Mining synthetic hexaploids for multiple disease resistance to improve bread wheat

Authors

F C. Ogbonnaya, Department of Primary Industries, Victoria
M Imtiaz, Department of Primary Industries, Victoria
Harbans S. Bariana, University of Sydney, Australia
Mark S. McLean, Agriculture Victoria
Manisha Shankar, Department of Agriculture and Food, Western AustraliaFollow
Grant J. Hollaway, Agriculture Victoria
Richard M. Trethowan, University of Sydney, Australia
E S. Lagudah, Commonwealth Scientific and Industrial Research Organisation
M van Ginkel, Department of Primary Industries, Victoria

Document Type

Article

Publication Date

5-12-2008

Journal Title

Australian Journal of Agricultural Research

ISSN

Print: 1836-0947 Electronic: 1836-5795

Keywords

genetic diversity, synthetic hexaploid wheat, Aegilops tauschii, durum, Triticum aestivum

Disciplines

Agronomy and Crop Sciences | Biosecurity | Plant Breeding and Genetics

Abstract

A collection of 253 synthetic hexaploid wheats (SHWs) produced from 192 Aegilops tauschii accessions and 39 elite durum varieties were studied to identify, characterise, and evaluate potentially untapped diversity of disease resistance in wheat. The diseases for which resistance was sought included cereal cyst nematode (CCN), root lesion nematode (RLN), Stagonospora nodorum blotch (SNB), Septoria tritici blotch (STB), and the 3 rusts, leaf rust, stem rust, and stripe rust, all important diseases of bread wheat worldwide, which can severely reduce wheat yield and quality. The SHWs exhibited a wide spectrum of resistance to the 8 pathogens. The frequency of disease-resistant SHWs ranged from 1% for one species of RLN (Pratylenchus neglectus), 3% and 10% for Septoria nodorum leaf and glume blotch, 10% for seedling resistance to yellow leaf spot, 16% for CCN, 21% for the second species of RLN (Pratylenchus thornei), 73% for Septoria tritici blotch, and 15%, 40%, and 24% for leaf rust, stem rust, and stripe rust, respectively. Five SHWs, Aus26860, Aus30258, Aus30294, Aus30301, and Aus30304, exhibited high levels of resistance to CCN, YLP, STB, LR, and SR, while 56 SHWs showed resistance to either 3 or 4 diseases. The genetics of resistance to CCN in some of the SHWs revealed that some of the accessions carry the same CCN gene(s) against pathotype Ha13, while others may carry different resistance gene(s). Additional studies were carried out to understand the relationship between the resistances identified in SHWs and the ones already present in common wheat, in particular the resistance genes Cre1 and Cre3 against CCN. The use of perfect markers associated with Cre1 and Cre3 suggested that some SHWs may carry a new CCN resistance gene(s), which could be deployed in breeding programs to increase the diversity of available resistance. The identification of SHWs with resistance to a range of diseases provides an opportunity to generate genetic knowledge and resistant germplasm to be used in future variety development.

Recommended Citation

Ogbonnaya, F C, Imtiaz, M, Bariana, H S, McLean, M S, Shankar, M, Hollaway, G J, Trethowan, R M, Lagudah, E S, and van Ginkel, M. (2008), Mining synthetic hexaploids for multiple disease resistance to improve bread wheat. Australian Journal of Agricultural Research, 59 (5), 421-431.
https://library.dpird.wa.gov.au/bs_research/107