Wild barley: a source of genes for crop improvement in the 21st century?

doi:10.1093/jexbot/51.342.9

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Journal of Experimental Botany, Vol. 51, No. 342, pp. 9-17, January 2000
© 2000 Oxford University Press

Wild barley: a source of genes for crop improvement in the 21st century?

R.P. Ellis¹, B.P. Forster, D. Robinson, L.L. Handley, D.C. Gordon, J.R. Russell and W. Powell

Scottish Crop Research Institute, Invergowrie, Dundee DD2 5DA, UK

The development of new barleys tolerant of abiotic and bioticstresses is an essential part of the continued improvement ofthe crop. The domestication of barley, as in many crops, resultedin a marked truncation of the genetical variation present inwild populations. This process is significant to agronomistsand scientists because a lack of allelic variation will preventthe development of adapted cultivars and hinder the investigationof the genetic mechanisms underlying performance. Wild barleywould be a useful source of new genetic variation for abioticstress tolerance if surveys identify appropriate genetic variationand the development of marker-assisted selection allows efficientmanipulation in cultivar development. There are many wild barleycollections from all areas of its natural distribution, butthe largest are derived from the Mediterranean region. The resultsof a range of assays designed to explore abiotic stress tolerancein barley are reported in this paper. The assays included; sodiumchloride uptake in wild barley and a mapping population, effectsfor ${delta}$ ¹³C and plant dry weight in wheat aneuploids, effects ofphotoperiod and vernalization in wild barley, and measurementsof root length in wild barley given drought and nitrogen starvationtreatments in hydroponic culture. There are examples of theuse of wild barley in breeding programmes, for example, as asource of new disease resistance genes, but the further explorationof the differences between wild barley and cultivars is hamperedby the lack of good genetic maps. In parallel to the need forgenetic studies there is also a need for the development ofgood physiological models of crop responses to the environment.Given these tools, wild barley offers the prospect of a ‘goldmine’of untapped genetic reserves.

Key words: Abiotic stress, genetic diversity, germplasm collections, SSR, barley

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