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Nitrogen Conversion in a Bivalve Culture System

Published online by Cambridge University Press:  11 May 2009

Ø. Strand ,
P.T. Solberg  and
T. Magnesen
Ø. Strand
Affiliation:
Department of Fisheries and Marine Biology, I-foyteknologisenteret, N-5020 Bergen, Norway.
P.T. Solberg
Affiliation:
Department of Fisheries and Marine Biology, I-foyteknologisenteret, N-5020 Bergen, Norway.
T. Magnesen
Affiliation:
Centre for Studies on Environment and Resources, Heyteknologisenteret, N-5020 Bergen, Norway.
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Extract

Bivalve spat were grown in an on-shore upwelling nursery using a landlocked heliothermic marine basin (Norwegian oyster-poll) as a food production system and thermal source. Several manipulations, involving artificial fertilization (N, P and Si), were performed in order to enhance the production capacity. Based on data from a monitoring programme (May-August) on physical, chemical and biological variables in the system, main paths of nitrogen flow and dynamics of bivalve production and nitrogen conversion efficiency were described. The conversion efficiency of the system, bivalve N production over estimated new N, of which 86% was fertilizer nitrogen, was 16·2% for the experimental period of 93 days. During this period the decrease in efficiency from levels of 22–25% to 8% was probably due to the transition from nitrate-limited to light- and grazing-limited phytoplankton production. The food utilization efficiency, bivalve N production over available particulate N in the nursery, was 19·8% for the experimental period. The efficiency increased in July from 19·4% for the first two weeks to 27·0% during late July. This was probably due to a higher food value of the phytoplankton community in late July, dominated by Skeletonema costatum (Bacillariophyceae) and Nitzschia sp., than the phytoplankton community in early July, dominated by Fragilaria sp.

Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 76 , Issue 1 , February 1996 , pp. 57 - 72
Copyright
Copyright © Marine Biological Association of the United Kingdom 1996

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References

Anon, ., 1990. Radiation observations in Bergen, Norway, 1990. Geophysical Institute, University of Bergen, Norway.Google Scholar
Chretiennot-Dinet, M.-J. & Guillocheau, N., 1987. Étude de diatomées d'écosystèmes marins côtiers. Observations nouvelles en microscopie électronique. Cahiers de Biologie Marine, 28, 271279.Google Scholar
Claus, C., 1981. Trends in nursery rearing of bivalve molluscs. In Nursery culturing of bivalve molluscs (ed. C., Claus et al.), pp. 133. Bredene, Belgium: European Mariculture Society. [Special Publication no. 7.]Google Scholar
De Pauw, N., 1981. Use and production of microalgae as food for nursery bivalves. In Nursery culturing of bivalve molluscs (ed. C., Claus et al.), pp. 3369. Bredene, Belgium: European Mariculture Society. [Special Publication no. 7.]Google Scholar
De Pauw, N., Verboven, J. & Claus, C., 1983. Large-scale microalgae production for nursery rearing of marine bivalves. Aquaculture Engineering, 2, 2747.CrossRefGoogle Scholar
Edler, L., 1977. Phytoplankton and primary production in the Sound. Department of Marine Botany, University of Gothenburg, Sweden.Google Scholar
Egge, J.K. & Aksnes, D.L., 1992. Silicate as regulating nutrient in phytoplankton competition. Marine Ecology Progress Series, 83, 281289.CrossRefGoogle Scholar
Frechette, M., Butman, C.A. & Geyer, W.R., 1989. The importance of boundary-layer flows in supplying phytoplankton to the benthic suspension feeder, Mytilus edulis L. Limnology and Oceanography, 34, 1936.CrossRefGoogle Scholar
Gaarder, T., 1932. Untersuchungen tiber Produktions - und Lebensbedingungen in norwegischen Austern-Pollen. Bergens Museums Årbok 1932. Naturvidenskapelig rekke, vol. 3, pp. 164.Google Scholar
Gaarder, T. & Spärck, R., 1932. Hydrographisch-biochemische Untersuchungen in norwegischen AusternPollen. Bergens Museums Årbok 1932. Naturvidenskapelig rekke, vol. 1, pp. 1144.Google Scholar
Gallager, S.M. & Mann, R., 1982. The effect of varying carbon/nitrogen ratio in the phytoplankter Thalassiosira pseudonana (3H) on its food value to the bivalve Tapes japonica. Aquaculture, 26, 95105.CrossRefGoogle Scholar
Goulletquer, P. & Wolowicz, M., 1989. The shell of Cardium edule, Cardium glaucum and Ruditapes philippinarum: organic content, composition and energy value, as determined by different methods. Journal of the Marine Biological Association of the United Kingdom, 69, 563572.CrossRefGoogle Scholar
Jordan, T.E. & Valiela, I., 1982. A nitrogen budget of the ribbed mussel, Geukensia demissa, and its significance in nitrogen flow in a New England salt marsh. Limnology and Oceanography, 27, 7590.Google Scholar
Kirkland, D.W., Platt, Bradbury J. & Dean, W.E., 1983. The heliothermic lake - a direct method of collecting and storing solar energy. Archiv für Hydrobiologie Supplementum, 65, 160.Google Scholar
Klaveness, D., 1990. Size structure and potential food value of the plankton community to Ostrea edulis L. in a traditional Norwegian ‘Østerspoll’. Aquaculture, 86, 231247.CrossRefGoogle Scholar
Klaveness, D. & Johansen, S.W., 1990. Østerspollene langs norskekysten: Soeregne biotoper for marine alger (the oyster ponds at the Norwegian coast: remarkable biotopes for marine algae). Blyttia, 48, 2731.Google Scholar
Laing, I., Utting, S.D. & Kilada, R.W.S., 1987. Interactive effect of diet and temperature on the growth of juvenile clams. Journal of Experimental Marine Biology and Ecology, 113, 2338.CrossRefGoogle Scholar
Langton, R.W., Winter, J.E. & Roels, O.A., 1977. The effect of ration size on the growth and growth efficiency of the bivalve mollusc Tapes japonica. Aquaculture, 12, 283292.Google Scholar
Malouf, R.E. & Bricelj, V.M., 1989. Comparative biology of clams: environmental tolerances, feeding and growth. In Clam mariculture in North America (ed. J.J., Manzi and M., Castagna), pp. 2373. New York: Elsevier. [Developments in Aquaculture and Fisheries Science no. 19.]Google Scholar
Manzi, J.J. & Castagna, M., 1989. Nursery culture of clams in North America. In Clam mariculture in North America (ed. J.J., Manzi and M., Castagna), pp. 127147. New York: Elsevier. [Developments in Aquaculture and Fisheries Science no. 19.]Google Scholar
Martin, M.T. & Comin, F.A., 1992. Plankton population dynamics in a salt marsh used as clam nursery. In Marine eutrophication and population dynamics. Proceedings of the 25th European Marine Biology Symposium, September 1990 (ed. G., Colombo et al.), pp. 7176. Fredensborg, Denmark: Olsen & Olsen.Google Scholar
Nakamura, M., Yamamuro, M., Ishikawa, M. & Nishimura, H., 1988. Role of the bivalve Corbicula japonica in the nitrogen cycle in a mesohaline lagoon. Marine Biology, 99, 369374.CrossRefGoogle Scholar
Nielsen, E.S., 1952. The use of radio-active carbon (14C) for measuring organic production in the sea. Journal du Conseil, 18, 117140.CrossRefGoogle Scholar
Nordø, E., 1991. En sammenligning av livssyklus for de to calanoide copepoder Acartia clausi og Acartia grani i Espevikpollen pä Tysnes. Candidatus Scientiarum thesis, University of Bergen.Google Scholar
Parsons, T.R., Takahashi, M. & Hargrave, B., 1984. Biological oceanographic processes, 3rd ed. Oxford: Pergamon Press.Google Scholar
Partali, V., Tangen, K. & Liaaen-Jensen, S., 1989. Carotenoids in food chain studies. III. Resorption and metabolic transformation of carotenoids in Mytilus edulis (edible mussel). Comparative Biochemistry and Physiology, 92B, 239246.Google Scholar
Pickard, G.L. & Emery, W.J., 1990. Descriptive physical oceanography, 5th ed. Oxford: Pergamon Press.Google Scholar
Rodhouse, P.G. & O'kelly, M., 1981. Flow requirements of the oysters Ostrea edulis L. and Crassostrea gigas Thunberg in an upwelling column system of culture. Aquaculture, 22, 110.CrossRefGoogle Scholar
Rodhouse, P.G., Ottway, B. & Burnell, G.M., 1981. Bivalve production and food chain efficiency in an experimental nursery system. Journal of the Marine Biological Association of the United Kingdom, 61, 243256.Google Scholar
Rodhouse, P.G., Roden, C. & Somerville-Jacklin, M.E., 1983. Nutritional value of microalgal mass cultures to the oyster Ostrea edulis L. Aquaculture, 32, 1118.CrossRefGoogle Scholar
Roels, O.A., Laurence, S., Farmer, M.W. & Van Hemelryck, L., 1978. Organic production potential of artificial upwelling marine culture. Process Biochemistry, 13, 1822.Google Scholar
Round, F.E., Crawford, R.M. & Mann, D.G., 1990. The diatoms: biology and morphology of the genera. Cambridge: Cambridge University Press.Google Scholar
Sakshaug, E. & Myklestad, S., 1973. Studies on the phytoplankton ecology of the Trondheimsfjord. III. Dynamics of phytoplankton blooms in relation to environmental factors, bioassay experiments and parameters for the physiological state of the populations. Journal of Experimental Marine Biology and Ecology, 11, 157188.CrossRefGoogle Scholar
Sornin, J.M., Collos, Y., Delmas, D.Feuillet-Girard, M. & Gouleau, D., 1990. Nitrogenous nutrient transfers in oyster ponds: role of sediment in deferred primary production. Marine Ecology Progress Series, 68, 1522.CrossRefGoogle Scholar
Strand, Ø., 1995. Enhancement of the bivalve production capacity in a landlocked heliothermic marine basin. Aquaculture Research, in press.CrossRefGoogle Scholar
Strickland, J.D.H. & Parsons, T.R., 1972. A practical handbook of sea-water analysis. Bulletin. Fisheries Research Board of Canada, no. 167, pp. 1311.Google Scholar
Tenore, K.R., Goldman, J.C. & Clarner, J.P., 1973. The food chain dynamics of the oyster, dam and mussel in an aquaculture food chain. Journal of Experimental Marine Biology and Ecology, 12, 157165.CrossRefGoogle Scholar
Utermöhl, H., 1931. Neue Wege in der quantitativen Erfassung des Planktons. (Mit besonderer Berucksichtigung des Ultraplanktons.) Verhandlungen der International Vereinigung fur Theoretische und Angewandte Limnologie, 5, 567596.Google Scholar
Walne, P.R., 1973. Growth rates and nitrogen and carbohydrate contents of juvenile clams, Saxidomus giganteus, fed three species of algae. Journal of the Fisheries Research Board of Canada, 30, 18251830.CrossRefGoogle Scholar
Walsh, D.T., Kraus, R.A., Withstandley, C.A., Talin, S.M. & Petrovits, E.J., 1985. Dimensioning of a mass algal culture facility for the temperate zone nursery culture of bivalve molluscs. Journal of World Mariculture Society, 16, 451—463.CrossRefGoogle Scholar
Yamamuro, M. & Koike, I., 1993. Nitrogen metabolism of the filter-feeding bivalve Corbicula japonica and its significance in primary production of a brackish lake in Japan. Limnology and Oceanography, 38, 9971007.CrossRefGoogle Scholar