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Consequences of an outbreak of columnaris disease (Flavobacterium columnare) to the helminth fauna of perch (Perca fluviatilis) in the Queen Mary reservoir, south-east England

Published online by Cambridge University Press:  08 September 2009

N.J. Morley  and
J.W. Lewis
N.J. Morley*
Affiliation:
School of Biological Sciences, Royal Holloway, University of London, Egham, SurreyTW20 0EX, UK
J.W. Lewis
Affiliation:
School of Biological Sciences, Royal Holloway, University of London, Egham, SurreyTW20 0EX, UK
*
*E-mail: n.morley@rhul.ac.uk
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Abstract

Parasitism of fish in fully bunded storage reservoirs has rarely been studied, while the impact of a rapid decline in a fish population on its parasite fauna is poorly understood. The present paper investigates the helminth fauna of perch (Perca fluviatilis) over a 5-year period in the Queen Mary reservoir, a large (290 ha) completely artificial water storage impoundment, which forms a unique and challenging habitat for its resident fish population. After 3 years of study, the perch population suffered a significant reduction due to a disease outbreak caused by the pathogenic bacterium Flavobacterium columnare, ‘columnaris disease’, and the subsequent effects on the helminth fauna over the next 2 years are evaluated. Conditions in the reservoir favour the development of large populations of zooplankton, which act as intermediate hosts for the majority of helminths in the dominant perch community. The prevalence and intensity of helminth infections showed much variation over the period prior to the perch mortality. These were likely to be due to changes in the zooplankton biomass, which was exposed to biotoxins released from periodic algal blooms and the application of copper to control them. The outbreak of F. columnare resulted in a significant decrease in the size and condition coefficient of the perch population. Changes also occurred in the composition of helminth parasites, with many species demonstrating either an increase or decrease in infection levels. These changes may be partly associated with an increase in the zooplankton biomass and altered population structure, probably caused by a decrease in fish predation pressure, which would influence the parasite population dynamics, although other factors directly associated with changes in the perch population are also likely to be influential. The long-term affects on the levels of helminth infections in the fish and associated intermediate hosts in the Queen Mary reservoir are discussed.

Type
Research Papers
Information
Journal of Helminthology , Volume 84 , Issue 2 , June 2010 , pp. 186 - 192
Copyright
Copyright © Cambridge University Press 2009

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References

Ajmal, M. & Hobbs, B.C. (1967) Causes and effects of columnaris-type diseases in fish: columnaris disease in roach and perch from English waters. Nature 215, 141142.CrossRefGoogle Scholar
Andrew, T.E. (1985) Seasonal variations in the metabolic rates of zooplankton populations in a Thames Valley reservoir. Hydrobiologia 127, 4152.CrossRefGoogle Scholar
Baylis, H.A. (1934) Fatal parasitic enteritis among razorbills. Veterinary Record 14, 14721473.Google Scholar
Brattey, J. (1986) Life history and population biology of larval Acanthocephalus lucii (Acanthocephala: Echinorhynchidae) in the isopod Asellus aquaticus. Journal of Parasitology 72, 633645.CrossRefGoogle ScholarPubMed
Brown, B.E. (1976) Observations on the tolerance of the isopod Asellus meridianus Rac. to copper and lead. Water Research 10, 555559.CrossRefGoogle Scholar
Bush, A.O., Lafferty, K.D., Lotz, J.M. & Shostak, A.W. (1997) Parasitology meets ecology on its own terms: Margolis et al. revisited. Journal of Parasitology 83, 575583.CrossRefGoogle Scholar
Codd, G.A. (2000) Cyanobacterial toxins, the perception of water quality, and the prioritisation of eutrophication control. Ecological Engineering 16, 5160.CrossRefGoogle Scholar
Collinge, V.K. & Davis, J.M. (1975) A survey of British reservoirs with examples of fluctuations in stored water volume. pp. 325inSymposium on the Effects of Storage on Water Quality. University of Reading, UK, 24–26 March. Medmenham, Water Research Centre.Google Scholar
Cremer, G.A. & Duncan, A. (1969) A seasonal study of zooplanktonic respiration under field conditions. Verhandlungen der Internationalen Vereinigung fur Theoretische und Angewandte Limnologie 17, 181190.Google Scholar
Duncan, A. (1975) The importance of zooplankton in the ecology of reservoirs. pp. 247272inSymposium on the Effects of Storage on Water Quality. University of Reading, UK, 24–26 March. Medmenham, Water Research Centre.Google Scholar
Duncan, A. (1990) A review: limnological management and biomanipulation in the London reservoirs. Hydrobiologia 200/201, 541548.CrossRefGoogle Scholar
Evseeva, N.V. (1996) Diapause of copepods as an element for stabilizing the parasite system of some fish helminths. Hydrobiologia 320, 229233.CrossRefGoogle Scholar
Hanzelova, V. (1992) Proteocephalus neglectus as a possible indicator of changes in the ecological balance of aquatic environments. Journal of Helminthology 66, 1724.CrossRefGoogle Scholar
Hopkins, D.G. (1975) An ecological study of fish in a Thames Valley storage reservoir. PhD thesis, Royal Holloway, University of London, UK.Google Scholar
Izyumova, N.A. (1987) Parasitic fauna of reservoir fishes of the USSR and its evolution. 325 pp. New Delhi, Oxonian Press.Google Scholar
Kennedy, C.R. (1998) Aquatic birds as agents of parasite dispersal: a field test of the effectiveness of helminth colonisation strategies. Bulletin of the Scandinavian Society for Parasitology 8, 2328.Google Scholar
Kennedy, C.R. (2001) Interspecific interactions between larval digeneans in the eyes of perch, Perca fluviatilis. Parasitology 122, S13S22.CrossRefGoogle ScholarPubMed
Kubecka, J. & Duncan, A. (1994) Low fish predation pressure in the London reservoirs: I. Species composition, density, and biomass. Internationale Revue der Gesamten Hydro Biologie 79, 143155.CrossRefGoogle Scholar
Kurmayer, R. & Juttner, F. (1999) Strategies for the co-existence of zooplankton with the toxic cyanobacterium Planktothrix rubescens in Lake Zurich. Journal of Plankton Research 21, 659683.CrossRefGoogle Scholar
Landsberg, J.H. (2002) The effects of harmful algal blooms on aquatic organisms. Reviews in Fisheries Science 10, 113390.CrossRefGoogle Scholar
Lewis, J.W., Morley, N.J., Drinkall, J., Jamieson, B.J., Wright, R. & Parry, J.D. (2009) Toxic effects of Streptomyces griseus spores and exudates on fish gill pathology. Ecotoxicology and Environmental Safety 72, 173181.CrossRefGoogle ScholarPubMed
Lowe, P.R. & Baylis, H.A. (1934) On a flock of Razorbills in Middlesex found to be infected with intestinal flukes. British Birds 28, 188190.Google Scholar
Marcogliese, D.J. (1995) The role of zooplankton in the transmission of helminth parasites to fish. Reviews of Fish Biology and Fisheries 5, 336371.CrossRefGoogle Scholar
Monchenko, V.I. (1996) The problem of induction and termination of diapause in cyclopoid copepods. Hydrobiologia 320, 119122.CrossRefGoogle Scholar
Morley, N.J. (2007) Anthropogenic effects of reservoir construction on the parasite fauna of aquatic wildlife. EcoHealth 4, 374383.CrossRefGoogle Scholar
Morley, N.J., Campbell, C. & Lewis, J.W. (2008) The occurrence and distribution of Dermocystidium percae (Mesomycetozoa) in perch (Perca fluviatilis) in the lower Thames Valley, UK. Journal of Applied Ichthyology 24, 629631.CrossRefGoogle Scholar
Poulin, R., Curtis, M.A. & Rau, M.E. (1992) Effects of Eubothrium salvelini (Cestoda) on the behaviour of Cyclops vernalis (Copepoda) and its susceptibility to fish predators. Parasitology 105, 265271.CrossRefGoogle Scholar
Rai, L.C. & Mallick, N. (1993) Heavy metal toxicity to algae under synthetic microcosm. Ecotoxicology 2, 231242.CrossRefGoogle ScholarPubMed
Reiczigel, J. & Rozsa, L. (2001) Quantitative parasitology 2.0, Budapest, distributed by the authors.Google Scholar
Renton, P.J., Duncan, A. & Kubecka, J. (1999) A review of the management implications of low fish stocks in the London reservoirs. Institute of Fisheries Management Annual Study Course 30, 111137.Google Scholar
Riggs, M.R. & Esch, G.W. (1987) The suprapopulation dynamics of Bothriocephalus acheilognathi in a North Carolina reservoir: abundance, dispersion, and prevalence. Journal of Parasitology 73, 877892.CrossRefGoogle Scholar
Seda, J. & Duncan, A. (1994) Low fish predation pressure in London reservoirs: II. Consequences to zooplankton community structure. Hydrobiologia 291, 179191.CrossRefGoogle Scholar
Sindermann, C.J. (1990) Principal diseases of marine fish and shellfish. New York, Academic Press.Google Scholar
Steel, J.A. (1972) The application of fundamental limnological research in water supply system design and management. Symposium of the Zoological Society of London 29, 4167.Google Scholar
Steel, J.A.P., Duncan, A. & Andrew, T.E. (1972) The daily carbon gains and losses in the seston of Queen Mary reservoir, England, during early and mid 1968. pp. 515527in Kajak, Z. & Hillbricht-Ilkowska, A. (Eds) Productivity problems of freshwaters. Proceedings of the IBP-UNESCO Symposium. Kazimierz Dolny, Poland, 6–12 May, 1970. Warszawa, Polish Scientific Publishers.Google Scholar
Tripathi, N.K., Latimer, K.S. & Rakich, P.M. (2003) Columnaris disease in freshwater fish. Compendium on Continuing Education for the Practicing Veterinarian 25, 528536.Google Scholar
Van Alstyne, K.L., Wolfe, G.V., Freidenburg, T.L., Neill, A. & Hicken, C. (2001) Activated defense systems in marine macroalgae: evidence for an ecological role for DMSP cleavage. Marine Ecology Progress Series 213, 5365.CrossRefGoogle Scholar
WHO (1998) Copper. Environmental health criteria 200. 382 pp. Geneva, WHO.Google Scholar
Windle Taylor, E. (1955) The reservoirs of the Metropolitan Water Board and their influence upon the character of the stored water. Verhandlungen der Internationalen Vereinigung fur Theoretische und Angewandte Limnologie 12, 4865.Google Scholar
Windle Taylor, E. (1961) 39th Report on the Results of the Bacteriological, Chemical and Biological Examination of the London Waters for the Years 1959–1960. 150 pp.London, Metropolitan Water Board.Google Scholar
Windle Taylor, E. (1965) 41st Report on the Results of the Bacteriological, Chemical and Biological Examination of the London Waters for the Years 1963–1964. 152 pp.London, Metropolitan Water Board.Google Scholar
Windle Taylor, E. (1969) 43rd Report on the Results of the Bacteriological, Chemical and Biological Examination of the London Waters for the Years 1967–1968. 130 pp.London, Metropolitan Water Board.Google Scholar
Windle Taylor, E. (1971) 44th Report on the Results of the Bacteriological, Chemical and Biological Examination of the London Waters for the Years 1969–1970. 163 pp.London, Metropolitan Water Board.Google Scholar
Zhokhov, A.E., Pugatcheva, M.N., Molodozhnikova, N.M. & Mironovskii, A.N. (2006) Ruffe (Gymnocephalus cernuus L.) (Perciformes, Percidae) helminth fauna in Rybinsk reservoir: recovery following a depression in abundance of the host population. Journal of Ichthyology 46, 668673.CrossRefGoogle Scholar