Abstract
Many seaweeds, seagrasses and many halophytes, grow in the tidal zone in similar environments. Their every-day-life and their life cycle are influenced by regular flooding during high tide and exposure to the air at low tide. Therefore they are confronted with similar daily changes in the osmotic potential and need to take up nutrients from the water and/or from the sediment. In addition, coastal zones and estuaries are often contaminated with high loads of some nutrients and heavy metals. Sulfur-deficiency is a major issue for land-based agriculture, whereas seawater act as a global sulfur reservoir and sulfur does not limit growth of marine plants. Sulfur-containing compounds and proteins seem to play a pivotal in the adaptation to these environmental conditions. This review highlights the putative roles of sulfur-containing compounds in a comparative way in seaweeds, seagrasses and halophytes. Can we observe similar metabolic and proteomic adaptations in regularly flooded coastal plants? The role of sulfur-containing proteins and of sulfur-containing secondary metabolites and their responsible set of enzymes will be analyzed from an evolutionary point of view. New strategies to increase salt-tolerance in higher plants based on sulfur-containing compounds are discussed.
Keywords
- Heavy Metal
- Green Alga
- Brown Alga
- Sulfated Polysaccharide
- Marine Plant
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
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Nguyen, XV., Klein, M., Riemenschneider, A., Papenbrock, J. (2014). Distinctive Features and Role of Sulfur-Containing Compounds in Marine Plants, Seaweeds, Seagrasses and Halophytes, from an Evolutionary Point of View. In: Khan, M.A., Böer, B., Öztürk, M., Al Abdessalaam, T.Z., Clüsener-Godt, M., Gul, B. (eds) Sabkha Ecosystems. Tasks for Vegetation Science, vol 47. Springer, Dordrecht. https://doi.org/10.1007/978-94-007-7411-7_21
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DOI: https://doi.org/10.1007/978-94-007-7411-7_21
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