Two Major Resistance Quantitative Trait Loci are Required to Counteract the Increased Susceptibility to Fusarium Head Blight of the Rht-D1b Dwarfing Gene in Wheat

文献类型: 外文期刊

第一作者: Lu, Qiongxian

作者: Lu, Qiongxian;Bjornstad, Asmund;Lillemo, Morten;Semagn, Kassa;Skinnes, Helge;Szabo-Hever, Agnes;Mesterhazy, Akos;Lu, Qiongxian;Ji, Fang;Shi, Jianrong

作者机构:

关键词: major resistance quantitative trait loci;QTL 5A;QTL 2BL;QTL Fhb1;phenotypic variation;segregating population

期刊名称:CROP SCIENCE ( 影响因子:2.319; 五年影响因子:2.631 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Fusarium head blight (FHB) is a destructive wheat (Triticum aestivum L.) disease of global importance. The widely used dwarfing allele Rht-D1b has recently been shown to compromise FHB resistance. The objectives of this study were to investigate the impact of this dwarfing allele in a segregating population with major resistance quantitative trait loci (QTL) derived from 'Sumai-3' and Nobeokabozu, and to determine how many resistance QTL are needed to counteract its negative effect. Fusarium head blight resistance was evaluated in four field trials with spray inoculation and two field trials with point inoculation in a double-haploid (DH) population from a cross between the Swedish cv. Avle (susceptible spring type; wild-type allele Rht-D1a) and Line 685 (resistant winter type; semi-dwarf allele Rht-D1b). The Rht-D1 locus explained up to 38% of the phenotypic variation and was the most important QTL for FHB severity under spray inoculation but did not show any effect after point inoculation. Fhb1 on 3BS was detected with both inoculation methods but was relatively more important after point inoculation. Another two QTL on 5A and 2BL were detected after spray inoculation and a QTL on 2D after point inoculation. Comparison of phenotypic effects of different allele combinations revealed that a combination of both Fhb1 and the 5A QTL was required to counteract the increased susceptibility of Rht-D1b. Although breeding of FHB resistant cultivars with this dwarfing allele is possible, it requires the pyramiding of several resistant QTL to achieve adequate levels of resistance.

分类号: S5

  • 相关文献

[1]QTL mapping for fiber quality traits across multiple generations and environments in upland cotton. Fu-Ding Sun,Jian-Hong Zhang,Shu-Fang Wang,Wan-Kui Gong,Yu-Zhen Shi,Ai-Ying Liu,Jun-Wen Li,Ju-Wu Gong,Hai-Hong Shang,You-Lu Yuan.

[2]Molecular mapping of quantitative trait loci for kernel morphology traits in a non-1BL.1RS x 1BL.1RS wheat cross. Yonggui Xiao,Shengmei He,Jun Yan,Yong Zhang,Yelun Zhang,Yunpeng Wu,Xianchun Xia,Jichun Tian,Wanquan Ji,Zhonghu He.

[3]Phenotypic Variation and Genetic Diversity in the Collections of Erianthus Arundinaceus (Retz.) Jesw. Li, Yang-Rui,Liu, Xi-Hui,Song, Huan-Zhong,Zhang, Ge-Min,Duan, Wei-Xing,Zhang, Rong-Hua,Li, Yang-Rui. 2017

[4]Mapping quantitative trait loci for sheath blight resistance in rice using double haploid population. Xu, Qun,Yuan, XiaoPing,Yu, HanYong,Wang, YiPing,Tang, ShengXiang,Wei, XingHua.

[5]Genetic analysis for main length ratio associated with morphological traits in Japanese flounder Paralichthys olivaceus. Liu, Y. X.,Yang, R. Q.,Sun, Z. H.,Wang, Y. F..

[6]Unconditional and Conditional Quantitative Trait Loci Mapping for Plant Height in Nonheading Chinese Cabbage. Yi, Ying,Hou, Xilin,Geng, Jianfeng,Zhang, Xiao Wei,Yi, Ying,Hou, Xilin.

[7]Genetic effects of introgression genomic components from Sea Island cotton (Gossypium barbadense L.) on fiber related traits in upland cotton (G. hirsutum L.). Wang, Furong,Gong, Yongchao,Zhang, Chuanyun,Liu, Guodong,Wang, Liuming,Xu, Zhenzhen,Zhang, Jun.

[8]Phenotypic variation analysis and QTL mapping for cotton (Gossypium hirsutum L.) fiber quality grown in different cotton-producing regions. Wang, Furong,Qiao, Qinghua,Yuan, Zhecheng,Fan, Shoujin,Wang, Furong,Zhang, Chuanyun,Liu, Guodong,Chen, Yu,Zhang, Jingxia,Zhang, Jun.

[9]A core collection and mini core collection of Oryza sativa L. in China. Zhang, Hongliang,Zhang, Dongling,Wang, Meixing,Sun, Junli,Qi, Yongwen,Li, Jinjie,Li, Zichao,Wei, Xinghua,Tang, Shengxiang,Han, Longzhi,Qiu, Zongen.

[10]Compare of Phenotypic Variation with the Polymorphism of One Coagulation Related Gene Locus in Buffalo Kappa-Casein. Lin, Bo,Yang, Bingzhuang,Li, Ling,Yan, Tang,Long, Haoru,Ren, Daxi,Zeng, Qingkun. 2013

[11]Research progress in allele-specific expression and its regulatory mechanisms. Gaur, Uma,Mei, Shuqi,Liu, Guisheng,Gaur, Uma,Mei, Shuqi,Liu, Guisheng,Li, Kui.

[12]The Analysis of Physiological Variations in M-2 Generation of Solanum melongena L. Mutagenized by Ethyl Methane Sulfonate. Xiao Xi-ou,Lin Wenqiu,Li Wei,Gao Xiaoming,Lv Lingling,Ma Feiyue,Liu Yuge,Xiao Xi-ou,Lin Wenqiu,Li Wei,Gao Xiaoming,Lv Lingling,Ma Feiyue,Liu Yuge. 2017

[13]Mapping quantitative trait loci for quality factors in an inter-class cross of US and Chinese wheat. Bai, Guihua,Sun, Xiaochun,Marza, Felix,Carver, Brett F.,Ma, Hongxiang.

[14]Saturation and mapping of a major Fusarium head blight resistance QTL on chromosome 3BS of Sumai 3 wheat. Zhou, M-P.,Lu, W-Z.,Ma, H-X.,Hayden, M. J.,Zhang, Z-Y..

[15]Development of sequence-specific PCR markers associated with a polygenic controlled trait for marker-assisted selection using a modified selective genotyping strategy: a case study on anthracnose disease resistance in white lupin (Lupinus albus L.). Yang, Huaan,Renshaw, Daniel,Li, Chengdao,Adhikari, Kedar,Thomas, Geoff,Buirchell, Bevan,Sweetingham, Mark,Lin, Ruiming,Yan, Guijun.

[16]Comparative LD mapping using single SNPs and haplotypes identifies QTL for plant height and biomass as secondary traits of drought tolerance in maize. Lu, Yanli,Xu, Jie,Yuan, Zhimin,Lan, Hai,Rong, Tingzhao,Lu, Yanli,Xu, Yunbi,Xu, Yunbi,Shah, Trushar.

[17]Genetic Relationships Among Panicle Characteristics of Rice (Oryza sativa L.) Using Unconditional and Conditional QTL Analyses. Ye, Zihong,Liu, Qian,Zhang, Minzhou,Zou, Keqin,Fu, Xianshu,Wang, Junmin.

作者其他论文 更多>>

微信小程序