Physiology, growth, and development of larval krill Euphausia superba in autumn and winter in the Lazarev Sea, Antarctica

20 pages, 13 figures, 8 tables The physiological condition of larval Antarctic krill was investigated during austral autumn 2004 and winter 2006 in the Lazarev Sea. The condition of larvae was quantified in both seasons by determining their body length (BL), dry weight (DW), elemental and biochemica...

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Bibliographic Details
Published in:Limnology and Oceanography
Main Authors: Meyer, Bettina, Fuentes, Veronica, Guerra, Citlali, Schmidt, Katrin, Atkinson, Angus, Spahic, Susanne, Cisewski, Boris, Freier, Ulrich, Olariaga, Alejandro
Format: Article in Journal/Newspaper
Language:English
Published: American Society of Limnology and Oceanography 2009
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Online Access:http://hdl.handle.net/10261/20334
https://doi.org/10.4319/lo.2009.54.5.1595
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Summary:20 pages, 13 figures, 8 tables The physiological condition of larval Antarctic krill was investigated during austral autumn 2004 and winter 2006 in the Lazarev Sea. The condition of larvae was quantified in both seasons by determining their body length (BL), dry weight (DW), elemental and biochemical composition, stomach content analysis, and rates of metabolism and growth. Overall the larvae in autumn were in better condition under the ice than in open water, and for those under the ice, condition decreased from autumn to winter. Thus, growth rates of furcilia larvae in open water in autumn were similar to winter values under the ice (mean, 0.008 mm d21), whereas autumn underice values were higher (0.015 mm d21). Equivalent larval stages in winter had up to 30% shorter BL and 70% lower DW than in autumn. Mean respiration rates of winter larvae were 43% lower than of autumn larvae. However, their ammonium excretion rates doubled in winter from 0.03 to 0.06 mg NH4 DW21 h21, resulting in mean O:N ratios of 46 in autumn and 15 in winter. Thus, differing metabolic substrates were used between autumn and winter, which supports a degree of flexibility for overwintering of larval krill. The larvae were eating small copepods (Oithona spp.) and protozoans, as well as autotrophic food under the ice. The interplay between under-ice topography, apparent current speed under sea ice, and the swimming ability of larval krill is probably critical to whether larval krill can maintain position and exploit suitable feeding areas under the ice This work was supported by funding from the German Ministry of Education and Science through project 03F0400A, Subproject 4, of the Lazarev Sea Krill Study (LAKRIS) Project, and the Natural Environment Research Council (United Kingdom, AFI 5/09). The LAKRIS Project is the German contribution to the Southern Ocean–Global Ocean Ecosystem Dynamics (SOGLOBEC) program Peer reviewed