Abstract
Two species of Copepoda Temora longicornis (Müller) and Pseudocalanus elongates (Boeck) were cultured continuously in the laboratory. Four and three generations, respectively, were raised at 16 different combinations of temperature and food concentration. Prosome length and ash-free dry weight were measured in the adult stage and in Pseudocalanus also in copepodite stage I, and the relation between length and weight was established. In Pseudocalanus also the relative amount of lipid was estimated.
Prosome length and length-specific body weight (condition factor) were positively correlated with food concentration. Lipid content in Pseudocalanus was also strongly affected by the concentration of food.
Prosome length was negatively correlated with temperature. However, length-specific body weight in Temora was positively correlated with temperature. Therefore, at higher temperature Temora was smaller, but heavier per unit body length. In Pseudocalanus a similar but less significant influence of temperature on length-specific weight was found; lipid content was not significantly influenced by the temperature.
Females of Temora had larger length-specific weights than males. In Pseudocalanus the opposite was found, coinciding with a higher lipid content in males than in females.
It is discussed that at natural concentrations of phytoplankton body size and weight of copepods are reduced in the North Sea during the major part of the growing-season.
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References
Baars, M.A. and H. G. Fransz, 1984. Grazing pressure of copepods on the phytoplankton stock of the central North Sea. Neth. J. Sea Rex. 18: 120–142.
Bakker, C. and P. van Rijswijk, 1987. Development lime and growth rate of the marine calanoid copepod Temora longicornis as related to food conditions in the Oosterschelde estuary (southern North Sea). Neth. J. Sea Rex. 21: 125–141.
Båmstedt, U., 1978. Studies on the deep-water pelagic community of Korsfjorden, western Norway: seasonal variation in weight and biochemical composition of Chiridius armatus (Copepoda), Boreomysis arctica (Mysidacea), and Eukrohnia hamata (Chaetognatha). Sarsia 63: 145–154.
Bottrell, H. H. and D. B. Robins, 1984. Seasonal variations in length, dry weight, carbon and nitrogen of Calanus hclgolandicus from the Celtic Sea. Mar. Ecol. Prog. Ser. 14. 259–268.
Checkley, D. M., 1985. Nitrogen limitation of Zooplankton production and its effect on the marine nitrogen cycle. Arch. Hydrobiol. 21: 103–113.
Cohen, R. E. and R. G. Lough, 1981. Length-weight relationships for several copepods dominant in the Georges Bank-Gulf of Maine area. J. northw. Atl. Fish. Sci. 2: 47–52.
Corkett, C. J. and I. A. McLaren, 1978. The biology of Pseudoealanux. Adv. mar. Biol 15: 2–231.
Crisp, D. J., 1971. Energy flow measurements. In N. A. Holme and A. D. McIntyre (eds). Methods for the study of marine benthos. IBP Handbook 16, Blackwell, Oxford: 197–279.
Daan, R., 1987. Impact of egg predation by Noctiluca miliaris on the summer development of copepod populations in the southern North Sea. Mar. Ecol. Prog. Ser. 37: 9–17.
Daan, R., S. R. Gonzalez and W. C. M. Klein Breteler, 1988. Cannibalism in omnivorous calanoid copepods. Mar. Ecol. Prog. Ser. in press
Daro, M. H. and B. van Gijsegem, 1984. Ecological factors affecting weight, feeding, and production of five dominant copepods in the Southern Bight of the North Sea Rapp. Proc. Verb. Réun. Cons. int. Explor. Mer 1983: 226–233.
Deevey, G. B., 1960. Relative effects of temperature and food on seasonal variations in length of marine copepods in some eastern american and western european waters. Bull. Bingham Oceanogr. Coll. 17: 54–85.
Diel, S. and W. C. M. Klein Breteler, 1986. Growth nnd development of Calanus spp. (Copepoda) during spring phytoplankton succession in the North Sea. Mar. Biol. 91: 85–92.
Duncan, A., 1985. Body carbon in daphnids as an indicator of the food concentration available in the field. Arch. Hydrobiol. 21: 81–90.
Durbin, E. G. and A. G. Durbin, 1978. Length and weight relationships of Acartia clausi from Narragansett Bay, R. I. Limnol. Oceanogr. 23: 958–969.
Durbin, E. G., A. G. Durbin, T. J. Smayda and P. G. Verity, 1983. Food limitation of production by adult Acartia tonsa in Narragansett Bay, Rhode Island. Limnol. Oceanogr. 28: 1199–1213.
Evans, F., 1981. An investigation into the relationship of sea temperature and food supply to the size of the planktonic copepod Temora longicornis Müller in the North Sea. Estuar. coast. Shelf Sci. 13: 145–158.
Falk-Petersen, S., 198I. Ecological investigations on the Zooplankton community of Balsfjorden, Northern Norway: seasonal changes in body weight and the main biochemical composition of Thysanoessa inermis (Krøyer), Thysanoessa raschii (M. Sars) and Meganyctiphanes norvegica (M. Sars) in relation to environmental parameters. J. exp. mar. Biol. Ecol. 49: 103–120.
Falk-Petersen, S., 1985. Growth of the Euphausiids Thysanoessa inermis, Thysanoessa raschii and Meganyctiphanes norvegica in a subarctic fjord, North Norway. Can. J. Fish. aquat Sci 42: 14–22
Foran, J. A., 1986. A companion of the life history features of a temperate and a subtropical Daphnia species. Oikos 46: 185–193.
Gatten, R. R., E. D. S. Corner, C.C. Kilvington and J. R. Sargent, 1979. A seasonal survey of the lipids in Calanus helgolandicus Claus from the English Channel. In E. Naylor and R. G. Hartnoll (eds). Cyclic phenomena in marine plants and animals. Pergamon Press, Oxford: 275–284.
Gatten, R. R., J R Sargent, T. E. V. Forsberg, S.C. M. O’Hara and E. D. S. Corner, 1980. On the nutrition and metabolism of Zooplankton. XIV Utilization of lipid by Calanus helgolandicus during maturation and reproduction. J. mar. boil. Ass. U. K. 60: 391–399.
Geller, W. and H. Müller, 1985. Seasonal variability in the relationship between body length and individual dry weight as related to food abundance and clutch size in two coexisting Daphnia species. J. Plankton Res. 7: 1–18.
Kane, J. 1982 Effect of season and location on the relationship between Zooplankton displacement volume and dry weight in the Northwest Atlantic Fish. Bull 80: 631–642.
Klein Breteler, W. C. M., 1980. Continuous breeding of marine pelagic copepods in the presence of heterotrophic dinoflagellates. Mar. Ecol. Progr. Ser. 2: 229–233.
Klein Breteler, W. C. M., 1982. The life stages of four pelagic copepods (Copepoda: Calanoida), illustrated by a series of photographs. Neth. Inst. Sea Res. Publ. Ser. 6–1982: 1–32.
Klein Breteler, W. C. M. and S. R. Gonzalez, 1982. Influence of cultivation and food concentration on body length of calanoid copepods. Mar. Biol. 71: 157–161.
Klein Breteler, W. C. M. and S. R. Gonzalez, 1986. Culture and development of Temora longicornis (Copepoda, Calanoida) at different conditions of temperature and food. Syllogeus 58: 71–84.
Klein Breteler, W. C. M., H. G. Fransz and S. R. Gonzalez, 1982. Growth and development of four calanoid copepod species under experimental and natural conditions. Neth. J. Sea Res. 16: 195–207.
Lonsdale, D. J. and J. S. Levinton, 1985. Latitudinal differentiation in copepod growth: an adaptation to temperature. Ecology 66: 1397–1407.
Marshall, S. M., 1949. On the biology of small copepods in Loch Striven. J. mar. biol. Ass. U. K. 28: 45–122
Marshall, S. M. and A. P. Orr, 1955. The biology of a marine copepod Calanus finmarchicus (Gunnerus). Oliver and Boyd, Edinburgh and London. 188 pp.
Marshall, S. M., A. G. Nicholls and A. P. Orr, 1934. On the biology of Calanus finmarchicus. V. Seasonal distribution, size, weight and chemical composition in Loch Striven in 1933 and their relation to the phytoplankton. J. mar. boil. Ass. U. K. 19: 793–827.
McLaren, I. A., 1978. Generation lengths of some temperate marine copepods: estimation, prediction, and implications. J. Fish. Res. Bd Can. 35: 1330–1342.
Ohman, M. D., 1985. Resource-satiated population growth of the copepod Pseudocalanus sp. Arch. Hydrobiol. 21: 15–32.
Omori, M. 1970. Variations of length, weight, respiratory rate, and chemical composition of Calanus cristatus in relation to its food and feeding. In J. H. Steele (ed.), Marine food chains. Oliver and Boyd, Edinburgh: 113–126.
Orr, A. P., 1934. On the biology of Calanus finmarchicus. IV. Seasonal changes in weight and chemical composition of Calanus from Loch Fyne. J. mar. biol. Ass. U. K. 19: 613–632.
Paffenhöfer, G. -A., 1984. Food ingestion by the marine planktonic copepod Paracalanus in relation to abundance and size distribution of food. Mar. Biol. 80: 323–333.
Paffenhöfer, G. -A. and R. P. Harris, 1976. Feeding, growth and reproduction of the marine planktonic copepod Pseudocalanus elongatus Boeck. J. mar. biol. Ass. U. K. 56: 327–344.
Robertson, A., 1968 The continuous plankton recorder: a method for studying the biomass of calanoid copepods. Bull. Mar. Ecol 6: 185–223.
Uye, S. -I., 1982. Length-weight relationships of important zooplankton from the inland sea of Japan. J. Oceanogr. Soc. Japan 38: 149–158.
Vidal, J., 1980 Physioecology of zooplankton. I. Effects of phytoplankton concentration, temperature, and body size on the growth rate of Calanus pacificus and Pseudocalanus sp. Mar. Biol. 56: 111–134.
Warren, G. J., M. S. Evans, D. J. Jude and J. C. Ayers, 1986. Seasonal variations in copepod size: effect of temperature, food abundance, and vertebrate predation. J Plankton Res. 8: 841–853.
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Breteler, W.C.M.K., Gonzalez, S.R. (1988). Influence of temperature and food concentration on body size, weight and lipid content of two Calanoid copepod species. In: Boxshall, G.A., Schminke, H.K. (eds) Biology of Copepods. Developments in Hydrobiology, vol 47. Springer, Dordrecht. https://doi.org/10.1007/978-94-009-3103-9_18
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DOI: https://doi.org/10.1007/978-94-009-3103-9_18
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