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36 1401 1410 Brown-Guedira, G.L., Singh, S., Fritz, A.K. 2003. Performance and mapping of leaf rust resistance transferred to wheat from Triticum

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Błaszczyk, L., Chełkowski, J., Korzun, V., Kraič, J., Ordon, F., Ovesná, J., Purnhauser, L., Tar, M., Vida, G. (2004): Verification of STS markers for leaf rust resistance genes of wheat by seven European laboratories. Cellular & Molecular Biology Letters

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Dedryver, F., Jubier, M.F., Thouverin, J., Goyeau, H. 1996. Molecular markers linked to leaf rust resistance gene Lr24 in different wheat cultivars. Genome 39 :830–835. Goyeau H

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.P., Moraes-Fernandes, M.I.B. 1999. Inheritance of adult plant leaf rust resistance in the Brazilian wheat cultivar Toropi. Plant Dis. 84 :90–93. Moraes-Fernandes M.I.B. Inheritance of

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Blazkova, V., Bartos, P., Park, R. F. and Goyeau, H. (2002): Verifying the presence of leaf rust resistance gene Lr10 in sixteen wheat cultivars by use of a PCR-based STS marker. Cereal Res. Comm. 30, 9

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Cereal Research Communications
Authors: A. Kokhmetova, A. Madenova, G. Kampitova, R. Urazaliev, M. Yessimbekova, A. Morgounov, and L. Purnhauser

. , Keller , B. 1995 . Genetic and physical characterization of the Lr1 leaf rust resistance locus in wheat ( Triticum aestivum L.) . Mol. Gen. Genet. 248 : 553 – 562

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422 Hiebert, C., Thomas, J., McCallum, B. 2002. Determining the chromosomal location of the wheat leaf-rust resistance gene LrW. Can. J. Plant Pathol 24 :92

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. 2013 . Molecular and phenotypic characterization of seedling and adult plant leaf rust resistance in a world wheat collection . Mol. Breeding 32 : 663 – 677 . Dyck , P.L. 1977

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Nearly twenty thousand wheat lines were phenotyped for the presence of leaf tip necrosis (LTN), a phenotypic trait linked to adult plant leaf rust resistance (APR) genes, viz. Lr34, Lr46 and Lr67 having pleiotropic association with multiple disease resistance genes. Thirty-six lines showed varied expression of LTN and moderate level of leaf rust severity at adult plant stage with slow rusting (disease progress at a retarded rate). Seedling resistance test (SRT) revealed susceptible and mixed infection types, a characteristic of adult plant resistance (APR) genes. Further molecular confirmation for the presence of these genes using available microsatellite markers revealed that of the 36 lines, five lines carried Lr46+ alone and five other lines carried Lr67+ alone. Seven lines carried the combination of Lr34+ and Lr67+ while six lines confirmed to carry the combination of Lr46+ and Lr67+. Remarkably three lines carried all the three APR genes, viz. Lr34+, Lr46+ and Lr67+. All these stocks can be a source of APR multiple disease resistance genes. Ten lines were not confirmed to carry any of the genes but still had LTN and SRT results showing an infection type typical of APR genes and these can be the source of identifying newer APR genes. The resistance based on minor APR genes when combined with a few additional minor genes in the background of high yielding cultivars is expected to have high level of race non-specific resistance and to be durable.

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Cultivation of winter wheat varieties in the West Siberian region of Russia has competitive advantages compared to spring varieties: utilization of spring-summer moisture, early maturation and harvest and a high yield potential. The poor resistance of winter varieties to foliar diseases results in significant yield losses and facilitates the spread of pathogens to the spring wheat cultivars. The present study was conducted to evaluate the effectiveness of molecular markers specific for VRN-1 and Lr loci in selecting winter wheat genotypes resistant to leaf rust. The winter wheat cultivars Biyskaya ozymaya and Filatovka were crossed with spring wheat introgression lines 21-4 and 5366-180 and the spring wheat cultivar Tulaikovskaya 10 carrying LrTt2, LrAsp5 and Lr6Ai#2 loci from Triticum timopheevii, Aegilops speltoides and Thynopyrum intermedium, respectively. To identify winter wheat plants homozygous for target loci, F2 populations were screened with functional markers to VRN-1 genes and with markers specific for alien genetic material. Based on the genotyping analysis of 371 F2 plants a total of 44 homozygous genotypes with winter habit was identified. There were eight genotypes containing Lr loci among them. Evaluation of F2-derived F3-4 families for both seedling and adult resistance showed that only one F3-4 family had moderate susceptible reaction type to the field population of leaf rust. Others ranged from nearly immune to resistant with severity of 5%. The data also indicated the utility of the VRN-1 allele-specific markers for detection of genotypes with winter habit without vernalization at early stages of plant breeding.

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