Author
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ZHANG, PENG - University Of Sydney |
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DUNDAS, IAN - University Of Adelaide |
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MCINTOSH, ROBERT - University Of Sydney |
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Xu, Steven |
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PARK, ROBERT - University Of Sydney |
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GILL, BIKRAM - Kansas State University |
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FRIEBE, BERND - Kansas State University |
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Submitted to: Book Chapter
Publication Type: Book / Chapter Publication Acceptance Date: 6/22/2015 Publication Date: 12/1/2015 Citation: Zhang, P., Dundas, I.S., Mcintosh, R.A., Xu, S.S., Park, R.F., Gill, B.S., Friebe, B. 2015. Chapter 9, Wheat-Aegilops introgressions. In: Ceoloni, C., Dolezel, J., Molnar-Lang, M., editors. Alien Introgression in Wheat. Switzerland: Springer International Publishing. p. 221-243. Interpretive Summary: Technical Abstract: Aegilops is the most closely related genus to Triticum in the tribe Triticeae. Aegilops speltoides Tausch (B genome donor) and Ae. tauschii Coss. (D genome donor) contributed two of the three genomes present in common wheat (Triticum aestivum L., 2n = 6x = 42, AABBDD genomes). The Aegilops genus consists of 10 diploid and 12 polyploid species, all can be crossed readily with common wheat and represent a large reservoir of agronomically useful genes that can be exploited in wheat improvement. Since the 1950s, many unique genes for disease and pest resistance have been transferred into wheat from various Aegilops species. In this chapter we will review all formally named genes transferred from Aegilops species into wheat except those transferred from Ae. tauschii, which belongs to the primary gene pool of wheat and is covered in a separate chapter. This review provides useful information to wheat breeders on the available resistant germplasm for breeding programs. It will also provide guidance to cytogeneticists to further utilize chromosome engineering to directly develop agronomically superior germplasm with good disease and pest resistance. |
