来自波斯小麦Ps5的一对隐性抗叶锈病基因的染色体定位

为了筛选小麦抗叶锈病资源和发掘新的抗叶锈病基因,对由抗病波斯小麦Ps5与感病粗山羊草Ae38合成的双二倍体Am3进行了单体分析。将中国春单体和二体分别与Am3杂交,测定杂交F1植株的染色体条数以及F1、F2群体对叶锈病的抗/感病性。结果表明:在18℃条件下,Am3对小麦叶锈菌致病类型DHS/GD的抗病性由1对隐性抗病基因控制,该基因来自四倍体亲本波斯小麦Ps5,具有剂量效应,位于5A染色体上。     

1个小麦NBS类抗病基因同源cDNA序列的克隆与鉴定

 利用cDNA末端快速扩增技术对小麦抗叶锈病近等基因系TcLr35中所获得的抗病基因同源片段S2A2 5'端和3'末端序列进行扩增,并根据拼接序列设计特异性引物,进行全长基因的扩增,获得了1个通读的NBS类抗病同源基因S2A2 cDNA序列,该序列全长为3476 bp,编码866个氨基酸序列。经BLASTp比较,该片段含有NB-ARC保守结构域和多个LRR结构域,与已知植物抗病基因I2C-1、L6、RPS2等相应区域相一致。半定量RT-PCR分析表明,该基因在小麦叶片中为低丰度组成型表达。本研究在TcLr35小麦中成功获得了抗病同源基因,这为最终克隆小麦抗叶锈病基因Lr35奠定了基础。     

43个中国小麦品种(系)抗叶锈性研究

 选用12个墨西哥叶锈菌生理小种对43个中国小麦品种(系)所携带的抗叶锈病基因进行了推导,在25个品种(系)中推导出6个抗叶锈基因Lr1,Lr10,Lr13,Lr14a,Lr16和Lr26,9个品种(系)对本试验所使有的12个叶锈菌生理小种都表现感病反应,另有9个品种(系)携带未知的抗叶锈基因。在墨西哥2个地点进行的田间成株期抗叶锈性试验表明,12个品种(系)表现慢叶锈性,在将来的抗病育种中有一定的应用价值。     

中国小麦农家品种红锁条和白蚂蚱的抗条锈性遗传分析

为明确小麦农家品种所含抗条锈病基因组成及其抗病性和遗传特点,通过接种中国小麦条锈菌生理小种CYR31、CYR32和CYR33,对红锁条和白蚂蚱2个农家品种进行抗病性鉴定、基因推导及系谱分析和苗期抗病性遗传分析。结果显示,红锁条和白蚂蚱苗期均高抗3个流行小种CYR31、CYR32和CYR33,成株期高抗CYR32;红锁条和白蚂蚱均含有未知抗条锈病基因;红锁条对CYR31和CYR32的抗病性由2对隐性独立或重叠遗传基因控制,对CYR33的抗病性由1对隐性基因控制;白蚂蚱对CYR31的抗病性由2对显性互补基因控制,对CYR32的抗病性由1对显性基因控制,对CYR33的抗病性由2对隐性独立或重叠基因控制。农家品种红锁条和白蚂蚱含有抗条锈病基因,可以为抗病育种提供新抗源。     

小麦新品系抗白粉病基因分析

 本文对6个小麦新品系所含的抗白粉病基因进行了遗传分析。将感病品种Liaochun10分别与SM 20121、SM 203390、SM 20125、SM 200332、SM 20126、SM 20005杂交和自交,并将这6个品系互配成半双列杂交组合。用小麦白粉菌15号小种的单孢堆菌系对各杂交组合的亲本、F₁、F₂代群体及F₃代家系进行了苗期抗病性鉴定。遗传分析表明,供试的6个品系对小麦白粉菌15号小种的抗性均由1对显性基因控制。等位性分析推断:SM 20121、SM 203390、SM 20125和SM 200332含有抗白粉病基因Pm12;SM 20126含有抗白粉病基因Pm21;SM 20005含有抗白粉病基因Pm16。建议将这6个品系作为优良抗病亲本利用。     

小麦抗叶锈基因Lr 38的AFLP标记

 小麦叶锈病是小麦的重要病害之一,几乎在所有小麦种植区都有发生,严重时可造成5%~15%甚至更大的产量损失^[1]。小麦抗叶锈基因Lr38发现位于中间偃麦草(Agropyron intermedium)第7组的一条染色体上,并被标定在6 DL上^[2],是抗性很强的抗叶锈病基因,国内外至今尚未发现对Lr38有毒性的菌株,是一个应用潜力很大的抗病基因。     

2011-2012年度中国六省小麦叶锈菌群体毒性分析

 为明确2011-2012年度云南、四川、青海、陕西、甘肃和河南小麦叶锈菌的毒性特点,用31个近等基因系或已知抗病基因品种为鉴别寄主,对从六省采集的180份小麦叶锈菌标样进行了苗期毒性分析,共鉴定出62个致病类型,主要包括SHJ(10%)、THT(8.9%)、PHK(6.1%)、SHN(5%)、PHT(4.4%)、SHD(4.4%)、PCH(3.9%)、THP(3.3%)和THK(3.3%)。其中对Lr2c、Lr10、Lr14a、Lr14b、Lr33和Lr36的毒性频率均超过75%,说明这些抗病基因的利用价值已经不大;对Lr9、Lr19、Lr24、Lr25、Lr28、Lr29、Lr38和Lr42的毒性频率低于30%,说明其在生产中仍然有效;对Lr2a、Lr3、Lr3bg、Lr20、Lr30和Lr32的毒性频率在六省中差异较大。毒性多态性结果表明云南和四川的小麦叶锈菌群体毒性多态性较高,其次为河南、甘肃和陕西,青海的毒性多态性最低。     

春小麦品种青春221抗叶锈性遗传分析

为明确青春221中抗叶锈病基因的有效性及其遗传机制,以青春221为父本,分别与感病品种铭贤169和Thatcher以及小麦抗叶锈病近等基因系Lr1、Lr3和Lr23的载体品系杂交,获得F1、F2和F3代群体后,分别在苗期和成株期进行抗病性测定。苗期,青春221对致病类型FGJ/QP、SHJ/GN和PHT/RP的抗病性分别由显性抗叶锈病基因Lr1、Lr3和Lr23控制,对致病类型BGD/HL的抗病性则由上述3对显性抗病基因独立或重叠作用控制,与Thatcher杂交后,青春221中的Lr23趋于隐性遗传并被Thatcher中的1对显性抑制基因抑制;成株期,青春221对优势致病类型PHT/RP和THT/TP混合菌种的抗病性由显性抗叶锈病基因Lr23控制,而Lr1和Lr3均不起作用。     

偃麦草属E染色体组特异SCAR标记对Lr19的特异性和稳定性研究

 小麦抗叶锈基因Lr19来源于长穗偃麦草,表现优良的抗叶锈性,国内外发现对Lr19有毒性的小麦叶锈菌菌株的报道较少。本研究以TcLr19和Thatcher亲本以及TcLr19×Thatcher F₂代单株构建的分离群体为材料,建立了与Lr19共分离的稳定的SCAR分子标记,命名为Y₁₉SCAR₉₈₂。对49个小麦抗叶锈近等基因系材料的稳定性检测结果表明,其重复性好且为Lr19特异的分子标记。对120个小麦品种检测的结果表明,该标记可有效应用于小麦抗叶锈分子辅助选择育种。     

普通小麦-华山新麦草易位系H9015-17抗条锈病基因的标记定位

 采用我国当前流行的小麦条锈菌小种和重要致病类型, 在常温条件下对普通小麦-华山新麦草易位系H9015-17进行苗期抗条锈性鉴定, 并用当前主要流行小种CYR32对H9015-17与铭贤169的杂交后代及其双亲进行抗条锈性遗传分析, 以揭示H9015-17抗条锈性遗传基础。结果显示, H9015-17对小麦条锈菌小种CYR31、CYR32、CYR33和致病类型Su11-4、Su11-7、V26、Su11-11均有良好的抗病性, 对当前主要流行小种CYR32的抗病性由1对显性基因控制, 暂命名为YrHua1。 采用分子标记定位技术,筛选到5个与抗病基因YrHua1连锁的RGAP标记(M1、M2、M3、M4和M5)和1个SSR标记(Xgwm292),这些标记与抗病基因YrHua1的遗传距离分别为17.3、15.7、13.1、3.3、2.9和11.2,并将基因YrHua1定位在小麦染色体5DL上。研究结果将为分子标记辅助选择改良小麦抗条锈性提供宝贵的种质材料,建议在抗病育种加以利用。     

Genetics of leaf rust resistance in spring wheat cultivars alsen and norm

ABSTRACT Alsen is a recently released spring wheat cultivar that has been widely grown in the United States because it has resistance to Fusarium head blight and leaf rust caused by Puccinia triticina. Norm is a high yielding wheat cultivar that has been very resistant to leaf rust since it was released. Alsen and Norm were genetically examined to determine the number and identity of the leaf rust resistance genes present in both wheats. The two cultivars were crossed with leaf rust susceptible cv. Thatcher and F(1) plants were backcrossed to Thatcher. Eighty one and seventy three BCF(1) of Thatcher times; Alsen and Thatcher x Norm respectively, were selfed to obtain BCF(2) families. The BCF(2) families were tested as seedlings with different isolates of P. triticina that differed for virulence to specific leaf rust resistance genes. The BCF(2) families that lacked seedling resistance were also tested as adult plants in greenhouse tests and in a field rust nursery plot. Segregation of BCF(2) families indicated that Alsen had seedling genes Lr2a, Lr10, and Lr23 and adult plant genes Lr13 and Lr34. Norm was determined to have seedling genes Lr1, Lr10, Lr16, and Lr23 and adult plant genes Lr13 and Lr34. The characterization of Lr23 in the segregating populations was complicated by the presence of a suppressor gene in Thatcher and the high temperature sensitivity of resistance expression for this gene. The effective leaf rust resistance in Alsen is due to the interaction of Lr13 and Lr23, with Lr34; and the effective leaf rust resistance in Norm is due to the interaction of Lr13, Lr16, and Lr23, with Lr34.     

Performance and Mapping of Leaf Rust Resistance Transferred to Wheat from Triticum timopheevii subsp. armeniacum

ABSTRACT Host plant resistance is an economical and environmentally sound method of control of leaf rust caused by the fungus Puccinia triticina, which is one of the most serious diseases of wheat (Triticum aestivum) worldwide. Wild relatives of wheat, including the tetraploid T. timopheevii subsp. armeniacum, represent an important source of genes for resistance to leaf rust. The objectives of this study were to (i) evaluate the performance of leaf rust resistance genes previously transferred to wheat from three accessions of T. timopheevii subsp. armeniacum, (ii) determine inheritance and allelic relationship of the new leaf rust resistance genes, and (iii) determine the genetic map location of one of the T. timopheevii subsp. armeniacum-derived genes using microsatellite markers. The leaf rust resistance gene transferred to hexaploid wheat from accession TA 28 of T. timopheevii subsp. armeniacum exhibited slightly different infection types (ITs) to diverse races of leaf rust in inoculated tests of seedlings compared with the gene transferred from TA 870 and TA 874. High ITs were exhibited when seedlings of all the germ plasm lines were inoculated with P. triticina races MBRL and PNMQ. However, low ITs were observed on adult plants of all lines having the T. timopheevii subsp. armeniacum-derived genes for resistance in the field at locations in Kansas and Texas. Analysis of crosses between resistant germ plasm lines showed that accessions TA 870 and TA 874 donated the same gene for resistance to leaf rust and TA 28 donated an independent resistance gene. The gene donated to germ plasm line KS96WGRC36 from TA 870 of T. timopheevii subsp. armeniacum was linked to microsatellite markers Xgwm382 (6.7 cM) and Xgdm87 (9.4 cM) on wheat chromosome arm 2B long. This new leaf rust resistance gene is designated Lr50. It is the first named gene for leaf rust resistance transferred from wild timopheevi wheat and is the only Lr gene located on the long arm of wheat homoeologous group 2 chromosomes.     

Virulence Phenotypes of a Worldwide Collection of Puccinia triticina from Durum Wheat

ABSTRACT A total of 78 isolates of Puccinia triticina from durum wheat from Argentina, Chile, Ethiopia, France, Mexico, Spain and the United States and 10 representative isolates of P. triticina from common wheat from the United States were tested for virulence phenotypes on seedling plants of 35 near-isogenic lines of Thatcher wheat. Isolates with virulence on lines with leaf rust resistance genes Lr10, Lr14b, Lr20, Lr22a, Lr23, Lr33, Lr34, Lr41, and Lr44 represented the most frequent phenotype. Cluster analysis showed that P. triticina from durum wheat from South America, North America, and Europe had an average similarity in virulence of 90%, whereas isolates from Ethiopia were <70% similar to the other leaf rust isolates collected from durum wheat. Of the 11 isolates from Ethiopia, 7 were avirulent to Thatcher and all near-isogenic lines of Thatcher. The isolates from common wheat had an average similarity in virulence of 60% to all leaf rust isolates from durum wheat. P. triticina from durum wheat was avirulent to many Lr genes frequently found in common wheat. It is possible that P. triticina currently found on durum wheat worldwide had a single origin, and then spread to cultivated durum wheat in North America, South America, and Europe, whereas P. triticina from Ethiopia evolved on landraces of durum wheat genetically distinct from the cultivated durum lines grown in Europe and the Americas.     

Molecular marker mapping of leaf rust resistance gene lr46 and its association with stripe rust resistance gene yr29 in wheat

ABSTRACT Leaf and stripe rusts, caused by Puccinia triticina and P. striiformis, respectively, are globally important fungal diseases of wheat that cause significant annual yield losses. A gene that confers slow rusting resistance to leaf rust, designated as Lr46, has recently been located on wheat chromosome 1B. The objectives of our study were to establish the precise genomic location of gene Lr46 using molecular approaches and to determine if there was an association of this locus with adult plant resistance to stripe rust. A population of 146 F(5) and F(6) lines produced from the cross of susceptible 'Avocet S' with resistant 'Pavon 76' was developed and classified for leaf rust and stripe rust severity for three seasons. Using patterns of segregation for the two diseases, we estimated that at least two genes with additive effects conferred resistance to leaf rust and three to four genes conferred resistance to stripe rust. Bulked segregant analysis and linkage mapping using amplified fragment length polymorphisms with the 'Avocet' x 'Pavon 76' population, F(3) progeny lines of a single chromosome recombinant line population from the cross 'Lalbahadur' x 'Lalbahadur (Pavon 1B)', and the International Triticeae Mapping Initiative population established the genomic location of Lr46 at the distal end of the long arm of wheat chromosome 1B. A gene that is closely linked to Lr46 and confers moderate levels of adult plant resistance to stripe rust is identified and designated as Yr29.     

1999年我国小麦叶锈菌毒性监测

采用国际通用的小麦叶锈菌鉴别寄主和辅助鉴别寄主分析了来自1999年我国不同地区小麦叶锈菌的毒性基因,479个叶锈菌株共划分为162个毒性类型,其中23个为主要毒性类型.毒性类型中出现频率最高的为FHB、PHT、FHG、THT,它们对抗叶锈基因Lr2a、Lr2b、Lr3、Lr10、Lr14b、Lr16、 Lr26的平均毒性频率高于80%,而对Lr3ka、Lr25、Lr19、Lr24、Lr30、Lr15、Lr35的平均毒性频率低于30%;发现对Lr35有毒力的菌株,出现频率为1.04%;至今尚未发现对Lr38、Lr45抗性基因有毒力的菌株.研究同时发现,不同地区小麦叶锈菌的毒性类型不同,毒性频率存在一定的差异.Lr9、Lr15、Lr19、Lr24、Lr35、Lr38、Lr45为小麦抗叶锈育种可利用的有效抗病基因.     

春小麦品种沈免2063抗叶锈性遗传分析

为明确春小麦品种沈免2063所含抗叶锈病基因的对数、身份、显隐性和互作关系,以沈免2063为父本,分别与感病品种Thatcher及小麦抗叶锈病近等基因系Lr9、Lr19、Lr24、Lr25、Lr28、Lr42和Lr43的载体品系杂交,获得F1、F2和F3代群体后,分别在苗期和成株期进行抗病性测定。结果表明:沈免2063含有3对显性遗传且相互独立作用的抗叶锈病基因Lr9、Lr19和Lr25,在苗期,沈免2063对致病类型CBG/QQ的抗病性由Lr9和Lr25控制,对PHT/RP的抗病性由上述3对抗叶锈病基因控制;在成株期,沈免2063对优势致病类型PHT/RP和THT/TP等比混合菌种的抗病性由上述3对抗叶锈病基因控制。Lr9、Lr19和Lr25在育成品种中出现频率很低,目前尚很有效,但这3个基因均为典型的垂直抗病性基因,应进行基因布局、基因轮换等科学组配,才能延长其使用寿命。     

我国40个小麦品种抗叶锈性研究

 选用11个具不同毒性基因组合的叶锈菌致病类型推导分析了1998~1999年度国家小麦区域试验40个品种所携带的抗叶锈病基因状况。在供试的39个已知抗叶锈基因(或基因组合)中,推导出Lr1、Lr2c、Lr3bg、Lr10、Lr13、Lr14a、Lr16、Lr23、Lr26、Lr32等10个抗叶锈基因,分布在24个品种中,有11个品种携带未知抗叶锈基因,5个品种不具有苗期抗叶锈基因。选用BBB、DHS、PGT和PHT等4个叶锈菌致病类型并设置5/10℃、15/20℃、25/30℃(黑暗/光照)3种不同的温度条件,研究了40个供试品种的抗性稳定性。结果表明,在这些品种中有15个品种的侵染型表现稳定或较稳定,3个品种表现为高温抗性,2个品种表现低温抗性,其余20个品种存在明显的品种、菌系和温度三者的相互作用;利用6个叶锈菌混合优势小种在田间进行成株期抗叶锈性鉴定结果表明,在40个供试品种中有21个品种具有良好的抗性,其中,至少有6个品种表现为慢锈性,有4个品种表现为明显的成株抗性,有4个品种可能携带成株抗性基因Lr34。文中还对几个主要抗叶锈基因的抗性特点及其利用价值等进行了讨论。