Characterization and Molecular Mapping of a Stripe Rust Resistance Gene in Synthetic Wheat CI110

文献类型: 外文期刊

第一作者: Liu Hui-juan

作者: Liu Hui-juan;Zhang Zeng-yan;Xin Zhi-yong;Feng Jing;Xu Shi-chang;Pu Zong-jun

作者机构:

关键词: synthetic wheat;Puccinia striiformis f. sp tritici;resistance gene;simple sequence repeat (SSR) marker;gene postulation

期刊名称:JOURNAL OF INTEGRATIVE AGRICULTURE ( 影响因子:2.848; 五年影响因子:2.979 )

ISSN: 2095-3119

年卷期: 2012 年 11 卷 4 期

页码:

收录情况: SCI

摘要: Stripe rust, caused by Puccinia striiformis f. sp. tritici (Psi), is one of the most destructive diseases of wheat (Triticum aestivum L.). To diversify stripe rust-resistant resources for wheat breeding programs, a CIMMYT synthetic wheat line CI110 was identified to be resistant to 28 isolates of Pst, including 6 Chinese prevalent races CYR28-CYR33. Genetic analysis indicated that a single dominant gene was responsible for the stripe rust resistance in CI110, temporarily designated YrC110. A molecular map, harboring YrC110 and 9 linked SSR markers, was constructed through simple sequence repeat (SSR), and bulked segregant analysis. These linked markers and YrC110 were assigned on the short arm of chromosome 1B using the Chinese Spring nullisomic-tetrasomic and ditelosomic stocks. Gene postulation based on seedling reaction patterns to 30 Pst isolates suggested that the resistance gene YrC110 seemed different from the other known resistance genes tested, such as Yr9, Yr10, Yr15, Yr24, and Yr26/YrCH42. Four SSR markers Xbarc187(150), Xgwm18(227), Xgwm11(223), and Xbarc240(292) distinguished YrC110 from Yr10, Yr15, Yr24, and Yr26/YrCH42, and could be used as diagnostic ones for YrC110 in wheat resistant breeding programs against stripe rust.

分类号:

  • 相关文献

[1]Postulation of Stripe Rust Resistance Genes in 44 Chinese Wheat Cultivars. Lin Ruiming,Xu Shichang,Xu Xiaodan,Lin Feng,Hussain, Khalid. 2011

[2]Assessment of genetic diversity by simple sequence repeat markers among forty elite varieties in the germplasm for malting barley breeding. Wang, Jun-mei,Yang, Jian-ming,Zhu, Jing-huan,Jia, Qiao-jun,Tao, Yue-zhi. 2010

[3]Development of SSR markers and assessment of genetic diversity of adzuki bean in the Chinese germplasm collection. Chen, Honglin,Wang, Lixia,Wang, Suhua,Cheng, Xuzhen,Liu, Liping,Wang, Ming Li.

[4]Molecular mapping of a recessive stripe rust resistance gene yrMY37 in Chinese wheat cultivar Mianmai 37. Ren, Yong,Xia, Xianchun,He, Zhonghu,Ren, Yong,Li, Shengrong,Zhou, Qiang,He, Yuanjiang,Wei, Yuming,Zheng, Youliang,He, Zhonghu.

[5]Identification, Gene Postulation and Molecular Tagging of a Stripe Rust Resistance Gene in Synthetic Wheat CI142. Wang, L. M.,Zhang, Z. Y.,Liu, H. J.,He, M. Z.,Liu, H. X.,Xin, Z. Y.,Xu, S. C.,Veisz, O..

[6]Characterization of Phytophthora resistance in soybean cultivars/lines bred in Henan province. Zhang, Jiqing,Sun, Suli,Duan, Canxing,Wang, Xiaoming,Wu, Xiaofei,Zhu, Zhendong,Wang, Guiqing.

[7]Identification of Seedling Resistance Genes to Stripe Rust and Analysis of Adult Plant Resistance in 82 Wheat Cultivars from Gansu Province in China. Huang Jin,Sun Zhenyu,Zhang Bo,Jia Qiuzhen,Jin Shelin,Wang Xiaoming,Cao Shiqin,Huang Jin,Sun Zhenyu,Zhang Bo,Jia Qiuzhen,Feng Jing,Xu Shichang,Li Mingju,Shang Xunwu. 2017

[8]Postulation of Seedlings Resistance Genes to Yellow Rust in Commercial Wheat Cultivars from Yunnan Province in China. Li Ming-ju,Feng Jing,Un Rui-ming,Chen Wan-quan,Xu Shi-chang,Li Ming-ju,Cao Shi-qin,Cheng Geng,Yu Ya-xiong. 2011

[9]Puroindoline grain hardness alleles in CIMMYT bread wheat germplasm. Lillemo, Morten,Chen, Feng,Xia, nchun Xia,William, Manilal,Pena, Roberto J.,Trethowan, Richard,He, Zhonghu. 2006

[10]Discovery of quantitative trait loci for crossability from a synthetic wheat genotype. Zhang, Li,Wang, Jin,Zhou, Ronghua,Jia, Jizeng,Zhang, Li,Zhang, Li. 2011

[11]Making the Bread: Insights from Newly Synthesized Allohexaploid Wheat. Li, Ai-Li,Geng, Shuai-Feng,Mao, Long,Zhang, Lian-Quan,Liu, Deng-Cai. 2015

[12]Postulation of Seedling Resistance Genes in 20 Wheat Cultivars to Yellow Rust (Puccinia striiformis f. sp tritici). Feng Jing,Zhang Zhen-yu,Lin Rui-ming,Xu Shi-chang. 2009

[13]The abundance of homoeologue transcripts is disrupted by hybridization and is partially restored by genome doubling in synthetic hexaploid wheat. Hao, Ming,Li, Aili,Luo, Jiangtao,Zhang, Lianquan,Ning, Shunzong,Yuan, Zhongwei,Zeng, Deying,Kong, Xingchen,Li, Xiaolong,Lan, Xiujin,Zheng, Youliang,Liu, Dengcai,Li, Aili,Mao, Long,Shi, Tongwei,Zhang, Xuechuan,Zheng, Hongkun,Zhang, Huaigang,Liu, Dengcai. 2017

[14]Novel and favorable QTL allele clusters for end-use quality revealed by introgression lines derived from synthetic wheat. Li, Yulian,Zhou, Ronghua,Wang, Jin,Liao, Xiangzheng,Jia, Jizeng,Branlard, Gerard,Li, Yulian. 2012

[15]Postulation of seedling leaf rust resistance genes in 84 Chinese winter wheat cultivars. Ren Xiao-li,Liu Tai-guo,Liu Bo,Gao Li,Chen Wan-quan. 2015

[16]Suppression of stripe rust and leaf rust resistances in interspecific crosses of wheat. Liu, Taiguo,Gao, Li.

[17]Quality potential of synthetic-derived commercial wheat cultivars in south-western China. Li, C. S.,Yang, W. Y.,Wu, X. L.,Ma, X. L.,Li, S. Z.,Wu, Y. Q.,Rosewarne, G. M.,Rosewarne, G. M..

[18]Molecular mapping of stripe rust resistance gene YrHu derived from Psathyrostachys huashanica. Yin, J. L.,Chao, K. X.,Jing, J. X.,Li, Q.,Wang, B. T.,Ma, D. F.,Fang, Z. W.,Ma, D. F..

[19]Direct DNA extraction method of an obligate parasitic fungus from infected plant tissue. Liu, L.,Wang, C. L.,Peng, W. Y.,Yang, J.,Lan, M. Q.,Zhang, B.,Zhu, Y. Y.,Li, C. Y.,Li, J. B.. 2015

[20]A new stripe rust resistance gene transferred from Thinopyrum intermedium to hexaploid wheat (Triticum aestivum). Luo, Pei-Gao,Hu, Xue-Yun,Zhang, Min,Zhang, Huai-Qiong,Ren, Zheng-Long,Chang, Zhi-Jian. 2009

作者其他论文 更多>>

微信小程序