Assessment of the adaptability of winter rye hybrids for cultivation in the Forest-Steppe zone of Ukraine

Svitlana Stoliar, Maksym Melnyk
Received: 14.06.2025 Revised: 29.10.2025 Accepted: 26.11.2025
Retrieved from Vol. 28, No. 12, 2025 Pages: 9-17
Download article Read article

Abstract

The aim of the study was to substantiate the ecological and adaptive performance of modern winter rye hybrids for their use under different cultivation systems in the Forest-Steppe zone of Ukraine. The methodology combined field phenological and biometric observations, phytosanitary assessments, yield determination, and statistical analysis of variation parameters, ecological plasticity and stability based on the Eberhart-Russell model modified by Finlay-Wilkinson. The response of nine hybrids to contrasting abiotic factors was examined, and differences in the rate of spring vegetation recovery, formation of stem biomass and yield structure were identified. The level of winter hardiness and drought tolerance was analysed, demonstrating the ability of hybrids to maintain productivity under snow-deficient winters and uneven precipitation distribution. High ecological plasticity (bi =0.93-1.02) and stability (S2 di = 0.09-0.14) of the leading genotypes were revealed, confirming their universality across diverse agroclimatic conditions. It was established that SU Futturi, KWS Vinetto, KWS Tayo and SU Arvid achieved yields of 8.4-9.6 t/ha, minimised leaf-area losses during hydrothermal stress and exhibited strong resistance to major diseases. It was generalised that the introduction of these hybrids enhanced the resource efficiency of production technologies, reduced agrochemical pressure and supported the formation of ecologically resilient agroecosystems. The practical value of the study lies in identifying hybrids suitable for both conventional and organic farming systems, with the results being applicable to agricultural producers, advisory services and breeding centres when optimising varietal policy and implementing environmentally oriented cultivation strategies

Keywords

ecological plasticity; yield stability; biometric traits; winter hardiness; hydrothermal stress; phytosanitary resistance

  1. Biliavska, L.H., & Biliavskyi, Yu.V. (2021). Current state of winter rye seed production in Ukraine. Scientific Progress & Innovations, 2, 67-73. doi: 10.31210/visnyk2021.02.08.
  2. Bogužas, V., Skinulienė, L., Butkevičienė, L.M., Steponavičienė, V., Petrauskas, E., & Maršalkienė, N. (2022). The effect of monoculture, crop rotation combinations, and continuous bare fallow on soil CO2 emissions, earthworms, and productivity of winter rye after a 50-year period. Plants, 11(3), article number 431. doi: 10.3390/ plants11030431.
  3. Convention on Biological Diversity. (1992, June). Retrieved from https://zakon.rada.gov.ua/laws/ show/995_030#Text.
  4. Convention on International Trade in Endangered Species of Wild Fauna and Flora. (1979, June). Retrieved from https://zakon.rada.gov.ua/laws/show/995_129#Text.
  5. External sustainability study confirms the excellent CO2 balance of KWS hybrid rye. (2023). Retrieved from https://www.kws.com/corp/en/media-press/company-news/external-sustainability-study-confirms-theexcellent-co2-balance-of-kws-hybrid-rye/.
  6. Hackauf, B., Siekmann, D., & Fromme, F.J. (2022). Improving yield and yield stability in winter rye by hybrid breeding. Plants, 11(19), article number 2666. doi: 10.3390/plants11192666.
  7. Hadasch, S., Laidig, F., Macholdt, J., Bönecke, E. & Piepho, H.P. (2020). Trends in mean performance and stability of winter wheat and winter rye yields in a long-term series of variety trials. Field Crops Research, 252, article number 107792. doi: 10.1016/j.fcr.2020.107792.
  8. Kostrzewska, M.K., & Jastrzębska, M. (2025). Hybrid cultivar and crop protection to support winter rye yield in continuous cropping. Agriculture, 15(13), article number 1368. doi: 10.3390/agriculture15131368.
  9. Laidig, F., Feike, T., Klocke, B., Macholdt, J., Miedaner, T., Rentel, D. & Piepho, H.P. (2021). Long-term breeding progress of yield, yield-related, and disease resistance traits in five cereal crops of German variety trials. Theoretical and Applied Genetics, 134, 3805-3827. doi: 10.1007/s00122-021-03929-5.
  10. Miedaner, Th., Lauenstein, S., & Lieberherr, B. (2025). Comparison of hybrid rye and wheat for grain yield and other agronomic traits under less favourable environmental conditions and two input levels. Agriculture, 15(2), article number 163. doi: 10.3390/agriculture15020163.
  11. Pasqui, M., & Di Giuseppe, E. (2019). Climate change, future warming, and adaptation in Europe. Animal Frontiers, 9(1), 6-11. doi: 10.1093/af/vfy036.
  12. Riedesel, L., Laidig, F., Hadasch, S., Rentel, D., Hackauf, B., Piepho, H.-P. & Feike, T. (2022). Breeding progress reduces carbon footprints of wheat and rye. Journal of Cleaner Production, 377, article number 134326. doi: 10.1016/j.jclepro.2022.134326.
  13. Sabluk, V.T., Kiienko, Z.B., & Dymytrov, S.H. (2018). Analysis of varietal resources of rye (Secale cereale L.) in the State Register of Plant Varieties of Ukraine. Plant Varieties Studying and Protection, 14(4), 431-439. doi: 10.21498/2518-1017.14.4.2018.151914.
  14. Smith, M.E., et al. (2023). Increasing crop rotational diversity can enhance cereal yields. Communications Earth & Environment, 4, article number 89. doi: 10.1038/s43247-023-00746-0.
  15. State Register of Plant Varieties Suitable for Distribution in Ukraine. (2024). Retrieved from https://minagro.gov.ua/napryamki/roslinnictvo/reyestr-sortiv-roslin-ukrayini/reyestr-sortiv-roslin-ukrayini.
  16. State Statistics Service of Ukraine. (n.d.). Retrieved from https://stat.gov.ua/en/node/5129.
  17. Symonenko, N.V., Levchenko, O.S., & Holyk, L.M. (2023). Proposals regarding the targeted use of short-stemmed winter rye grain in Ukraine. Agriculture and Plant Sciences: Theory and Practice, 1, 107-115. doi: 10.54651/ agri.2023.01.12.
  18. ter Steeg, E.M.S., Struik, P.C., Visser, R.G.F. & Lindhout, P. (2022). Crucial factors for the feasibility of commercial hybrid breeding in food crops. Nature Plants, 8, 463-473doi: 10.1038/s41477-022-01142-w.
  19. Topchii, O.V., Smulska, I.V., Zhytomyrets, O.S., Prysiazhniuk, L.M., Hryniv, S.M., Mykhailyk, S.M., & Kulyk, T.E. (2024). Yield and grain quality of new varieties of winter rye (Secale cereale L.) in different soil and climatic zones of Ukraine. Plant Varieties Studying and Protection, 20(2), 120-126. doi: 10.21498/2518-1017.20.2.2024.304100.
  20. Yang, W.Y., & Ma, C.X. (2024). Evolutionary biology of rye (Secale cereale): Domestication and adaptation. Triticeae Genomics and Genetics, 15(4), 221-233. doi: 10.5376/tgg.2024.15.0021.
  21. Zymaroieva, A., & Nykytiuk, Y. (2023). Agroecological drivers of winter rye (Secale cereale) yield spatio-temporal variation. Agrology, 6(4), 86-91. doi: 10.32819/021114.
Stoliar, S., & Melnyk, M. (2025). Assessment of the adaptability of winter rye hybrids for cultivation in the Forest-Steppe zone of Ukraine. Scientific Horizons, 28(12), 9-17. https://doi.org/10.48077/scihor12.2025.09