Науковий журнал «Український журнал лісівництва та деревинознавства»

Abstract. Cultivation of qualitative planting material involves optimal extra nutrition conditions, which requires understanding of biochemical and physiological processes associated with seedlings adaptation. A reliable integral indicator of plants viability is plastidial pigments composition, oxidoreductases activity, secondary metabolites synthesis, including phenolic compounds of pigmental complex.

Research results of water-soluble fertilizers “Harmoniya”, “Rozsada-start” and “Novofert-Universal” on phenolic substances content in pine seedlings needles in their extra nutrition different conditions are given. Peculiarities of phenolic compounds synthesis, content and ratio of plastidial pigments in Scots pine seedlings needles under water-soluble fertilizers influence are shown.

Volynets, A. P. (2013). Fenolnye soedynenyia v jyznedeiatelnosty rastenyu [Phenolic compounds in plant activity]. Mynsk, 283.

Zaprometov, M. N. (1993). Fenolnye soedynenyia. Rasprostranenye, metabolyzm i funkcyu v rastenyiax [Phenolic compounds. Distribution, metabolism and function in plants]. Moskva, 272.

Lykhanov, A. F. Sereda, O. V., Kliachenko, & O. L., Melnychuk, M. D. (2018). Vplyv oksykorychnyx i oksybenzoynux kyslot na syntez plastydnyx pygmentov I fenolnyx spolyk v lystkax vynogradu (Vitis vinifera) in vitro [Influence of oxycoric and oxybenzoic acids on synthesis of plastid pigments and fenolic compounds in the leaves of common grape vine (Vitis vinifera) in vitro]. Plant Physilogy and Genetics, 50, 4, 331–343.

Sybgatullina, G. V., Haertdynova, E. A., Gumerova, E. A., & et al. (2011). Metody opredelenia redoks-statusa kultyvyruemyx kletok rastenyu [Methods for determining the redox status of cultured plant cells]. Kazan, 61.

Pinchuk, A. P., & Gengalo, O. M. (2015). Efektyvnyst pozakorenevyx pydjyvlen dlia pydvyschennya produktyvnosty nakopychennia masy ta elementyv myneralnogo jyvlennia syianciamu sosny [Efficiency of foliar feeding to increase the productivity of mass accumulation and mineral nutrition elements by pine seedlings]. Forestry and Landscape Gardening, 8. Availabe at: http://ejournal.studnubip.com/zhurnal-8/ukr/pinchuk_henhalo/.

Sudachkova, N. E. Celi i perspektivy fiziologo-biohimicheskih issledovanij drevesnyh rastenij Sibiri [Goals and prospects of physiological and biochemical studies of woody plants of Siberia]. Available at: http://www.professors.ru/A_Sudachkova.html.

Beggs, C. J., Wellmann E., & Grisebach, H. (1986). Photocontrol of flavonoid biosynthesis. In: Kendrick R. E., Kronenberg G. H. M. (eds). Morphogenesis in plants. Martinus Nijhoff, Dordrecht, 467–499.

Fliegmann, J., Schroder, G., Schanz, S., Britsch, L., & Schroder, J. (1992). Molecular analysis of chalcone and dihydropinosylvin synthase from Scots pine (Pinus sylvestris) and differential regulation of these and related enzyme activities in stressed plants. Plant Molecular Biology, 18, 489–503.

Grana E., Costas-Gil A., Longueira S., Celeiro M., Teijeira M., Reigosa M. J., & Sanchez-Moreiras A. M. (2017). Auxin-like effects of the natural coumarin scopoletin on Arabidopsis cell structure and morphology. Journal of Plant Physiology, 218, 45–55.

Wrolstad, R. & et al. (eds.). (2005). Handbook of Food Analytical Chemistry: Pigments, Colorants, Flavors, Texture, and Bioactive Food Components – Pigments and colorants. F. 4, 175–176.

Pinchuk, A. P., Likhanov, A. F., Babenko, L. P., Kryvtsova, M. V., Demchenko, O. A., Sherbakov, O. B., Lazarenko, L. M., & Spivak, M. Ya. (2017). The influence of cerium dioxide nanoparticles on seed germination and secondary metabolism of pine seedlings (Pinus sylvestris L.). Biotechnologia Acta, 10, 5, 14.

Schnitzler, J.-P., Jungblut, T. P., Feicht, C., Kоfferlein, M., Langebartels, C., Heller, W., & Sandermann, H. (1997). UV-B induction of flavonoid biosynthesis in Scots pine (Pinus sylvestris L.) seedlings. Jr. Trees, 11, 162–168.