小麦品种中梁88375抗条锈病基因的分子作图

【目的】中梁88375是甘肃省天水市农业科学研究所以中4/S394//咸农4号复合杂交选育而成的冬小麦品系,对小麦三锈免疫。明确其抗条锈病基因及遗传特点,建立与其连锁的微卫星标记,以利于抗源筛选和培育持久抗病新品种。【方法】将中梁88375与感病品种铭贤169杂交、自交和测交并对双亲及其杂交后代进行苗期抗性鉴定。用小麦条锈菌条中31号对其进行遗传分析;采用SSR技术,选用普通小麦的320对微卫星引物对中梁88375及铭贤169的基因组DNA进行PCR扩增和电泳分析。【结果】中梁88375对多个条锈菌小种具有良好的抗病性,对CY31的抗病性由1对显性核基因控制,把该基因暂命名为Yr88375。建立了与Yr88375连锁的6个微卫星标记Xgwm335、Xwmc289、Xwmc810、Xgdm116、Xbarc59与 Xwmc783,并将Yr88375定位于小麦5BL。距离Yr88375 最近的两个微卫星位点是Xgdm116、Xwmc810,遗传距离分别是3.1 cM和3.9 cM,最远的标记Xwmc783与Yr88375之间的遗传距离为13.5 cM。【结论】系谱分析结合分子标记结果表明,Yr88375很有可能是一个来自中间偃麦草(E.intermedium)并与已知抗条锈病基因不同的新基因。     

小麦品系西农1163-4抗叶锈病基因的遗传分析和分子作图

【目的】小麦品系西农1163-4高抗小麦叶锈、条锈和白粉病,综合农艺性状良好。明确该小麦品系中所含的抗叶锈病基因及遗传特点,找到与其紧密连锁的分子标记,有利于抗病基因利用和培育抗病新品种。【方法】将西农1163-4与感病品种Thatcher杂交,获得F1、F2代群体,利用中国叶锈菌优势小种THTT进行苗期抗性鉴定和抗性遗传分析;采用SSR技术对西农1163-4所携带的抗叶锈基因进行分子标记研究,共筛选了1 273对SSR引物。【结果】小麦品系西农1163-4对多个叶锈菌小种具有良好的抗病性,对THTT的抗性是由1个显性基因控制,该基因暂命名为LrXi。获得了与LrXi紧密连锁的3个微卫星分子标记Xbarc8、Xgwm582、Xwmc269和1个STS标记(ω-secali/Glu-B3),将LrXi定位于小麦1BL染色体上。距离最近的2个微卫星位点是Xgwm582、Xbarc8,与抗叶锈基因间的遗传距离分别为2.3 cM和3.2 cM。【结论】LrXi位于1BL染色体,抗叶锈表现不同于所有已知抗叶锈病基因,该基因的发现将有利于丰富中国抗叶锈病基因资源,为培育持久抗病品种奠定基础。     

Molecular Mapping of a Stripe Rust Resistance Gene YrH9020a Transferred from Psathyrostachys huashanica Keng on Wheat Chromosome 6D

Stripe rust （yellow rust）, caused by Puccinia striiformis f. sp. tritici （Pst）, is one of the most devastating diseases of wheat throughout the world. H9020-1-6-8-3 is a translocation line originally developed from interspeciifc hybridization between wheat line 7182 and Psathyrostachys huashanica Keng and is resistant to most Pst races in China. To identify the resistance gene（s） in the translocation line, H9020-1-6-8-3 was crossed with susceptible cultivar Mingxian 169, and seedlings of the parents, F1, F2, F3, and BC1 generations were tested with prevalent Chinese Pst race CYR32 under controlled greenhouse conditions. The results indicated that there is a single dominant gene, temporarily designated as YrH9020a, conferring resistance to CYR32. The resistance gene was mapped by the F2 population from Mingxian 169/H9020-1-6-8-3. It was linked to six microsatellite markers, including Xbarc196, Xbarc202, Xbarc96, Xgpw4372, Xbarc21, and Xgdm141, lfanked by Xbarc96 and Xbarc202 with at 4.5 and 8.3 cM, respectively. Based on the chromosomal locations of these markers and the test of Chinese Spring （CS） nullitetrasomic and ditelosomic lines, the gene was assigned to chromosome 6D. According to the origin and the chromosomal location, YrH9020a might be a new resistance gene to stripe rust. The lfanking markers linked to YrH9020a could be useful for marker-assisted selection in breeding programs.     

和尚麦中抗条锈基因的SSR标记定位研究

利用SSR标记技术对小麦农家品种和尚麦中的抗条锈病基因进行了分子标记筛选.在290对微卫星引物中,发现引物Xwmc216,Xgdm126,Xgwm153,Xbarc188和Xbarc81在抗亲、感亲和抗池、感池之间有差异.群体验证的结果表明,Xwmc216,Xgdm126,Xgwm153,Xbarc J88和Xbarc81与和尚麦中抗病基因连锁,基因和标记之间的顺序为着丝点-Xwmc216-YrHe-Xgdm126-Xgwm 153-Xbarc J88-Xbarc81,遗传距离依次为25.7,14.7,18.4,3.7和5.4 cM.根据SSR标记在染色体上的分布,将和尚麦中所含有的抗病基因定位于1B染色体长臂上.根据该基因在染色体上的位置与抗病谱分析,认为该基因可能是1个新的抗条锈基因.暂定名为yrHe.     

小麦品系西农1163-4抗叶锈病基因的遗传分析和分子作图#br#

【目的】小麦品系西农1163-4高抗小麦叶锈、条锈和白粉病,综合农艺性状良好。明确该小麦品系中所含的抗叶锈病基因及遗传特点,找到与其紧密连锁的分子标记,有利于抗病基因利用和培育抗病新品种。【方法】将西农1163-4与感病品种Thatcher杂交,获得F1、F2代群体,利用中国叶锈菌优势小种THTT进行苗期抗性鉴定和抗性遗传分析;采用SSR技术对西农1163-4所携带的抗叶锈基因进行分子标记研究,共筛选了1 273对SSR引物。【结果】小麦品系西农1163-4对多个叶锈菌小种具有良好的抗病性,对THTT的抗性是由1个显性基因控制,该基因暂命名为LrXi。获得了与LrXi紧密连锁的3个微卫星分子标记Xbarc8、Xgwm582、Xwmc269和1个STS标记(ω-secali/Glu-B3),将LrXi定位于小麦1BL染色体上。距离最近的2个微卫星位点是Xgwm582、Xbarc8,与抗叶锈基因间的遗传距离分别为2.3 cM和3.2 cM。【结论】LrXi位于1BL染色体,抗叶锈表现不同于所有已知抗叶锈病基因,该基因的发现将有利于丰富中国抗叶锈病基因资源,为培育持久抗病品种奠定基础。     

中梁12小麦抗条锈病基因遗传分析与SSR分子定位

中梁12具有抗逆性强、适应性广、抗条锈性强等许多优良的生物学特性。为明确其抗条锈性及遗传规律,利用当前流行的中国条锈菌小种CYR30对抗病品种中梁12与感病品种铭贤169及其杂交后代代F1、F2、F3和BC1代进行苗期抗条锈性遗传分析,并对其抗条锈基因进行SSR分子标记。结果表明,中梁12对CYR30小种具有良好的抗性,由1对显性基因控制,暂命名为YrZh12。该基因与位于小麦7AL染色体上的4个SSR位点Xwmc695、Xcfd20、Xbarc121和Xbarc49连锁,其中最近的侧翼位点为Xcfd20和Xbarc121,其遗传距离分别是3.1cM和4.9cM。系谱分析YrZh12基因可能来自抗引655,由于7AL染色体上没有其他抗条锈病基因,YrZh12可能是一个抗条锈病的新基因。     

巨麦6号抗叶锈病基因的推导和分子定位

巨麦6号在田间表现出很好的抗叶锈性,鉴定其抗叶锈病基因对小麦抗叶锈病育种具有重要意义。在小麦苗期对36个含有已知抗叶锈病基因的对照品种和巨麦6号接种15个中国小麦叶锈菌小种进行抗叶锈病鉴定,推导巨麦6号中可能含有的抗叶锈病基因。以巨麦6号为抗病亲本与感病品种郑州5389进行杂交、自交获得F1、F2代群体,苗期利用叶锈菌小种FHBQ接种F2代群体进行抗叶锈病遗传分析。结果表明,巨麦6号中可能含有已知抗叶锈病基因Lr1,其抗叶锈性由1对显性的抗病基因控制。利用与Lr1共分离的STS标记WR003进一步检测F2单株DNA,结果显示,该标记与抗叶锈病基因共分离,进一步证实巨麦6号携带已知抗叶锈病基因Lr1。     

Inheritance and Molecular Mapping of Stripe Rust Resistance Gene Yr88375 in Chinese Wheat Line Zhongliang 88375

Stripe rust is one of the most important diseases of wheat worldwide. Inheritance of stripe rust resistance and mapping of resistance gene with simple sequence repeat (SSR) markers are studied to formulate efficient strategies for breeding cultivars resistant to stripe rust. Zhongliang 88375, a common wheat line, is highly resistant to all three rusts of wheat in China. The gene conferring rust disease was deduced originating from Elytrigia intermedium. Genetic analysis of Zhongliang 88375 indicated that the resistance to PST race CYR31 was controlled by a single dominant gene, temporarily designated as Yr88375. To molecular map Yr88375, a F2 segregating population consisting of 163 individuals was constructed on the basis of the hybridization between Zhongliang 88375 and a susceptible wheat line Mingxian 169; 320 SSR primer pairs were used for analyzing the genetic linkage relation. Six SSR markers, Xgwm335, Xwmc289, Xwmc810, Xgdm116, Xbarc59, and Xwmc783, are linked to Yr88375 as they were all located on chromosome 5BL. Yr88375 was also located on that chromosome arm, closely linked to Xgdmll6 and Xwmc810 with genetic distances of 3.1 and 3.9 cM, respectively. The furthest marker Xwmc783 was 13.5 cM to Yr88375. Hence, pedigree analysis of Zhongliang 88375 combined with SSR markers supports the conclusion that the highly resistance gene Yr88375 derived from Elytrigia intermedium is a novel gene for resistance to stripe rust in wheat. It could play an important role in wheat breeding programs for stripe rust resistance.     

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

Stripe rust,caused by Puccinia striiformis f.sp.tritici (Pst),is one of the most destructive diseases of wheat (Triticum aestivum L.).To diversify stripe rust-resistant resources for wheat breeding pro...     

Molecular Mapping of a Gene for Resistance to Stripe Rust in Wheat Variety PIW138

Stripe rust, caused by Puccinia striiformis f. sp. tritici （Pst）, is one of the most damaging diseases of common wheat （Triticum aestivum L.）. Wheat variety PIW138 introduced from Pakistan is resistant to the currently prevailing Pst race CYR32 in China. In this study, the bulked segregant analysis （BSA） method and simple sequence repeat （SSR） markers were used to map the stripe rust resistance gene in PIW138. The resistant and susceptible DNA bulks were prepared from the segregating F2 population of the cross between Thatcher, a susceptible variety as the female parent, and PIW138 as the male parent. The segregation of resistant and susceptible F2 plants inoculated with CYR32 indicated that single dominant gene determined the reactions of PIW138 line and temporarily designated as YrP138. Total 200 SSR primers were screened, and 4 SSR markers, Xwmc52, Xbarc61, Xgwm268, and Xgwm153, on chromosome 1B were found to be polymorphic between the resistant and the susceptible DNA bulks as well as their parents. Genetic linkage was tested on the segregating F2 population with 259 plants, including 196 resistant and 63 susceptible plants. All 4 SSR markers were linked to the stripe rust resistance gene in PIW138. The genetic distances of Xwmc52, Xbarc61, Xgwm268, and Xgwm153 to the resistance gene were 29.8, 6.2, 6.8, and 8.2 cM, respectively.     

Genetic Analysis and Molecular Mapping of an All-Stage Stripe Rust Resistance Gene in Triticum aestivum-Haynaldia villosa Translocation Line V3

Triticum aestivum-Hayaldia villosa translocation line V3 has shown effective all-stage resistance to the seven dominant pathotypes of Puccinia striiforms f.sp.tritici prevalent in China.To elucidate the genetic basis of the resistance,the segregating populations were developed from the cross between V3 and susceptible genotype Mingxian 169,seedlings of the parents and F 2 progeny were tested with six prevalent pathotypes,including CYR29,CYR31,CYR32-6,CYR33,Sun11-4,and Sun11-11,F 1 plants and F 3 lines were also inoculated with Sun11-11 to confirm the result further.The genetic studied results showed that the resistance of V3 against CYR29 was conferred by two dominant genes,independently,one dominant gene and one recessive gene conferring independently or a single dominant gene to confer resistance to CYR31,two complementary dominant genes conferring resistance to both CYR32-6 and Sun11-4,two independently dominant genes or three dominant genes（two of the genes show cumulative effect） conferring resistance to CYR33,a single dominant gene for resistance to Sun11-11.Resistance gene analog polymorphism（RGAP） and simple-sequence repeat（SSR） techniques were used to identify molecular markers linked to the single dominant gene（temporarily designated as YrV3） for resistance to Sun11-11.A linkage map of 2 RGAP and 7 SSR markers was constructed for the dominant gene using data from 221 F 2 plants and their derived F 2：3 lines tested with Sun11-11 in the greenhouse.Amplification of the complete set of nulli-tetrasomic lines of Chinese Spring with a RGAP marker RG1 mapped the gene on the chromosome 1B,and then the linked 7 SSR markers located this gene on the long arm of chromosome 1B.The linkage map spanned a genetic distance of 25.0 cM,the SSR markers Xgwm124 and Xcfa2147 closely linked to YrV3 with genetic distances of 3.0 and 3.8 cM,respectively.Based on the linkage map,it concluded that the resistance gene YrV3 was located on chromosome arm 1BL.Given chromosomal location,the reaction patterns and pedigree analysis,YrV3 should be a novel gene for resistance to stripe rust in wheat.These closely linked markers should be useful in stacking genes from different sources for wheat breeding and diversification of resistance genes against stripe rust.     

Genetics and Molecular Mapping of a High-Temperature Resistance Gene to Stripe Rust in Seeding-Stage in Winter Wheat Cultivar Lantian 1

Stripe rust, caused by Puccinia striiformis Westend. f. sp. tritici (Pst), is a severe foliar disease of common wheat (Triticum aestivum L.) in the world. Resistance is the best approach to control the disease. The winter wheat cultivar Lantian 1 has high-temperature resistance to stripe rust. To determing the gene(s) for the stripe rust resistance, Lantian 1 was crossed with Mingxian 169 (M169). Seedlings of the parents, and F 1 , F 2 and F 2-3 progenies were tested with races CYR32 of Pst under controlled greenhouse conditions. Lantian 1 has a single partially dominant gene conferred resistance to race CYR32, designated as YrLT1. Simple sequence repeat (SSR) techniques were used to identify molecular markers linked to YrLT1. A linkage group of five SSR markers was constructed for YrLT1 using 166 F 2 plants. Based on the SSR marker consensus map and the position on wheat chromosome, the resistance gene was assigned on chromosome 2DL. Amplification of a set of nulli-tetrasomic Chinese Spring lines with SSR marker Xwmc797 confirmed that the resistance gene was located on the long arm of chromosome 2D. Because of its chromosomal location and the high-temperature resistance, this gene is different from previously described genes. The molecular map spanned 29.9 cM, and the genetic distance of two close markers Xbarc228 and Xcfd16 to resistance gene locus was 4.0 and 5.7 cM, respectively. The polymorphism rates of the flanking markers in 46 wheat lines were 2.1 and 2.1%, respectively; and the two markers in combination could distinguish the alleles at the resistance locus in 97.9% of tested genotypes. This new gene and flanking markers should be useful in developing wheat cultivars with high level and possible durable resistance to stripe rust.     

Inheritance and Molecular Mapping of Stripe Rust Resistance Gene Yr88375 in Chinese Wheat Line Zhongliang 88375

Stripe rust is one of the most important diseases of wheat worldwide. Inheritance of stripe rust resistance and mapping of resistance gene with simple sequence repeat （SSR） markers are studied to formulate efficient strategies for breeding cultivars resistant to stripe rust. Zhongliang 88375, a common wheat line, is highly resistant to all three rusts of wheat in China. The gene conferring rust disease was deduced originating from Elytrigia intermedium. Genetic analysis of Zhongliang 88375 indicated that the resistance to PST race CYR31 was controlled by a single dominant gene, temporarily designated as Yr88375. To molecular map Yr88375, a F2 segregating population consisting of 163 individuals was constructed on the basis of the hybridization between Zhongliang 88375 and a susceptible wheat line Mingxian 169; 320 SSR primer pairs were used for analyzing the genetic linkage relation. Six SSR markers, Xgwm335, Xwmc289, Xwmc810, Xgdmll6, Xbarc59, and Xwmc783, are linked to Yr88375 as they were all located on chromosome 5BL Yr88375 was also located on that chromosome arm, closely linked to Xgdmll6 and Xwmc810 with genetic distances of 3.1 and 3.9 cM, respectively. The furthest marker Xwmc783 was 13.5 cM to Yr88375. Hence, pedigree analysis of Zhongliang 88375 combined with SSR markers supports the conclusion that the highly resistance gene Yr88375 derived from Elytrigia intermedium is a novel gene for resistance to stripe rust in wheat. It could play an important role in wheat breeding programs for stripe rust resistance.     

小偃6号抗条锈性遗传分析

【目的】小偃6号是20世纪70年代末利用长穗偃麦草基因育成的著名品种，具有高温抗条锈性，研究其抗条锈遗传规律，对揭示其抗病机制和培育持久抗病品种具有重要意义。【方法】在常温[（10±1）℃～（16±1）℃]下，以小偃6号和铭贤169的杂交群体为研究对象，分析遗传规律，利用中国春单体对抗条锈基因进行染色体定位，利用SSR对抗条锈基因进行分子标记。测定所用菌种为Cy28和Cy29-mut3。【结果】小偃6号对CY28、CY29 mut-3的抗病性均由1对显性核基因控制。该抗条锈基因定位在4B染色体上。用4B上的11对SSR引物对该抗条锈基因进行了分子标记，找到了一个与小偃6号抗条锈基因紧密连锁的SSR标记Xgwm 107，这个标记位于4B染色体的长臂上，连锁分析表明其遗传距离为7.08 cM。【结论】经典遗传学分析、单体分析、分子标记研究均支持将小偃6号的常     

Genetics and Molecular Mapping of Stripe Rust Resistance Gene YrShan515in Chinese Wheat Cultivar Shan 515

Stripe rust is one of the most important wheat diseases worldwide. To identify new resistance genes is significant in wheat breeding. In this study, stripe rust resistance of a Chinese cultivar Shah 515 was tested with Chinese predominant races of P. striiformis f. sp. tritici in the seedling stage, and genetic analysis and simple sequence repeats (SSR) technique were used to identify the inheritance model of seedling stripe rust resistance in cultivar Shan 515 and to mark the sites of resistance gene(s) on chromosome. The genetic analysis indicated that the resistance of Shan 515 against Su 11-4 was conferred by a single dominant gene, which was temporarily designated as YrShan515. Using bulked segregant analysis (BSA) and SSR markers, 12 SSR markers (Xwmc335, Xwmc696, Xwmc476, Xbarc267, Xgwm333, Xwmc653, Xwmc396,Xgwm213, Xgwm112, Xgwm274, Xcfd22, Xgwm131, and Xwmc517) located on wheat chromosome 7BL were linked to YrShan515 with genetic distance ranging from 3 to 24 eM. Based on the previously published genetic map and Chinese Spring nulli-tetrasomic analysis, YrShan515 was located on wheat chromosome 7BL. Polymorphism of wheat cuitivars collected from Huanghuai wheat grown regions were screened with two markers, Xwmc653 and Xbarc267, and all of these wheat cultivars tested did not present the polymorphic bands as Shan 515 did. Therefore, it suggested that YrShan515 might be a allele of the available yellow rust resistance gene. The mapping of the new resistance gene in Shan 515 is useful for wheat breeding and diversification of resistance genes against stripe rust in commercial wheat cultivars in China.     

源于中间偃麦草的抗条锈基因YrCH223的遗传分析及SSR定位

CH223是一个衍生于中间偃麦草的多抗性小偃麦种质系,通过感病的小麦品种与八倍体小偃麦TAI7047杂交、回交选育而成。抗性鉴定表明,CH223对我国当前小麦条锈病的流行小种CYR32,CYR33均有良好抗性。利用CH223与感病品种(系)的F2,F2∶3和BC1抗性分离群体进行抗性遗传分析,发现其条锈病抗性来自中间偃麦草,且由1对显性基因控制,暂时命名为YrCH223。用CYR32对来自台长29×CH223的221个F2植株进行接种鉴定,并构建抗、感DNA池。共筛选738对SSR引物,发现5对共显性SSR标记与抗病基因连锁,位置顺序为:Xgwm540-Xbarc1096-YrCH223-Xwmc47-Xwmc310-Xgpw7272,遗传距离分别为21.9,8.0,7.2,12.5,11.3 cM。进一步利用中国春缺体-四体和双端体材料扩增鉴定,将YrCH223定位于小麦4B染色体的长臂上(4BL)。经F2∶3群体验证,5个标记与YrCH223连锁。迄今为止,在4BL上未发现有公开报道的抗小麦条锈病基因。因此,基于抗病基因所在的染色体位置与来源,推断YrCH223是一个新的抗条锈病基因。     

源自ICARDA小麦hm18的抗条锈性研究

源于国际农业干旱研究中心的耐旱型小麦hm18对条锈菌优势生理小种条中33的反应型,不同于目前育种利用的抗条锈基因Yr5、Yr10和Yr15,表现为中度抗病型。用条锈菌小种条中33接种hm18分别与夏440、台长29杂交的F1、F2和F2∶3家系群体进行抗病基因分析。结果表明,hm18在夏440和台长29的遗传背景下对条中33号均表现由1对隐性基因控制的遗传,暂将该基因定名为Yrhm。利用台长29/hm18的F2群体及抗感亲本筛选到4对SSR引物wmc797、barc228、xgwm382和wmc817与Yrhm连锁,遗传距离分别为15.2、6.5、9.3和14.1 cM。根据Mapmarker3.0确定标记引物、Yrhm基因和着丝点在染色体上的顺序为:-着丝点-wmc797-barc228-Yrhm-xgwm382-wmc817-。根据作图结果,将Yrhm基因定位在2DL。     

普通小麦-柔软滨麦草易位系M8657-4抗条锈病基因的遗传分析

[目的]对普通小麦-柔软滨麦草易位系M8657-4的抗条锈病基因进行遗传分析,明确其抗条锈病基因及遗传特点。[方法]用中国小麦条锈菌CYR29、CYR30、CYR31、CYR32、Su11-4及Su11-11共6个生理小种对易位系M8657-4的苗期抗条锈性进行评价;采用常规杂交法对M8657-4的抗条锈病基因进行遗传分析。[结果]易位系M8657-4对中国小麦条锈菌具有良好的抗性;M8657-4对菌系CYR29和Su11-4的抗锈性由2对核基因（互补作用）控制,对CYR31的抗锈性由1对隐性核基因控制,对Su11-11的抗病性,M8657-4做母本时由2对基因（互补作用）控制,M8657-4做父本时由1对隐性基因控制。[结论]易位系M8657-4的抗条锈性由主效基因控制,可将其作为优良种质加以开发利用。     

小麦条锈菌中国鉴别寄主维尔中抗条锈病基因YrVir1的微卫星标记

【目的】明确中国小麦条锈菌重要鉴别寄主维尔的抗条锈病基因及其遗传特点,建立与其连锁的微卫星标记,将病菌小种监测和抗病性分析提高到基因水平。【方法】由维尔为基因供体转育而成的含有小麦重要抗条锈基因YrVir1的近等基因系Taichung29*6/YrVir1,用小麦条锈菌单胞菌系2E16对近等基因系Taichung29*6/YrVir1、轮回亲本Taichung29及其杂交后代进行遗传分析;选用YrVir1所在2B染色体上的141对引物对近等基因系和轮回亲本的基因组DNA进行SSR分析。【结果】近等基因系Taichung29*6/YrVir1对2E16的抗病性由1对显性基因控制;引物Xbarc349在近等基因系与轮回亲本间稳定扩增出特异性DNA片段,同时在近等基因系和基因供体维尔间存在相同扩增片段,经F2代群体200个抗、感单株检测证实,Xbarc349标记位点与抗条锈病基因YrVir1连锁,遗传距离为4.2 cm。【结论】Xbarc349引物扩增出的特异性DNA片段可作为抗条锈病基因YrVir1的SSR标记;根据小麦SSR遗传图谱,将YrVir1基因定位在小麦2B染色体上。