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The cryopelagic meroplankton community in the shallow waters of Gerlache Inlet, Terra Nova Bay, Antarctica

Published online by Cambridge University Press:  27 November 2007

Mary A. Sewell*
Affiliation:
School of Biological Sciences, University of Auckland, Private Bag 92019, Auckland 1142, New Zealand
Schannel G. van Dijken
Affiliation:
School of Biological Sciences, University of Auckland, Private Bag 92019, Auckland 1142, New Zealand
Lavinia Suberg
Affiliation:
School of Biological Sciences, University of Auckland, Private Bag 92019, Auckland 1142, New Zealand

Abstract

Limited sampling has so far been conducted of the meroplankton community of the high Antarctic, with most research being conducted using vertical hauls in waters > 50 m, and little focused research on the meroplankton community directly under the sea ice (cryopelagic). Here we report the composition of the early summer cryopelagic meroplankton community of the shallow waters of Gerlache Inlet, Terra Nova Bay. A fixed-frame stationary plankton net was deployed c. 1 m below the annual sea ice and sampled at c. 24 hour intervals over a period of 19 days from mid-November to early December 2006. A total of 173 larvae from the phyla Annelida (n = 66), Mollusca (n = 30), Nemertea (n = 4), Echinodermata (n = 8), several Pleuragramma antarcticum (n = 4) and numerous planulae (n = 61) were collected, as well as 265 egg/embryo stages. A mean of 9.1 larvae (SD = 7.3, n = 19) and 13.9 eggs/embryos (SD = 20.5, n = 19) were found directly below the sea ice in each 24 hour period, and these early life history stages may be subject to the hazards of extensive platelet ice and penetrating ultraviolet radiation. The cryopelagic meroplankton community of shallow water is also compositionally similar to that of deeper waters, suggesting that the 50–0 m plankton tows used in previous research are providing a reliable assessment of the biodiversity of coastal Antarctic meroplankton.

Type
Biological Sciences
Copyright
Copyright © Antarctic Science Ltd 2008

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References

Andriashev, A.P. 1968. The problem of the life community associated with the Antarctic fast ice. In Currie, R.I., ed. Symposium on Antarctic Oceanography, Santiago, Chile, 13–16 September 1966. Cambridge: Scott Polar Research Institute, 147155.Google Scholar
Andriashev, A.P. 1970. Cryopelagic fishes of the Arctic and Antarctic and their significance in polar ecosystems. In Holdgate, M.W., ed. Antarctic ecology, vol. 1. London: Academic Press, 297304.Google Scholar
Boltovskoy, D. 1999. South Atlantic zooplankton. Leiden: Backhuys, 1706 pp.Google Scholar
Bosch, I., Beauchamp, K.A., Steele, M.E. & Pearse, J.S. 1987. Development, metamorphosis, and seasonal abundance of embryos and larvae of the Antarctic sea urchin Sterechinus neumayeri. Biological Bulletin, 173, 126135.CrossRefGoogle ScholarPubMed
Bradford, J.M. 1978. Sea ice, organisms and their importance to the Antarctic ecosystem. New Zealand Antarctic Record, 1, 4350.Google Scholar
Efremenko, V.N. 1985. Illustrated guide to fish larvae of the Southern Ocean. BIOMASS Scientific Series No. 5. Cambridge: SCAR & SCOR, 74 pp.Google Scholar
Freire, A.S., Absher, T.M., Cruz-kaled, A.C., Kern, Y. & Elbers, K.L. 2006. Seasonal variation of pelagic invertebrate larvae in the shallow Antarctic waters of Admiralty Bay (King George Island). Polar Biology, 29, 294302.CrossRefGoogle Scholar
Howard-Williams, C., Peterson, D., Lyons, W.B., Cattaneo-Vietti, R. & Gordon, S. 2006. Measuring ecosystem response in a rapidly changing environment: the Latitudinal Gradient Project. Antarctic Science, 18, 465471.CrossRefGoogle Scholar
Hureau, J.-C. 1994. The significance of fish in Antarctic ecosystems. Polar Biology, 14, 307313.CrossRefGoogle Scholar
ICES. 2005. Report of the Working Group on Zooplankton Ecology (WGZE), 4–7 April 2005, Lisbon, Portugal. ICES CM 2005/C:02, 84 pp.Google Scholar
Karentz, D. & Bosch, I. 2001. Influence of ozone-related increases in ultraviolet radiation on Antarctic marine organisms. American Zoologist, 41, 316.Google Scholar
Karentz, D., Bosch, I. & Mitchell, D.M. 2004. Limited effects of Antarctic ozone depletion on sea urchin development. Marine Biology, 145, 277292.CrossRefGoogle Scholar
Kellermann, A. 1989. Identification key and catalogue of larval Antarctic fishes. BIOMASS Scientific Series, No. 10, 136 pp.Google Scholar
Kirby, R.R. & Reid, P.C. 2001. PCR from the CPR offers a historical perspective on marine population ecology. Journal of the Marine Biological Association of the United Kingdom, 81, 539540.CrossRefGoogle Scholar
Knox, G.A. 2006. Biology of the Southern Ocean. 2nd ed.Boca Raton, FL: CRC Press, 621 pp.CrossRefGoogle Scholar
Lesser, M.P., Lamare, M.D. & Barker, M.F. 2004. Transmission of ultraviolet radiation through the Antarctic annual sea ice and its biological effects on sea urchin embryos. Limnology and Oceanography, 49, 19571963.CrossRefGoogle Scholar
Lesser, M.P., Barry, T.M., Lamare, M.D. & Barker, M.F. 2006. Biological weighting functions for DNA damage in sea urchin embryos exposed to ultraviolet radiation. Journal of Experimental Marine Biology and Ecology, 328, 1021.CrossRefGoogle Scholar
O'sullivan, D & Hosie, G. 1985. A general guide to the metazoan zooplankton groups of the Southern Ocean. ANARE Research Notes, 30, 30 pp.Google Scholar
Parin, N.V. 1968. Ichthyofauna of the epipelagic zone. Jerusalem: Israel Program for Scientific Translations, 205 pp.Google Scholar
Pearse, J.S. & Bosch, I. 1986. Are the feeding larvae of the commonest Antarctic asteroid really demersal? Bulletin of Marine Science, 39, 477484.Google Scholar
Pearse, J.S. & Lockhart, S.J. 2004. Reproduction in cold water: paradigm changes in the 20th century and a role for cidaroid sea urchins. Deep-Sea Research II, 51, 15331549.CrossRefGoogle Scholar
Sewell, M.A. 2005. Examination of the meroplankton community in the south-western Ross Sea, Antarctica, using a collapsible plankton net. Polar Biology, 28, 119131.CrossRefGoogle Scholar
Sewell, M.A. 2006. The meroplankton community of the northern Ross Sea: a preliminary comparison with the McMurdo Sound region. Antarctic Science, 18, 595602.CrossRefGoogle Scholar
Sewell, M.A., Cameron, M.J. & McArdle, B.H. 2004. Developmental plasticity in larval development in the echinometrid sea urchin Evechinus chloroticus with varying food ration. Journal of Experimental Marine Biology and Ecology, 309, 219237.CrossRefGoogle Scholar
Sewell, M.A., Lavery, S. & Baker, C.S. 2006. Whose larva is that? Molecular identification of planktonic larvae of the Ross Sea. New Zealand Aquatic Environment and Biodiversity Report, No. 3, 57 pp.Google Scholar
Shreeve, R.S. & Peck, L.S. 1995. Distribution of pelagic larvae of benthic marine invertebrates in the Bellingshausen Sea. Polar Biology, 15, 369374.CrossRefGoogle Scholar
Stanwell-Smith, D. & Clarke, A. 1998. Seasonality of reproduction in the cushion star Odontaster validus at Signy Island, Antarctica. Marine Biology, 131, 479487.CrossRefGoogle Scholar
Stanwell-Smith, D., Hood, A. & Peck, L.S. 1997. A field guide to the pelagic invertebrate larvae of the maritime Antarctic. Cambridge: British Antarctic Survey, 152 pp.Google Scholar
Stanwell-Smith, D., Peck, L.S., Clarke, A., Murray, A.W.A. & Todd, C.D. 1999. The distribution, abundance and seasonality of pelagic marine invertebrate larvae in the maritime Antarctic. Philosophical Transactions of the Royal Society London, B354, 471484.CrossRefGoogle Scholar
Tanimura, A., Minoda, T., Fukuchi, M., Hoshiai, T. & Ohtsuka, H. 1984. Swarm of Paralabidocera antarctica (Calanoida, Copepods) under sea ice near Syowa Station, Antarctica. Antarctic Record, 82, 1219.Google Scholar
Webb, K.E., Barnes, D.K.A., Clark, M.S. & Bowdon, D.A. 2006. DNA barcoding: a molecular tool to identify Antarctic larvae. Deep-Sea Research II, 53, 10531060.CrossRefGoogle Scholar
Young, C.M. 2002. A brief history and some fundamentals. In Young, C.M., Sewell, M.A. & Rice, M.E., eds. Atlas of marine invertebrate larvae. London: Academic Press, 120.Google Scholar