Ishen N Besaliev, Alexander L Panfilov

Animal Husbandry and Fodder Production. 2023. Vol. 106, no 3. Р. 202-212.

doi: 10.33284/2658-3135-106-3-202

Original article

Duration and conditions of interphase periods of vegetation as productivity factors of spring

wheat varieties in Orenburg Cis-Urals

Ishen N Besaliev¹, Alexander L Panfilov²

^1,2Federal Research Centre for Biological Systems and Agrotechnologies of the Russian Academy of Sciences, Orenburg, Russia

¹orniish_tzk@mail.ru, https://orcid.org/0000-0001-9389-1938

²panfilov-1@mail.ru, https://orcid.org/0000-0002-1210-6350

Abstract. The duration of the vegetation period of a spring wheat variety determines its belonging to the ripeness group and largely characterizes the biological characteristics in the formation of productivity. In recent years, as a result of changes in climatic factors, the meteorological conditions of interphase periods have a significant impact on their duration. The article contains the results of 6-year studies on the duration of interphase periods of vegetation of varieties of spring soft wheat, their relationship with productivity and dependence on meteorological conditions. The years of research differed in the presence of favorable (2017, 2022), average (2016) and extremely unfavorable (2018, 2019, 2020) years. The duration of the growing season varied from 69 to 85 days for Uchitel variety, from 72 to 90 days for the Tulajkovskaya zolotistaya variety, and from 69 to 92 days for the Ulyanovskaya 105 variety favorable weather conditions and the dependence of the yield of varieties on the duration of the growing season. It has been established that the yield of spring wheat is closely related to the duration of the entire growing season (r = 0.976), as well as to a large extent with the duration of the period shoots - tillering (r = 0.900), tillering - tube growth (r = 0.514), tube growth – heading (r = 0.844). The optimal parameters of the duration of the interphase periods of vegetation were calculated, at which the formation of the maximum yield of spring wheat varieties under the conditions of the study area is possible.

Keywords: spring wheat, variety, yield, interphase period, correlation coefficient

Acknowledgments: the work was performed in accordance to the plan of research works for 2022-2024 FSBRI FRC BST RAS (FNWZ -2022-0014).

For citation: Besaliev IN, Panfilov AL. Duration and conditions of interphase periods of vegetation as productivity factors of spring wheat varieties in Orenburg Cis-Urals. Animal Husbandry and Fodder Production. 2023;106(3):202-212. (In Russ.). https://doi.org/10.33284/2658-3135-106-3-202

References

1. Dospekhov BA. Methods of field experiment (with the basics of statistical processing of research results). 5th ed., supplement. and reworked. Moscow: Agropromizdat; 1985:351 p.
2. Evdokimov MG, Yusov VS, Pakhotina IV. Influence of the duration of the growing season on the formation of economically valuable traits of hard spring wheat in Western Siberia. Bulletin of KSAU. 2022;11(188):19-26. doi: 10.36718/1819-4036-2022-11-19-26
3. Kumratova AM, Aleshhenko VV. Productivity of grain production in Russia: trends and prospects. Vestnik of the Kazan State Agrarian University. 2021;3(63):142-146. doi: 10.12737/2073-0462-2021-142-146
4. Methods of state variety testing of agricultural crops. Issue 2: Cereals, cereals, legumes, corn and fodder crops. Moscow; 1989:194 p.
5. Methods of state variety testing of agricultural crops. Issue 1. General part. Moscow; 2019:329 p.
6. Mishhenko LN, Teryokhin MV, Teryokhin NM. The influence of the duration of the growing season on the crop yield and grain size of spring wheat in the Amur region. Far Eastern Agrarian Herald. 2019;4(52):31-37. doi: 24411/1999-6837-2019-14049
7. Poskrebysheva MM, Ismagilov RR. Growth and development rates of spring wheat depending on hydrothermal conditions. Vestnik of the Kazan State Agrarian University. 2020;1(57):38-42. (In Russ.)]. doi: 10.12737/2073-0462-2020-1-38-42
8. Rozova MA, Ziborov AI, Egiazaryan EE. Relationship of temperature indicators of the growing season with the main agronomically significant characteristics of spring durum wheat varieties in Altai. Russian Agricultural Science. 2021;5:9-15. doi: 31857/S2500262721050021
9. Syzdykova GT, Sereda SG, Malitskaya NV. Selection of spring soft wheat (Triticum aestivum L.) varieties for the adaptability in the conditions of steppe zone of the Akmolinsk region, Kazakhstan. Sel’skokhozyaistvennaya biologiya [Agricultural Biology]. 2018;53(1):103-110.  doi: 10.15389/agrobiology.2018.1.103rus   doi: 10.15389/agrobiology.2018.1.103eng
10. Fyorster E, Ryonc B. Methods of correlation and regression analysis: a guide for economists. transl. with him. and foreword. V.M. Ivanova. Moscow: Finance and statistics, 1983. 302 p.
11. Ahmad S, Abbas G, Ahmed M, Fatima Z, Anjum MA, Rasul G, Khan MA, Hoogenboom G. Climate warming and management impact on the change of phenology of the rice-wheat cropping system in Punjab, Pakistan. Field Crops Res. 2019;230:46-61. doi: 10.1016/j.fcr.2018.10.008
12. Akter N, Rafiqul IM. Heat stress effects and management in wheat. A review. Agron Sustain Dev. 2017;37:37. doi: 10.1007/s13593-017-0443-9
13. Fang L, Martre P, Jin K, Du X, van der Putten PEL, Yin X, Struik PC. Neglecting acclimation of photosynthesis under drought can cause significant errors in predicting leaf photosynthesis in wheat. Glob Chang Biol. 2023;29(2):505-521. doi: 10.1111/gcb.16488
14. He L, Jin N, Yu Q. Impacts of climate change and crop management practices on soybean phenology changes in China. Sci Total Environ. 2020;707:135638. doi: 10.1016/j.scitotenv.2019.135638
15. Kahiluoto H, Kaseva J, Balek J, Olesen JE, Ruiz-Ramos M, Gobin A, Kersebaum KC, Takáč J, Ruget F, Ferrise R, Bezak P, Capellades G, Dibari C, Mäkinen H, Nendel C, Ventrella D, Rodríguez A, Bindi M, Trnka M. Decline in climate resilience of European wheat. 2019;116(1):123-128. doi: 10.1073/pnas.1804387115
16. Menzel A, Yuan Y, Matiu M, Sparks T, Scheifinger H, Gehrig R, Estrella N. Climate change fingerprints in recent European plant phenology. Glob Change Biol. 2020;26(4):2599-2612. doi: 10.1111/gcb.15000
17. Menzel A. Trends in phenological phases in Europe between 1951 and 1996. Int J Biometeorol. 2000;44:76-81. doi: 10.1007/s004840000054
18. Narayanan S. Effects of high temperature stress and traits associated with tolerance in wheat. Open Access J Sci. 2018;2(3):177-186. doi: 10.15406/oajs.2018.02.00067
19. Ru C, Hu X, Chen D, Wang W, Zhen J, Song T. Individual and combined effects of heat and drought and subsequent recovery on winter wheat (Triticum aestivum L.) photosynthesis, nitrogen metabolism, cell osmoregulation, and yield formation. Plant Physiol Biochem. 2023;196:222-235. doi: 10.1016/j.plaphy.2023.01.038
20. Sonkar G, Mall RK, Banerjee T, Sing N, Lakshmi Kumar L, Chand R. Vulnerability of Indian wheat against rising temperature and aerosols. Environmental Pollution. 2019;254:112946. doi: 10.1016/j.envpol.2019.07.114
21. Wang Х, Mao Z, Zhang J, Hemat M, Huang M, Cai J, Zhou Q, Dai T, Jiang D. Osmolyte accumulation plays important roles in the drought priming induced tolerance to post-anthesis drought stress in winter wheat (Triticum aestivum L.) Environmental and Experimental Botany. 2019;166:103804. doi: 10.1016/j.envexpbot.2019.1038044

Information about the autors:

Ishen N Besaliev, Dr. Sci. (Agriculture), Head of the Department of Grain and Forage Crops Technologies, Federal Research Centre for Biological Systems and Agrotechnologies of the Russian Academy of Sciences, 27/1 Gagarin Ave., Orenburg, 460051, tel.: 8 (3532)30-83-47.

Alexander L Panfilov, Cand. Sci. (Agriculture), Leading Researcher, Department of Grain and Forage Crops Technologies, Federal Research Centre for Biological Systems and Agrotechnologies of the Russian Academy of Sciences, 27/1 Gagarin Ave., Orenburg, 460051, tel.: 89225585392.

The article was submitted 26.06.2023; approved after reviewing 01.08.2023; accepted for publication 11.09.2023.