Аналіз білкового комплексу та вмісту ізофлавонів насіння сої та нуту в зв’язку з селекцією продовольчого напряму

  • О. О. Молодченкова Plant Breeding & Genetic Institute – National Center of Seed and Cultivar Investigation, Ukraine, 65036, Оdessa, Оvidiopolskaya doroga, 3
  • В. І. Січкар Plant Breeding & Genetic Institute – National Center of Seed and Cultivar Investigation, Ukraine, 65036, Оdessa, Оvidiopolskaya doroga, 3
  • Т. В. Картузова Plant Breeding & Genetic Institute – National Center of Seed and Cultivar Investigation, Ukraine, 65036, Оdessa, Оvidiopolskaya doroga, 3
  • Л. Я. Безкровна Plant Breeding & Genetic Institute – National Center of Seed and Cultivar Investigation, Ukraine, 65036, Оdessa, Оvidiopolskaya doroga, 3
  • О. Б. Лихота Plant Breeding & Genetic Institute – National Center of Seed and Cultivar Investigation, Ukraine, 65036, Оdessa, Оvidiopolskaya doroga, 3
  • Г. Д. Лаврова Plant Breeding & Genetic Institute – National Center of Seed and Cultivar Investigation, Ukraine, 65036, Оdessa, Оvidiopolskaya doroga, 3

Анотація

Aim. The goal of research was to study the features of protein complex and isoflavones content in the soybean and checkpea seed for development the characterictics of legume selection of food direction. Methods. 7S and 11S globu-lins were separated by method, which was developed in the Laboratory of Plant Biochemistry (Patent # 42181). Protein content was determined by Kjeldahl method. Isoflavones content were determined by spectrophotometric method. Results. The features of protein complex and isoflavones content in the soybean and checkpea seed of genotypes of Ukrainian and foreign plant breeding were researched. It was shown that the studied genotypes of soybean, chickpea differ widely in the content of total protein, 7S and 11S globulins and isoflavones. The polymorphism between varieties on the electrophoresis spectrums of component composition of 7S and 11S globulins of soybean was established. The features of 7S and 11S globulins content, its ratio and component composition of genotypes of different phylogenesis origin, F3.F8 hybrids of soybean and their paternal forms were identified. It was established that soybean and checkpea genotypes of different phylogenesis origin were characterized by different content in the component composition of storage proteins of α, α', β subunits of β-conglycinin, А3, А5, А, B components of glycinin, 2S albumin, vicilin subunit (50 kDa), legumin subunit (20 kDa). These subunits and components have negative and positive influence on the man health. Conclusions. The got results open fundamentally new approach of estimation of legumes on a quality of seed and can be used for authetication of legume varieties of the food direction.

Keywords: Legume, 11S globulin, 7S globulin, isoflavones.

Посилання

Klimenko V.G. Belki semian bobovykh rasteniy. Kishinev, Shtiitsa, 1978. 248 p. [in Russian]

Guo S.T., Meng Y., Zhang X.M., Zhang X.L., Qi J., Qiu L.J., Chang R.Z. Analysis of protein subunit composition of Chinise soybean [Glycine max (L.) Merrill] cultivars and screening cultivars lacking some subunits. Acta Agronomica. 2006. P. 1130–1134.

Casey R., Domoney C., Smith A.M. Pear: genetics, molecular biology and biotechnology. In: R. Casey&D.R. Davies, Biotechnology in agricultural series. Wallingford, Oxon, UK: CAB International, 1993. P. 121–164.

Rao J.A.V., Qadri A., Koundal K.R. Purification and immunochemical characterization of vicilin storage protein of chickpea (Cicer arietinum L.). International Journal of Biological Technology. 2011. V. 2 (3). P. 21–28.

Yaklich R.W. β-Congycinin and glycininin in high protein soybean. G. Agric. Food. Chem. 2000. V. 49. P. 729–735. doi: 10.1021/jf001110s

Dadon S.B.E., Pascual C.Y., Eshel D., Teper-Bamnolker P., Ibanez M.D.P., Reifen R. Vicilin and the basic of legumin are putative chickpea allergens. Food chemistry. 2013. V. 138. P. 13–18. doi: 10.1016/j.foodchem.2012.10.031

Baraboy V.A. Izoflavony soi: biologicheskaia aktivnost' i primenenie// Biotekhnologiia. 2009. V. 2(3). P. 44–54. [in Russian]

Hasanah Y., Nisa T.C., Armidin H., Hanum H. Isoflavone content of soybean [Glycine max(L.) Merr.] cultivars with different nitrogen sources and growing season under dry land conditions. Journal of Agriculture and Environmental Development. 2015. V. 109 (1). P. 5–17.

Megias C., Cotes-Giraldo I., Alaiz M., Vioque J., Giron-Calle J. Isoflavone in chickpea (Cicer arietinim L.) protein concentrates. Journal of functional foods. 2016. V. 21. P. 186–192. doi: 10.1016/j.jff.2015.12.012

Adamovs'ka V.H., Molodchenkova O.O., Sichkar V.I., Tsisel's'ka L.Y., Sahaydak T.V. Patent na korysnu model' No. 42181. Sposib doboru soi. 25.06.2009. [in Ukrainian]

Vasiukova A.N. Izuchenie soderzhaniia summy flavonoidov v semenakh i prorostkakh soi. Sel'skokhoziaystvennye nauki i agropromyshlennyy kompleks. 2013. No. 4. P. 9–13. [in Russian]

Levitskiy A.P. Metody opredeleniia ingibitorov tripsina. Biokhimicheskie metody issledovaniia selektsionnogo materiala. Odessa: VSGI, 1979. V. 15. P. 68–72. [in Russian]

Budnitskaia E.V. Issledovanie aktivnosti lipoksigenazy kormovikh trav metodom okisleniia karotina. Biokhimiia. 1955. V. 20(5). P. 615–621. [in Russian]

Carrão-Panizzi M.C., Kwanyuen P., Erhan S.Z., Lopes I.O.N. Genetic variation and environmental effects on beta-conglycinin and glycinin content in Brazilian soybean cultivars. Pesquisa Agropecuária Brasileira. 2008. V. 43(9). P. 725–729. doi: 10.1590/S0100-204X2008000900002