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DNA evidence for multiple introductions of barley into Europe following dispersed domestications in Western Asia

Published online by Cambridge University Press:  02 January 2015

G. Jones
Affiliation:
1Department of Archaeology, University of Sheffield, Northgate House, West Street, Sheffield S1 4ET, UK
M.P. Charles
Affiliation:
2Institute of Archaeology, University of Oxford, 36 Beaumont Street, Oxford OX1 2PG, UK
M.K. Jones
Affiliation:
3McDonald Institute for Archaeological Research, University of Cambridge, Downing Street, Cambridge CB2 3ER, UK
S. Colledge
Affiliation:
4Institute of Archaeology, University College London, 31–34 Gordon Square, London WC1H 0PY, UK
F.J. Leigh
Affiliation:
5National Institute of Agricultural Botany, Huntingdon Road, Cambridge CB3 0LE, UK
D.A. Lister
Affiliation:
3McDonald Institute for Archaeological Research, University of Cambridge, Downing Street, Cambridge CB2 3ER, UK
L.M.J. Smith
Affiliation:
5National Institute of Agricultural Botany, Huntingdon Road, Cambridge CB3 0LE, UK
W. Powell
Affiliation:
6Institute of Biological, Environmental and Rural Sciences, Aberystwyth University, Aberystwyth SY23 3DA, UK
T.A. Brown
Affiliation:
7Manchester Interdisciplinary Biocentre, Faculty of Life Sciences, University of Manchester, Manchester M1 7DN, UK
H. Jones
Affiliation:
5National Institute of Agricultural Botany, Huntingdon Road, Cambridge CB3 0LE, UK

Abstract

It has long been recognised that the Neolithic spread across Europe via two separate routes, one along the Mediterranean coasts, the other following the axis of the major rivers. But did these two streams have a common point of origin in south-west Asia, at least with regard to the principal plant and animals species that were involved? This study of barley DNA shows that the domesticated barley grown in Neolithic Europe falls into three separate types (groups A, B and C), each of which may have had a separate centre of origin in south-west Asia. Barley was relatively rarely cultivated by the early Linearbandkeramik farmers of Central and Northern Europe, but became more common during the fifth and fourth millennia BC. The analysis reported here indicates that a genetic variety of barley more suitable for northern growing conditions was introduced from south-west Asia at this period. It also suggests that the barley grown in south-eastern Europe at the very beginning of the Neolithic may have arrived there by different routes from two separate centres of domestication in south-west Asia. The multiple domestications that this pattern reveals imply that domestication may have been more a co-evolutionary process between plants and people than an intentional human action.

Type
Research
Copyright
Copyright © Antiquity Publications Ltd 2013

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References

Abbo, S., Lev-Yadun, S. & Gopher, A.. 2010. Agricultural origins: centres and non-centres: a Near Eastern reappraisal. Critical Reviews in Plant Sciences 29: 317328.Google Scholar
Allaby, R.G., Banerjee, M. & Brown, T.A.. 1999. Evolution of the high molecular weight glutenin loci of the A, B, D and G genomes of wheat. Genome 42: 296307.Google Scholar
Allaby, R.G, Fuller, D.Q., & Brown, T.A.. 2008. The genetic expectations of a protracted model for the origins of domesticated crops. Proceedings of the National Academy of Sciences of the USA 105: 1398213986.Google Scholar
Azhaguvel, P.T & Komatsuda, T.. 2007. A phylogenetic analysis based on nucleotide sequence of a marker linked to the brittle rachis locus indicates a diphyletic origin of barley. Annals of Botany 100: 100915.Google Scholar
BADR, A., Müller, K., Schäfer-Pregl, R., El Rabey, H., Effgen, S., Ibrahim, H.H., Pozzi, C., Rohde, W., & Salamini, F.. 2000. On the origin and domestication history of barley (Hordeum vulgare). Molecular Biology and Evolution 17: 499510.Google Scholar
Bakels, C. 2007. Cereal crops raised by Neolithic farmers on Dutch loess soils, in Colledge, S. & Conolly, J. (ed.) The origins and spread of domestic plants in southwest Asia and Europe: 343347. Walnut Creek (CA): Left Coast.Google Scholar
Bar-Yosef, O. 2011. Climatic fluctuations and early farming in West and East Asia. Current Anthropology 52 (S4): 175193.Google Scholar
Bettinger, R., Richerson, P. & Boyd, R.. 2009. Constraints on the development of agriculture. Current Anthropology 50: 627631.Google Scholar
Bogaard, A. 2004. Neolithic farmingin Central Europe: an archaeobotanical study of crop husbandry practices. Abingdon: Routledge.Google Scholar
Bogaard, A. 2011. Farming practice and society in the Central European Neolithic and Bronze Age: an archaeobotanical response to the secondary products revolution model, in Hadjikoumis, A., Robinson, E. & Viner, S. (ed.) Dynamics of Neolithisation in Europe: studies in honour of Andrew Sherratt: 266283. Oxford: Oxbow.Google Scholar
Bogaard, A., Charles, M., Livarda, A., Ergun, M., Filipovic, D. & Jones, G.. In press. The archaeobotany of mid-later Neolithic Çatalhöyük, in Hodder, I. (ed.) Humans and landscapes of Çatalhöyük: reports from the 2000 — 2008 seasons. Los Angeles: Cotsen Institute.Google Scholar
Bogucki, P. 1996. The spread of early farming in Europe. American Scientist 84: 242253.Google Scholar
Bogucki, P. 1999. The origins of human society. Oxford: Blackwell.Google Scholar
Brown, T.A., Lindsay, S. & Allaby, R.G.. 2006. Using modern landraces of wheat to study the origins of European agriculture, in Motley, T.J., Zerega, N. & Cross, H. (ed.) Darwin's harvest: new approaches to the origins, evolution, and conservation of crops: 197212. New York: Columbia University Press.Google Scholar
Cohen, M.N. 2009. Introduction: rethinking the origins of agriculture. Current Anthropology 50: 591595.Google Scholar
Colledge, S. 1998. The origins of agriculture and crop domestication, in Damania, A.B., Valkoun, J., Willcox, G. & Qualset, C.O. (ed.) The origins of agriculture and crop domestication: 121131. Aleppo: ICARDA.Google Scholar
Colledge, S. & Conolly, J.. 2007. A review and synthesis of the evidence for the origins of farming on Cyprus and Crete, in Colledge, S. & Conolly, J. (ed.) The origins andspreadofdomestic plants in southwest Asia and Europe:5374. Walnut Creek (CA): Left Coast.Google Scholar
Colledge, S., Conolly, J. & Shennan, S.. 2004. Archaeobotanical evidence for the spread of farming in the eastern Mediterranean. Current Anthropology 45: 3547.Google Scholar
Conolly, J., Colledge, S. & Shennan, S.. 2008. Founder effect, drift and adaptive change in domestic crop use in early Neolithic Europe. Journal of Archaeological Science 35: 27972804.Google Scholar
Cymbron, T., Freeman, A.R., Malheiro, M.I., Vigne, J.-D. & Bradley, D.G.. 2005. Microsatellite diversity suggests different histories for Mediterranean and Northern European cattle populations. Proceedings of the Royal Society of London B272: 18371843.Google Scholar
Fuller, D.Q., Willcox, G. & Allaby, R.G.. 2011. Cultivation and domestication had multiple origins: arguments against the core area hypothesis for the origins of agriculture in the Near East. World Archaeology 43: 628652.Google Scholar
Gignoux, C.R., Henn, B.M. & Mountain, J.L.. 2011. Rapid, global demographic expansions after the origins of agriculture. Proceedings of the National Academy of Sciences of the USA 108: 60446049.Google Scholar
Halstead, P. 1989. Like rising damp? An ecological approach to the spread of farming in south-east and Central Europe, in Milles, A., Williams, D. & Gardner, N. (ed.) The beginnings of agriculture (British Archaeological Reports international series 496): 2553. Oxford: British Archaeological Reports.Google Scholar
Hayden, B. 2009. The proof is in the pudding: feasting and the origins of domestication. Current Anthropology 50: 597601.Google Scholar
Heun, M., Schäfer-PREGL, R., Klawan, D., Castagna, R., Accerbi, M., Borghi, B. & Salamini, F.. 1997. Site of einkorn wheat domestication identified by DNA fingerprinting. Science 278: 13121314.Google Scholar
Jones, G., Jones, H., Charles, M.P., Jones, M.K., Colledge, S., Leigh, F.J., LIster, D.A., Smith, L.M.J., Powell, W., & Brown, T.A.. 2012. Phylogeographic analysis of barley DNA as evidence for the spread of Neolithic agriculture through Europe. Journal of Archaeological Science 39: 32303238.Google Scholar
Jones, H. 2008. The origins of diversity at the Ppd-H1 locus among European barley landraces. Unpublished PhD dissertation, University of Manchester.Google Scholar
Jones, H., Leigh, F.J., Mackay, I., Bower, M.A., Smith, L.M.J., Charles, M.P., Jones, G., Jones, M.K., BROWN, T.A. & Powell, W.. 2008. Population-based resequencing reveals that the flowering time adaptation of cultivated barley originated east of the Fertile Crescent. Molecular Biology and Evolution 25: 22112219.Google Scholar
Jones, H., Smith, L.M.J., Powell, W., Jones, M.K., Jones, G., Charles, M.P. & Brown, T.A.. 2011. Microsatellite analysis of European barley landraces reveals geographically structured variation: implications for the study of prehistoric agriculture. BMC Evolutionary Biology 11: 320.Google Scholar
Kilian, B., Özkan, K., Walther, A., Kohl, J., Dagan, T., Salamini, F. & Martin, W.. 2007. Molecular diversity at 18 loci in 321 wild and 92 domesticate lines reveals no reduction of nucleotide diversity during Triticum monococcum (einkorn) domestication: implications for the origins of agriculture. Molecular Biologyand Evolution 24: 26572668.Google Scholar
Kirleis, W., Klooss, S., Kroll, H. & Müller, J.. 2012. Crop growing and gathering in the northern German Neolithic: a review supplemented by new results. Vegetation History and Archaeobotany 21: 221242.Google Scholar
Kohl, P. 2007. The making of Bronze Age Eurasia. Cambridge: Cambridge university Press.Google Scholar
Kreuz, A. 2007. Archaeobotanical perspectives on the beginning of agriculture north of the Alps, in Colledge, S. & Conolly, J. (ed.) The origins and spread of domestic plants in southwest Asia and Europe: 259294. Walnut Creek (CA): Left Coast.Google Scholar
Larson, G., Albarella, U., Dobney, K., Rowley-Conwy, P., Schibler, J., Tresset, A., Vigne, J.-D., Edwards, C.J., Schlumbaum, A., Dinui, A.Bãlãçsescu, A., Dolman, G., Tagliacozzo, A., Manaseryan, N., Miracle, P., Van Wijngaarden-Bakker, L., Masseti, M., Bradley, D.G. & Cooper, A.. 2007. Ancient DNA, pig domestication and the spread of the Neolithic into Europe. Proceedings of the National Academy of Sciences of the USA 104: 1527615281.Google Scholar
Lev-Yadun, S., Gopher, A. & Abbo, S.. 2000. The cradle of agriculture. Science 288: 16021603.Google Scholar
Molina-Cano, J.L., Russell, J.R., Moralejo, M.A.Escacena, J.L., Arias, G. & Powell, W.. 2005. Chloroplast DNA microsatellite analysis supports a polyphyletic origin for barley. Theoretical and Applied Genetics 110: 613619.Google Scholar
Morrell, P.L. & Clegg, M.T.. 2007. Genetic evidence for a second domestication of barley (Hordeum vulgare) east of the Fertile Crescent. Proceedings of the National Academy of Sciences of the USA 104:32893294.Google Scholar
Öadogan, M. 2011. Archaeological evidence on the westward expansion of farming communities from eastern Anatolia to the Aegean and the Balkans. Current Anthropology 52: 415430.Google Scholar
Özkan, H., Brandolini, A., Schäfer-Pregl, R. & Salamini, F.. 2002. AFLP analysis of a collection of tetraploid wheats indicates the origin of emmer and hard wheat in southeast Turkey. Molecular Biology and Evolution 19: 17971801.Google Scholar
Perlès, C. 2005. From the Near East to Greece: let's reverse the focus: cultural elements that didn't transfer, in Lichter, C. (ed.) How did farming reach Europe? (BYZAS 2): 275290. Istanbul: German Archaeological Institute.Google Scholar
Perlès, C. 2010. Grece et Balkans: deux voies de pénétration distinctes en Europe? in Demoule, J.-P. (ed.) La révolution néolithique dans le monde: 263281. Paris: CNRS.Google Scholar
Rindos, D. 1984. The origins of agriculture: an evolutionary perspective. New York: Academic.Google Scholar
Sarpaki, A. 2009. Knossos, Crete: invaders, ‘sea goers’, or previously ‘invisible’, the Neolithic plant economy appears fully-fledged in 9000 BP, in Fairbairn, A. S. & Weiss, E. (ed.) From foragers to farmers: papers in honour of Gordon C. Hillman: 220234. Oxford: Oxbow.Google Scholar
Shennan, S.J. & Conolly, J.. 2007. The origin and spread of Neolithic plant economies in the Near East and Europe [data-set]. York: Archaeology Data Service [distributor]. doi:10.5284/1000093Google Scholar
Sherratt, A. 1976. Resources, technology and trade: an essay on early European metallurgy, in Longworth, I., Sieveking, G. & Wilson, K. (ed.) Problems in social and economic archaeology:557581. London: Duckworth.Google Scholar
Sherratt, A. 1981. Plough and pastoralism: aspects of the secondary products revolution, in Hodder, I., Isaac, G. & Hammond, N. (ed.) Pattern ofthe past: 261305. Cambridge: Cambridge University Press.Google Scholar
Tresset, A. & Vigne, J.-D.. 2011. Last hunter-gatherers and first farmers of Europe. Comptes Rendus Biologies 334: 182189.Google Scholar
Turner, A., Beales, J., Faure, S., Dunford, R. & Laurie, A.. 2005. The pseudo-response regulator Ppd-H1 provides adaptation to photoperiod in barley. Science 310: 10311034.Google Scholar
Valamoti, S. & Jones, G.. 2010. Bronze and oil: a possible link between the introduction of tin and Lallemantia to northern Greece. Annual of the British Schoolat Athens 105: 8396.Google Scholar
Van Zeist, W. & De Roller, G.J.. 1995. Plant remains from Aşikli Höyük, a Pre-Pottery Neolithic site in central Anatolia. Vegetation History and Archaeobotany 4: 179185.Google Scholar
Vigne, J.-D., Briois, F., Zazzo, A., Willcox, G., Cucchi, T., Thiébault, S., Carrère, I., Franel, Y., Touquet, R., Martin, C., Moreau, C., Comby, C. & Guilaine, J.. 2012. First wave of cultivators spread to Cyprus at least 10 600 y ago. Proceedings ofthe National Academy of Sciences of the USA 109: 84458449.Google Scholar
Willcox, G. 1998. Archaeobotanical evidence for the beginnings of agriculture in south-west Asia, in Damania, A.B., Valkoun, J., Willcox, G. & Qualset, C.O. (ed.) The origins ofagriculture and crop domestication:2538. Aleppo: ICARDA.Google Scholar
Willcox, G. 2005. The distribution, natural habitats and availability of wild cereals in relation to their domestication in the Near East: multiple events, multiple centres. Vegetation Historyand Archaeobotany 14: 534541.Google Scholar
Willcox, G. 2012. Pre-domestic cultivation during the late Pleistocene and early Holocene in the northern Levant, in Gepts, P., Famula, T.R., Bettinger, R.L., Brush, S.B., Damania, A.B., McGuire, P.E. & Qualset, C.O. (ed.) Biodiversityin agriculture: domestication, evolution and sustainability:92109. Cambridge: Cambridge university Press.Google Scholar
Willcox, G., Fornite, S. & Herveux, L.. 2008. Early Holocene cultivation before domestication in northern Syria. Vegetation Historyand Archaeobotany 17: 313325.Google Scholar
Zeder, M.A.. 2006. Central questions in the domestication of plants and animals. Evolutionary Anthropology 15: 105117.Google Scholar
Zeder, M.A.. 2011. The origins ofagriculture in the Near East. Current Anthropology 52 (S4): 221235.Google Scholar
Zohary, D. 1999. Monophyletic vs polyphyletic origin of the crops on which agriculture was founded in the Near East. Genetic Resources and Crop Evolution 46: 133142.Google Scholar
Zohary, D. & Hopf, M.. 2000. Domestication of plants in the Old World. Oxford: Oxford University Press.Google Scholar