机构地区:[1]College of Plant Science&Technology,Huazhong Agricultural University,Wuhan 430070,Hubei,China [2]International Maize and Wheat Improvement Center(CIMMYT),Apdo.Postal 6-641,06600 Mexico D.F.,Mexico [3]Qinghai Provincial Key Laboratory of Crop Molecular Breeding,Northwest Institute of Plateau Biology,Chinese Academy of Science,Xining 810008,Qinghai,China [4]Campo Experimental Valle de México INIFAP,Apdo.Postal 10,56230,Chapingo,Edo.de Mexico,Mexico [5]CSIRO Agriculture&Food,GPO Box 1600,Canberra,ACT 2601,Australia
出 处:《The Crop Journal》2022年第2期490-497,共8页作物学报(英文版)
基 金:supported by the International Cooperation and Exchange of the National Natural Science Foundation of China(31861143010);Huazhong Agricultural University Scientific&Technological Self-innovation Foundation;Australian Grains Research and Development Corporation(GRDC)with funding to the Australian Cereal Rust Control Program(ACRCP);CGIAR Research Program WHEAT(CRP-WHEAT);the Open Project of Qinghai Provincial Key Laboratory of Crop Molecular Breeding(2021-ZJ-Y05);the Strategic Priority Research Program of the Chinese Academy of Sciences(XDA24030102)。
摘 要:Leaf rust(LR) and stripe rust(YR) are important diseases in wheat producing areas worldwide and cause severe yield losses under favorable environmental conditions when susceptible varieties are grown. We determined the genetic basis of resistance to LR and YR in variety Borlaug 100 by developing and phenotyping a population of 198 F6 recombinant inbred lines derived from a cross with the susceptible parent Apav#1. LR and YR phenotyping were conducted for 4 and 3 seasons, respectively, at CIMMYT research stations in Mexico under artificial epidemics. Mendelian segregation analyses indicated that 3–5 LR and 2 YR genes conferred resistance in Borlaug 100. Lr46/Yr29(1 BL), Yr17(2 AS) and Yr30(3 BS) were present in the resistant parent and segregated in the RIL population based on characterization by molecular markers linked to these genes. When present alone, Lr46/Yr29 caused average 13% and 16% reductions in LR and YR severities, respectively, in RILs. Similarly, Yr17 and Yr30 reduced YR severities by 57% and 11%, respectively. The Yr30 and the Yr17 translocation were also associated with 27% and 14% reductions, respectively, in LR severity, indicating that the 3 BS and 2 AS chromosomal regions likely carry new slow rusting LR resistance genes, temporarily designated as Lr B1 and Lr B2, respectively. Additive effects of Yr30*Yr17, Yr29*Yr17 and Yr29*Yr30 on YR and LR were significant and reduced YR severities by 56%,55%, and 45%, respectively, and LR severities by 34%, 40%, and 45%, respectively. Furthermore, interaction between the three genes was also significant, with mean reductions of 70% for YR and 54% for LR severities. Borlaug 100, or any one of the 21 lines with variable agronomic traits but carrying all three colocated resistance loci, can be used as resistance sources in wheat breeding programs.
关 键 词:Co-located resistance loci Common wheat Gene interaction Puccinia triticina Puccinia striiformis Triticum aestivum
分 类 号:S435.121.4[农业科学—农业昆虫与害虫防治]
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