Seaweeds in Cold Seas: Evolution and Carbon Acquisition

TitleSeaweeds in Cold Seas: Evolution and Carbon Acquisition
Publication TypeJournal Article
Year of Publication2002
Refereed DesignationRefereed
AuthorsRaven, J. A., Johnston A. M., Kubler J. E., Korb R., McInroy S. G., Handley L. L., Scrimgeour C. M., Walker D. I., Beardall J., Clayton M. N., Vanderklift M., Fredriksen S., & Dunton K. H.
JournalAnnals of Botany
Volume90
Issue4
Pagination525 - 536
ISSN10958290
Abstract

Much evidence suggests that life originated in hydrothermal habitats, and for much of the time since the origin of cyanobacteria (at least 2·5 Ga ago) and of eukaryotic algae (at least 2·1 Ga ago) the average sea surface and land surface temperatures were higher than they are today. However, there have been at least four significant glacial episodes prior to the Pleistocene glaciations. Two of these (approx. 2·1 and 0·7 Ga ago) may have involved a ‘Snowball Earth’ with a very great impact on the algae (sensu lato) of the time (cyanobacteria, Chlorophyta and Rhodophyta) and especially those that were adapted to warm habitats. By contrast, it is possible that heterokont, dinophyte and haptophyte phototrophs only evolved after the Carboniferous–Permian ice age (approx. 250 Ma ago) and so did not encounter low (≤5 °C) sea surface temperatures until the Antarctic cooled some 15 Ma ago. Despite this, many of the dominant macroalgae in cooler seas today are (heterokont) brown algae, and many laminarians cannot reproduce at temperatures above 18–25 °C. By contrast to plants in the aerial environment, photosynthetic structures in water are at essentially the same temperature as the fluid medium. The impact of low temperatures on photosynthesis by marine macrophytes is predicted to favour diffusive CO2 entry rather than a CO2‐concentrating mechanism. Some evidence favours this suggestion, but more data are needed.

DOI10.1093/aob/mcf171