the reconstruction of its Holocene history. Environmental Archaeology 14(2): 103–136.CrossRef Google Scholar

Albarella, U., Manconi, F., Rowley-Conwy, P., and Vigne, J.D. 2006a. Pigs of Sardinia and Corsica: a biometrical re-evaluation of their status and history. In Tecchiati, U. and Sala, B. (eds.) Archaeozoological Studies in Honour of Alfredo Riedel. Bolzano: Province of Balzano.

Albarella, U., Tagliacozzo, A., Dobney, K., and Rowley-Conwy, P. 2006b. Pig hunting and husbandry in prehistoric Italy: a contribution to the domestication debate. Proceedings of the Prehistoric Society 72: 193–227.Google Scholar

Allen, M.S., Matisoo-Smith, E., and Horsburgh, A. 2001. Pacific ‘Babes’: Issues in the origins and dispersal of Pacific pigs and the potential of mitochondrial DNA analysis. International Journal of Osteoarchaeology 11: 4–13.Google Scholar

Allentoft, M.E., et al. 2012. The half-life of DNA in bone: measuring decay kinetics in 158 dated fossils. Proceedings of the Royal Society B: Biological Sciences 279: 4724–4733.Google Scholar

Anderson, A.J. 2005. Crossing the Luzon Strait: Archaeological Chronology in the Batanes Islands, Philippines and the Regional Sequence of Neolithic Dispersal. Journal of Austronesian Studies 1: 27–48.Google Scholar

Angerbjörn, A., Hersteinsson, P., and Tannerfeldt, M. 2004a. Arctic Fox. In Sillero-Zubiri, C., Hoffman, M., and Macdonald, D.W. (eds.) Canids: Foxes, Wolves, Jackals and Dogs – Status Survey and Conservation Action Plan. Gland: IUCN.

Angerbjörn, A., Hersteinsson, P., and Tannerfeldt, M. 2004b. Consequences of resource predictability in the Arctic fox – two life history strategies. In Macdonald, D.W. and Sillero-Zubiri, C. (eds.) The Biology and Conservation of Wild Canids. Oxford: Oxford University Press.

Austin, J.J., et al. 2013. The origins of the enigmatic Falkland Islands wolf. Nature Communications 4: 1552.Google Scholar

Bellwood, P. 1998. The archaeology of Papuan and Austronesian prehistory in the Northern Moluccas, Eastern Indonesia. In Blench, R. and Spriggs, M. (eds.) Archaeology and Language II: Archaeological Data and Linguistic Hypotheses. London: Routledge.

Bellwood, P. and Diamond, J. 2005. On explicit ‘replacement’ in Island Southeast Asia: a reply to Stephen Oppenheimer. World Archaeology 37: 503–506.Google Scholar

Bellwood, P. and White, P. 2005. Domesticated pigs in eastern Indonesia. Science 309: 381–381.Google Scholar

Berta, A. 1987. Origin, diversification, and zoogeography of the South American Canidae Fieldiana. Zoology 39: 455–471.Google Scholar

Binladen, J., et al. 2006. Assessing the fidelity of ancient DNA sequences amplified from nuclear genes. Genetics 172(2): 733–741.Google Scholar

Blench, R.M. 2005. From the moutains to the valleys: understanding ethnoliguistic geography in Southeast Asia. In Blench, R.M., Sagart, L., and Sanchez-Mazas, A. (eds.) Perspectives on the Phylogeny of East Asian Languages. London: Curzon Press.

Brace, S., et al. 2012. Serial population extinctions in a small mammal indicate Late Pleistocene ecosystem instability. Proceedings of the National Academy of Sciences 109: 20532–20536.Google Scholar

Bryce, T. 2005. The kingdom of the Hittites. Oxford: Oxford University Press.

Carmichael, L.E., et al. 2007. Historical and ecological determinants of genetic structure in arctic canids. Molecular Ecology 16: 3466–3483.Google Scholar

Chessa, B., et al. 2009. Revealing the history of sheep domestication using retrovirus integrations. Science 324: 532–536.Google Scholar

Clutton-Brock, J. 1999. A Natural History of Domesticated Mammals. Cambridge: Cambridge University Press.

Cucchi, T., Hulme-Beaman, A., and Yuan, J. 2010. Early Neolithic pig domestication at Jiahu, Henan Province, China: clues from molar shape analyses using geometric morphometric approaches. Journal of Archaeological Science 38(1): 11–22.Google Scholar

Currat, M., Ruedi, M., Petit, R.J., and Excoffier, L. 2008. The hidden side of invasions: massive introgression by local genes. Evolution 62: 1908–1920.Google Scholar

Dalén, L., et al. 2005. Population history and genetic structure of a circumpolar species: the Arctic fox. Biological Journal of the Linnean Society 84: 79–89.Google Scholar

Darwin, C. 1839. Narrative of the surveying voyages of His Majesty's Ships Adventure and Beagle between the years 1826 and 1836, describing their examination of the southern shores of South America, and the Beagle's circumnavigation of the globe. London: Henry Colborn.

Diamond, J.M. 2000. Taiwan's gift to the world. Nature 403: 709–710.Google Scholar

Donohue, M. and Denham, T. 2010. Farming and language in Island Southeast Asia. Current Anthropology 51: 223–256.Google Scholar

Edwards, C.J., Bollongino, R., Scheu, A., Chamberlain, A., Tresset, A., Vigne, J.-D., Baird, J.F. et al. 2007. Mitochondrial DNA analysis shows a Near Eastern Neolithic origin for domestic cattle and no indication of domestication of European aurochs. Proceedings of the Royal Society B: Biological Sciences 274: 1377–1385.Google Scholar

Ervynck, A., Dobney, K., Hongo, H., and Meadow, R. 2001. Born free? New evidence for the status of Sus scrofa at Neolithic Çayönü Tepesi (Southeastern Anatolia, Turkey). Paléorient 27: 47–73.CrossRef Google Scholar

Fernandez, H., et al. 2006. Divergent mtDNA lineages of goats in an Early Neolithic site, far from the initial domestication areas. Proceedings of the National Academy of Sciences 103: 15375–15379.Google Scholar

Flannery, T.F. and White, J.P. 1991. Animal translocation. Research and Exploration 7: 96–113.Google Scholar

Geffen, E., et al. 2007. Sea ice occurrence predicts genetic isolation in the Arctic fox. Molecular Ecology 16: 4241–4255.Google Scholar

Giuffra, E., Andersson, L., and Nissen, P. 2000. Genetic diversity of eleven European pig breeds. Genetics Selection Evolution 32: 187–203.Google Scholar

Glover, I. 1986. Archaeology in Eastern Timor 1966–1967, Canberra: ANU.

Gongora, J., et al. 2008. Indo-European and Asian origins for Chilean and Pacific chickens revealed by mtDNA. Proceedings of the National Academy of Sciences 105: 10308–10313.Google Scholar

Green, R.C. 2000. Lapita and the cultural model for intrusion, integration and innovation. In Anderson, A. and Murray, T. (eds.) Australian Archaeologist – Collected Papers in Honour of Jim Allen. Canberra: Coombs Academic Publishing.

Grindon, A.J. and Davison, A. 2013. Irish Cepaea nemoralis land snails have a cryptic Franco-Iberian origin that is most easily explained by the movements of Mesolithic humans. PLoS ONE 8: e65792.Google Scholar

Grove, J.M. 2003. Little Ice Ages: Ancient and Modern, London: Routledge.

Hanotte, O., Bradley, D.G., Ochieng, J.W., Verjee, Y., Hill, E.W., and Rege, J.E.O. 2002. African pastoralism: genetic imprints of origins and migrations. Science 296: 336–339.Google Scholar

Heinsohn, T. 2003. Animal translocation: long-term human influences on the vertebrate zoogeography of Australasia (natural dispersal versus ethnophoresy). Zoologist 32: 351–376.Google Scholar

Hersteinsson, P. 2010. Íslenska tófan. Veididagbok 2010. Reykjavik: Environmental Agency of Iceland.

Hersteinsson, P., Angerbjörn, A., Frafjord, K., and Kaikusalo, A. 1989. The Arctic Fox in Fennoscandia and Iceland: management problems. Biological Conservation 49: 67–81.Google Scholar

Hersteinsson, P., Nyström, V., Jóhannsson, J.H., Guðjónsdóttir, B., and Hallsdóttir, M. 2007. Elstu Þekktu Leifar Melrakka á íslandi. Náttúrufræðingurinn 76: 13–21.Google Scholar

Higham, C.F.W. 1975. Aspects of economy and ritual in Prehistoric Northeast Thailand. Journal of Archaeological Science 2: 245–288.Google Scholar

Higham, C.F.W. 2002. Early Culture of Mainland Southeast Asia. Bangkok: River Books.

Hongo, H. and Meadow, R. 1998. Pig exploitation at Neolithic Cayonu Tepesi (Southeastern Anatolia). In Nelson, S.M. (ed.) Ancestors for the Pigs: Pigs in Prehistory. Penn press.

Hurles, M.E., Matisoo-Smith, E., Gray, R.D., and Penny, D. 2003. Untangling Oceanic settlement: the edge of the knowable. Trends in Ecology & Evolution 18: 531–540.Google Scholar

Jordana, J., Pares, P.M., and Sanchez, A. 1995. Analysis of genetic relationships in horse breeds. Journal of Equine Veterinary Science 15: 320–328.Google Scholar

Kirch, P.V. 2000. On the Road of the Winds: An Archaeological History of the Pacific Islands before European Contact. Berkeley: University of California Press.

Krause-Kyora, B., Makarewicz, C., Evin, A., Flink, L.G., Dobney, K., Larson, G., Hartz, S., et al. 2013. Use of domesticated pigs by Mesolithic hunter-gatherers in northwestern Europe. Nature Communications 4 (2348).Google Scholar

Larson, G. and Burger, J. 2013. A population genetics view of animal domestication. Trends in Genetics 29(4): 197–205.CrossRef Google Scholar

Larson, G., Albarella, U., Dobney, K., Rowley-Conwy, P., Schibler, J., Tresset, A., Vigne, J.-D., et al. 2007a. Ancient DNA, pig domestication, and the spread of the Neolithic into Europe. Proceedings of the National Academy of Sciences 104: 15276–15281.Google Scholar

Larson, G., Cucchi, T., Fujita, M., Matisoo-Smith, E., Robins, J., Anderson, A., Rolett, B., et al. 2007b. Phylogeny and ancient DNA of Sus provides insights into neolithic expansion in island southeast Asia and Oceania. Proceedings of the National Academy of Sciences 104: 4834–4839.Google Scholar

Larson, G., Dobney, K., Albarella, U., Fang, M., Matisoo-Smith, E., Robins, J., Lowden, S., et al. 2005. Worldwide phylogeography of wild boar reveals multiple centers of pig domestication. Science 307: 1618–1621.Google Scholar

Larson, G., Liu, R., Zhao, X., Yuan, J., Fuller, D., Barton, L., Dobney, K., et al. 2010. Patterns of East Asian pig domestication, migration, and turnover revealed by modern and ancient DNA. Proceedings of the National Academy of Sciences 107: 7686–7691.Google Scholar

Lee, T., Burch, J.B., Coote, T., Fontaine, B., Gargominy, O., Pearce-Kelly, P., and Foighil, D.Ó. 2007. Prehistoric inter-archipelago trading of Polynesian tree snails leaves a conservation legacy. Proceedings of the Royal Society B: Biological Sciences 274: 2907–2914.Google Scholar

Luetkemeier, E., Sodhi, M., Schook, L.B., and Malhi, R.S. 2010. Multiple Asian pig origins revealed through genomic analyses. Molecular Phylogenetics and Evolution 54: 680–686.Google Scholar

Mann, M.E. 2002. Little Ice Age. In Maccracken, M.C. and Perry, J.S. (eds.) Encyclopedia of Global Environmental Change. Chichester: Wiley.

Matisoo-Smith, E. and Robins, J.H. 2004. Origins and dispersals of Pacific peoples: Evidence from mtDNA phylogenies of the Pacific rat. Proceedings of the National Academy of Sciences 101: 9167–9172.Google Scholar

Mellows, A., Barnett, R., Dalén, L., Sandoval-Castellanos, E., Linderholm, A., McGovern, T.H., Church, M.J., and Larson, G. 2012. The impact of past climate change on genetic variation and population connectivity in the Icelandic Arctic fox. Proceedings of the Royal Society B: Biological Sciences 279 (1747): 4568–4573.CrossRef Google Scholar

Morwood, M.J., Morwood, , Soejono, R.P., Roberts, R.G., Sutikna, T., Turney, C.S.M., Westaway, K.E., Rink, W.J., et al. 2004. Archaeology and age of a new hominin from Flores in eastern Indonesia. Nature 431: 1087–1091.Google Scholar

Norén, K., Angerbjörn, A., and Hersteinsson, P. 2009a. Population structure in an isolated Arctic fox, Vulpes lagopus, population: the impact of geographical barriers. Biological Journal of the Linnean Society 97: 18–26.Google Scholar

Norén, K., Carmichael, L., Dalén, L., Hersteinsson, P., Samelius, G., Fuglei, E., and Kapel, C.M.O., et al. 2010. Arctic fox Vulpes lagopus population structure: circumpolar patterns and processes. Oikos 120: 873–885.Google Scholar

Norén, K., Carmichael, L., Fuglei, E., Eide, N.E., Hersteinsson, P., and Angerbjörn, A. 2011. Pulses of movement across the sea ice: population connectivity and temporal genetic structure in the Arctic fox. Oecologia 166: 973–984.Google Scholar

Norén, K., Dalén, L., Kvaløy, K., and Angerbjörn, A. 2005. Detection of farm fox and hybrid genotypes among wild Arctic foxes in Scandinavia. Conservation Genetics 6: 885–894.Google Scholar

Norén, K., Kvaløy, K., Nyström, V., Landa, A., Dalén, L., Eide, N.E., Østbye, E., et al. 2009b. Farmed Arctic foxes on the Fennoscandian mountain tundra: implications for conservation. Animal Conservation 12: 434–444.Google Scholar

Ogilvie, A.E.J. 1991. Climatic changes in Iceland AD c. 865 to 1598, in the Norse of the North Atlantic. Acta Archaeology 61: 233–251.Google Scholar

Oppenheimer, S. 2004. The ‘Express Train from Taiwan to Polynesia’: on the congruence of proxy lines of evidence. World Archaeology 36: 591–600.Google Scholar

Ottoni, C., Flink, L.G., Evin, A., Geörg, C., De Cupere, B., Van Neer, W., Bartosiewicz, L., et al. 2013. Pig domestication and human-mediated dispersal in western Eurasia revealed through ancient DNA and geometric morphometrics. Molecular Biology and Evolution 30: 824–832.Google Scholar

Pamperin, N.J., Follmann, E.H., and Person, B.T. 2008. Sea ice use by Arctic foxes in northern Alaska. Polar Biology 31: 1421–1426.Google Scholar

Pawley, A. 2003. The Austronesian dispersal: languages, technologies and people. In Renfrew, C. and Bellwood, P. (eds.) Examining the Farming/Language Dispersal Hypothesis. Cambridge: McDonald Institute for Archaeological Research.

Pierpaoli, M., Birò, Z.S., Herrmann, M., Hupe, K., Fernandes, M., Ragni, B., Szemethy, L., and Randi, E. 2003. Genetic distinction of wildcat (Felis silvestris) populations in Europe, and hybridization with domestic cats in Hungary. Molecular Ecology 12: 2585–2598.Google Scholar

Piper, P.J., Hung, H., Campos, F.Z., Bellwood, P., and Santiago, R. 2009. A 4000 year-old introduction of domestic pigs into the Philippine Archipelago: implications for understanding routes of human migration through Island Southeast Asia and Wallacea. Antiquity 83: 687–695.Google Scholar

Ramírez, O., Ojeda, A., Tomàs, A., Gallardo, D., Huang, L.S., Folch, J.M., Clop, A., et al. 2009. Integrating Y-chromosome, mitochondrial, and autosomal data to analyze the origin of pig breeds. Molecular Biology and Evolution 26: 2061.Google Scholar

Seeher, J. 2011. The plateau: the Hittites. In Steadman, S.R. and Mcmahon, J.G. (eds.) The Oxford Handbook of Ancient Anatolia: 10,000–323 BCE. New York: Oxford University Press.

Shapiro, B. and Hofreiter, M. (eds.) 2012. Ancient DNA: Methods and Protocols. New York: Springer.

Slater, G.J., Thalmann, O., Leonard, J.A., Schweizer, R.M., Koepfli, K.-P., Pollinger, J.P., Rawlence, N.J., et al. 2009. Evolutionary history of the Falklands wolf. Current Biology 19: R937–R938.Google Scholar

Spriggs, M.J.T. 1997. The Island Melanesians, Cambridge: Blackwell.

Tannerfeldt, M. and Angerbjörn, A. 1996. Life history strategies in a fluctuating environment: establishment and reproductive success in the Arctic fox. Ecography 19: 209–220.Google Scholar

Tarroux, A., Berteaux, D., and Bêty, J. 2010. Northern nomads: ability for extensive movements in adult Arctic foxes. Polar Biology 33: 1021–1026.Google Scholar

Terrell, J.E., Kelly, K.M., and Rainbird, P. 2001. Foregone conclusions? In search of ‘Papuans’ and ‘Austronesians’. Current Anthropology 42: 97–124.Google Scholar

Van Driem, G. 1998. Neolithic correlates of ancient Tibeto-Burman migrations. In Blench, R. and Spriggs, M. (eds.) Archaeology and Language II: Archaeological Data and Linguistic Hypotheses. London: Routledge.

Verkaar, E.L.C., Nijman, I.J., Beeke, M., Hanekamp, E., and Lenstra, J.A. 2004. Maternal and paternal lineages in cross-breeding bovine species. Has wisent a hybrid origin? Molecular Biology and Evolution 21: 1165–1170.Google Scholar

Vinnikov, K.Y., Robock, A., Stouffer, R.J., Walsh, J.E., Parkinson, C.L., Cavalieri, D.J., Mitchell, J.F.B., et al. 1999. Global warming and northern hemisphere sea ice extent. Science 286: 1934–1937.Google Scholar

Wilmshurst, J.M., Hunt, T.L., Lipo, C.P., and Anderson, A.J. 2011. High-precision radiocarbon dating shows recent and rapid initial human colonization of East Polynesia. Proceedings of the National Academy of Sciences 108: 1815–1820.Google Scholar

Wollstein, A., Lao, O., Becker, C., Brauer, S., Trent, R.J., Nürnberg, P., Stoneking, M., and Kayser, M. 2010. Demographic history of Oceania inferred from genome-wide data. Current Biology 20: 1983–1992.Google Scholar

Wu, C.Y., Jiang, Y.N., Chu, H.P., Li, S.H., Wang, Y., Li, Y.H., Chang, Y., and Ju, Y.T. 2007. The type I Lanyu pig has a maternal genetic lineage distinct from Asian and European pigs. Animal Genetics. 38: 499–505.Google Scholar