06. Resistance against basic causal organisms of diseases of winter wheat in F1-F3, created at participation wheat-rye translocations

https://doi.org/10.31073/agrovisnyk201904-06
Dubovyk N. S., Demydov O. A., Kyrylenko V. V., Gumeniuk O. V., Lisova G. M.
Pages: 37-44.

Full article: 
Abstract
The purpose. To analyze and determine trends of inheritance of group resistance against basic causal organisms of diseases of soft winter wheat in hybrid generations of F1–F3 created with participation of varieties with wheat-rye translocations. Methods. Field with use of artificial complex of infection background of pathogenes, observation and assessment of defeat by basic causal organisms of diseases according to conventional techniques and methodical recommendations in selection of soft winter wheat. Results. Researches were spent in 2016–2018 on fields of laboratory of selection of winter wheat of Myronivka institute of wheat. They studied 30 intervarietal hybrids F1–F3 gained as a result of crossing varieties-carriers of wheat-rye translocations (WRT). They determined overdominance of resistance against Erysiphe graminis DC. f.sp. tritici in combinations of crossing Zolotokolosa/Kolumbiya and Kolumbiya/Expromt, created at participation WRT 1AL.1RS, in both years of researches. They detected indexes of fractionally positive prevalence of resistance against causal organism Septoria tritici Rob. et Desm in 2016 of combination of crossing Zolotokosa/Expromt in group of crossing 1AL.1RS/1AL.1RS and in group 1BL.1RS/1AL.1RS. Index of phenotypical overdominance (heterosis) was established in hybrid combination Svitanok Myronivskyi / Kolumbiya. Negative prevalence (up to 16,7 %) was fixed in group of crossing 1AL.1RS/1BL.1RS. Positive transgressions were established in F2: 97 % — resistance against E. graminis; 100 % — Puccinia recondita f. sp. tritici Rob. et Desm; 87 % — S. tritici; in F3 100% — on resistance against E. graminis and S. tritici; 90 % — against P. recondita. According to results of researches hybrid combinations of crossing (43 %) which formed resistance to 3 causal organisms of diseases were established. The greatest share (38 %) of complex resistance was fixed for hybrids of group of crossing 1AL.1RS/1BL.1RS. Conclusions. In 2016–2017 they had determined: for hybrid combinations Zolotokosa/Kolumbiya and Kolumbiya/Expromt overdominance of resistance against causal organism E. graminis; for Zolotokosa/Kolumbiya — against causal organism S. tritici, parent forms were carrying agents of translocation 1AL.1RS. Positive transgressions were established in hybrid populations of F2 and F3 — resistance against E. graminis, P. recondita and S. tritici. The most valuable were combinations Expromt/Kalinova, Kolumbiya/Svitanok Myronivskyi, Kolumbiya/Lehenda Myronivska, Zolotokosa/Kalinova, Kolumbiya/Lehenda Myronivska.

Key words: wheat, variety, hybrids, wheat-rye translocations, artificial complex infection background, causal organisms of diseases, inheritance, transgression.

References
  1. Yevtushenko M.D., Lisovyi M.P., Pantelieiev V.K., Sliusarenko O.M. (2004) Imunitet Roslyn [Plant immunity]. Kyiv: Kolobih. 270 p. [In Ukrainian].
  2. Levitin M.M. (2012) Zashchita rasteniy ot bolezney pri globalnom poteplenii [Protecting plants from diseases during global warming]. Zashchita i karantin rasteniy [Plant protection and quarantine]. № 8. pp. 16-17. [In Russian].
  3. Zadoks J.C. (2004) A Plant Pathologist on Wheat Breeding with Special Reference to Septoria Diseases. Czech J. Genet. Plant Breed. V. 40. pp. 63 – 71.
  4. McIntosh R.A., Yamazaki Y., Dubcovsky J. et al. (2008) Catalogue of gene symbols for wheat. Proc. 11th Int. Wheat Genet. Symp. Brisbane, Qld Australia, 24 – 29 August. KOMUGI. Integrated wheat Science Database: http//www.shigen.nig.ac.jp/wheat/komugi/top/
  5. Petrenkova V.P., Cherniaieva I.M., Luchna I.S. et al. (2013) Stvorennia perspektyvnoho vykhidnoho materialu dlia selektsii zernovykh i zernobobovykh kultur na stiikist do khvorob [Creation of promising starting material for breeding of cereals and legumes for disease resistance]. Selektsiia i nasinnytstvo [Breeding and seed production]. Kharkiv,. Vyp. 103. pp. 8 – 14. [In Ukrainian].
  6. Kyrylenko V.V., Humeniuk O.V., Kovalyshyna H.M., Lisova H.M. (2017) Dzherela stiikosti do zbudnykiv khvorob ta yikh efektyvnist u selektsiinomu protsesi Triticum aestivum L. Henetychni resursy roslyn [Sources of resistance to pathogens and their effectiveness in the breeding process of Triticum aestivum L. Plant genetic resources]. Kharkiv. № 21. pp. 61 – 74. [In Ukrainian].
  7. Kuzmenko N.V., Litvinov A.Ye., Oleynikov Ye.S. Chemical protection of winter bread wheat against root rots and Septoria infection. Annual Wheat NewsLetter. Kansas Agricultural Experiment Station, Kansas State university, Manhattan. 2017. V. 63. pp. 65 – 68.
  8. Osmachko O.M., Vlasenko V.A. (2015) Stiikist kolektsii sortiv i hibrydiv F1 pshenytsi miakoi ozymoi proty boroshnystoi rosy v umovakh pivnichno-skhidnoho Lisostepu Ukrainy. Avtokhtonni ta introdukovani roslyny: zbirnyk naukovykh prats [Stability of a collection of soft winter wheat varieties and hybrids of F1 against powdery mildew in the north-eastern forest-steppe of Ukraine. Indigenous and Introduced Plants: A Collection of Scientific Papers]. Sofiivka. Vyp. 1. pp. 156 – 162. [In Ukrainian].
  9. Orlyuk A.P., Bazaliy V.V. (1998) Printsipy transgressivnoy selektsii pshenitsy: monografiya [Principles of transgressive wheat breeding: monograph]. Kherson. 271 p. [In Russian].
  10. Villareal R.S., Toro E., Rajaram S., Mujeeb-Kazi A. (2013) The effect of chromosome 1AL/1RS translocation on agronomic performance of 85 F2 — derived F6 lines from three Triticum aestivum L. srosses. Euphytica. 1996. V. 89. pp. 363 – 369.
  11. Zhangaziev A., Ziyaeva G., Taichibekov A. et al. Species Hybrid Genetic Analysis. European Researcher. V.(54). pp. 1810 – 1817.
  12. Vlasenko V.A., Kochmarskyi V.S., Koliuchyi V.T. et al. (2012) Selektsiina evoliutsiia myronivskykh pshenyts [Breeding evolution of Miron wheat]. Myronivka. 330 p. [In Ukrainian].
  13. Griffing B. (1950). Analysis of quantitative geneaction by constant parent regression and related techniques. Genetics. V. 35. pp. 303 – 321.
  14. Beil G.M., Atkins R.E. (1965) Inheritance of quantitative characters in grain sorghum. Iowa State J. V. 39. N 3. pp. 345 – 358.
  15. Voskresenskaya G.S., Shpota V.I. (1967) Transgressiya priznakov Brassica i metodika kolichestvennogo ucheta etogo yavleniya [Transgression of Brassica traits and methods for quantifying this phenomenon]. Doklady VASKhNIL [Reports of the UASKHNIL]. № 7. pp. 18 – 20. [In Russian].
  16. Babayants O.V., Babayants L.T. (2014) Osnovy selektsii i metodologiya otsenok ustoychivosti pshenitsy k vozbuditelyam bolezney [Fundamentals of selection and methodology for assessing the resistance of wheat to pathogens]. NAAN, Selektsionno-geneticheskiy institut. Natsionalnyy tsentr semenovedeniya i sortoizucheniya. Odessa: VMV, 401 p. [In Russian].
  17. Dospekhov B.A. (1985) Metodika polevogo opyta (s osnovami statisticheskoy obrabotki rezultatov issledovaniy) [Methods of field experience (with the basics of statistical processing of research results)]. Moskva: Agropromizdat. 352 p. [In Russian].