PROTECTION WITH A BIOACTIVE COMPOSITION BASED ON PLUMBAGIN (CERATOSTIGMA PLUMBAGINOIDES BUNGE) AND NA-ASCORBATE PIGMENTS AND PSII IN OXIDATIVE STRESS
Abstract
The protective properties of Na-ascorbate and a bioactive composition (BAC) obtained on the basis of plumbagin from roots (Ceratostigma plumbaginoides Bunge) under the toxic effect of Zn2+ and Ni2+ on wheat seedlings (Triticum aestivum L.) were studied. The change in the characteristics of millisecond delayed fluorescence (msec DF Chl a) reflecting the state of PS II shows a decrease in the blocking of the activity of the electron transport chain (ETC) on the acceptor side under the action of Zn2+ and Ni2+ and on the donor side under the action of Ni2+. The resistance of Chl b 650 decreases and the resistance of carotenoids to this stress increases. The action of Na-asс and BAC changes the ratio of pigments. Na-asc restores the activity of the donor side and increases the work of the acceptor side of the ETC upon sequential action with Zn2+. The activity of the acceptor side of the ETC is restored with the simultaneous action of Na-asc with Ni2+. The effect of the BAC is manifested in the restoration of the activity of the donor side of the ETC PS II with sequential action with metals. The corrective effect of Na-asc and LHC is determined by their ability to neutralize reactive oxygen species formed under stress and to support the redox reactions of photosystems.
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