Are saturating pulses indeed saturating? Evidence for considerable PSII yield underestimation in leaves adapted to high levels of natural light

The “saturating pulse” method of in vivo Chl fluorescence measurement has been widely used by physiologists and especially ecophysiologists, as it allows a simple, rapid and non-invasive assessment of PSII function and the allocation of absorbed energy into photochemical and non-photochemical proces...

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Bibliographic Details
Published in:Journal of plant physiology 2007-10, Vol.164 (10), p.1331-1336
Main Authors: Karageorgou, Panagiota, Tziortzis, Iakovos, Manetas, Yiannis
Format: Article
Language:English
Subjects:
Adaptation, Physiological
Biological and medical sciences
chlorophyll
Chlorophyll - metabolism
Chlorophyll fluorescence
electron transport chain
Electron transport rates
Euphorbia
Euphorbia - metabolism
Euphorbia - radiation effects
Euphorbia helioscopia
Fundamental and applied biological sciences. Psychology
Light
light intensity
Melissa - metabolism
Melissa - radiation effects
Melissa officinalis
Metabolism
Nerium - metabolism
Nerium - radiation effects
Nerium oleander
Photosynthesis, respiration. Anabolism, catabolism
photosystem II
Photosystem II Protein Complex - metabolism
plant ecology
Plant Leaves - metabolism
Plant Leaves - radiation effects
plant physiology
Plant physiology and development
saturating pulse
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Summary:The “saturating pulse” method of in vivo Chl fluorescence measurement has been widely used by physiologists and especially ecophysiologists, as it allows a simple, rapid and non-invasive assessment of PSII function and the allocation of absorbed energy into photochemical and non-photochemical processes. It is based on the accurate determination of the so-called Fm ′ , i.e. the fluorescence signal emitted when a “saturating” light pulse closes all PSII centers. In this methodological investigation, we examined whether the saturating pulse intensities required to obtain maximal fluorescence yields differ between leaves of various species receiving varying actinic light irradiances. It was shown that, in leaves adapted to comparatively high (yet realistic) levels of natural irradiances, the saturating pulses usually applied are not able to close all PSII reaction centers. As a result, there is a high risk of considerable Fm ′ underestimation. Accordingly, the derived values of effective PSII yields and linear electron transport rates (ETR) are also underestimated, even at the highest saturation pulse levels afforded by commercial instruments. Since the extent of underestimation increases with actinic irradiance, the ETR versus light curves are considerably distorted. The possible reasons for the apparent inability of “saturating” pulses to close all PSII centers at high actinic light and the practical implications, especially in field work, are discussed.
ISSN:0176-1617
1618-1328
DOI:10.1016/j.jplph.2006.07.015