High Root Temperature Blocks Both Linear and Cyclic Electron Transport in the Dark During Chilling of the Leaves of Rice Seedlings

The most photosynthetically active leaves of rice seedlings were severely damaged when shoots but not roots were chilled (10°C/25°C, respectively), but no such injury was observed when the whole seedling was chilled (10°C/10°C). To elucidate the mechanisms, we compared the photosynthetic characteris...

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Published inPlant and cell physiology Vol. 52; no. 9; pp. 1697 - 1707
Main Authors Suzuki, Kensaku, Ohmori, Yukimi, Ratel, Emilien
Format Journal Article
LanguageEnglish
Published Japan Oxford University Press 01.09.2011
Subjects
Chlorophyll - analysis
Cold Temperature
Darkness
Electron Transport
Fluorescence
Oryza - physiology
Photosynthesis
Photosystem I Protein Complex - metabolism
Photosystem II Protein Complex - metabolism
Plant Leaves - physiology
Plant Roots - physiology
Seedlings - physiology
Thylakoids - metabolism
Root temperature
Thermal dissipation
Electron transport
PSII
Chilling injury
Rice
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Summary:The most photosynthetically active leaves of rice seedlings were severely damaged when shoots but not roots were chilled (10°C/25°C, respectively), but no such injury was observed when the whole seedling was chilled (10°C/10°C). To elucidate the mechanisms, we compared the photosynthetic characteristics of the seedlings during the dark chilling treatments. Simultaneous analyses of Chl fluorescence and the change in absorbance of P700 showed that electron transport almost disappeared in both PSII and PSI in the 10°C/25°C leaves, whereas the electron transport rate in PSI in the 10°C/10°C leaves was similar to or higher than that in non-chilled control leaves. Light-induced non-photochemical quenching in PSII was inhibited in the 10°C/25°C leaves, occurring at only half the level in the 10°C/10°C leaves, whereas non-light-induced non-photochemical quenching remained high in the 10°C/25°C leaves. The light induction of Chl a fluorescence (OJIP curves) in the 10°C/25°C leaves was similar to that in leaves treated with DCMU. The fluorescence decay after a single turnover saturating flash in the 10°C/25°C leaves was much slower than in the 10°C/10°C leaves. In vivo analyses of the 550-515 nm difference signal indicated decreased formation of a proton gradient across the thylakoid membrane and decreased zeaxanthin formation in the 10°C/25°C leaves. Our results suggest that electron transport was blocked between QA and QB in the dark 10°C/25°C leaves, but without irreversible damage to the components of this system. The consequent light-dependent losses of electron transport, proton gradient formation across the thylakoids and thermal dissipation may therefore be responsible for the visible injury.
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ISSN:0032-0781
1471-9053
DOI:10.1093/pcp/pcr104