Identification of the leaf rust resistance genes LR26, LR28, LR34, LR37 in wheat (Triticum Aestivum L.) using STS and SCAR markers
Keywords:
leaf rust, SCAR, STS markers, resistance, gene, DNA, wheatAbstract
Gene Lr26 has identified in 7 specimens of common wheat and wild species Tr. timopheevii and Tr. kiharae. For the first time highly effective genes Lr26, Lr34 and Lr37 were identified in most varieties of local selection using molecular markers - Iag95, csLV34, VENTRIUP-LN2.References
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16 McIntosh R.A., Miller T.E., Chapman V. Cytogenetical studies in wheat. XII. Lr28 for esistance to Puccinia recondita and
Sr34 for resistance to P. graminis tritici. Z. Pflanzenzuchtg. – 1982. – V. 89. – P. 295-306.
17 Dyck P.L., Samborski D.J., Anderson R.G. Inheritance of adult-plant leaf rust resistance derived from the common wheat
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5. – P. 24-31.
aestivum L.) cultivars using molecular markers // Russian Journal of Genetics. – 2006. – V.42(5). – P. 546–554.
2 McIntosh R.A., Yamazaki Y., Dubcovsky J., Rogers W.J., Morris C.F., Somers D.J. et al. Catalogue of gene symbols for wheat.Proceedings of the 11th International Wheat Genetics Symposium. Brisbane, Australia. – 2008.
3 McIntosh R.A., Yamazaki Y., Rogers W.J., Morris C.F., Devos K.M. Catalogue of gene symbols for wheat (http://www.shigen.
nig.ac.jp/wheat/komugi/genes/ download.jsp). – 2010.
4 Riar A.K., Kaur S., Dhaliwal H.S., Singh K., Chhuneja P. Introgression of a leaf rust resistance gene from Aegilops caudate
to bread wheat // Journal of Genetics. – 2012. – V.91(2). – P. 155-161.
5 Cherukuri D.P., Gupta S.K., Charpe A., Koul S., Prabhu K.V., Singh R.B., Haq Q.M.R., Chauhan S.V.S. Identification of a
molecular marker linked to an Agropyron elongatum-derived gene Lr19 for leaf rust resistance in wheat // Plant Breed. – 2003. – V.122.
– P. 204–208.
6 Landjeva S., Korzun V., Burner A. Molecular markers: actual and potential contributions to wheat genome haracterization and
breeding // Euphytica. – 2007. – V.156. – P. 271–296.
Kuchel H., Ye G., Fox R., Jefferies S. Genetic and economic analysis of a targeted marker-assisted wheat breeding strategy //
Molecular Breeding. – 2005. – V.16. P. 67–78.
7 Singh R.P., William H.M., Huerta-Espino J., Rosewarne G. Wheat rust in Asia: meeting the challenges with old and new
technologies. “New directions for a diverse planet”. Proceedings of the 4th International Crop Science Congress, 26 Sep – 1 Oct.
Brisbane, Australia. Published on CDROM. Web site www.cropscience.org.au. – 2004.
8 Edwards K., Jonstone C., Thompson C.A. Simple and rspid method for the preparation of plant genomic DNA for PCR
analysis // Nucl. Acids Res. – 1991. – V. 19(6). – P. 1349.
9 Mago R., Spielmeyer W., Lawrence G.J., Lagudah E.S., Ellis J.G., Pryor A. Identification and mapping of molecular markers
linked to rust resistance genes located on chromosome 1RS of rye using wheat-rye translocation lines // Theor. Appl. Genet. – 2002. – V.
104: – P.1317-1324.
10 Naik S., Gill K.S., Prakasa Rao V.S., Gupta V.S., Tamhankar S.A., Putjar S., Gill B.S., Ranjekar P.K.. Identification of a STS
marker linked to the Aegilops speltoides-derived leaf rust resistance gene Lr28 in wheat // Theor. Appl. Genet. – 1998. – V. 97. – P. 535-
540.
11 Lagudah E.S., McFadden H., Singh R.P., Huerta-Espino J., Bariana H.S., Spielmeyer W. Molecular genetic characterization
of the Lr34/Yr18 slow rusting resistance gene region in wheat // Theor. Appl. Genet. – 2006. V. 114. – P. 21-30.
12 Singh R.P., Huerta-Espino J. Effect of leaf rust resistance gene Lr34 on components of slow rusting at seven growth stages in
wheat // In: Euphytica. – 2003. – V. 129. – P.371-376.
13 Rajaram S., Mann C.H.E., Ortiz-Ferrara G., Mujeeb-Kazi A. Adaptation, stability and high yield potential of certain 1B/1R
CIMMYT wheats. In S Sakamoto, ed., Proc. 6th Int. Wheat Genetics Symp. – Kyoto, 1983. – P. 613-621.
14 Gul’tyaeva E.I., Kanyuka I.A., Alpat’eva N.V., Baranova O.A., Dmitriev A.P., Pavlyushin VA. Molecular approaches in
identifying leaf rust resistance genes in russian wheat varieties // Russian Agricultural Sciences. – 2009. – V. 35(5). – 316–319
15 Moreno-Sevilla B., Baenziger P.S. The 1BL/1RS translocation: Agronomic performance of F3-derived lines from a winter
wheat cross // Crop Sci. – 1995. – V. 35.- P.1051-1055.
16 McIntosh R.A., Miller T.E., Chapman V. Cytogenetical studies in wheat. XII. Lr28 for esistance to Puccinia recondita and
Sr34 for resistance to P. graminis tritici. Z. Pflanzenzuchtg. – 1982. – V. 89. – P. 295-306.
17 Dyck P.L., Samborski D.J., Anderson R.G. Inheritance of adult-plant leaf rust resistance derived from the common wheat
varieties Exchange and Frontana // In: Canadian Journal of Genetics and Cytology. – 1966. –V. 8. – P. 665-671.
18 Singh RP, Rajaram S. Genetics of adult plant resistance of leaf rust in Frontana and CIMMYT wheat // Genome. – 1992. – V.
5. – P. 24-31.
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Tokubayeva A. А., & Shulembaeva, K. K. (2015). Identification of the leaf rust resistance genes LR26, LR28, LR34, LR37 in wheat (Triticum Aestivum L.) using STS and SCAR markers. Experimental Biology, 57(1), 158–164. Retrieved from https://bb.kaznu.kz/index.php/biology/article/view/227
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HUMAN and ANIMAL PHYSIOLOGY