Abstract
Key messageDecreased absorptance and increased singlet oxygen production may cause photoinhibition of both PSII and PSI in birch leaves during autumn senescence; however, photosynthetic electron transfer stays functional until late senescence.During autumn senescence, deciduous trees degrade chlorophyll and may synthesize flavonols. We measured photosynthetic parameters, epidermal flavonols, singlet oxygen production in vivo and photoinhibition of the photosystems (PSII and PSI) from green and senescing silver birch (Betula pendula) leaves. Chlorophyll a fluorescence and P700 absorbance measurements showed that the amounts of both photosystems decreased throughout autumn senescence, but the remaining PSII units stayed functional until ~ 90% of leaf chlorophyll was degraded. An increase in the chlorophyll a to b ratio, a decrease in > 700 nm absorbance and a blue shift of the PSI fluorescence peak at 77 K suggest that light-harvesting complex I was first degraded during senescence, followed by light-harvesting complex II and finally the photosystems. Senescing leaves produced more singlet oxygen than green leaves, possibly because low light absorption by senescing leaves allows high flux of incident light per photosystem. Senescing leaves also induced less non-photochemical quenching, which may contribute to increased singlet oxygen production. Faster photoinhibition of both photosystems in senescing than in green leaves, under high light, was most probably caused by low absorption of light and rapid singlet oxygen production. However, senescing leaves maintained the capacity to recover from photoinhibition of PSII. Amounts of epidermal flavonols and singlet oxygen correlated neither in green nor in senescing leaves of silver birch. Moreover, Arabidopsis thaliana mutants, incapable of synthesizing flavonols, were not more susceptible to photoinhibition of PSII or PSI than wild type plants; screening of chlorophyll absorption by flavonols was, however, small in A. thaliana. These results suggest that flavonols do not protect against photoinhibition or singlet oxygen production in chloroplasts.
Highlights
During autumn senescence, deciduous trees degrade a vast number of macromolecules to remobilize nutrients for winter storage
To investigate the photosynthetic reactions during autumn senescence, especially the fates of both photosystems (PSII and photosystem I (PSI)), chlorophyll a fluorescence parameters and P 700 absorbance changes were simultaneously recorded with Dual/KLAS-NIR fluorometer/spectrophotometer from darkacclimated leaves with different chlorophyll concentrations
The fluorescence parameter FV/FM is a measure of the maximum quantum yield of photosystem II (PSII) photochemistry and F M is the maximum fluorescence value, obtained when all PSII reaction centers are closed for photochemistry
Summary
Deciduous trees degrade a vast number of macromolecules to remobilize nutrients for winter storage. Even though the nitrogen atoms of the chlorophyll molecules are not remobilized (Kräutler et al 1991; Curty and Engel 1996; for a review see Kuai et al 2018), chlorophyll is degraded via controlled pathways to colorless end products which remain in the vacuole (Matile et al 1988) and do not produce 1O2 (Hörtensteiner 2004; Kashiyama and Tamiaki 2014; Kuai et al 2018) To our knowledge, it is not known whether 1O2 production increases in deciduous species during autumn senescence. Large amounts of 1O2 were produced during methyl jasmonate-induced senescence (Springer et al 2015) and during monocarpic senescence in another H. vulgare accession (Lomerit; Krieger-Liszkay et al 2015). Krieger-Liszkay et al (2015) showed that the Lomerit accession degraded PSII early during senescence and the authors concluded that the degradation of PSII or LHCII might be responsible for the observed 1O2 production
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