Book contents
- Frontmatter
- Dedication
- Contents
- List of contributors
- Preface
- 1 Seaweed thalli and cells
- 2 Life histories, reproduction, and morphogenesis
- 3 Seaweed communities
- 4 Biotic interactions
- 5 Light and photosynthesis
- 6 Nutrients
- 7 Physico-chemical factors as environmental stressors in seaweed biology
- 8 Water motion
- 9 Pollution
- 10 Seaweed mariculture
- References
- Subject Index
1 - Seaweed thalli and cells
Published online by Cambridge University Press: 05 August 2014
- Frontmatter
- Dedication
- Contents
- List of contributors
- Preface
- 1 Seaweed thalli and cells
- 2 Life histories, reproduction, and morphogenesis
- 3 Seaweed communities
- 4 Biotic interactions
- 5 Light and photosynthesis
- 6 Nutrients
- 7 Physico-chemical factors as environmental stressors in seaweed biology
- 8 Water motion
- 9 Pollution
- 10 Seaweed mariculture
- References
- Subject Index
Summary
Introduction: the algae and their environments
Seaweeds
The term “seaweed” traditionally includes only macroscopic, multicellular marine red, green, and brown algae. However, each of these groups has microscopic, if not unicellular, representatives. All seaweeds at some stage in their life cycles are unicellular, as spores or gametes and zygotes, and may be temporarily planktonic (Amsler and Searles 1980; Maximova and Sazhin 2010). Some remain small, forming sparse but productive turfs on coral reefs (Hackney et al. 1989) while others, such as the “kelps” of temperate reefs, can form extensive underwater forests (Graham et al. 2007a). Siphonous algae such as Codium, Caulerpa and Bryopsis that form large thalli are, in fact, acellular. The prokaryotic Cyanobacteria have occasionally been acknowledged in “seaweed” floras (e.g. Setchell and Gardner 1919; Littler and Littler 2011a). They are widespread on temperate rocky and sandy shores (Whitton and Potts 1982) and are particularly important in the tropics, where large macroscopic tufts of Oscillatoriaceae and smaller but abundant nitrogen-fixing Nostocaceae are major components of the reef flora (Littler and Littler 2011a, b; Charpy et al. 2012). Benthic diatoms also form large and sometimes abundant tube-dwelling colonies that resemble seaweeds (Lobban 1989). An ancient lineage of (mostly) deep-water green algae, the Palmophyllales, that includes Verdigellas and Palmophyllum, have a palmelloid organization with complex thalli built from an amorphous matrix with a nearly uniform distribution of spherical cells (Womersley 1971; Zechman et al. 2010). On a smaller scale are the colonial filaments of some simple red algae, such as Stylonema (previously Goniotrichum). A “seaweed” is therefore problematic to precisely define: here “seaweed” refers to algae from the red, green, and brown lineages that, at some stage of their life cycle, form multicellular or siphonous macrothalli. In this book we shall consider macroscopic and microscopic marine benthic environments and how seaweeds respond to those environments.
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- Seaweed Ecology and Physiology , pp. 1 - 47Publisher: Cambridge University PressPrint publication year: 2014
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