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2 results

  • 14 - Algae in Extreme and Unusual Environments

  • from Part II - Physiology of Photosynthetic Autotrophs in Present-Day Environments
  • Edited by Mario Giordano, Università degli Studi di Ancona, Italy, John Beardall, Monash University, Victoria, John A. Raven, University of Dundee, Stephen C. Maberly, UK Centre for Ecology & Hydrology, Lancaster
  • Book:
    Evolutionary Physiology of Algae and Aquatic Plants
    Published online:
    24 October 2024
    Print publication:
    07 November 2024, pp 272-292

  • Summary

    Aquatic phototrophs have a remarkable ability to cope with variations in a range of environmental factors, such as light, temperature, pH and salinity. However, some environmental conditions are beyond what are considered the normal limits for growth and can thus be considered as extreme. Focusing on algae and cyanobacteria, we discuss the capacity of extremophilic organisms to cope and even thrive in extremes of temperature ranging from hot springs to snow and ice algae, under extremes of pH and in situations where water is in short supply, such as in biological soil crusts and on man-made surfaces such as buildings and statues. Many of the mechanisms that allow algae to cope with these extremes are common across different situations and involve, for instance, processes to dissipate excess light energy and deal with reactive oxygen species. Algae and cyanobacteria enter symbiotic associations with other organisms, such as lichens and corals. They are also found as intracellular symbionts in plants, other algae and various protists and metazoans. There are looser associations where algae grow on animals such as gastropods, seals and terrestrial animals such as sloths. We also discuss the retention of active chloroplasts by phagotrophs in the process of kleptoplasty.

  • Effects of photosynthesis on the survival and weight retention of two kleptoplastic sacoglossan opisthobranchs

  • Shoko Yamamoto, Yayoi M. Hirano, Yoshiaki J. Hirano, Cynthia D. Trowbridge, Ayana Akimoto, Atsushi Sakai, Yoichi Yusa
  • Journal:
    Journal of the Marine Biological Association of the United Kingdom / Volume 93 / Issue 1 / February 2013
    Published online by Cambridge University Press:
    25 May 2012, pp. 209-215

  • Many sacoglossan sea slugs utilize chloroplasts ingested from food algae for photosynthesis (functional kleptoplasty), and the extent and duration of kleptoplast retention differs greatly among sacoglossan species. Although most recent studies focus on the genetic, microscopic, or physiological mechanisms responsible for this unique phenomenon, its effects on the life history traits of sacoglossans have not been fully explored. To study the effects of light conditions on survival and weight retention, adult individuals of two sacoglossan species, Elysia trisinuata and Plakobranchus ocellatus (‘black type'), were reared under light conditions (a 14-hour light: 10-hour dark photoperiod with an irradiance level of 28 µmol m−2s−1) or complete darkness for 21 days. There was no significant difference in the survival rate between the light and dark treatments for E. trisinuata, and its wet weight relative to the initial weight was smaller in the light than in the dark. However, both the survival and relative weights were greater in the light than dark for P. ocellatus. Based on the fluorescent yield measurement using pulse-amplitude-modulated fluorometry, the retention duration of functional chloroplasts was longer (>17 days) for P. ocellatus than E. trisinuata (<4 days). These results indicate that P. ocellatus benefits from photosynthesis for survival and growth, whereas E. trisinuata does not under starved conditions. This interspecific difference is likely related to the period of functional chloroplast retention.