High density genetic mapping of stripe rust resistance in a ‘Strongfield’ / ‘Blackbird’ durum wheat population
Firdissa E. BokoreYuefeng RuanCurt A. McCartneyR. E. KnoxXiangyu PeiReem AboukhaddourHarpinder RandhawaKarim AmmarBrad MeyerRichard D. CuthbertSamia BerraiesR. M. DePauwPierre R. Fobert
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Abstract:
Resistance breeding is an effective strategy against wheat stripe (yellow) rust caused by Puccinia striiformis f. sp. tritici (Pst). To identify and map quantitative trait loci (QTL) associated with stripe rust resistance, a durum wheat doubled haploid population (n = 87) derived from 'Strongfield/Blackbird' was evaluated for disease severity near Toluca, Mexico (2017–2019) and Lethbridge, Canada (2016–2019). The population was genotyped with the wheat 90 K Illumina iSelect single nucleotide polymorphism (SNP) array and simple sequence repeat (SSR) markers, and QTL analysis was performed with MapQTL 6. We identified stripe rust-resistance QTL contributed by 'Blackbird' on chromosomes 3A (2 loci, designated QYr.spa-3A.1, QYr.spa-3A.2) and 5B (QYr.spa-5B), and 'Strongfield' on 2B (QYr.spa-2B). All seem to represent QTL not reported previously. The QYr.spa-3A.2 was most consistently effective against Pst races across the Lethbridge and Toluca nurseries. With a LOD value of 4.9, QYr.spa-3A.2 explained a maximum phenotypic variation of 22.7% observed at the Toluca 2019 nursery. The QYr.spa-2B from 'Strongfield' and QYr.spa-3A.1 from 'Blackbird' expressed in multiple years at Toluca but were not detected at Lethbridge. QYr.spa-5B was identified in the Lethbridge 2016 environment. The identified QTL should be valuable in diversifying resistance genes used in breeding durum wheat cultivars with stripe rust resistance. 'Blackbird' was particularly useful for introducing the new QTL QYr.spa-3A.2 resistance that is effective in Canada and Mexico into traditional durum wheat germplasm. SNP markers associated with QTL will have application in marker-assisted breeding of resistance to Pst in durum wheat.Keywords:
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Rust (programming language)
Germ plasm
Genome-wide Association Study
Association mapping
Rust (programming language)
Linkage Disequilibrium
Genetic architecture
Family-based QTL mapping
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Resistance in modern wheat cultivars for stripe rust is not long lasting due to the narrow genetic base and periodical evolution of new pathogenic races. Though nearly 83 Yr genes conferring resistance to stripe rust have been cataloged so far, few of them have been mapped and utilized in breeding programs. Characterization of wheat germplasm for novel sources of resistance and their incorporation into elite cultivars is required to achieve durable resistance and thus to minimize the yield losses. Here, a genome-wide association study (GWAS) was performed on a set of 391 germplasm lines with the aim to identify quantitative trait loci (QTL) using 35K Axiom® array. Phenotypic evaluation disease severity against four stripe rust pathotypes, i.e., 46S119, 110S119, 238S119, and 47S103 (T) at the seedling stage in a greenhouse providing optimal conditions was carried out consecutively for 2 years (2018 and 2019 winter season). We identified, a total of 17 promising QTl which passed FDR criteria. Moreover these 17 QTL identified in the current study were mapped at different genomic locations i.e. 1B, 2A, 2B, 2D, 3A, 3B, 3D, 4B, 5B and 6B. These 17 QTLs identified in the present study might play a key role in marker-assisted breeding for developing stripe rust resistant wheat cultivars.
Germ plasm
Stripe rust
Rust (programming language)
Marker-Assisted Selection
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Germ plasm
Association mapping
Linkage Disequilibrium
Genome-wide Association Study
Rust (programming language)
Genetic Association
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Plant biochemistry
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Family-based QTL mapping
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10 spring wheat germplasm from CIMMYT and 15 spring wheat cultivars from China, sown at 9 (locations) in 2001 and 2002 crop seasons, were used to investigate their performance on yield and industrial (quality). Significant differences were observed for all measured traits between China and CIMMYT wheat, and CIMMYT wheat performed wide adaptation with high and stable yield, good industrial (quality) and resistance to leaf rust. Therefore, CIMMYT wheat could contribute a lot to the spring wheat breeding program of China. It suggests that direct or indirect use of CIMMYT germplasm need to be further strengthened, and the priority of wheat breeding in China should be given to improve industrial (quality) and disease resistance, as well as high and stable yield.
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Abstract Leaf or brown rust caused by Puccinia triticina Eriks. ( Pt ) is a limiting factor for wheat production. Thus, a constant search for new resistance genes or QTLs is essential to improve the resistance durability against the continued evolution of new races of Pt . This study was aimed at exploring potentially novel genes/QTLs resistance to leaf rust in Iranian wheat landraces and cultivars by using association mapping. Using a panel of 320 wheat accessions, genome-wide association study (GWAS) genotyping-by-sequencing (GBS) techniques were adopted to map loci associated with resistance to five races of Pt . A total of 17 major marker-trait associations (MTAs) were found on wheat chromosomes that were significantly linked with seedling resistance to Pt . Three markers including rs12954, rs15705, and rs42447 were detected as novel loci for resistance to PKTTS race. Our findings presented new and putative resources of leaf rust resistance in Iranian bread wheat accessions. The new identified SNPs will be valuable to expand the set of resistance genes available to control this serious disease.
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The hexaploid spring wheat cultivar, Carberry, was registered in Canada in 2009, and has since been grown over an extensive area on the Canadian Prairies. Carberry has maintained a very high level of leaf rust ( Puccinia triticina Eriks.) resistance since its release. To understand the genetic basis of Carberry’s leaf rust resistance, Carberry was crossed with the susceptible cultivar, Thatcher, and a doubled haploid (DH) population of 297 lines was generated. The DH population was evaluated for leaf rust in seven field environments at the adult plant stage. Seedling and adult plant resistance (APR) to multiple virulence phenotypes of P. triticina was evaluated on the parents and the progeny population in controlled greenhouse studies. The population was genotyped with the wheat 90 K iSelect single nucleotide polymorphism (SNP) array, and quantitative trait loci (QTL) analysis was performed. The analysis using field leaf rust response indicated that Carberry contributed nine QTL located on chromosomes 1B, 2B (2 loci), 2D, 4A, 4B, 5A, 5B, and 7D. The QTL located on 1B, 2B, 5B, and 7D chromosomes were observed in two or more environments, whereas the remainder were detected in single environments. The resistance on 1B, detected in five environments, was attributed to Lr46 and on 7D, detected in seven environments to Lr34 . The first 2B QTL corresponded with the adult plant gene, Lr13 , while the second QTL corresponded with Lr16 . The seedling analysis showed that Carberry carries Lr2a , Lr16 , and Lr23 . Five epistatic effects were identified in the population, with synergistic interactions being observed for Lr34 with Lr46 , Lr16 , and Lr2a . The durable rust resistance of Carberry is attributed to Lr34 and Lr46 in combination with these other resistance genes, because the resistance has remained effective even though the P. triticina population has evolved virulent to Lr2a, Lr13, Lr16 , and Lr23 .
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Alfalfa leaf rust caused by the fungal pathogen Uromyces striatus compromises forage yield and quality. We investigated the genetic basis of leaf rust resistance in alfalfa using an F1 mapping population segregating for resistance to the disease in addition to segregation for fall dormancy (FD) and winter hardiness (WH). The objective of this work was to map quantitative trait loci (QTL) associated with alfalfa leaf rust resistance using genotyping-by-sequencing (GBS) SNP markers in the biparental F1 mapping population. The female parent 3010 displayed susceptibility to rust while the male parent CW 1010 was moderately resistant. The mapping population consisted of 184 F1 progenies that were planted with the parents in a randomized complete block (RCBD) design with three replications at Watkinsville and Blairsville, GA. Four clones generated from stem cuttings of each genotype were planted in each replication. Phenotyping rust severity (RS) was based on the NAAIC visual rating scores of 1–5. RS and FD exhibited a negative phenotypic correlation (r = −0.26). RS and WH also exhibited a negative correlation (r = −0.27) suggesting that the dormant and winter hardy genotypes were more susceptible to leaf rust than the non-dormant and cold sensitive. Four QTL for alfalfa leaf rust resistance and one QTL for rust susceptibility were identified in the CW 1010 genetic map while three QTL for rust susceptibility were identified in the 3010 parent. The most important QTL Us-RustR1 explained 13% (R2 = 0.13) of the phenotypic variance. This study suggests that leaf rust resistance in alfalfa is most likely incomplete and has polygenic inheritance. Comparative genome analysis of QTL regions using sequences of significant SNPs revealed homology to M. truncatula sequences that were previously reported for their role in plant defense mechanisms. Validation of the QTLs in different genetic backgrounds as well as fine mapping of the QTL regions would be the next step of this research. The markers presented in this study would be valuable resources for alfalfa genetic improvement via marker-assisted selection (MAS).
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Yellow (YR) and leaf (LR) rusts caused by Puccinia striiformis f. sp. tritici (Pst) and Puccinia triticina, respectively, are of utmost importance to wheat producers because of their qualitative and quantitative effect on yield. The search for new loci resistant to both rusts is an ongoing challenge faced by plant breeders and pathologists. Our investigation was conducted on a subset of 168 pre-breeding lines (PBLs) to identify the resistant germplasm against the prevalent local races of LR and YR under field conditions followed by its genetic mapping. Our analysis revealed a range of phenotypic responses towards both rusts. We identified 28 wheat lines with immune response and 85 resistant wheat genotypes against LR, whereas there were only eight immune and 52 resistant genotypes against YR. A GWAS (genome-wide association study) identified 190 marker-trait associations (MTAs), where 120 were specific to LR and 70 were specific to YR. These MTAs were confined to 86 quantitative trait loci (QTLs), where 50 QTLs carried MTAs associated with only LR, 29 QTLs carried MTAs associated with YR, and seven QTLs carried MTAs associated with both LR and YR. Possible candidate genes at the site of these QTLs are discussed. Overall, 70 PBLs carried all seven LR/YR QTLs. Furthermore, there were five PBLs with less than five scores for both LR and YR carrying positive alleles of all seven YR/LR QTLs, which are fit to be included in a breeding program for rust resistance induction.
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A panel of 114 genetically diverse barley lines were assessed in the greenhouse and field for resistance to the pathogen Puccinia hordei, the causal agent of barley leaf rust. Multi-pathotype tests revealed that 16.6% of the lines carried the all-stage resistance (ASR) gene Rph3, followed by Rph2 (4.4%), Rph1 (1.7%), Rph12 (1.7%) or Rph19 (1.7%). Five lines (4.4%) were postulated to carry the gene combinations Rph2+9.am, Rph2+19 and Rph8+19. Three lines (2.6%) were postulated to carry Rph15 based on seedling rust tests and genotyping with a marker linked closely to this gene. Based on greenhouse seedling tests and adult-plant field tests, 84 genotypes (73.7%) were identified as carrying APR, and genotyping with molecular markers linked closely to three known APR genes (Rph20, Rph23 and Rph24) revealed that 48 of the 84 genotypes (57.1%) likely carry novel (uncharacterized) sources of APR. Seven lines were found to carry known APR gene combinations (Rph20+Rph23, Rph23+Rph24 and Rph20+Rph24), and these lines had higher levels of field resistance compared to those carrying each of these three APR genes singly. GWAS identified 12 putative QTLs; strongly associated markers located on chromosomes 1H, 2H, 3H, 5H and 7H. Of these, the QTL on chromosome 7H had the largest effect on resistance response to P. hordei. Overall, these studies detected several potentially novel genomic regions associated with resistance. The findings provide useful information for breeders to support the utilization of these sources of resistance to diversify resistance to leaf rust in barley and increase resistance durability.
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