Underwater Photosynthesis in Flooded Terrestrial Plants: A Matter of Leaf Plasticity

doi:10.1093/aob/mci212

AOBPreview originally published online on July 15, 2005
Annals of Botany 2005 96(4):581-589; doi:10.1093/aob/mci212

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© The Author 2005. Published by Oxford University Press on behalf of the Annals of Botany Company. All rights reserved. For Permissions, please email: journals.permissions@oupjournals.org

REVIEW

Underwater Photosynthesis in Flooded Terrestrial Plants: A Matter of Leaf Plasticity

LIESJE MOMMER^* and ERIC J. W. VISSER

Department of Experimental Plant Ecology, Radboud University Nijmegen, Toernooiveld 1, 6525 ED Nijmegen, The Netherlands

^* For correspondence. E-mail L.Mommer{at}science.ru.nl

Received: 15 November 2004 Returned for revision: 20 January 2005 Accepted: 14 February 2005 Published electronically: 15 July 2005

• Background Flooding causes substantial stress for terrestrialplants, particularly if the floodwater completely submergesthe shoot. The main problems during submergence are shortageof oxygen due to the slow diffusion rates of gases in water,and depletion of carbohydrates, which is the substrate for respiration.These two factors together lead to loss of biomass and eventuallydeath of the submerged plants. Although conditions under waterare unfavourable with respect to light and carbon dioxide supply,photosynthesis may provide both oxygen and carbohydrates, resultingin continuation of aerobic respiration.

• Scope This review focuses on evidence in the literaturethat photosynthesis contributes to survival of terrestrial plantsduring complete submergence. Furthermore, we discuss relevantmorphological and physiological responses of the shoot of terrestrialplant species that enable the positive effects of light on underwaterplant performance.

• Conclusions Light increases the survival of terrestrialplants under water, indicating that photosynthesis commonlyoccurs under these submerged conditions. Such underwater photosynthesisincreases both internal oxygen concentrations and carbohydratecontents, compared with plants submerged in the dark, and therebyalleviates the adverse effects of flooding. Additionally, severalterrestrial species show high plasticity with respect to theirleaf development. In a number of species, leaf morphology changesin response to submergence, probably to facilitate underwatergas exchange. Such increased gas exchange may result in higherassimilation rates, and lower carbon dioxide compensation pointsunder water, which is particularly important at the low carbondioxide concentrations observed in the field. As a result ofhigher internal carbon dioxide concentrations in submergence-acclimatedplants, underwater photorespiration rates are expected to belower than in non-acclimated plants. Furthermore, the regulatorymechanisms that induce the switch from terrestrial to submergence-acclimatedleaves may be controlled by the same pathways as described forheterophyllous aquatic plants.

Key words: Flooding, gas exchange, heterophylly, hormonal regulation, leaf morphology, phenotypic plasticity, photorespiration, photosynthesis, Rumex, submergence, survival, wetlands

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