Dark-Season Survival Strategies of Coastal Zone Zooplankton in the Canadian Arctic

ABSTRACT. For herbivorous zooplankton, surviving the arctic winter requires that sufficient energy be stored in summer to enable ten months or more of possible starvation. Energy and materials for reproduction may also be totally derived from stored lipid and bodily protein. The predominant storage...

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Bibliographic Details
Main Authors: Robert J. Conover, Timothy D. Siferd
Other Authors: The Pennsylvania State University CiteSeerX Archives
Format: Text
Language:English
Published: 1992
Subjects:
Key words
copepods
zooplankton
phytoplankton
ice-algae
fast ice
lipid
overwintering
survival strategies
growth
reproduction
Arctic
Calanus hyperboreus
ice algae
Phytoplankton
Zooplankton
Copepods
Online Access:http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.499.7046
http://pubs.aina.ucalgary.ca/arctic/Arctic46-4-303.pdf
Description
Summary:ABSTRACT. For herbivorous zooplankton, surviving the arctic winter requires that sufficient energy be stored in summer to enable ten months or more of possible starvation. Energy and materials for reproduction may also be totally derived from stored lipid and bodily protein. The predominant storage products are wax esters, often visible as translucent droplets or a fusiform inclusion in the tissues. Lipid may constitute more than 50 % of dry weight at the end of summer. Reproduction is synchronized with season and environmental conditions to enable offspring to exploit the brief period f intense primary production. So far as we know, fertilization occurs only once in the copepods studied here, which make up more than 98 % of the total zooplankton by numbers, and males are short lived, but in one species (Calanus hyperboreus) females may survive into a second productive season, thereby storing sufficient reserves to spawn a second time. Several planktonic species, including larval invertebrates, start growth early by utilizing algae that develop on the under-ice surface several months before the pelagic phytoplankton bloom. The minimum water temperature (-13°C) is constant and much warmer than the atmosphere, so overwintering should be less stressful for aquatic species than for terrestrial forms. Additional adaptations used by zooplankton in winter include seeking deeper water to escape predation, reducing swimming costs by regulating buoyancy, and further lowering metabolic rates by limiting synthesis of enzymes and increasing the fraction of lipid used in respiration.

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