What leads to reduced fitness in non-photochemical quenching mutants?. Kulheim, C. & Jansson, S. Physiologia Plantarum, 125(2):202–211, October, 2005. Place: Oxford Publisher: Blackwell Publishing WOS:000231677000006doi abstract bibtex Feedback de-excitation (FDE) is a process that protects photosystem II from damage during short periods of overexcitation. Arabidopsis thaliana mutants lacking this mechanism have reduced fitness in environments with variable light intensities. We have assayed the physiological consequences of mutations resulting in the lack of FDE and analysed the differences between field-grown plants and plants grown under fluctuating light in the laboratory. We show that FDE is an important mechanism in short-term responses to fluctuating light. Anthocyanin and carbohydrate levels indicated that the mutant plants were stressed to a higher degree than wild-type (WT) plants. Field-grown mutants were photo-inactivated to a greater degree than WT, whereas mutant plants in the fluctuating light environment in the laboratory seemed to downregulate the photosynthetic quantum yield, thereby avoiding photo-damage but resulting in impaired growth in the case of one mutant. Finally, we provide evidence that FDE is most important under conditions when photosynthesis limits plant growth, for example during flower and seed development.
@article{kulheim_what_2005,
title = {What leads to reduced fitness in non-photochemical quenching mutants?},
volume = {125},
issn = {0031-9317},
doi = {10/djtwsp},
abstract = {Feedback de-excitation (FDE) is a process that protects photosystem II from damage during short periods of overexcitation. Arabidopsis thaliana mutants lacking this mechanism have reduced fitness in environments with variable light intensities. We have assayed the physiological consequences of mutations resulting in the lack of FDE and analysed the differences between field-grown plants and plants grown under fluctuating light in the laboratory. We show that FDE is an important mechanism in short-term responses to fluctuating light. Anthocyanin and carbohydrate levels indicated that the mutant plants were stressed to a higher degree than wild-type (WT) plants. Field-grown mutants were photo-inactivated to a greater degree than WT, whereas mutant plants in the fluctuating light environment in the laboratory seemed to downregulate the photosynthetic quantum yield, thereby avoiding photo-damage but resulting in impaired growth in the case of one mutant. Finally, we provide evidence that FDE is most important under conditions when photosynthesis limits plant growth, for example during flower and seed development.},
language = {English},
number = {2},
journal = {Physiologia Plantarum},
author = {Kulheim, C. and Jansson, S.},
month = oct,
year = {2005},
note = {Place: Oxford
Publisher: Blackwell Publishing
WOS:000231677000006},
keywords = {arabidopsis-thaliana, chlorophyll fluorescence, cold-acclimation, energy-dissipation, light-harvesting complex, low-temperature, photoinhibition, photosynthesis, plants, xanthophyll cycle},
pages = {202--211},
}
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