The involvement of dual mechanisms of photoinactivation of photosystem II in Capsicum annuum L. plants

For plants, light is an indispensable resource. However, it also causes a loss of photosynthetic activity associated with photoinactivation of photosystem II (PSII). In studies of the mechanism of this photoinactivation, there are two conflicting hypotheses at present. One is that excess energy rece...

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Bibliographic Details
Published in:Plant and cell physiology 2009-10, Vol.50 (10), p.1815-1825
Main Authors: Oguchi, R.(Tokyo Univ. (Japan)), Terashima, I, Chow, W.S
Format: Article
Language:English
Subjects:
adaxial and abaxial side of leaves
BESOIN EN LUMIERE
Capsicum - metabolism
Capsicum - radiation effects
CAPSICUM ANNUUM
Chlorophyll - analysis
chlorophyll fluorescence
CHLOROPHYLLE
CHLOROPHYLLS
CLOROFILAS
excess energy hypothesis
FEUILLE
Fluorescence
FOTOSINTESIS
HOJAS
INHIBICION
INHIBITION
intact leaves
LEAVES
Light
LIGHT REQUIREMENTS
NECESIDADES DE LUZ
Oxygen - metabolism
photoinhibition
PHOTOSYNTHESE
PHOTOSYNTHESIS
Photosystem II Protein Complex - metabolism
Plant Leaves - metabolism
Plant Leaves - radiation effects
two-step hypothesis
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Summary:For plants, light is an indispensable resource. However, it also causes a loss of photosynthetic activity associated with photoinactivation of photosystem II (PSII). In studies of the mechanism of this photoinactivation, there are two conflicting hypotheses at present. One is that excess energy received by leaves, being neither utilized by photosynthesis nor dissipated safely in non-photochemical quenching, causes the photoinactivation. The other involves a two-step mechanism in which excitation of Mn by photons is the primary cause. In the former hypothesis, photoinactivation of PSII should not occur in low light that provides little excess energy, but in the latter hypothesis it should. Therefore, we tested these two hypotheses in different irradiances. We used a system that can measure the fraction of functional PSII complexes under natural conditions and over a long period in intact leaves, which were attached to a plant treated with lincomycin taken up via the roots. The leaves were photoinactivated in low, medium or high light (30, 60 or 950 μmol m−2 s−1) with white, blue, green or red light-emitting diode arrays. Our results showed that the extent of photoinactivation per photon exposure was higher in high light than in low light, consistent with the abundance of excess energy. However, photoinactivation did occur in low light with little excess energy, and blue light caused the greatest extent of photoinactivation followed by white, green and red light in this order, an order that can be predicted from the Mn absorbance spectrum. These results suggest that both mechanisms occur in the photoinactivation process.
ISSN:0032-0781
1471-9053
DOI:10.1093/pcp/pcp123