Mapping QTL for resistance to eyespot of wheat in Aegilops longissima

Eyespot is an economically important disease of wheat caused by the soilborne fungi Oculimacula yallundae and O. acuformis. These pathogens infect and colonize the stem base, which results in lodging of diseased plants and reduced grain yield. Disease resistant cultivars are the most desirable control method, but resistance genes are limited in the wheat gene pool. Some accessions of the wheat wild relative Aegilops longissima are resistant to eyespot, but nothing is known about the genetic control of resistance. A recombinant inbred line population was developed from the cross PI 542196 (R) × PI 330486 (S) to map the resistance genes and better understand resistance in Ae. longissima. A genetic linkage map of the S(l) genome was constructed with 169 wheat microsatellite markers covering 1261.3 cM in 7 groups. F(5) lines (189) were tested for reaction to O. yallundae and four QTL were detected in chromosomes 1S(l), 3S(l), 5S(l), and 7S(l). These QTL explained 44 % of the total phenotypic variation in reaction to eyespot based on GUS scores and 63 % for visual disease ratings. These results demonstrate that genetic control of O. yallundae resistance in Ae. longissima is polygenic. This is the first report of multiple QTL conferring resistance to eyespot in Ae. longissima. Markers cfd6, wmc597, wmc415, and cfd2 are tightly linked to Q.Pch.wsu-1S ( l ), Q.Pch.wsu-3S ( l ), Q.Pch.wsu-5S ( l ), and Q.Pch.wsu-7S ( l ), respectively. These markers may be useful in marker-assisted selection for transferring resistance genes to wheat to increase the effectiveness of resistance and broaden the genetic diversity of eyespot resistance.     

Linkage mapping of prolamin and isozyme genes on the 1Sl chromosome of Aegilops longissima

The storage proteins and isozymes of two accessions of Aegilops longissima, and the F₂ progeny from the cross between them, were analyzed. Six loci were identified on the 1S^l chromosome: Glu-S ^l 1 (coding for HMW subunits of glutenin), Gpi-S ^l 1 (coding for a Gpi isozyme), Glu-S ^l 3 (coding for LMW subunits of glutenin), Gli-S ^l 1 (coding for gliadins) and two, so far, not described new loci Gli-S ^l 4 and Gli-S ^l 5. The Gli-S ^l 4 locus codes for a -gliadin and the Gli-S ^l 5 codes for a gliadin with mobility in the -region. The genetical distances found between the six loci allowed the establishment of the following gene order on the 1S^l chromosome: Glu-S ^l 1 —centromere —Gpi-S ^l 1 — Gli-S ^l 4 — Gli-S ^l 3 — Gli-S ^l 1 -Gli-S ^l 5.     

高大山羊草Aegilops longissima puroindoline b基因的克隆与表达分析

籽粒硬度是小麦加工品质的重要影响因素。puroindoline a（Pina）和puroindoline b（Pinb）是控制小麦籽粒硬度的主效基因。根据已报导的小麦Pinb基因的保守序列,设计合成了一对特异性引物,对高大山羊草Aegilops longissima（SS）的基因组DNA和胚乳RNA进行Pinb基因扩增、克隆、序列测定和表达分析,发现了一个新型Pinb等位基因。基因长360bp,编码119个氨基酸残基,对应于麦类作物Puroindoline B（PinB）成熟蛋白的结构区域,具有麦类作物Pinb基因特有的WPTKWWK的色氨酸结构域基因序列和10个半胱氨酸所形成的5个二硫键结构。与软粒小麦cv．Capitole的Pinb—D1a相比较,其核苷酸和氨基酸同源性分别为93．3％和92．4％。RT—PCR证实了Pinb基因在籽粒胚乳中的表达。研究结果表明,高大山羊草中包含着与小麦差异较大的籽粒硬度控制基因,为栽培小麦品质改良提供了丰富的遗传资源。     

Callus induction and organogenesis in wheat/Aegilops longissima chromosome addition lines

The influence of individual Aegilops longissima addition chromosomes on callus induction and organogenesis of in vitro cultivated immature embryos of wheat was studied. Immature 14-day-old embryos of seven Chinese Spring lines with added chromosomes of Aegilops longissima were in vitro cultivated. Although relatively high number of calli were formed in embryo cultures of all lines studied, the different genotypes expressed variation in respect to their response to in vitro cultivation. The number of initiated calli of line D, containing chromosome l l arms 7S L and 4S L was relatively low. The lines showed substantial differences in respect to the number of initiated morphogenic calli and regenerants recovered. The highest number of morphogenic calli and regenerants l l l were obtained in cultures of lines containing the chromosomes 2S , 6S and to less extend 3S.     

Identification of molecular markers linked to Pm13, an Aegilops longissima gene conferring resistance to powdery mildew in wheat

 RFLP, RAPD, STS and DDRT-PCR techniques were applied to find molecular markers linked to Pm13, an Aegilops longissima gene conferring resistance to powdery mildew in wheat. The experimental strategy was based on the differential comparison of DNAs from common wheat and from common wheat/Ae. longissima recombinant lines carrying short segments of the 3S ^l S chromosome arm containing the Pm13 gene. Sixteen RFLP clones that detect loci previously located in the short arms of group-3 wheat chromosomes were screened for their ability to hybridise to Ae. longissima restriction fragments derived from the 3S ^l S segments introgressed into the recombinant lines. Eight RFLP clones and one STS marker detected 3S ^l S-specific fragments whose location relative to the wheat-alien chromatin breakage point of the recombinant lines was determined. Four amplification products were identified through the screening of about 200 RAPD primers. Their polymorphism was associated with the introgression of the alien DNA. One of the differential fragments was derived from the 3S ^l S DNA segment, while the remaining three corresponded to the replaced 3DS DNA. Further analyses carried out using 40 combinations of DDRT-PCR primers detected an additional reproducible polymorphism associated with the presence of 3S ^l S DNA. In view of their possible utilisation in Pm13 marker-assisted selection, differentially amplified RAPD and DDRT-PCR fragments were cloned, transformed into RFLP markers and converted into STS markers. Received: 23 March 1998 / Accepted: 5 August 1998     

The incorporation and characterization of powdery mildew resistance from Aegilops longissima in common wheat (T. aestivum L.)

Summary In the progeny of a hybrid between monotelosomic line 3B of Chinese Spring wheat and Chinese Spring — Aegilops longissima ditelosomic addition line G a cytologically stable strain was selected consisting of 20 wheat chromosome pairs, one pair of telosomic chromosome 3BL and one pair of telosomic longissima chromosome G. Inoculating Chinese Spring — Aegilops longissima addition and substitution lines with ten different powdery mildew isolates, partial resistance was observed. The infection grade as well as the number of spores/cm² leaf area were significantly reduced.     

Mapping genes for resistance to Leptosphaeria maculans in Brassica juncea.

Blackleg disease of crucifers, caused by the fungus Leptosphaeria maculans, is a major concern to oilseed rape producers worldwide. Brassica species containing the B genome have high levels of resistance to blackleg. Brassica juncea F2 and first-backcross (B1) populations segregating for resistance to a PG2 isolate of L. maculans were created. Segregation for resistance to L. maculans in these populations suggested that resistance was controlled by two independent genes, one dominant and one recessive in nature. A map of the B. juncea genome was constructed using segregation in the F2 population of a combination of restriction fragment length polymorphism (RFLP) and microsatel lite markers. The B. juncea map consisted of 325 loci and was aligned with previous maps of the Brassica A and B genomes. The gene controlling dominant resistance to L. maculans was positioned on linkage group J13 based on segregation for resistance in the F2 population. This position was confirmed in the B1 population in which the resistance gene was definitively mapped in the interval flanked by pN199RV and sB31143F. The provisional location of the recessive gene controlling resistance to L. maculans on linkage group J18 was identified using a subset of informative F2 individuals.     

Mapping spot blotch resistance genes in four barley populations

Bipolaris sorokiniana (teleomorph: Cochliobolus sativus) is the fungal pathogen responsible for spot blotch in barley (Hordeum vulgare L.) and occurs worldwide in warmer, humid growing conditions. Current Australian barley varieties are largely susceptible to this disease and attempts are being made to introduce sources of resistance from North America. In this study we have compared chromosomal locations of spot blotch resistance reactions in four North American two-rowed barley lines; the North Dakota lines ND11231-12 and ND11231-11 and the Canadian lines TR251 and WPG8412-9-2-1. Diversity arrays technology-based PCR, expressed sequence tag and SSR markers have been mapped across four populations derived from crosses between susceptible parental lines and these four resistant parents to determine the location of resistance loci. Quantitative trait loci (QTL) conferring resistance to spot blotch in adult plants (APR) were detected on chromosomes 3HS and 7HS. In contrast, seedling resistance (SLR) was controlled solely by a locus on chromosome 7HS. The phenotypic variance explained by the APR QTL on 3HS was between 16 and 25% and the phenotypic variance explained by the 7HS APR QTL was between 8 and 42% across the four populations. The SLR QTL on 7HS explained between 52 and 64% of the phenotypic variance. An examination of the pedigrees of these resistance sources supports the common identity of resistance in these lines and indicates that only a limited number of major resistance loci are available in current two-rowed germplasm.     

Molecular cloning and characterization of four novel LMW glutenin subunit genes from Aegilops longissima, Triticum dicoccoides and T. zhukovskyi

This paper reports cloning and characterisation of four novel low-molecular-weight glutenin subunit (LMW-GS) genes (designated as TzLMW-m2, TzLMW-m1, TdLMW-m1 and AlLMW-m2) from the genomic DNA of Triticum dicoccoides, T. zhukovskyi and Aegilops longissima. The coding regions of TzLMW-m2, TzLMW-m1, TdLMW-m1 and AlLMW-m2 were 1056 bp, 903 bp, 1056 bp and 1050 bp in length, encoding 350, 300, 350 and 348 amino acid residues, respectively. The deduced amino acid sequences showed that the four novel genes were classified as LMW-m types and the comparison results indicated that the four genes had a more similar structure and a higher level of homology with the LMW-m genes than the LMW-s and -i types genes. However, the first cysteine residue's positions of TzLMW-m2, TdLMW-m1 and AlLMW-m2 were different from the others. Moreover, AlLMW-m2, TdLMW-m1 and TzLMW-m2 all possessed a longer repetitive domain, which was considered to be associated with good quality of wheat. The secondary structure prediction revealed that the content of beta-strand in AlLMW-m2 and TdLMW-m1 exceeded the positive control, suggesting that AlLMW-m2 and TdLMW-m1 should be considered as candidate genes that may have positive effect on dough quality. In order to investigate the evolutionary relationship of the novel genes with the other LMW-GSs, a phylogenetic tree was constructed. The results lead to a speculation that AlLMW-m2, TdLMW-m1 and TzLMW-m2 may be the middle types during the evolution of LMW-m and LMW-s.     

Mapping soybean aphid resistance genes in PI 567598B

The soybean aphid (Aphis glycines Matsumura) has been a major pest of soybean [Glycine max (L.) Merr.] in North America since it was first reported in 2000. Our previous study revealed that the strong aphid resistance of plant introduction (PI) 567598B was controlled by two recessive genes. The objective of this study was to locate these two genes on the soybean genetic linkage map using molecular markers. A mapping population of 282 F_4:5 lines derived from IA2070 × E06902 was evaluated for aphid resistance in a field trial in 2009 and a greenhouse trial in 2010. Two quantitative trait loci (QTLs) were identified using the composite and multiple interval mapping methods, and were mapped on chromosomes 7 (linkage group M) and 16 (linkage group J), respectively. E06902, a parent derived from PI 567598B, conferred resistance at both loci. In the 2010 greenhouse trial, each of the two QTLs explained over 30 % of the phenotypic variation. Significant epistatic interaction was also found between these two QTLs. However, in the 2009 field trial, only the QTL on chromosome 16 was found and it explained 56.1 % of the phenotypic variation. These two QTLs and their interaction were confirmed with another population consisting of 94 F_2:5 lines in the 2008 and 2009 greenhouse trials. For both trials in the alternative population, these two loci explained about 50 and 80.4 % of the total phenotypic variation, respectively. Our study shows that soybean aphid isolate used in the 2009 field trial defeated the QTL found on chromosome 7. Presence of the QTL on chromosome 16 conferred soybean aphid resistance in all trials. The markers linked to the aphid-resistant QTLs in PI 567598B or its derived lines can be used in marker-assisted breeding for aphid resistance.     

高大山羊草(Aegilops longissima Schweinf.and Muschl.)遗传多样性的RAPD分析

通过70个 RAPD 引物对高大山羊草15份材料进行扩增,共扩增出766条带,其中无多态性(即相同带)的带115条,占总带数的15%,有多态性的带651条,占总带数的85%。通过分析,发现高大山羊草的 Y315、Y316、Y317与其它12份材料差异很大,这3份材料的特异带有253条,占整个多态性带数的38.9%。经 NTSYS 系统聚类表明,高大山羊草 Y315、Y316、Y317这3份材料为一个类群,而其余12份材料为另一类群;这2个类群中任何一份山羊草与另一类群中任何一份山羊草的遗传距离均很大,变幅为1.38～1.58,是它们各自类群内遗传距离的3倍以上。鉴于这两类材料在分子水平的 RAPD 扩增产物上差异很大,并考虑到这两个类群在形态上也确实存在明显差异,因而建议将高大山羊草分为两个亚种,当然这一观点还有待收集更多的材料做进一步的研究。     

Effect of eyespot caused by Oculimacula yallundae and O. acuformis, assessed visually and by competitive PCR, on stem strength associated with lodging resistance and yield of winter wheat

Winter wheat, (cv. Consort) was inoculated with three isolates of either Oculimacula yallundae or O. acuformis to determine the effect of eyespot caused by each species on yield and lodging resistance of winter wheat. Plants were visually assessed for disease incidence and severity, and pathogen DNA was quantified at GS 33 and GS 60. At early milk development of the crop (GS 72), 900 main shoots were also visually assessed for the disease and subjected to mechanical tests for stem strength. Pathogen DNA was extracted from each shoot and quantified using competitive polymerase chain reaction (PCR). Although slight and moderate eyespot lesions caused by either species had no effect on ear weight, severe lesions caused by O. acuformis and O. yallundae reduced ear weight by 3% and 7%, respectively. Stem lodging failed to occur at the site; however, yield losses of 11% for O. acuformis and 6% for O. yallundae were observed. Visual assessment failed to reveal differences between species in their effect on plant characteristics, stem bending strength, or stem safety factor. PCR data, however, showed that the two species had similar effects determined by different DNA concentrations. Both species reduced lodging resistance (stem safety factor) compared with the control. In contrast to healthy plants, where reductions were related predominantly to the height and weight distribution of the plants, the observed reductions of stem lodging resistance in infected plants with Oculimacula spp. were associated primarily with reductions in stem bending strength.     

山羊草Aegilops kotschyi及其供体种Ae.longissima和Ae.umbellulata的醇溶蛋白研究

采用酸性聚丙烯酰胺凝胶电泳(APAGE)法对11份A担心Aegilops kotschyi及其S^1染色体组供体种Ae.longissima2份和U染色体组供体种Ae.umbellulata6份进行了醇溶蛋白位点的研究。结果表明：11份Ae.kotschyi共分离出32条带,31条具有多态性,占96．88％,每份材料可以分离出10-17条谱带,其中仅1条(3．12％)是共有带;11份Ae.kotschyi的遗传距离的变异范围在0-0.704之间,平均为0．409;11份Ae.kotschyi分离出的多数醇溶蛋白谱带均与其染色体组供体种Ae.longissi-ma及Ae.umbellulata相同,但仍有8条谱带未在两供体种中找到;11份Ae.kotschyi的醇溶蛋白多态性(96．88％)明显高于Ae.longissima(52．94％)与Ae.umbellulata(88．89％)11份Ae.kotschyi中有4份表现出了一定的特征带,分析知可能在γ区发生了较大的变异。     

Genomic changes at early stages of formation of allopolyploid Aegilops longissima x Triticum urartu

Using the model of synthetic allopolyploid Aegilops longissima TL05 x Triticum urartu TMU06 of the first generation, the degree and character of changes in subtelomeric, microsatellite and random amplified DNA sequences (RAPD) on early stage of polyploidization was estimated. Study of genome changes was performed by comparing of PCR spectra obtained while amplifying genome DNA of allopolyploid and its parental forms. For analysis of subtelomeric DNA, we used 66 pairs of primers composed of 11 singular primers designed for subtelomere DNA sequences of cereals. RAPD analysis was performed with usage of 38 primers, in microsatellite (SSR) analysis 23 primer pairs were used. RAPD analysis appeared to be a more effective PCR-based method to identify genome changes. Absence of some PCR fragments typical for parental genome in RAPD specters of allopolyploid TL05 x TMU06 was shown using 13 primers of 38 (34%), and with usage of subtelomere primers such changes in PSR specters were shown only for one of 66 pays of primers (1.5%). SSR loci were stable during the polyploidization process. Subsequent analysis of PCR fragments absent in specter of synthetic allopolyploid showed that high level of genome changes in RAPD analysis is probably connected with more effective ability of this method to reveal point mutations. Some data was found suggesting that not all genome changes observed in experimentally synthesized allopolyploids of the first generation are consequences of coadaptation of few genomes in one nucleus.     

Inheritance and molecular mapping of new greenbug resistance genes in wheat germplasms derived from Aegilops tauschii

Molecular mapping of genes for crop resistance to the greenbug, Schizaphis graminum Rondani, will facilitate selection of greenbug resistance in breeding through marker-assisted selection and provide information for map-based gene cloning. In the present study, microsatellite marker and deletion line analyses were used to map greenbug resistance genes in five newly identified wheat germplasms derived from Aegilops tauschii. Our results indicate that the Gb genes in these germplasms are inherited as single dominant traits. Microsatellite markers Xwmc157 and Xgdm150 flank Gbx1 at 2.7 and 3.3 cM, respectively. Xwmc671 is proximately linked to Gba, Gbb, Gbc and Gbd at 34.3, 5.4, 13.7, 7.9 cM, respectively. Xbarc53 is linked distally to Gba and Gbb at 20.7 and 20.2 cM, respectively. Xgdm150 is distal to Gbc at 17.9 cM, and Xwmc157 is distal to Gbd at 1.9 cM. Gbx1, Gba, Gbb, Gbc, Gbd and the previously characterized Gbz are located in the distal 18% region of wheat chromosome 7DL. Gbd appears to be a new greenbug resistance gene different from Gbx1 or Gbz. Gbx1, Gbz Gba, Gbb, Gbc and Gbd are either allelic or linked to Gb3.     

Comparative genetic analysis of the Aegilops longissima and Ae. sharonensis genomes with common wheat

Aegilops longissima Schw. et Musch. (2n= 2x=14, S^lS^l) and Aegilops sharonensis Eig. (2n=2x=14, S^lS^l) are diploid species belonging to the section Sitopsis in the tribe Triticeae and potential donors of useful genes for wheat breeding. A comparative genetic map was constructed of the Ae. longissima genome, using RFLP probes with known location in wheat. A high degree of conserved colinearity was observed between the wild diploid and basic wheat genome, represented by the D genome of cultivated wheat. Chromosomes 1S^l, 2S^l, 3S^l, 5S^l and 6S^l are colinear with wheat chromosomes 1D, 2D, 3D, 5D and 6D, respectively. The analysis confirmed that chromosomes 4S^l and 7S^l are translocated relative to wheat. The short arms and major part of the long arms are homoeologous to most of wheat chromosomes 4D and 7D respectively, but the region corresponding to the distal segment of 7D was translocated from 7S^lL to the distal region of 4S^lL. The map and RFLP markers were then used to analyse the genomes and added chromosomes in a set of ’Chinese Spring’ (CS)/Ae. longissima chromosome additions. The study confirmed the availability of disomic CS/Ae. longissima addition lines for chromosomes 1S^l, 2S^l, 3S^l, 4S^l and 5S^l. An as yet unpublished set of Ae. sharonensis chromosome addition lines were also available for analysis. Due to the gametocidal nature of Ae. sharonensis chromosomes 2S^l and 4S^l, additions 1S^l, 3S^l, 5S^l, 6S^l and 7S^l were produced in a (4D)4S^l background, and 2S^l and 4S^l in a euploid wheat background. The analysis also confirmed that the 4/7 translocation found in Ae. longissima was not present in Ae. sharonensis although the two wild relatives of wheat are considered to be closely related. The phenotypes of the Ae. sharonensis addition lines are described in an Appendix. Received: 28 September 2000 / Accepted: 19 January 2001     

Mapping candidate genes for Drosophila melanogaster resistance to the parasitoid wasp Leptopilina boulardi

Drosophila melanogaster resistance against the parasitoid wasp Leptopilina boulardi is under the control of a single gene (Rlb), with two alleles, the resistant one being dominant. Using strains bearing deletions, we previously demonstrated that the 55E2-E6; 55F3 region on chromosome 2R is involved in the resistance phenomenon. In this paper, we first restricted the Rlb containing region by mapping at the molecular level the breakpoints of the Df(2R)Pc66, Df(2R)P34 and Df(2R)Pc4 deficiencies, using both chromosomal in situ hybridization and Southern analyses. The resistance gene was localized in a 100 kb fragment, predicted to contain about 10 different genes. Male recombination genetic experiments were then performed, leading to identification of two possible candidates for the Rlb gene. Potential involvement of one of this genes, edl/mae, is discussed.     

Genetic characterization and molecular mapping of Hessian fly resistance genes derived from Aegilops tauschii in synthetic wheat

Two synthetic hexaploid wheat lines (×Aegilotriticum spp., 2n = 6x = 42, genomes AABBDD), SW8 and SW34, developed from the crosses of the durum wheat cultivar Langdon (Triticum turgidum L. var. durum, 2n = 4x = 28, genomes AABB) with two Aegilops tauschii Cosson accessions (2n = 2x = 14, genome DD), were determined to carry Hessian fly [Mayetiola destructor (Say)] resistance genes derived from the Ae. tauschii parents. SW8 was resistant to the Hessian fly biotype Great Plains (GP) and strain vH13 (virulent to H13). SW34 was resistant to biotype GP, but susceptible to strain vH13. Allelism tests indicated that resistance genes in SW8 and SW34 may be allelic to H26 and H13 or correspond to paralogs at both loci, respectively. H26 and H13 were localized to chromosome 4D and 6D, respectively, in previous studies. Molecular mapping in the present study, however, assigned the H26 locus to chromosome 3D rather than 4D. On the other hand, mapping of the resistance gene in SW34 verified the previous assignment of the H13 locus to chromosome 6D. Linkage analysis and physical mapping positioned the H26 locus to the chromosomal deletion bin 3DL3-0.81–1.00. A linkage map for each of these two resistance genes was constructed using simple sequence repeat (SSR) and target region amplification polymorphism (TRAP) markers.     

Introgression of stem rust resistance genes SrTA10187 and SrTA10171 from Aegilops tauschii to wheat

Aegilops tauschii, the diploid progenitor of the wheat D genome, is a readily accessible germplasm pool for wheat breeding as genes can be transferred to elite wheat cultivars through direct hybridization followed by backcrossing. Gene transfer and genetic mapping can be integrated by developing mapping populations during backcrossing. Using direct crossing, two genes for resistance to the African stem rust fungus race TTKSK (Ug99), were transferred from the Ae. tauschii accessions TA10187 and TA10171 to an elite hard winter wheat line, KS05HW14. BC₂ mapping populations were created concurrently with developing advanced backcross lines carrying rust resistance. Bulked segregant analysis on the BC₂ populations identified marker loci on 6DS and 7DS linked to stem rust resistance genes transferred from TA10187 and TA10171, respectively. Linkage maps were developed for both genes and closely linked markers reported in this study will be useful for selection and pyramiding with other Ug99-effective stem rust resistance genes. The Ae. tauschii-derived resistance genes were temporarily designated SrTA10187 and SrTA10171 and will serve as valuable resources for stem rust resistance breeding.