Rapid, blue-light-induced acidifications at the surface of Ectocarpus and other marine macroalgae

In most brown algae, photosynthesis saturated with red light can be stimulated by continuous blue light. Pulses of blue light lead to transient increases in photosynthetic rate. When a CO2-sensitive electrode was used, occasionally blue light was observed to cause an apparent increase of CO2 instead...

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Bibliographic Details
Published in:Plant physiology (Bethesda) 1993-03, Vol.101 (3), p.907-913
Main Authors: Schmid, R, Dring, M.J
Format: Article
Language:English
Subjects:
ACIDIFICACION
ACIDIFICATION
Brown algae
Carbon dioxide
CHLOROPHYCEAE
DIURON
Ectocarpus
Electrodes
Enteromorpha
Environmental and Stress Physiology
Evolution
Irradiation
LUMIERE
LUZ
Marine
PHAEOPHYCEAE
Phaeophyta
Photosynthesis
Plants
Sea water
Ulva
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Summary:In most brown algae, photosynthesis saturated with red light can be stimulated by continuous blue light. Pulses of blue light lead to transient increases in photosynthetic rate. When a CO2-sensitive electrode was used, occasionally blue light was observed to cause an apparent increase of CO2 instead of the expected decrease. This was changed by buffering the seawater medium and, under these conditions, blue light caused stimulation of CO2 consumption. These results led to investigations of blue-light-dependent pH changes at the outer surface of the plants. Shifts of the pH were recorded in the presence of the photosynthetic inhibitor 3-(3,4- dichlorophenyl)-1,1-dimethylurea. In all brown algae tested and in the green algae Ulva and Enteromorpha, blue-light pulses caused transient acidification of 0.03 to 0.18 pH units, depending on the species. The kinetics showed lag phases of a few seconds and the minimum was reached after 5 to 9 min. Fluence response relationships indicated that the sensitivity threshold) to blue light was very similar in all species. The responses in Ectocarpus changed with time, and about 5 h after the beginning of red light or darkness, a second component became evident, which peaked 20 min after the blue-light pulse. The refractory period of the whole system was about 3 h in Ectocarpus. The blue-light-dependent pH changes show striking similarities to those of higher plant guard cells, and it is possible that similar responses may occur in other tissues of higher plants. In red algae, however, no blue-light-dependent acidifications could be detected. The possible role of the observed pH shifts in a mechanism of CO2 acquisition is discussed
ISSN:0032-0889
1532-2548
DOI:10.1104/pp.101.3.907