Autor: |
Logvinenko L; Nikitsky Botanic Gardens, National Scientific Center of RAS, 298648 Yalta, Russia., Golubkina N; Analytical Laboratory Department, Federal Scientific Vegetable Center, 143072 Moscow, Russia., Fedotova I; Nikitsky Botanic Gardens, National Scientific Center of RAS, 298648 Yalta, Russia., Bogachuk M; Laboratory of Food Products, Institute of Nutrition and Biotechnology, 109240 Moscow, Russia., Fedotov M; Laboratory of New Metallurgical Processes and Alloys, A. Baikov Institute of Metallurgy and Material Science, 119334 Moscow, Russia., Kataev V; Laboratory of New Metallurgical Processes and Alloys, A. Baikov Institute of Metallurgy and Material Science, 119334 Moscow, Russia., Alpatov A; Laboratory of New Metallurgical Processes and Alloys, A. Baikov Institute of Metallurgy and Material Science, 119334 Moscow, Russia., Shevchuk O; Nikitsky Botanic Gardens, National Scientific Center of RAS, 298648 Yalta, Russia., Caruso G; Department of Agricultural Sciences, University of Naples Federico II, Portici, 80055 Naples, Italy. |
Abstrakt: |
Selenium (Se) biofortification of aromatic plants is a promising strategy to produce valuable functional food with high biological activity and enhanced essential oil yield. The experiment carried out in 2021 and 2022 on A. annua treated with sodium selenate or nano-Se sprayed on foliar apparatus demonstrated a significant increase in photosynthetic pigments, pectin, waxes, macro- and microelements and a decrease in malonic dialdehyde (MDA) accumulation. Contrary to literature reports, neither selenate nor nano-Se showed a beneficial effect on essential oil accumulation; the oil yield did not differ between the selenate treated and control plants but was halved by the nano-Se application. Extremely high variations in the number of essential oil components, as well as in the eucalyptol, artemisia ketone, camphor and germacrene D ratio in the 2021 and 2022 experiments were recorded. The analysis of the 2016-2022 data for oil yield and composition in the control plants revealed a direct correlation between the number of components and of solar flares, and a negative correlation between oil yield and the percentage of spotless days. Both control plants and plants fortified with selenium showed higher levels of germacrene D and lower levels of artemisia ketone in 2022, characterized by more remarkable solar activity compared to 2021. Nano-Se supply resulted in the highest percentage of germacrene D accumulation. The results of the present research highlight the importance of the solar activity effect on the essential oil yield and quality of aromatic plants. |