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Do the age compositions and growth of the crab Portunus pelagicus in marine embayments and estuaries differ?

Published online by Cambridge University Press:  19 September 2003

S. de Lestang*
Affiliation:
Centre for Fish and Fisheries Research, School of Biological Sciences and Biotechnology, Division of Science and Engineering, Murdoch University, Murdoch, Western Australia 6150, Australia
N.G. Hall
Affiliation:
Centre for Fish and Fisheries Research, School of Biological Sciences and Biotechnology, Division of Science and Engineering, Murdoch University, Murdoch, Western Australia 6150, Australia
I.C. Potter
Affiliation:
Centre for Fish and Fisheries Research, School of Biological Sciences and Biotechnology, Division of Science and Engineering, Murdoch University, Murdoch, Western Australia 6150, Australia
*
Corresponding author, e-mail: [email protected]

Abstract

Portunus pelagicus (Crustacea: Portunidae) was collected monthly for a minimum of two years from two marine embayments (Cockburn Sound and Koombana Bay) and two estuaries (Peel-Harvey and Leschenault) that are located between 32° and 33°S on the lower west coast of Australia. A birth date of 1 December, derived from estimates of the peak time of spawning, was used to determine the average age of crabs in the main size cohort(s) in carapace width–frequency histograms for each month in each water body. The resultant carapace width-at-age data for each sex in Cockburn Sound and the Peel-Harvey Estuary, in which recruitment occurs at an early age, were then described using a seasonal von Bertalanffy growth curve. The results demonstrated that the growth rates of P. pelagicus differed significantly neither between females and males nor between crabs in the two water bodies and that growth was highly seasonal, with little or no increase in size occurring during the cold winter and early spring months. They also showed that relatively few P. pelagicus live beyond 18 months and indicate that, as a result of legal restrictions against retaining ovigerous crabs and the poor quality of recently-moulted females, fishing mortality is far lower amongst female than male crabs. The fact that the carapace widths attained by P. pelagicus at the end of its first year of life in Cockburn Sound (105 mm) and the Peel-Harvey Estuary (109 mm) were very similar to those in the Leschenault Estuary (105 mm) and Koombana Bay (107 mm) into which that estuary discharges emphasizes that the growth of P. pelagicus in each of these systems was similar. Data are also presented which strongly indicate that the second moult undergone by mature females is accompanied by an increase in the relative size of the abdominal flap.

Type
Research Article
Copyright
Copyright © Marine Biological Association of the United Kingdom 2003

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References

Anon., 2000. FAO Yearbook. Fisheries statistics. Capture Production, 86/1. Rome: FAO.Google Scholar
Bradby, K., 1997. Peel Harvey. The decline and rescue of an ecosystem. Mandurah, Western Australia: Greening the Catchment Taskforce.Google Scholar
Campbell, G.R., 1984. A comparative study ofadult sexual behaviour and larval ecology of three commercially important portunid crabs from the Moreton Bay region of Queensland, Australia. PhD thesis, University of Queensland, Australia.Google Scholar
Campbell, G.R. & Fielder, D.R., 1986. Size at sexual maturity and occurrence of ovigerous females in three species of commercially exploited portunid crabs in S.E. Queensland. Proceedings of the Royal Society of Queensland, 97, 79–87.Google Scholar
Cerrato, R.M., 1990. Interpretable statistical tests for growth comparisons using parameters in the von Bertalanffy equation. Canadian Journal of Fisheries and Aquatic Sciences, 47, 1416–1426.CrossRefGoogle Scholar
Debelius, H., 1999. Crustacea, guide of the world (ed. R.M. Hennemann and B. Peyer). Frankfurt, Germany: IKAN— Unterwasserarchiv.Google Scholar
Fielder, D.R. & Eales, A.J., 1972. Observations on courtship, mating and sexual maturity in Portunus pelagicus (L., 1766). Journal of Natural History, 6, 273–277.Google Scholar
Fournier, D.A. & Silbert, J.R., 1990. MULTIFAN a likelihood based method for estimating growth parameters and age compositions from multiple length frequency data sets illustrated using data for southern bluefin tuna (Thunnus maccoyii). Canadian Journal of Fisheries and Aquatic Sciences, 47, 301–317.CrossRefGoogle Scholar
Hanumara, R.C. & Hoenig, N.A., 1987. An empirical comparison of a fit of linear and non-linear models for seasonal growth in fish. Fisheries Research, 5, 359–381.CrossRefGoogle Scholar
Hill, B.J., 1975. Abundance, breeding and growth of the crab Scylla serrata in two South African estuaries. Marine Biology, 32, 119–126.Google Scholar
Ingles, J. & Braum, E., 1989. Reproduction and larval ecology of the blue swimming crab Portunus pelagicus in Ragay Gulf, Philippines. Internationale Revue der Gesamten Hydrobiologie, 74, 471–490.Google Scholar
Kailola, P.J., Williams, M.J., Stewart, P.C., Riechelt, R.E., McNee, A. & Grieve, C., 1993. Australian fisheries resources. Canberra: Bureau of Resource Sciences.Google Scholar
Lestang, S. de, Hall, N.G. & Potter, I.C., in press. Reproductive biology of the blue swimmer crab, Portunus pelagicus (Decapoda: Portunidae) in five water bodies on the west coast of Australia. Fishery Bulletin. Google Scholar
McComb, A.J., Atkins, R.P., Birch, P.B., Gordon, D.M. & Lukatelich, R.J., 1981. Eutrophication in the Peel-Harvey estuarine system, Western Australia. In Estuaries and nutrients (ed B.J. Neilson and L.E. Cronin), pp. 323–342. New Jersey: Humana Press.Google Scholar
Meagher, T.D., 1971. Ecology of the crab Portunus pelagicus (Crustacea: Portunidae) in south western Australia. PhD thesis, University of Western Australia, Perth.Google Scholar
Paul, R.K.G., 1982. Abundance, breeding and growth of Callinectes arcuatus Ordway and Callinectes toxotes Ordway (Decapoda, Brachyura, Portunidae) in a lagoon system on the Mexican pacific coast. Estuarine, Coastal and Shelf Science, 14, 13–26.Google Scholar
Pauly, D. & David, N., 1981. Elefan I., a basic programme for the objective extraction of growth parameters from length — frequency data. Meeresforchung, 28, 205–211.Google Scholar
Penn, J.W., 1977. Trawl caught fish and crustaceans from Cockburn Sound. Report. Department of Fisheries and Wildlife, Western Australia, no. 20, Perth, Australia.Google Scholar
Potter, I.C., Chrystal, P.J. & Loneragan, N.R., 1983a. The biology of the blue manna crab Portunus pelagicus in an Australian estuary. Marine Biology, 78, 75–85.Google Scholar
Potter, I.C., Loneragan, N.R., Lenanton, R.C.J., Chrystal, P.J. & Grant, C.J., 1983b. Abundance, distribution and age structure of fish populations in a Western Australian estuary. Journal of Zoology, 200, 21–50.Google Scholar
Potter, I.C. & de Lestang, S., 2000. Blue swimmer crab Portunus pelagicus in Leschenault Estuary and Koombana Bay, south-western Australia. Journal of the Royal Society of Western Australia, 83, 221–236.Google Scholar
Potter, I.C., de Lestang, S. & Melville-Smith, R., 2001. The collection of biological data required for management of the blue swimmer crab fishery in the central and lower west coasts of Australia. Fisheries Research and Development Corporation Report, FRDC Project no. 97/137, Canberra, Australia.Google Scholar
Potter, M.A., Sumpton, W.D. & Smith, G.S., 1991. Movement, fishing sector impact, and factors affecting the recapture rate of tagged sand crabs, Portunus pelagicus (L.), in Moreton Bay. Australian Journal of Marine and Freshwater Research, 42, 751–760.Google Scholar
Rose, T.H., 1994. Comparisons of the benthic and zooplankton communities in the eutrophic Peel-Harvey and nearby Swan estuaries in south-western Australia. PhD thesis, Murdoch University, Western Australia.Google Scholar
Schnute, J. & Fournier, D.A., 1980. A new approach to length — frequency analysis: growth structure. Canadian Journal of Fisheries and Aquatic Sciences, 37, 1337–1351.CrossRefGoogle Scholar
Semeniuk, V., Semeniuk, T.A. & Unno, J., 2000. The Leschenault Inlet estuary: an overview. Journal of the Royal Society of Western Australia, 83, 207–228.Google Scholar
Smith, H., 1982. Blue crabs in South Australia—their status, potential and biology. South Australian Fisheries Industry Council, Adelaide, Australia, 6, 33–51.Google Scholar
Stephenson, W., 1962. The evolution and ecology of portunid crabs, with especial reference to Australian species. In The evolution of living organisms (ed. G.W. Leeper), pp. 34–67. Melbourne, Australia: Melbourne University Press.Google Scholar
Sukumaran, K.K. & Neelakantan, B., 1996. Relative growth and sexual maturity in the marine crabs, Portunus (Portunus) sanguinolentus (Herbst) and Portunus (Portunus) pelagicus (Linnaeus) along the southwest coast of India. Indian Journal of Fish Science, 43, 215–223.Google Scholar
Sukumaran, K.K. & Neelakantan, B., 1997. Age and growth in two marine portunid crabs, Portunus (Portunus) sanguinolentus (Herbst) and Portunus (Portunus) pelagicus (Linnaeus) along the southwest coast of India. Indian Journal of Fisheries, 44, 111–131.Google Scholar
Sumpton, W.D., Potter, M.A. & Smith, G.S., 1994. Reproduction and growth of the commercial sand crab, Portunus pelagicus (L.) in Moreton Bay, Queensland. Asian Fisheries Science, 7, 103–113.Google Scholar
Van Engel, W.A., 1958. The blue crab and its fishery in Chesapeake Bay. Part 1. Reproduction, early development, growth and migration. Commercial Fisheries Review, 20, 6–17.Google Scholar