Contrasting Oxygen Dynamics in the Freshwater Isoetid Lobelia dortmanna and the Marine Seagrass Zostera marina

doi:10.1093/aob/mci214

AOBPreview originally published online on July 18, 2005
Annals of Botany 2005 96(4):613-623; doi:10.1093/aob/mci214

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Contrasting Oxygen Dynamics in the Freshwater Isoetid Lobelia dortmanna and the Marine Seagrass Zostera marina

KAJ SAND-JENSEN, OLE PEDERSEN^*, THOMAS BINZER and JENS BORUM

Freshwater Biological Laboratory, Biological Institute, University of Copenhagen, Helsingørsgade 51, DK-3400 Hillerød, Denmark

^* For correspondence. E-mail opedersen{at}bi.ku.dk

Received: 12 October 2004 Returned for revision: 7 December 2004 Accepted: 17 January 2005 Published electronically: 18 July 2005

• Background and Aims Submerged plants possess well-developedaerenchyma facilitating intra-plant gas-phase diffusion of O₂to below-ground tissues, which are usually buried in anoxicsediments. However, aquatic habitats differ in terms of O₂ fluctuationsin the water column and in O₂ consumption of the sediment, andaquatic plants differ in aerenchymal volume and resistance toO₂ diffusion through the plant and across leaf and root surfaces.The hypothesis that the freshwater isoetid Lobelia dortmannaand the marine seagrass Zostera marina should display pronouncedcontrasts in intra-plant O₂ dynamics because of differencesin morphology/anatomy, physiology and growth habitat was tested.

• Methods In order to determine the O₂ dynamics and relatethis to the anatomy and morphology of the two species, O₂ microelectrodeswere inserted in the aerenchyma of leaves and roots, the sedimentpore-water, and the water column in the field. Manipulationof water column O₂ in the laboratory was also carried out.

• Key Results It was found that intra-plant transport ofO₂ between leaf and root tips takes place more readily in L.dortmanna than in Z. marina due to shorter distances and greatercross-sections of the aerenchyma. The major exchange of O₂ acrossroots of L. dortmanna can be accounted for by small intra-plantresistances to diffusion, larger root than leaf surfaces, andgreater radial diffusive resistance of leaves than roots. Incontrast, the major O₂ exchange across leaves than roots ofZ. marina can be accounted for by the opposite anatomical–morphologicalfeatures. The larger aerenchymal volume and the smaller metabolicrates of L. dortmanna compared to Z. marina imply that turnoverof O₂ is slower in the aerenchyma of L. dortmanna and O₂ fluctuationsare more dampened following changes in irradiance. Also, O₂accumulated in the aerenchyma can theoretically support darkrespiration for a few hours in L. dortmanna but for only a fewminutes in Z. marina.

• Conclusions The build-up of O₂ in the pore-water of L.dortmanna sediments during the day as a result of high releaseof photosynthetic O₂ from roots and low O₂ consumption of sedimentsmeans that sediment, aerenchyma and water are important O₂ sourcesfor respiration during the following night, while Z. marinarelies on the water column as the sole source of O₂ becauseits sediments are anoxic. These differences between L. dortmannaand Z. marina appear to represent a general difference betweenthe isoetid species mainly inhabiting sediments of low reducingcapacity of oligotrophic lakes and the elodeid freshwater speciesand marine seagrasses mainly inhabiting sediments of higherreducing capacity in more nutrient-rich habitats.

Key words: Anaerobiosis, isoetids, oxygen microelectrodes, radial oxygen loss (ROL), root aeration, seagrasses, submerged plants

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