References

vavilov

Вавиловский журнал генетики и селекции

Vavilov Journal of Genetics and Breeding

2500-3259

Institute of Cytology and Genetics of Siberian Branch of the RAS

10.18699/VJ18.414

vavilov-1657

Research Article

Селекция растений на иммунитет и продуктивность

Plant breeding for immunity and performance

Влияние погодно-климатических условий на содержание белка и масла в семенах сои на Северном Кавказе

Impact of weather and climate on seed protein and oil content of soybean in the North Сaucasus

https://orcid.org/0000-0003-4051-3671

Новикова

Л. Ю.

Novikova

L. Yu.

Санкт-Петербург.

St. Petersburg.

https://orcid.org/0000-0003-3308-9198

Сеферова

И. В.

Seferova

I. V.

Санкт-Петербург.

St. Petersburg.

i.seferova@vir.nw.ru

https://orcid.org/0000-0001-7332-1209

Некрасов

А. Ю.

Nekrasov

A. Yu.

Краснодарский край, Гулькевичский район, пос. Ботаника.

village Botanika, Gul’kevichskii Region, Krasnodarskii Krai.

https://orcid.org/0000-0001-6568-5248

Перчук

И. Н.

Perchuk

I. N.

Санкт-Петербург.

St. Petersburg.

https://orcid.org/0000-0003-3992-5353

Шеленга

Т. В.

Shelenga

T. V.

Санкт-Петербург.

St. Petersburg.

https://orcid.org/0000-0001-8170-1260

Самсонова

М. Г.

Samsonova

M. G.

Санкт-Петербург.

St. Petersburg.

https://orcid.org/0000-0003-2808-7745

Вишнякова

М. А.

Vishnyakova

M. A.

Санкт-Петербург.

St. Petersburg.

Федеральный исследовательский центр Всероссийский институт генетических ресурсов растений им. Н.И. Вавилова (ВИР); Санкт-Петербургский политехнический университет им. Петра Великого.РоссияFederal Research Center the N.I. Vavilov All-Russian Institute of Plant Genetic Resources (VIR); Peter the Great St. Petersburg Polytechnic University.Russian Federation

Федеральный исследовательский центр Всероссийский институт генетических ресурсов растений им. Н.И. Вавилова (ВИР).РоссияFederal Research Center the N.I. Vavilov All-Russian Institute of Plant Genetic Resources (VIR).Russian Federation

Кубанская опытная станция – филиал Федерального исследовательского центра Всероссийский институт генетических ресурсов растений им. Н.И. Вавилова.РоссияKuban Experiment Breeding Station, Branch of N.I. Vavilov All-Russian Institute of Plant Genetic Resources.Russian Federation

Санкт-Петербургский политехнический университет им. Петра Великого.РоссияPeter the Great St. Petersburg Polytechnic University.Russian Federation

2018

26092018

226708715

2018

Новикова Л.Ю., Сеферова И.В., Некрасов А.Ю., Перчук И.Н., Шеленга Т.В., Самсонова М.Г., Вишнякова М.А.

Novikova L.Y., Seferova I.V., Nekrasov A.Y., Perchuk I.N., Shelenga T.V., Samsonova M.G., Vishnyakova M.A.

This work is licensed under a Creative Commons Attribution 4.0 License.

https://vavilov.elpub.ru/jour/article/view/1657

Для адресного подбора исходного материала в селекции на качество семян сои необходимо знание зависимости соответствующих характеристик семян от погодно-климатических условий в конкретном регионе. Определенное влияние на качество семян оказывает и глобальное изменение климата. Поэтому целью данной работы было выявление связи изменчивости содержания белка и масла в семенах сои с климатическими параметрами на Северном Кавказе, а также трендов этой изменчивости за длительный временной период. На основе изучения 1 442 образцов сои из коллекции ВИР оценены тенденции изменчивости содержания белка и масла в семенах в условиях Краснодарского края за период 1987–2015 гг. Методом регрессионного анализа в разностях с последовательным включением переменных построены модели зависимости содержания белка и масла от обобщенных агрометеорологических показателей. В течение 1987–2015 гг. для периода с температурами выше 10 °С наблюдался рост сумм активных температур на 218 °С/10 лет и недостоверное уменьшение осадков на 20.9 мм/10 лет. В динамике содержания белка выявлен тренд к росту на 2.5 % за 10 лет, по содержанию масла достоверной тенденции нет. Наибольшее среднее содержание масла и наименьшее белка было у среднеспелых образцов (22.2 и 38.8 %), а относительно высоким содержанием белка характеризовались ранние (21.6 и 40.0 %) и поздние (20.2 и 39.9 %) образцы. Содержание белка росло с увеличением продолжительности периода с температурами выше 22 °С и уменьшалось с ростом осадков за период с температурами выше 18 °С. Накоплению масла в семенах способствовало увеличение гидротермического коэффициента за период с температурами выше 19 °С, у поздних сортов этому препятствовал длительный осенний период с температурами ниже 15 °С. Многолетний рост содержания белка обусловлен как изменением климата, так и генетическим улучшением сортов.

For a targeted search of initial breeding material for the quality of soybean seeds, it is necessary to know the patterns of the dependence of the corresponding seed characters on the weather and climatic conditions in a particular region. Global climatic change, the concretization of which is relevant, has a share in this dependence. Thus, the aim of this work was to identify the relationship between the variability of protein and oil content in soybean seeds with climatic parameters in the North Caucasus as well as trends in this variability over a long time period. The study of 1 442 soybean accessions from VIR collection in the Krasnodar region during 1987–2015 had been carried out and the tendencies of the variability of protein and oil content in seeds in this environment were estimated. The regression analysis in differences with forward stepwise selection of variables has been used to construct models for the dependence of the protein and oil content on generalized agrometeorological indices. During 1987–2015, for the period with temperatures above 10 °C, the sums of active temperatures increased by 218 °C/10 years and precipitation decreased by 20.9 mm/10 years. In the dynamics of protein content, a trend has been revealed as an increase by 2.5 % over 10 years, while there is no reliable trend in oil content. The maximum average mean of oil content and the smallest protein were in the middle-maturing accessions (22.2 and 38.8 %), and a relatively high protein content was detected, on average, in the early- (21.6 and 40.0 %) and late-maturing (20.2 and 39.9 %) varieties. The protein content had been increasing with a growth of the duration of the period with temperatures above 22 °C and decreasing with a raise in precipitation over a period of temperatures above 18 °C. The accumulation of oil in seeds was promoted by an increase of the hydrothermal coefficient over the period with temperatures above 19 °C, and, in late-maturating varieties, prevented by a prolonged autumn period with temperatures below 15 °C. Long-term growth in protein content is due to both climatic change and genetic improvement of varieties.

соябелокмаслоизменения климатаСеверный Кавказ

soybeanproteinoilclimate changeNorth Caucasus

References1

Andresen J.A., Alagarswamy G., Rotz C.A., Ritchie J.T., LeBaron A.W. Weather impacts on maize, soybean, and alfalfa production in the great lakes region. 1895–1996.

Agron. J. 2001;93:1059-1070. DOI 10.2134/agronj2001.9351059x.

Baranov V.F., Lukomec V.M. (Ed.). Soybean: Biology and Technology of Cultivation. Krasnodar: Sovetskaya Kuban’ Publ., 2005. (in Russian)

Bellaloui N., Bruns H.A., Abbas H.K., Mengistu A., Fisher D.K., Reddy K.N. Agricultural practices altered soybean seed protein, oil, fatty acids, sugars, and minerals in the Midsouth USA. Front. Plant Sci. 2015;6:31. DOI 10.3389/fpls.2015.00031.

Belolyubcev A.I., Senni kov V.A. Bioclimatic Potential of Ecosystems: Manual. Moscow: Russian State Agrarian University – Moscow Timiryazev Agricultural Academy, 2012. (in Russian)

Dardanelli J.L., Balzarini M., Martinez M.J., Cuniberti M., Resnik S., Ramunda S.F., Herrero R., Baigorri H. Soybean maturity groups, environments, and their interaction define mega-environments for seed composition in Argentina. Crop Sci. 2006;46(5):1939-1947. DOI 10.2135/cropsci2005.12-0480.

Dornbos D.L., Mullen R.E. Soybean seed protein and oil contents and fatty acid composition adjustments by drought and temperature. J. Am. Oil Chem. Soc. 1992;69:228-231. DOI 10.1007/BF02635891.

Eliseeva I.I. (Ed.). Econometrics. Moscow: Finansy i Statistika Publ., 2007. (in Russian) Enken V.B. Soybean. Economic value. In: Grain Legumes. Moscow; Leningrad: Sel’khozgiz Publ., 1953;174-220. (in Russian)

Ermakov A.I. (Ed.). Methods of Biochemical Evaluation of Plants. Leningrad, 1987. (in Russian)

Ermolina O.V., Antonov S.I., Korotkova O.V. Change of soybean seed quality during breeding in the Don region. Zernovoe Khozjaistvo Rossii = Grain Economy of Russia. 2011;6:20-28. (in Russian)

Gibson L.R., Mullen R.E. Soybean seed composition under high day and night growth temperatures. J. Am. Oil Chem. Soc. 1996;73:733737. DOI 10.1007/BF02517949.

Iler A.M., Inouye D.W., Schmidt N.M., Høye T.T. Detrending phenological time series improves climate-phenology analyses and reveals evidence of plasticity. Ecology. 2017;98(3):647-655. DOI 10.1002/ecy.1690.

Kaukoranta T., Hakala K. Impact of spring warming on sowing times of cereal, potato and sugar beet in Finland. Agric. Food Sci. 2008; 17:165-176. DOI 10.2137/145960608785328198.

Kochegura A.V., Zelen tsov S.V., Moshnenko E.V., Petibskaya V.S. Breeding and genetic improvement of biochemical parameters in soybean. Maslichnye Kultury. Nauchno-Tekhnicheskiy Byulleten VNIIMK = Oil Crops. Scientific and Technical Bulletin of the AllRussian Research Institute of Oil Crops. 2005;2(133):24-35. (in Russian)

Korsakov N.I., Adamova O.P., Budanova V.I. Methodical Guidelines on the Study of the Collection of Grain Legumes. Leningrad: VIR Publ., 1975. (in Russian)

Leshchenko A.K., Mikhailov V.G., Sichkar V.I. Soybean Breeding, Seed Studies, and Seed Industry. Kiev: Urozhaj Publ., 1985. (in Russian)

Myakushko Yu.P., Baranov V.F. Soybean. Moscow: Kolos Publ., 1984. (in Russian)

Ojo D.K., Adebisi M.A., Tijani B.O. Influence of environment on protein and oil contents of soybeans seed (Glycine max (L.) Merril). Global J. Agric. Sci. 2002;1(1):27-32. DOI 10.4314/gjass.v1i1.2199.

Petibskaya V.S. Soy: Chemical Composition and Use. Krasnodar, 2012. (in Russian)

Piper E., Boote K.I. Temperature and cultivar effects on soybean seed oil and protein concentrations. J. Am. Oil Chem. Soc. 1999;76(10): 1233-1241. DOI 10.1007/s11746-999-0099-y.

Sato K., Ikeda Т. The growth responses of soybean to photoperiod and temperature. IV. The effect of temperature during the ripening period on the yield and characters of seeds. Jpn J. Crop. Sci. 1979;48:283290. DOI 10.1626/jcs.48.283.

Seferova I.V., Novikova L. Yu., Nekrasov A.Yu. Assessment of the response of soybean cv. Komsomolka to climate changes in the Krasnodar region. Maslichnye Kultury. Nauchno-Tekhnicheskiy Byulleten VNIIMK = Oil Crops. Scientific and Technical Bulletin of the All-Russian Research Institute of Oil Crops. 2011;1(146-147):7277. (in Russian)

Shchelko L., Sedova T., Kornej chuk V., Pastukha L., Sinskiy T., Gof irek P., Baresh I., Segnalova I. The International Comecon List of Descriptors for the Genus Glycine Willd. Leningrad, 1990. (in Russian)

Sirotenko O.D. Basis of Agricultural Meteorology. Vol. 2: Methods of Calculations and Forecasts in Agricultural Meteorology. Book 1: Mathematical Models in Agricultural Meteorology. Obninsk, 2012. (in Russian)

Song W., Yang R., Wu T., Wu C., Sun S., Zhang S., Jiang B., Tian S., Liu X., Han T. Analyzing the effects of climate factors on soybean protein, oil contents, and composition by extensive and high-density sampling in China. J. Agric. Food Chem. 2016;64(20):4121-4130. DOI 10.1021/acs.jafc.6b00008.

Stepanova V.M. Climate and Variety: Soybean. Leningrad: Gidrometeoizdat Publ., 1985. (in Russian)

Sudaric A., Simic D., Vrataric M. Characterization of genotype by environment interactions in soybean breeding programmes of Southeast Europe. Plant Breed. 2006;125:191-194. DOI 10.1111/j.14390523.2006.01185.x.

USDA (United States Department of Agriculture). Agricultural Research Service. https://www.ars-grin.gov/npgs/index.html. Available 08.02.2018.

Usual Planting and Harvesting Dates for U.S. field crops. Agricultural Statistics Board December. National Agricultural Statistic Service, USDA. 1997. Agricultural Handbook.

Vishnyakova M.A. (Ed.). Collection of World Genetic Resources of Grain Legumes in VIR: Enlargement, Preservation, and Investigation. St. Petersburg: VIR Publ., 2010. (in Russian)

Vrochinskij I.D. Breeding works of the Harbin experimental field of CER. Work of the Agronomical Branch of the Land Department of CER over 12 years (1922–1933). Harbin, 1935;251-299. (in Russian)

Wolf R.B., Cavins J.F., Kleiman R., Black L.T. Effect of temperature on soybean seed constituents: oil, protein, moisture, fatty acids, amino acids, and sugars. J. Am. Oil Chem. Soc. 1982;59:230-232. DOI 10.1007/BF02582182.

Yaklich E.W., Vinyard B., Camp M., Douglass S. Analysis of seed protein and oil from soybean Northern and Southern Region Uniform Tests. Crop. Sci. 2002;42:1504-1515. DOI 10.2135/cropsci2002.1504.

Zelentsov S.V., Moshnenko E.V. Ways of adaptation of Russian agriculture to global climatic changes by the example of soybean ecological breeding. Nauchnyi Dialog = Scientific Dialogue. 2012; 7:40-59. (in Russian)

Zelentsov S.V., Moshnenko E.V. Prospects of the breeding of highprotein soybean varieties: modeling of mechanisms increasing protein content in seeds: Report 1. Maslichnye Kultury. Nauchno-Tekhnicheskiy Byulleten VNIIMK = Oil Crops. Scientific and Technical Bulletin of the All-Russian Research Institute of Oil Crops. 2016;2(166):34-41. (in Russian)

The authors declare that there are no conflicts of interest present.