Thermal tolerance and heat shock proteins in encysted embryos of Artemia from widely different thermal habitats

Thermal tolerance and heat shock proteins in encysted embryos of Artemia from widely different thermal habitats

James S. Clegg, N. Van Hoa, P. Sorgeloos-2001

Hydrobiologia, 466(1-3): 221-229

Abstract:

Encysted embryos (cysts) of the brine shrimp, Artemia provide an excellent model system for the study of biochemical adaptation to environmental extremes. Here, we describe an experiment in which cysts of A. franciscana from the San Francisco Bay (SFB), California, U.S.A., were inoculated into experimental ponds in the Mekong Delta region of Vietnam where water temperatures are much higher than the SFB. Cysts produced in each of three successive growing seasons (1996–1998) were collected and examined in the laboratory for resistance to high temperature and relative contents of three stress proteins (Hsp-70, artemin and p26). Thermal adaptation took place rapidly, during the first growing season. The increase in thermal tolerance was reflected in an overall increase in stress protein content, compared to SFB cysts used for the initial inoculation. Also examined were cysts of A. tibetiana collected from a lake on the high plateau of Tibet, PR China, almost 4.5 km above sea level. These cysts were very sensitive to high temperatures, and contained much lower levels of all stress proteins examined, compared to A. franciscana cysts from SFB and Vietnam. Cysts of A. sinica, collected from a hypersaline lake in Inner Mongolia, PR China, were examined in the same fashion and found to be similar to SFB cysts in terms of thermal resistance and stress protein content. The harsh environments in which Artemia are found, and the great diversity of its habitats, world-wide, provide excellent opportunities to relate the ecological setting of an organism to the underlying physiological and biochemical processes enabling its survival.

(Section of Molecular and Cellular Biology and the Bodega Marine Laboratory, University of California (Davis), Bodega Bay, CA 94923, U.S.A., Tel: +707-875-2010. Fax: +707-875-2009. E-mail: jsclegg@ucdavis.edu)

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