小麦抗条锈病基因YrCN19的诊断检测和遗传分析

用小麦条锈病抗性基因YrCN19的诊断标记Xgwm410对19个小麦品种或品系进行PCR筛选,其中川农19、新抗5号、爱民5号和爱民6号扩增出与条锈病抗性基因YrCN19共分离的特征片断,其大小为391个碱基,而在其他的小麦品种或品系中未能检测到该片断。系谱分析和抗性鉴定结果表明川农19、新抗5号、爱民5号和爱民6号含有小麦条锈病基因YrCN19。抗性遗传分析发现小麦条锈病抗性在川农19,新抗5号和爱民5号中的遗传符合单个显性基因的遗传规律(3抗:1感);杂交组合烟辐188/爱民6号的抗性遗传也符合单个显性基因的遗传规律,而另外一些杂交组合(如R25/爱民6号,鲁955159/爱民6号和苏3110/爱民6号)中的抗性分离则符合两对基因互补的遗传规律(9抗:7感)。本研究揭示了小麦条锈病抗性基因YrCN19在不同遗传背景和杂交组合的抗性表达和分离有差异,从而加速YrCN19在小麦抗条锈育种中的开发与利用。     

一粒小麦抗白粉病和条锈病基因的分析

一粒小麦是普通小麦抗性改良的宝贵资源.本研究对24份一粒小麦分别进行了白粉病和条锈病混合菌种苗期接种鉴定,进一步分别用一套白粉病菌菌株(15个)对2份乌拉尔图小麦和条锈病菌小种(21个)对1份栽培一粒小麦进行接种鉴定,其中乌拉尔图小麦UR206能抵抗所有供试白粉菌菌株,UR204除对白粉菌菌株E11感病外,对其余菌株表现抗性;栽培一粒小麦MO205对不同条锈菌小种表现出不同的抗性反应,研究表明乌拉尔图小麦UR206、UR204和栽培一粒小麦MO205分别含有与已知抗白粉病和抗条锈病基因不同的新基因.对乌拉尔图小麦UR204、UR206和栽培一粒小麦MO205分别进行抗白粉和条锈病基因的遗传分析,结果表明乌拉尔图小麦UR204和UR206分别含有一对显性抗白粉病基因,栽培一粒小麦MO205含有两对独立遗传的显性抗条锈病基因.     

条形柄锈菌小麦专化型小种CYR29有性自交及毒性与无毒性基因的遗传分析

由条形柄锈菌小麦专化型(小麦条锈菌)Puccinia striiformisf.sp.tritici引起的条锈病是小麦上重大的生物灾害,严重威胁小麦安全生产.应用抗病品种是防治小麦条锈病最为经济有效的措施,但是条锈菌毒性的频繁变异,常常导致品种抗病性丧失,从而引发条锈病新的大流行.有性生殖是条锈菌毒性变异的重要途径,本...     

粗山羊草抗条锈病新基因YrY206遗传分析和微卫星 标记

从小麦野生近缘属——粗山羊草中挖掘小麦条锈病抗病基因, 拓展小麦抗病性的遗传基础。利用抗小麦条锈病与感小麦条锈病的粗山羊草间杂交, 从粗山羊草[Aegilops tauschii (Coss.) Schmal] Y206中鉴定出1个显性抗小麦条锈病基因, 暂定名为YrY206。应用分离群体分组法(Bulked segregant analysis, BSA)筛选到Wmc11a、Xgwm71c、Xgwm161和Xgwm183标记, 与该基因之间的遗传距离分别为4.0、3.3、1.5和9.3 cM。根据连锁标记所在小麦微卫星图谱的位置, YrY206被定位在3DS染色体上。分析基因所在染色体的位置、抗病性特征, 认为YrY206是一个新的抗小麦条锈病基因。     

小麦农家品种赤壳中一个主效抗条锈病基因的微卫星标记和定位

小麦农家品种赤壳(苏1900)对当前我国小麦条锈菌(Puccinia striiformis Westend.f.sp.tritici)多个流行小种均有较好抗性。遗传分析表明,该品种对条中32号小种的抗性是由一对显性基因控制。本文采用分离群体分析法(bulked segregant analysis,BSA)和微卫星多态性分析方法,对该基因进行了分子标记和定位研究。用Taichung29×赤壳的F2代分离群体建立抗、感DNA池,共筛选了400多对SSR引物,发现5个标记Xwmc44、Xgwm259、Xwmc367、Xcfa2292、Xbarc80在抗、感DNA池间与在抗、感亲本间同样具有多态性,它们均位于1BL染色体臂上。经用具有140株抗病株、60株感病株共200株植株的F2代分离群体进行的遗传连锁性检测,上述5个标记均与目的基因相连锁,遗传距离分别为8.3cM、9.1cM、17.2cM、20.6cM和31.6cM。用全套21个中国春缺-四体材料进行的检测进一步证实了这5个SSR标记均位于小麦1B染色体上。综合上述结果,将赤壳中的主效抗条锈病基因YrChk定位在1BL染色体臂上。与以前已定位于1B染色体上的抗条锈病基因的比较研究表明,YrChk基因可能是一个新的抗条锈病基因。小麦农家品种中抗病基因资源的发掘和利用将有助于提高我国小麦生产品种中的抗病基因丰富度,有助于改善长期以来小麦生产品种中抗病基因单一化的局面。     

西南地区小麦抗条锈病种质的遗传多样性及群体结构分析

全面了解西南地区小麦抗条锈病种质遗传多样性和群体结构信息,能有效提高抗病品种的育种效率。在本研究中,我们利用基于基因分型测序（GBS）技术的DArT-seqTM方法对134份小麦材料开展了全基因组基因分型,共获得了6919个多态性的SNP（single nucleotide polymorphism）标记。它们的多态性指数（PIC,polymorphism information content）的范围在0.01到0.50之间,平均值为0.32。根据SNP标记在134份小麦品种中的基因分型数据,计算了品种间的遗传相似系数（GS）,其变异范围为 0.51～0.98,平均值0.61。非加权组平均法（UPGMA,unweighted pair-group method with arithmetic mean）聚类分析结果显示根据来源地和亲缘关系的不同,这批小麦品种（系）可划分为五个群。主坐标分析（PCoA）结果显示,小麦材料清晰地聚集形成了两个群。第一类群由不同来源的小麦材料组成,群体较大且分布更紧密。而第二类群几乎都由贵州小麦组成,品种数目较少但更加分散。在抗条锈病基因的分布上,大多数携带Yr9基因位点的小麦品系聚集在第一类群中,而绝大多数携带Yr26抗病基因位点的小麦品系则聚集在第二类群中。本研究从基因型多样性水平上阐释了西南地区小麦抗病种质遗传背景,为西南地区和我国小麦的抗条锈病育种的提供了理论依据。     

小麦新抗源贵农775抗条锈性特征与遗传分析

发掘并利用不同类型抗条锈病基因,构建区域间抗病基因多样性差异布局,是阻遏条锈菌大区域传播、实现小麦条锈病持续控制的重要策略。为了明确小麦新抗源贵农775抗条锈性特征和抗性遗传规律,为其合理布局应用提供依据,文章利用10个条锈菌菌系进行苗期分小种鉴定;构建贵农775与感病品种Avocet(S)杂交后代F2:3及回交BC1遗传群体,利用小麦条锈菌流行小种CYR32和最近发现的对Yr26基因有毒性的新致病类型CH42,对贵农775进行抗条锈性遗传分析。结果表明,贵农775对包括CH42致病类型在内的所有10个供试菌系均表现为免疫或近免疫的抗病性反应,而中国当前主要条锈病抗源品种92R137、川麦42(YrCH42)、贵农22(YrGN22)及Yr24等均不抗CH42;抗病遗传分析结果表明,贵农775对小麦条锈菌小种CYR32和CH42的抗性分别由一对显性核基因控制,并且为不同的小种专化抗性基因。     

小麦抗条锈病基因定位及分子标记研究进展

本文综述了小麦抗条锈病基因染色体定位及抗条锈病基因分子标记的研究进展,并对几种分子标记技术的应用潜力作了比较分析,特别是对ＳＳＲ、ＩＳＳＲ、ＡＦＬＰ等新型分子标记在小麦遗传育种中的应用前景作了初步探讨。     

小麦新抗源CH5383抗条锈病基因的遗传分析及分子定位

CH5383是新育成的源于中间偃麦草的渗入系,对小麦条锈病和白粉病均表现免疫。为明确其抗性来源、遗传方式和抗病基因在染色体上的位置,将CH5383的系谱材料及其与高感条锈病品种(系)杂交的F1、F2和F2:3家系群体进行条锈病抗性鉴定。结果表明,CH5383对条锈病的抗性源于中间偃麦草,对条锈病生理小种CYR32的抗性由一对显性核基因控制,将此基因暂时命名为YrCH5383。从476对SSR引物中筛选到3对引物Xgwm108、Xbarc206和Xbarc77与抗病基因连锁,遗传距离分别是8.2 cM、10.7 cM和13.6 cM。根据这两对标记在染色体上的位置,将抗病基因定位到3B染色体的长臂上。3B染色体的长臂还未见有正式命名的抗条锈病基因的报道,推测YrCH5383可能是一个源于中间偃麦草的新抗条锈病基因。     

我国科学家发现抗小麦条锈病新基因

经过4年多的研究，巾国农业科学院作物科学研究所的一个课题组人工合成了小麦新种质CI108．发现其含有一个抗条锈病新基凼YrC108．并利州分子标记对该基因进行了染色体定位．该成果不仅为抗条锈病小麦育种提供了新抗源。而且为高效分子育种提供了选择标记。[第一段]     

中国小麦条锈菌转主寄主小檗的鉴定

用萌发的小麦条锈菌冬孢子接种采自陕西省境内的陕西小檗、少齿小檗和长穗小檗,3种小檗均产生了性孢子器和锈孢子器。用人工接种小麦条锈菌冬孢子在陕西小檗上产生的锈孢子器接种小麦铭贤169产生了典型的条锈菌夏孢子堆症状。特异性PCR和DNA序列分析表明,人工接种产生于小檗上的锈孢子、接种锈孢子于小麦上产生的夏孢子堆与小麦条锈菌DNA的ITS区序列完全一致。更为重要的是,用采自田间受锈菌侵染的小檗叶片产生的锈孢子接种小麦铭贤169,经培养在小麦铭贤169叶片上产生了典型的条锈病症状。从而证实,在自然条件下,在中国,小檗不仅可作为小麦条锈菌的转主寄主,而且小麦条锈菌可在小檗上完成其有性繁殖过程。这一发现对进一步揭示我国小麦条锈菌高度的群体遗传多样性与毒性变异机理、完善小麦条锈病的防治策略具有十分重要的理论和实际意义。     

黄淮麦区小麦品种(系)中Yr26基因的SSR检测

选用与Yr26紧密连锁的SSR标记Xgwm11和Xgwm18结合田间抗性鉴定,对239份黄淮麦区小麦品种(系)进行检测,以明确Yr26基因在黄淮麦区小麦品种资源中的分布.结果表明:共有35份品种(系)含有与Yr26紧密连锁的SSR标记Xgwm18或Xgwm11的特征带,占检测样本的14.6%.在这35份材料中,31份田间抗性鉴定表现免疫至中抗,4份表现中感.分子标记检测与田间抗病性检测吻合度较好,该标记可以用于Yr26基因的分子标记辅助选择.综合分子标记和田间鉴定,31份小麦(系)含有Yr26基因,占102份抗病材料的30.39%.     

1994 - 2002年小麦品种(系)抗条锈性鉴定与监测

1994—2002年经对3822份小麦品种(系)材料抗条锈性鉴定结果表明,冬小麦抗条锈性优于春小麦,甘肃品种抗条锈性优于国内其它省区品种。田间抗条锈性监测结果表明,我国主要生产品种均表现感病,甘肃主要生产品种仅陇鉴127等少数几个品种抗病,抗源材料中也仅有中四等少数品种表现抗病,结合抗病性鉴定、监测结果及田间综合农艺性状观察,筛选出20余份可供育种利用的抗源材料。同时在针对今后抗条中31、32号等主要小种类型的抗病育种、抗病性监测等方面进行了讨论。     

Genetic and Molecular Mapping of Stripe Rust Resistance Genes in Wheat Cultivar Zhongliang 12

Stripe rust, caused by Puccinia striiformis f.sp. tritici (Pst), is one of the most widespread and destructive diseases of wheat worldwide. Resistance breeding is constantly pursued for decades to tackle the variations of prevalent Pst races. Zhongliang 12 has strong resistance to abiotic stresses, wide adaptability, higher resistance to stripe rust and excellent biological characteristics. To identify the resistance gene(s) against stripe rust, Zhongliang 12 was crossed with stripe rust susceptible genotype Mingxian 169, and F₁, F₂, F_2 : 3 and BC₁ progenies were tested with Chinese Pst race CYR30 and CYR31 in seedling stage in greenhouse. Zhongliang 12 possessed different dominant genes for resistance to each race. Linkage maps were constructed with four simple sequence repeats (SSRs) markers, Xwmc695, Xcfd20, Xbarc121 and Xbarc49, for the gene on wheat chromosome 7AL conferring resistance to CYR30 (temporarily designated as Yrzhong12‐1) with genetic distance ranging from 3.1 to 10.8 cM and four SSR markers, Xpsp3003, Xcfd2129, Xwmc673 and Xwmc51, for the gene on wheat chromosome 1AL conferring resistance to CYR31 (temporarily designated as Yrzhong12‐2) with genetic distance ranging from 3.9 cM to 9.3 cM. The molecular markers closely linked to each gene should be useful in marker‐assisted selection in breeding programmes for against stripe rust.     

小麦持久抗条锈品种斯汤佩利的遗传机制研究

对持久抗条锈小麦品种斯汤佩利进行了抗条锈特点研究和抗性遗传分析.斯汤佩利反应型0～1型,普遍率、严重度和病情指数3个抗性组分及其平均日变化率都很低,与三类对照品种之间有极显著差异.与中抗-中感为特征的、抗性由多基因或由主效基因与多基因共同控制的一般持久抗病品种相比,属于典型特例.其抗条锈性由2对显性基因互补控制,干尖性状由1对显性基因控制,二者之间不连锁,因此,干尖不能作为斯汤佩利抗锈性的辅助选择标记.     

2003-2013年小麦品种(系)抗条锈性鉴定及评价

2003-2013年在甘肃省农业科学院植物保护研究所兰州温室和甘谷试验站,分别对来自国内35个相关育种单位的冬春小麦品种(系)5001份,其中冬小麦4291份、春小麦710份,进行苗期混合菌、成株期分小种和混合菌抗条锈性接种鉴定,结果表明:全生育期表现免疫近免疫的有兰天31号等479份,高抗的有兰天23号等76份,中抗的有天选49等291份,分别占9.58％、1.52％和5.82％;成株期表现免疫近免疫的有天选50号等840份,高抗的有兰天27号等47份,中抗的有天选52等311份,分别占16.80％、0.94％和6.22％;苗期表现免疫近免疫的有兰天30号等964份,高抗的有天98102等122份,中抗的有00-30等273份,分别占19.28％、2.44％和5.46％.冬小麦有天选49号等914份材料表现全生育期抗病,占18.28％;有97-473等906份成株期表现抗病,占18.12％;有兰天20号等1225份苗期表现抗病,占24.50％.春小麦有定西41号等113份材料全生育期表现抗病,占2.26％;有陇春28号等125份成株期表现抗病,占2.50％;有0109-1等114份苗期对混合菌表现抗病,占2.28％.先后在甘肃天水汪川良种场对相关材料进行成株期抗条锈性评价,结果发现:1154份从小种圃筛选出的抗病材料中,表现抗病的有兰天31号等745份,占64.56％;105份甘肃陇南生产品种中,到2013年表现抗病的仅有兰天28号、中梁31号等30份材料,占28.57％;后备品系中,00-30-2-1、CP04-20、00127-2-3等抗性表现优异;抗源材料中,仅有贵农775、中四、T.Spelta albun、贵协1、贵协3等少数材料表现抗病,重要抗源材料贵农21、贵农22、南农92R、川麦42、Moro从2011年开始在田间表现感病,逐步失去利用价值.其衍生系品种材料如陇鉴9343、天选43号、中梁29号、兰天17号、兰天24号等也在田间逐步感病,条锈病发生流行压力持续增大.     

Inheritance and expression of stripe rust resistance in common wheat (Triticum aestivum) transferred from Aegilops tauschii and its utilization

Stripe rust is one of the most destructive diseases for wheat crops in China. Two stripe rust physiological strains, i.e. CYR30 (intern. name: 175E191) and CYR31 (intern. name: 293E175) have been the dominant and epidemic physiological strains since 1994. One Aegilops tauschii accession (SQ-214) from CIMMYT was found immune from or highly resistant to Chinese new stripe rust races CYR30 and CYR31 at adult stage. SQ-214 was crossed with a highly susceptible Ae. tauschii accession As-80. Analysis of data from F1-F2 populations of SQ-214/As-80 revealed that the resistance was controlled by a single dominant gene. To exploit the resistance for wheat breeding, SQ-214 was crossed with Chinese Spring (CS) and backcrossed by two Chinese commercial wheat varieties MY26 and SW3243. The resistance from SQ-214 was suppressed in the F1 hybrids (CS/SQ-214) and the F2 population of CS/SQ-214//MY26. However, the resistance of SQ-214 was expressed in several F2 individuals of CS/SQ-214//SW3243. Eleven advanced lines with high level of resistance to the Chinese stripe rust CYR30 and CYR31 have been developed. This result suggested that SW3243 does not suppress the expression of the Chinese stripe rust and should be used as wheat germplasm for exploiting resistance of Ae. tauschii in wheat breeding. The gliadin electrophoretic pattern of the eleven advanced lines with high stripe rust resistances was compared with their parents SQ-214, CS and SW3243 by acid polyacrylamide gel electrophoresis. The omega-gliadin bands of Gli-Dt1 in Ae. tauschii SQ-214 were transferred to some advanced lines and freely expressed in common wheat genetic background. One of advanced lines possesses a null Gli-D1 allele, where the omega-gliadin bands encoding by the Gli-D1 allele were absent. The potential utilization of this advanced line for wheat quality and stripe rust resistance breeding is also discussed in this paper.     

Molecular mapping of a non-host resistance gene YrpstY1 in barley (Hordeum vulgare L.) for resistance to wheat stripe rust

Cultivated barley (Hordeum vulgare L.) is considered as a non-host or inappropriate host species for wheat stripe rust caused by Puccinia striiformis f. sp. tritici. Most barley cultivars show a broad-spectrum resistance to wheat stripe rust. To determine the genes for resistance to wheat stripe rust in barley, a cross was made between a resistant barley line Y12 and a susceptible line Y16. The two parents, F(1) and 147 BC(1) plants were tested at seedling stage with Chinese prevalent race CYR32 of Puccinia striiformis f. sp. tritici by artificial inoculation in greenhouse. The results indicated that Y12 possessed one dominant resistance gene to wheat stripe rust, designated YrpstY1 provisionally. A total of 388 simple sequence repeat (SSR) markers were used to map the resistance gene in Y12 using bulked segregant analysis. A linkage map, including nine SSR loci on chromosome 7H and YrpstY1, was constructed using the BC(1) population, indicating that the resistance gene YrpstY1 is located on chromosome 7H. It is potential to transfer the resistance gene into common wheat for stripe rust resistance.     

The 3Ns chromosome of Psathyrostachys huashanica carries the gene(s) underlying wheat stripe rust resistance

Stripe rust (Puccinia striiformis tritici (Pst)) is one of the most destructive diseases of wheat in the world. Exploiting and utilizing stripe rust resistance genes of wild species has become an essential strategy for resistance breeding. Psathyrostachyshuashanica Keng ex Kuo is a wild species in Triticeae that has been used for wheat improvement because of its high resistance or immunity to stripe rust. In this study, 9 wheat-P. huashanica addition lines were characterized by Giemsa C-banding, genomic in situ hybridization (GISH), and disease resistance evaluation. Giemsa C-banding and GISH demonstrated that lines 163-5, 165-1, 183-5, 240-3, and 240-4 are P. huashanica 3Ns chromosome monosomic addition lines; lines 183-1 and 183-20 are P. huashanica 3Ns chromosome disomic addition lines; line 165-20 is a P. huashanica 3Ns and 4Ns chromosomes double disomic addition line, and line 219-1 is a P. huashanica 1Ns and 3Ns/5A chromosomes double disomic addition-substitution line. All these addition lines with P. huashanica 3Ns chromosome(s) expressed high resistance or immunity to stripe rust. By comparing the series of wheat-P. huashanica chromosome addition lines, we concluded that the P. huashanica 3Ns chromosome carries the gene(s) for resistance or immunity to stripe rust. These addition lines can be used as a donor source of novel stripe rust resistance to wheat breeding programs.     

小麦条锈菌国际鉴别寄主Vilmorin23的抗条锈病基因YrV23微卫星标记

Vilmorin23是小麦条锈菌国际鉴别寄主和国际上重要抗源材料。采用SSR技术,利用由Vilmorin23为基因供体转育而成的小麦抗条锈近等基因系Taichung29*6/YrV23,选用YrV23所在2B染色体上的55对SSR引物,对Taichung29*6/ YrV23及其轮回亲本Taichung29和抗性基因供体Vilmorin23的基因组DNA进行PCR扩增和聚丙烯酰胺凝胶电泳分析。结果显示,引物Xwmc356在近等基因系与轮回亲本间扩增出特异性DNA片段,经F₂代群体150个抗、感单株检测证实,该片段位点与抗条锈病基因YrV23有连锁关系,遗传距离为9.4 cM。Xwmc356可作为抗条锈基因YrV23的SSR标记。