Pm23: a new allele of Pm4 located on chromosome 2AL in wheat

Powdery mildew, caused by Blumeria graminis f. sp. tritici, is one of the major diseases of common wheat (Triticum aestivum) worldwide. The powdery mildew resistance gene Pm23, identified in the common wheat Line 81-7241 and originally assigned to wheat chromosome 5A, was relocated on chromosome 2AL with the aid of molecular markers. Mapping of microsatellite markers in two wheat crosses segregating for Pm23 and Pm4b, respectively, in combination with the reported mapping of Pm4a, indicated that the three genes were all linked to the marker Xgwm356 with a distance of 3-5 cM. Allelism between Pm4b and Pm23 was then confirmed, when the progenies of a cross between VPM1 (Pm4b) and Line 81-7241, were shown to be all resistant to a B. graminis isolate avirulent to the both parents. Pm23 is therefore a new allele of the Pm4 locus, and was redesignated as Pm4c.     

硬粒小麦-粗山羊草双二倍体白粉病抗性的遗传分析与基因推导

对99份硬粒小麦-粗山羊双二倍体用北京地区流行的5号白粉菌生理小种进行了白粉病抗性鉴定,筛选出11个苗期抗病的双二倍体材料和2个全生育期抗病的材料M53和M81。对M53和M81及其硬粒小麦和粗山羊草亲本进行的抗白粉病鉴定结果表明,其抗性来源于粗山羊草。与M53和M81具有相同硬粒小麦亲本、不同粗山羊草亲本双二倍体的抗性结果也表明抗性基因来源于粗山羊草。对M53和M81的抗性遗传分析表明,它们均携带1个单显性抗病基因。用14个白粉菌生理小种对已知抗病基因品系与M53和M81两份待测材料进行接种鉴定,结果表明,M53和M81与已知基因的抗菌谱均不相同,M53与M81的抗菌谱也不相同,说明M53和M81各自分别携带1个新的显性抗白粉病基因。     

Gene-for-gene interactions between the rye mildew fungus and wheat cultivars.

Genetic mechanisms of the incompatibility between Erysiphe graminis f.sp. secalis and wheat cultivars were analyzed using F1 hybrids between E. graminis f.sp. secalis, Sk-1, and f.sp. tritici, Tk-1. The avirulence of Sk-1 on Triticum aestivum 'Norin 4', 'Chinese Spring', and 'Kokeshi-komugi' was controlled by a single gene. The resistance of the three cultivars to Sk-1 was also controlled by a single gene, Pm15, a gene for resistance to E. graminis f.sp. agropyri. Implications of these results were discussed in terms of host-parasite coevolution.     

The barley apoptosis suppressor homologue BAX inhibitor-1 compromises nonhost penetration resistance of barley to the inappropriate pathogen Blumeria graminis f. sp. tritici

BAX inhibitor-1 (BI-1) proteins have been characterized as suppressors of programmed cell death in mammals and plants. The barley BI-1 is a suppressor of nonspecific background resistance and mlo-mediated penetration resistance to the biotrophic fungal pathogen Blumeria graminis f. sp. hordei when overexpressed in epidermal cells of barley. We report here that BI-1 expression is also slightly up-regulated during interaction with the inappropriate wheat pathogen Blumeria graminis f. sp. tritici. Significantly, overexpression of BI-1 in single epidermal cells of barley by microprojectile-mediated transformation rendered cells susceptible to penetration by inappropriate B. graminis f. sp. tritici. The degree of transgene-induced accessibility to B. graminis f. sp. tritici was thereby similar to the effect achieved by overexpression of the defense suppressor gene Mlo and could not be further enhanced by double expression of both BI-1 and Mlo. Confocal laser scanning microscopy was used to locate a functional green fluorescing GFP:BI-1 fusion protein in endomembranes and the nuclear envelope of barley epidermal cells. Together, enhanced expression of barley BI-1 suppresses penetration resistance to B. graminis f. sp. tritici, linking barley nonhost resistance with cell death regulation.     

Powdery mildew resistance genes in wheat: verification of STS markers

Five accessions of Aegilops speltoides and 67 European wheat cultivars (winter and spring) originating from the Czech Republic, Germany, Poland, Russia, Slovakia, United Kingdom, and 4 non-European wheat cultivars from Brazil and the USA were examined with molecular Sequence Tagged Site (STS) markers for resistance genes to powdery mildew: Pm 1, Pm 2, Pm 3 and Pm 13. All markers gave clear, repeatable results, although three of them (Pm 1, Pm 2 and Pm 3) appeared as not specific for resistance genes. Comparison of STS analysis results with Pm genes, postulated as the reaction type after inoculation with differential isolates of Erysiphe graminis f.sp. tritici (Blumeria graminis), revealed a high number of disparities. The marker for Pm 13 was not detected in any examined cultivar but was present in five accessions of Aegilops speltoides.     

普通小麦99-2439 中的白粉病抗性遗传

普通冬小麦品系99-2439在郑州连续4年对田间白粉菌(Blumeria graminis sp. tritici)表现高抗,但其抗性基因来源不清。通过染色体C-分带和1RS染色体特异性SCAR标记鉴定, 表明它是一个小麦-黑麦(Triticum aestivum - Secale cereale)1BL/1RS异易位系。通过对中国春×99-2439杂交F2代分离群 体抗性鉴定和1RS染色体臂检测结果分析, 证明该抗病基因不在1RS染色体臂上。用单孢小麦白粉菌分离株对其抗性遗传进行研究, 结果表明, 99-2439的白粉病抗性由一对小种专化、隐性抗病基因控制。由于携带Pm5a的Hope/8Cc对中国的21个小麦白粉菌分离菌株均高度感病, 而99-2439高抗混和白粉菌和5个单孢分离菌株, 所以, 99-2439所携带的抗白粉病基因不同于Pm5a。     

RFLP markers linked to powdery mildew resistance genes Pm1, Pm2, Pm3, and Pm4 in wheat.

Near-isogenic lines (NILs) and their recurrent parent Chancellor (Cc) were used to identify restriction fragment length polymorphic markers linked to powdery mildew (Blumeria graminis (DC.) E.O. Speer f.sp. tritici) resistance genes Pm1, Pm2, Pm3, and Pm4 in wheat (Triticum aestivum L. em. Thell). By mapping these polymorphic markers in F2 progenies from crosses of the NILs with Cc, it was found that Pm1 cosegregated with a polymorphic locus detected by DNA probe CDO347; Pm2 was linked to a locus detected by probe BCD1871 with a distance of 3.5 cM; Pm3b was linked to a locus detected by probe BCD1434 with a distance of 1.3 cM; Pm4a cosegregated with Xbcd1231-2A(2) and Xcdo678-2A, and was closely flanked by Xbcd1231-2A(1) and Xbcd292-2A both with a distance of 1.5 cM. Aneuploid mapping of these markers indicated that locus Xcdo347-7A is on 7AL, Xbcd1871-5D on 5DS, Xbcd1434-1A on 1AS, and loci Xbcd292-2A and Xcdo678-2A are on 2AL. The same polymorphic fragments detected in the Pm3b NIL by Xbcd1434-1A were found in Pm3a NIL using several enzyme digestions.     

Powdery mildew resistance gene <Emphasis Type="Italic">Pm22</Emphasis> in cultivar Virest is a member of the complex <Emphasis Type="Italic">Pm1</Emphasis> locus in common wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L. em Thell.)

The powdery mildew resistance gene Pm22, identified in the Italian wheat cultivar Virest and originally assigned to wheat chromosome 1D, was mapped to chromosome 7A with the aid of molecular markers. Mapping of common AFLP and SSR markers in two wheat crosses segregating for Pm22 and Pm1c, respectively, indicated that Pm22 is a member of the complex Pm1 locus. Pm22 also showed a pattern of resistance reaction to a differential set of Blumeria graminis f. sp. tritici isolates that was distinguishable from those from other Pm1 alleles in lines Axminster/8*Cc ( Pm1a), MocZlatka ( Pm1b), Weihenstephan Stamm M1N ( Pm1c) and Triticum spelta var. duhamelianum TRI 2258 ( Pm1d). Based on these results, the gene symbol Pm1e is proposed for the powdery mildew resistance gene in cv. Virest.     

Allelic series of four powdery mildew resistance genes at the Pm3 locus in hexaploid bread wheat

At the Pm3 locus in hexaploid wheat (Triticum aestivum), 10 alleles conferring race-specific resistance to powdery mildew (Blumeria graminis f. sp. tritici) are known. A cluster of genes encoding coiled-coil-nucleotide-binding site-leucine-rich repeat proteins spans the Pm3 locus on wheat chromosome 1A, and one member of this gene family has recently been identified as the Pm3b resistance gene. Using molecular markers closely linked to Pm3b, we performed haplotype analysis of 10 lines carrying different Pm3 alleles. All these lines have a conserved genomic region delimited by markers cosegregating with Pm3b and including a structurally conserved Pm3b-like gene. A polymerase chain reaction-based strategy allowed the amplification of one Pm3b-like sequence from lines carrying Pm3a, Pm3d, and Pm3f alleles. These candidate genes for Pm3a, Pm3d, and Pm3f conferred AvrPm3a-, AvrPm3d-, and AvrPm3f-dependent resistance, respectively, to wheat powdery mildew in a single cell transient transformation assay. A high level of amino acid similarity (97.8%) was found between the PM3A, PM3B, PM3D, and PM3F proteins. The coiled-coil domain was 100% conserved, whereas, in the nucleotide binding site region, sequence exchange was detected, indicating intragenic recombination or gene conversion between alleles. All these results indicate that Pm3a, Pm3b, Pm3d, and Pm3f form a true allelic series. The low level of sequence divergence between the four characterized alleles as well as the finding of a conserved Pm3 haplotype are in agreement with the hypothesis of a recent evolution of Pm3-based resistance, suggesting that some or most of the diversity found at the Pm3 locus in modern wheat has evolved after wheat domestication.     

小麦硫代硫酸硫转移酶类似基因的克隆与定位

小麦-簇毛麦6VS/6AL易位系92R137含有抗白粉病基因Pm21。为了研究该易位系的抗病机理,应用mRNA差异显示和快速扩增cDNA未端（Rapid Amplification of cDNAEnd,RACE)技术对在白粉菌诱导后表达增强的基因进行了克隆,分离到1个命名为TaTST的全长cDNA序列。Northern杂交分析表明,TaTST基因在白粉菌诱导后表达明显增强,24h达到峰值,氨基酸序列同源性分析表明,TaTST与Datisca glomerata的硫代硫酸硫转移酶基因（rho-danese,EC,2.8.1.1)序列有64%相同,80%相似,用中国春缺体/四体系和端体系Southern杂交和基因特异性引物扩增（gene specific primer-PCR)将TaTST基因定位在小麦6B染色体短臂上,Southern杂交表明,该基因为单拷贝基因,由于在杨麦5号和6VS/6AL易位系间存在明显多态,可以推测在6VS上有TaTST的同源基因,TaTST是从小麦中分离的新基因。白粉菌诱导后的表达变化提示;TaTST与小麦抗白粉病反应有关。     

Cloning of a Resistance Gene Analog from Wheat and Development of a Codominant PCR Marker for Pm21

To Investigate the mechanism of resistance to wheat （Triticum aestivum L.） powdery mildew, suppression subtractlve hybridization was conducted between an isogenic resistant line carrying Pm21 and its recurrent parent Yangmal 5 to Isolate the resistance relative genes. A cDNA fragment specifically expressed in the resistant line was obtained and its full length was cloned by in silico cloning and RT-PCR. This gene encoded a deduced protein of 219 amino acids with a leucine-rich repeat （LRR） motif, often found In plant resistance genes, and was designated as Ta-LRR2. Ta-LRR2 had an increased expression level in the resistant line after Inoculation with Erysiphe graminis DC. f. sp. tritici Marchal. PCR analysis with different cytogenetlc stocks suggested that Ta-LRR2 was specifically associated with chromosome arms 6VS and 6AS. Linkage analysis further showed that Ta-LRR2 could be used as a resistance gene analog polymorphism marker of Pm21 for marker-assisted selection in germplasm enhancement and breeding practice. Moreover, how to Isolate Pm21 based on the Information obtained for Ta-LRR2 is discussed.     

54份CIMMYT小麦材料抗白粉病分析

选用来自我国不同地区的20个白粉病菌毒性菌株,对54个CIMMYT小麦品种(系)进行抗病性分析.结果表明:(1)34个品种(系)含有抗病基因,以Pm8基因出现频率最高,有15个品种(系)携带该基因;(2)参试主效基因中,Pm1、Pm3e、Pm5、Pm6和Pm7基因已丧失对我国白粉菌的抗性,Pm16和Pm20基因的抗性最强;(3)50个1B/1R易位系品种(系)中31个含有抗病基因,48%的抗病1B/1R易位系可检测到Pm8基因.根据田间成株期病程曲线下面积(AUDPC)聚类分析结果,可将54份材料分为高抗、中抗、中感和高感4类,7个品种(系)不含任何主效抗病基因而田间表现中到高的抗性,是典型慢病性品种.     

Expression of resistance to Blumeria graminis f.sp. tritici in 'Chinese Spring' wheat addition lines containing chromosomes from Hordeum vulgare and H. chilense

Blumeria graminis f.sp. tritici (syn. Erysiphe graminis f.sp. tritici) causes an important disease of wheat (powdery mildew) to which Hordeum vulgare and H. chilense are resistant. The study of chromosomal addition lines of H. vulgare and H. chilense in wheat showed that they possessed resistance to wheat powdery mildew. This was expressed as a reduction of disease severity but it was not associated with increased macroscopically visible necrosis. The resistance is of broad genetic basis, conferred by gene(s) present on different chromosomes of both H. vulgare and H. chilense. The feasibility of transferring this resistance to wheat is discussed.     

荧光素钠和考马斯亮蓝应用于小麦白粉病菌染色效果比较*

比较了荧光素钠和考马斯亮蓝应用于小麦白粉病菌染色的效果。荧光素钠法中样品处理只需20min.左右,具有直接、快速的特点;荧光指示剂对病菌分生孢子萌发及菌丝生长无抑制作用,主要沉集于活菌体的隔膜和细胞质部位,使病菌产生明显的亮绿荧光和清晰的细胞轮廓,亮绿荧光衰退期为7min.;借助荧光显微镜可以观察病菌在小麦叶表的发展过程,区别活菌体和失活菌体。考马斯亮蓝法包括传统的组织学染色步骤,经过改进后的样品处理过程需要40min.左右;染色后使寄主组织呈现淡蓝色,病菌菌体染成深蓝色;该方法可以观察病菌在小麦叶表和被侵染细胞内部发育形成的结构,包括孢子发育形成的初生芽管、附着胞芽管、成熟附着胞以及在寄主细胞内形成的初生吸器原体、成熟的指状体吸器和次生吸器。     

Genetic mapping of three alleles at the Pm3 locus conferring powdery mildew resistance in common wheat (Triticum aestivum L.).

A set of differential isolates of Blumeria graminis f.sp. tritici was used to identify 10 alleles at the Pm3 locus on the short arm of chromosome 1A. Three F3 populations were used to map Pm3h in Abessi, Pm3i in line N324, and Pm3j alleles in GUS 122 relative to microsatellite markers. In total, 13 marker loci were mapped on chromosome 1AS and 1 marker on 1AL. The order of marker loci in the 3 mapping populations is consistent with previously published maps. All 3 alleles were mapped in the distal region of chromosome 1AS. The present study indicated that microsatellite markers are an ideal marker system for comparative mapping of alleles at the same gene locus in different mapping populations. The linkage distances of the closest microsatellite marker, Xgwm905-1A, to Pm3h, Pm3i, and Pm3j were 3.7 cM, 7.2 cM, and 1.2 cM, respectively. The microsatellite marker Xgwm905-1A cannot be used to distinguish between Pm3 alleles. The development of specific markers for individual Pm3 alleles is discussed on the basis of the recently cloned Pm3b allele.     

小麦抗白粉病基因Pm6的RAPD标记

从提莫菲维小麦转移到普通小麦中的小麦白粉病抗性基因Ｐｍ６是小麦白粉病（Ｅｒｙｓｉｐｈｅ ｈｒａｍｉｎｉｓ ｆ ｓｐ．ｔｒｉｔｉｃｉ）的有效抗性基因。用７００个随机引物对Ｐｍ６近等基因系进行ＲＡＰＤ分析,发现引物ＯＰＶ２０可在抗病近等基因系中产生大小为２ｋｂ的稳定的多态片段。用该引物检测１０个其他携Ｐｍ６的渐渗系材料,均可稳定扩增出该２ｋｂ的多态片段。理一步用ＯＰＶ２０对Ｐｍ６Ｆ２（ＩＧＶ１－４６３     

普通小麦99-2439中的白粉病抗性遗传

普通冬小麦品系99-2439在郑州连续4年对田间白粉菌(Blumeria graminis sp.tritici)表现高抗,但其抗性基因来源不清.通过染色体C-分带和IRS染色体特异性SCAR标记鉴定,表明它是一个小麦-黑麦(Triticum aestivum-Secale cereale)lBL/1RS异易位系.通过对中国春×99-2439杂交F2代分离群体抗性鉴定和1RS染色体臂检测结果分析,证明该抗病基因不在1RS染色体臂上.用单孢小麦白粉菌分离株对其抗性遗传进行研究,结果表明,99-2439的白粉病抗性由一对小种专化、隐性抗病基因控制.由于携带Pm5a的Hope/8Cc对中国的21个小麦白粉菌分离菌株均高度感病,而99-2439高抗混和白粉菌和5个单孢分离菌株,所以,99-2439所携带的抗白粉病基因不同于Pm5a.     

Transient transformation of the rust fungus Puccinia graminis f. sp. tritici

The biotrophic rust fungus Puccinia graminis f. sp. tritici (Pgt) was transformed by particle bombardment. The promoter from the Pgt translation elongation factor 1alpha (EF-1alpha) gene was fused to the bacterial marker genes hygromycin B phosphotransferase (hpt) and beta-glucuronidase (GUS). Transformation constructs were introduced into uredospores of Pgt, an obligate pathogen of wheat, by biolistic bombardment. Uredospores transformed with the construct containing the hpt gene germinated and initiated branching on selective medium, indicating that they had acquired resistance to hygromycin B. However, transformants stopped growing 5 days after bombardment. GUS activity in uredospores and germlings was histochemically detected 4-16 h after bombardment. GUS expression was also obtained using the INF24 promoter from the bean rust fungus Uromyces appendiculatus, demonstrating that heterologous genes can be expressed in P. graminis under the control of regulatory sequences from closely related organisms.     

Transgenic Pm3 multilines of wheat show increased powdery mildew resistance in the field

Resistance (R) genes protect plants very effectively from disease, but many of them are rapidly overcome when present in widely grown cultivars. To overcome this lack of durability, strategies that increase host resistance diversity have been proposed. Among them is the use of multilines composed of near-isogenic lines (NILs) containing different disease resistance genes. In contrast to classical R-gene introgression by recurrent backcrossing, a transgenic approach allows the development of lines with identical genetic background, differing only in a single R gene. We have used alleles of the resistance locus Pm3 in wheat, conferring race-specific resistance to wheat powdery mildew (Blumeria graminis f. sp. tritici), to develop transgenic wheat lines overexpressing Pm3a, Pm3c, Pm3d, Pm3f or Pm3g. In field experiments, all tested transgenic lines were significantly more resistant than their respective nontransformed sister lines. The resistance level of the transgenic Pm3 lines was determined mainly by the frequency of virulence to the particular Pm3 allele in the powdery mildew population, Pm3 expression levels and most likely also allele-specific properties. We created six two-way multilines by mixing seeds of the parental line Bobwhite and transgenic Pm3a, Pm3b and Pm3d lines. The Pm3 multilines were more resistant than their components when tested in the field. This demonstrates that the difference in a single R gene is sufficient to cause host-diversity effects and that multilines of transgenic Pm3 wheat lines represent a promising strategy for an effective and sustainable use of Pm3 alleles.     

Genome analysis at different ploidy levels allows cloning of the powdery mildew resistance gene Pm3b from hexaploid wheat

In wheat, race-specific resistance to the fungal pathogen powdery mildew (Blumeria graminis f. sp. tritici) is controlled by the Pm genes. There are 10 alleles conferring resistance at the Pm3 locus (Pm3a to Pm3j) on chromosome 1AS of hexaploid bread wheat (Triticum aestivum L.). The genome of hexaploid wheat has a size of 1.6 x 1010 bp and contains more than 80% of repetitive sequences, making positional cloning difficult. Here, we demonstrate that the combined analysis of genomes from wheat species with different ploidy levels can be exploited for positional cloning in bread wheat. We have mapped the Pm3b gene in hexaploid wheat to a genetic interval of 0.97 centimorgan (cM). The diploid T. monococcum and the tetraploid T. turgidum ssp. durum provided models for the A genome of hexaploid wheat and allowed to establish a physical contig spanning the Pm3 locus. Although the haplotypes at the Pm3 locus differed markedly between the three species, a large resistance gene-like family specific to wheat group 1 chromosomes was consistently found at the Pm3 locus. A candidate gene for Pm3b was identified using partial sequence conservation between resistant line Chul and T. monococcum cv. DV92. A susceptible Pm3b mutant, carrying a single-base pair deletion in the coding region of the candidate gene was isolated. When tested in a single cell transformation assay, the Pm3b candidate gene conferred race-specific resistance to powdery mildew. These results demonstrate that the candidate gene, a member of the coiled-coil nucleotide binding site leucine-rich repeat (NBS-LRR) type of disease resistance genes, is the Pm3b gene.