Wheat Rusts | ScienceGate

Description of Wheat Rusts and Their Virulence Variations Determined through Annual Pathotype Surveys and Controlled Multi-Pathotype Tests

Advances in Agriculture ◽

10.1155/2019/2673706 ◽

2019 ◽

Vol 2019 ◽

pp. 1-7 ◽

Cited By ~ 1

Author(s):

Mesfin Kebede Gessese

Keyword(s):

Leaf Rust ◽

Stripe Rust ◽

Resistance Genes ◽

Stem Rust ◽

Rust Resistance ◽

Yellow Rust ◽

Stripe Rust Resistance ◽

Wheat Production ◽

The World ◽

Rust Resistance Genes

Wheat production started in Australia around 1788 using early maturing varieties adapted to Australian conditions that were able to escape diseases as well as moisture stress conditions. Wheat production is concentrated on mainland Australia in a narrow crescent land considered as the wheat belt occupying an area of about 13.9 million hectares. Rusts are the most important production constraints to wheat production in the world and Australia causing significant yield losses and decreased the qualities of grains. Wheat is affected by three different types of rust diseases: leaf rust, stripe rust or yellow rust, and stem rust. Each species of the rust pathogen has many races or pathotypes that parasitize only on certain varieties of host species, which can only be traced and identified by differential cultivars. Pathotype surveillance is the basis for information on the virulence or pathogenic variations existing in a particular country or wheat growing region of the world. Studies in pathotype variation are conducted in controlled environments using multi-pathotype tests. The currently cultivated commercial wheat varieties of Australia possess leaf rust resistant genes: Lr1, Lr3a, Lr13, Lr13+, Lr14a, Lr17a, Lr17b, Lr20, Lr23, Lr24, Lr26, Lr27, Lr31, Lr34, Lr37, and Lr46; stem rust resistance genes: Sr2, Sr5, Sr8a, Sr8b, Sr9b, Sr9g, Sr11, Sr12, Sr13, Sr15, Sr17, Sr22, Sr24, Sr26, Sr30, Sr36, Sr38, and Sr57; and stripe rust resistance genes: Yr4, Yr9, Yr17, Yr18, Yr27, and Yr33. This paper discusses the historical and current significance of rusts to wheat production in the world with particular reference to Australia viz-a-viz detail description of each of the three rusts and their respective virulence variations through the resistance genes deployed in the commercial cultivars.

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Status of Wheat Rust Research and Progress in Rust Management-Indian Context

Agronomy ◽

10.3390/agronomy9120892 ◽

2019 ◽

Vol 9 (12) ◽

pp. 892 ◽

Cited By ~ 6

Author(s):

Subhash C. Bhardwaj ◽

Gyanendra P. Singh ◽

Om P. Gangwar ◽

Pramod Prasad ◽

Subodh Kumar

Keyword(s):

Stripe Rust ◽

Rust Resistance ◽

Wheat Breeding ◽

Stripe Rust Resistance ◽

Comprehensive Overview ◽

Wheat Varieties ◽

Biotic Stresses ◽

Rust Diseases ◽

Wheat Rust ◽

Wheat Rusts

The rusts of wheat, caused by three species of Puccinia, are very devastating diseases and are major biotic constraints in efforts to sustain wheat production worldwide. Their capacity to spread aerially over long distances, rapid production of infectious uredospores, and abilities to evolve new pathotypes, makes the management of wheat pathogens a very challenging task. The development and deployment of resistant wheat varieties has proven to be the most economic, effective and efficient means of managing rust diseases. Rust resistance used in wheat improvement has included sources from the primary gene pool as well as from species distantly related to wheat. The 1BL/1RS translocation from cereal rye was used widely in wheat breeding, and for some time provided resistance to the wheat leaf rust, stripe rust, and stem rust pathogens conferred by genes Lr26, Yr9, and Sr31, respectively. However, the emergence of virulence for all three genes, and stripe rust resistance gene Yr27, has posed major threats to the cultivation of wheat globally. To overcome this threat, efforts are going on worldwide to monitor rust diseases, identify rust pathotypes, and to evaluate wheat germplasm for rust resistance. Anticipatory breeding and the responsible deployment of rust resistant cultivars have proven to be effective strategies to manage wheat rusts. Efforts are still however being made to decipher the recurrence of wheat rusts, their epidemiologies, and new genomic approaches are being used to break the yield barriers and manage biotic stresses such as the rusts. Efficient monitoring of pathotypes of Puccinia species on wheat, identification of resistance sources, pre-emptive breeding, and strategic deployment of rust resistant wheat cultivars have been the key factors to effective management of wheat rusts in India. The success in containing wheat rusts in India can be gauged by the fact that we had no wheat rust epiphytotic for nearly last five decades. This publication provides a comprehensive overview of the wheat rust research conducted in India.

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Resistance of Tangmai 4 wheat to powdery mildew, stem rust, leaf rust, and stripe rust and its chromosome composition

Canadian Journal of Plant Science ◽

10.4141/p03-195 ◽

2004 ◽

Vol 84 (4) ◽

pp. 1015-1023 ◽

Cited By ~ 9

Author(s):

H. J. Li ◽

R. L. Conner ◽

B. D. McCallum ◽

X. M. Chen ◽

H. Su ◽

...

Keyword(s):

Powdery Mildew ◽

Leaf Rust ◽

Stripe Rust ◽

Stem Rust ◽

Northern China ◽

Western Canada ◽

C Banding ◽

Rust Diseases ◽

Hard Red Winter Wheat ◽

Secale Cereale L

The hard red winter wheat Tangmai 4 did not develop symptoms of infection following inoculation with powdery mildew (Erysiphe graminis DC. f. sp. tritici E. Marchal) isolates from regions of western Canada and northern China. Tangmai 4 exhibited resistance to stem rust (Puccinia graminis Pers. f. sp. tritici Eriks. & Henn.) and leaf rust (P. triticina Eriks.) races from western Canada. This wheat line was resistant to individual stripe rust (P. striiformis Westend. f. sp. tritici Eriks.) races from the U.S. and Canada. Sequential C-banding and genomic in situ hybridization (GISH), and electrophoretic analyses of high molecular weight glutenins and gliadins demonstrated that Tangmai 4 carried a pair of T1BL·1RS wheat-rye (Secale cereale L.) translocated chromosomes. Since the genes located on T1BL·1RS are no longer effective in controlling powdery mildew and the rust diseases, Tangmai 4 must carry additional genes for resistance to these diseases, which makes it a valuable resource for the improvement of resistance in wheat against these diseases. Key words: T1BL·1RS translocation, disease resistance, sequential C-banding and GISH, glutenin, gliadin

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Virulence surveillance of wheat black stem rust fungus

Baghdad Science Journal ◽

10.21123/bsj.11.2.803-812 ◽

2014 ◽

Vol 11 (2) ◽

pp. 803-812

Author(s):

Baghdad Science Journal

Keyword(s):

Leaf Rust ◽

Disease Severity ◽

Stem Rust ◽

Yellow Rust ◽

Rust Fungus ◽

The North ◽

Rust Diseases ◽

Northern Regions ◽

Infection Disease ◽

Wheat Rust

General survey for wheat rust diseases in Iraqi fields was done during the seasons of 2010, 2011 and 2012. The survey covered different fields in southern, middle and northern regions. Results of the first season indicated that most of Iraqi cultivars such as Tmmoze2, IPA 99 and Mexipak showed different types of susceptibility to both yellow and leaf rust infection. Disease severity increased when the conditions were favorable for infections with using susceptible cultivars. The severity of leaf rust was less in the north region comparing with the middle and south regions. Most of the introduced cultivars such as Sham6 and Cimmyto showed susceptible reaction to yellow and leaf rust. Yellow rust was in epiphytotic form at the Iraqi-Syrian-Turkish triangle where the disease severity was 100%. Low disease severity of stem rust was observed on some cultivars (1-5%), except for the cultivar Mexipak which showed 40%S in Najaf. Rusts at season of 2011 were restricted mostly in Baghdad and the yellow rust was dominant. The AUDPC of 15 wheat cultivars showed that Sawa and Sali were highly susceptible to the three types of rusts while Babil113 and Tamoze2 were resistant. No rusts were detected at season 2012.

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Molecular Marker Based Design for Breeding Wheat Lines with Multiple Resistance and Superior Quality

Plant Disease ◽

10.1094/pdis-02-20-0420-re ◽

2020 ◽

Vol 104 (10) ◽

pp. 2658-2664

Author(s):

Tao Liu ◽

George Fedak ◽

Lianquan Zhang ◽

Rangrang Zhou ◽

Dawn Chi ◽

...

Keyword(s):

Stripe Rust ◽

Resistance Genes ◽

High Resistance ◽

Stem Rust ◽

Rust Resistance ◽

Stripe Rust Resistance ◽

Multiple Resistance ◽

Wheat Stem Rust ◽

Wheat Production ◽

Rust Resistance Genes

There has not been a major wheat stem rust epidemic worldwide since the 1970s, but the emergence of race TTKSK of Puccinia graminis f. sp. tritici in 1998 presented a great threat to the world wheat production. Single disease-resistance genes are usually effective for only several years before the pathogen changes genetically to overcome the resistance. Stripe rust caused by Puccinia striiformis f. sp. tritici (Pst) is one of the most common and persistent wheat diseases worldwide. The development of varieties with multiple resistance is the most economical and effective strategy for preventing stripe rust and stem rust, the two main rust diseases constraining wheat production. Plateau 448 has been widely used in the spring wheat growing region in northwest China, but it has become susceptible to stripe rust and is susceptible to TTKSK. To produce more durable resistance to race TTKSK as well as to stripe rust, four stem rust resistance genes (Sr33, Sr36, Sr-Cad, and Sr43) and three stripe rust resistance genes (Yr5, Yr18, and Yr26) were simultaneously introgressed into Plateau 448 to improve its stem rust (Ug99) and stripe rust resistance using a marker-assisted backcrossing strategy combined with phenotypic selection. We obtained 131 BC1F5 lines that pyramided two to four Ug99 resistance genes and one to two Pst resistance genes simultaneously. Thirteen of these lines were selected for their TTKSK resistance, and all of them exhibited near immunity or high resistance to TTKSK. Among the 131 pyramided lines, 95 showed high resistance to mixed Pst races. Nine lines exhibited not only high resistance to TTKSK and Pst but also better agronomic traits and high-molecular-weight glutenin subunit compositions than Plateau 448.

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Seedling resistances to rust diseases in international triticale germplasm

Crop and Pasture Science ◽

10.1071/cp10252 ◽

2010 ◽

Vol 61 (12) ◽

pp. 1036 ◽

Cited By ~ 8

Author(s):

J. Zhang ◽

C. R. Wellings ◽

R. A. McIntosh ◽

R. F. Park

Keyword(s):

Leaf Rust ◽

Stripe Rust ◽

Plant Resistance ◽

Stem Rust ◽

Rust Resistance ◽

Adult Plant Resistance ◽

Stem Rust Resistance ◽

Adult Plant ◽

Seedling Resistance ◽

Rust Diseases

Seedling resistances to stem rust, leaf rust and stripe rust were evaluated in the 37th International Triticale Screening Nursery, distributed by the International Wheat and Maize Improvement Centre (CIMMYT) in 2005. In stem rust tests, 12 and 69 of a total of 81 entries were postulated to carry Sr27 and SrSatu, respectively. When compared with previous studies of CIMMYT triticale nurseries distributed from 1980 to 1986 and 1991 to 1993, the results suggest a lack of expansion in the diversity of stem rust resistance. A total of 62 of 64 entries were resistant to five leaf rust pathotypes. In stripe rust tests, ~93% of the lines were postulated to carry Yr9 alone or in combination with other genes. The absence of Lr26 in these entries indicated that Yr9 and Lr26 are not genetically associated in triticale. A high proportion of nursery entries (63%) were postulated to carry an uncharacterised gene, YrJackie. The 13 lines resistant to stripe rust and the 62 entries resistant to leaf rust represent potentially useful sources of seedling resistance in developing new triticale cultivars. Field rust tests are needed to verify if seedling susceptible entries also carry adult plant resistance.

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Genome-Wide Association Studies Reveal All-Stage Rust Resistance Loci in Elite Durum Wheat Genotypes

Frontiers in Plant Science ◽

10.3389/fpls.2021.640739 ◽

2021 ◽

Vol 12 ◽

Author(s):

Meriem Aoun ◽

Matthew N. Rouse ◽

James A. Kolmer ◽

Ajay Kumar ◽

Elias M. Elias

Keyword(s):

Durum Wheat ◽

Leaf Rust ◽

Stripe Rust ◽

Resistance Genes ◽

Stem Rust ◽

Rust Resistance ◽

Genome Wide Association ◽

Genome Wide ◽

Rust Pathogen ◽

Rust Resistance Genes

Leaf rust, caused by Puccinia triticina (Pt), stripe rust caused by Puccinia striiformis f. sp. tritici (Pst), and stem rust caused by Puccinia graminis f. sp. tritici (Pgt) are major diseases to wheat production globally. Host resistance is the most suitable approach to manage these fungal pathogens. We investigated the phenotypic and genotypic structure of resistance to leaf rust, stem rust, and stripe rust pathogen races at the seedling stage in a collection of advanced durum wheat breeding lines and cultivars adapted to Upper Mid-West region of the United States. Phenotypic evaluation showed that the majority of the durum wheat genotypes were susceptible to Pt isolates adapted to durum wheat, whereas all the genotypes were resistant to common wheat type-Pt isolate. The majority of genotypes were resistant to stripe rust and stem rust pathogen races. The durum panel genotyped using Illumina iSelect 90 K wheat SNP assay was used for genome-wide association mapping (GWAS). The GWAS revealed 64 marker-trait associations (MTAs) representing six leaf rust resistance loci located on chromosome arms 2AS, 2AL, 5BS, 6AL, and 6BL. Two of these loci were identified at the positions of Lr52 and Lr64 genes, whereas the remaining loci are most likely novel. A total of 46 MTAs corresponding to four loci located on chromosome arms 1BS, 5BL, and 7BL were associated with stripe rust response. None of these loci correspond to designated stripe rust resistance genes. For stem rust, a total of 260 MTAs, representing 22 loci were identified on chromosome arms 1BL, 2BL, 3AL, 3BL, 4AL, 5AL, 5BL, 6AS, 6AL, 6BL, and 7BL. Four of these loci were located at the positions of known genes/alleles (Sr7b, Sr8155B1, Sr13a, and Sr13b). The discovery of known and novel rust resistance genes and their linked SNPs will help diversify rust resistance in durum wheat.

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A walk on the wild side: mining wild wheat and barley collections for rust resistance genes

Australian Journal of Agricultural Research ◽

10.1071/ar07123 ◽

2007 ◽

Vol 58 (6) ◽

pp. 532 ◽

Cited By ~ 74

Author(s):

Brian J. Steffenson ◽

Pablo Olivera ◽

Joy K. Roy ◽

Yue Jin ◽

Kevin P. Smith ◽

...

Keyword(s):

Leaf Rust ◽

Stripe Rust ◽

Resistance Genes ◽

Stem Rust ◽

Rust Resistance ◽

Wild Barley ◽

Stem Rust Resistance ◽

Dart Markers ◽

Wide Range ◽

Rust Resistance Genes

Leaf rust, stem rust, and stripe rust are among the most important diseases of wheat and barley worldwide and are best controlled using genetic resistance. To increase the diversity of rust resistance in wheat and barley, a project was initiated to identify and characterise rust resistance genes from the wild species of Aegilops sharonensis (Sharon goatgrass) and Hordeum vulgare ssp. spontaneum (wild barley), respectively. One hundred and two accessions of Sharon goatgrass from Israel and 318 Wild Barley Diversity Collection (WBDC) accessions from the Fertile Crescent, Central Asia, North Africa, and the Caucasus region were evaluated for resistance to leaf rust, stem rust, and/or stripe rust. Sharon goatgrass exhibited a wide range of infection types (ITs) in response to leaf rust, stem rust, and stripe rust. The percentage of resistant accessions in Sharon goatgrass was 58.8–78.4% for leaf rust, 11.8–69.6% for stem rust, and 46.1% for stripe rust, depending on the race used and the plant growth stage. Genetic studies with Sharon goatgrass revealed oligogenic resistance to leaf rust and stem rust. Wild barley also exhibited a wide range of ITs to leaf rust and stem rust; however, the overall frequency of resistance was lower than for Sharon goatgrass. The percentage of resistant accessions in wild barley was 25.8% for leaf rust and 5.7–20.1% for stem rust, depending on the race used. Resistance to the new virulent stem rust race TTKS (i.e. Ug99), present in eastern Africa, was found in both Sharon goatgrass (70% of accessions) and wild barley (25% of 20 accessions tested). Association mapping for stem rust resistance was applied in the WBDC using Diversity Arrays Technology (DArT) markers. Using the highly conservative P value threshold of 0.001, 14 and 15 significant marker associations were detected when the number of subpopulations (K value) was set for 10 and 8, respectively. These significant associations were in 9 and 8 unique chromosome bins, respectively. Two significant marker associations were detected for resistance to the wheat stem rust race MCCF in the same bin as the rpg4/Rpg5 complex on chromosome 7(5H). The presence of a major stem rust resistance gene in this bin on chromosome 7(5H) was validated in a bi-parental mapping population (WBDC accession Damon × cv. Harrington) constructed with DArT markers. The results from this study indicate that Sharon goatgrass and wild barley are rich sources of rust resistance genes for cultivated wheat and barley improvement, respectively, and that association mapping may be useful for positioning disease resistance genes in wild barley.

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Wheat rust resistance research at CSIRO

Australian Journal of Agricultural Research ◽

10.1071/ar06151 ◽

2007 ◽

Vol 58 (6) ◽

pp. 507 ◽

Cited By ~ 10

Author(s):

Jeffrey G. Ellis ◽

Rohit Mago ◽

Raja Kota ◽

Peter N. Dodds ◽

Helen McFadden ◽

...

Keyword(s):

Resistance Genes ◽

Molecular Basis ◽

Rust Resistance ◽

Gene Sequence ◽

Adult Plant Resistance ◽

Sequence Data ◽

Adult Plant ◽

Rust Diseases ◽

Efficient Breeding ◽

Wheat Rust

Although chemical control is available for rust diseases in wheat, economic and environmental factors favour genetic solutions. Maintenance and improvement of levels of resistance and durability of the genetic control of the 3 wheat rust diseases will occur with the application of DNA markers for pyramiding resistance genes. Information about the molecular basis of rust resistance, including durable, adult-plant resistance, coming from studies in model species such as flax and flax rust and from studies of wheat and barley, will provide knowledge for new biotechnological approaches to rust resistance. Increasing cereal gene sequence data will improve the efficiency of cloning disease resistance genes and, together with the rapid progress in understanding the molecular basis of rust resistance, will make it possible to construct transgenic plants with multiple rust resistance genes at a single locus, which will provide efficient breeding and increased durability of rust resistance.

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Bulked segregant analysis RNA-seq (BSR-Seq) validated a stem resistance locus in Aegilops umbellulata, a wild relative of wheat

10.1101/599597 ◽

2019 ◽

Author(s):

Erena A. Edae ◽

Matthew N. Rouse

Keyword(s):

Resistance Genes ◽

Stem Rust ◽

Bulk Segregant Analysis ◽

Bulked Segregant Analysis ◽

Analysis Approach ◽

Resistance Locus ◽

Potential Candidate ◽

Chromosome Location ◽

Sources Of Resistance ◽

Stem Resistance

AbstractMany disease resistance genes that have been transferred from wild relatives to cultivated wheat have played a significant role in wheat production worldwide. Ae. umbellulata is one of the species within the genus Aegilops that have been successfully used as sources of resistance genes to leaf rust, stem rust and powdery mildew. The objectives of the current work was to validate the map position of a major QTL that confers resistance to the stem rust pathogen races Ug99 (TTKSK) and TTTTF with an independent bi-parental mapping population and to refine the QTL region with a bulk segregant analysis approach. Two F2 bi-parental mapping populations were developed from stem rust resistant Ae. umbellulata accessions (PI 298905 and PI 5422375) and stem rust susceptible accessions (PI 542369 and PI 554395). Firstly, one of the two populations was used to map the chromosome location of the resistance gene. Later on, the 2nd population was used to validate the chromosome location in combination with a bulk segregant analysis approach. For the bulk segregant analysis, RNA was extracted from a bulk of leaf tissues of 12 homozygous resistant F3 families, and a separate bulk of 11 susceptible homozygous F3 families derived from the PI 5422375 and PI 554395 cross. The RNA samples of the two bulks and the two parents were sequenced for SNPs identification. Stem rust resistance QTL was validated on chromosome 2U of Ae. umbellulata in the same region in both populations. With bulk segregant analysis, the QTL position was delimited within 3.2 Mbp. Although there were a large number of genes in the orthologous region of the detected QTL on chromosome 2D of Ae. tauschii, we detected only two Ae. umbellulata NLR genes which can be considered as a potential candidate genes.

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