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Long-lasting effect of stress on susceptibility of a freshwater clam to copepod parasitism

Published online by Cambridge University Press:  02 December 2004

M. SAARINEN
Affiliation:
Department of Biological and Environmental Science, University of Jyväskylä, P.O. Box 35, FI-40014 University of Jyväskylä, Finland
J. TASKINEN
Affiliation:
Karelian Institute, Department of Ecology, University of Joensuu, P.O. Box 111, FI-80101 Joensuu, Finland

Abstract

The question whether a stress event can have a long-lasting effect on susceptibility to parasites was studied using a freshwater bivalve clam and its crustacean parasite as a model system. Anodonta piscinalis clams were collected from 2 populations during August–September 2002. Clams were transported to the laboratory and marked. The stressed clams were subjected to low oxygen for 25 days, while the unstressed control clams were caged in their lakes of origin for the same period. Then the clams were transported to a third lake where they were exposed to natural infections by the ergasilid copepod, Paraergasilus rylovi, 11 months after the stress event. The stressed clams were more intensively parasitized. They also showed lower growth, lower reproduction and lower survival than the unstressed control clams. The results indicate that susceptibility of A. piscinalis to P. rylovi infection may be condition dependent, and that stress may have a long-lasting, increasing effect on host susceptibility to parasitism in natural populations.

Type
Research Article
Copyright
© 2004 Cambridge University Press

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References

REFERENCES

ABROUS, M., RONDELAUD, D. & DREYFUSS, G. ( 2001). The stress of Lymnaea truncatula just before miracidial exposure with Fasciola hepatica increased the prevalence of infection. Experimental Parasitology 99, 4951.CrossRefGoogle Scholar
BAUER, G., HOCHWALD, S. & SILKENAT, W. ( 1991). Spatial distribution of freshwater mussels – The role of host fish and metabolic rate. Freshwater Biology 26, 377386.CrossRefGoogle Scholar
BAUER, O. N., MUSSELIUS, V. A. & STRELKOV, Y. A. ( 1973). Diseases of Pond Fishes. Israel Program for Scientific Translations, Jerusalem, Israel.
BROWN, M. J. F., LOOSLI, R. & SCHMID-HEMPEL, P. ( 2000). Condition-dependent expression of virulence in a trypanosome infecting bumblebees. Oikos 91, 421427.CrossRefGoogle Scholar
CHERNYSHEVA, N. B. & PURASJOKI, K. J. ( 1991). A redescription of Paraergasilus rylovi Markevich, 1937 (Copepoda, Ergasilidae). Systematic Parasitology 20, 165172.CrossRefGoogle Scholar
HAUKIOJA, E. & HAKALA, T. ( 1978 a). Life-history evolution in Anodonta piscinalis (Mollusca, Pelecypoda). Oecologia 35, 253266.Google Scholar
HAUKIOJA, E. & HAKALA, T. ( 1978 b). Measuring growth from shell rings in populations of Anodonta piscinalis (Pelecypoda, Unionidae). Annales Zoologici Fennici 15, 6065.Google Scholar
HINE, P. M. ( 1999). The inter-relationship of bivalve haemocytes. Fish and Shellfish Immunology 9, 367385.CrossRefGoogle Scholar
HINE, P. M., DIGGLES, B. K., PARSONS, M. J. D., PRINGLE, A. & BULL, B. ( 2002). The effects of stressors on the dynamics of Bonamia exitiosus Hine, Cochennec-Laureau & Berthe, infections in flat oysters Ostrea chilensis (Philippi). Journal of Fish Diseases 25, 545554.CrossRefGoogle Scholar
JOKELA, J. ( 1996). Within-season reproductive and somatic energy allocation in a freshwater clam, Anodonta piscinalis. Oecologia 105, 167174.CrossRefGoogle Scholar
JOKELA, J., SCHMID-HEMPEL, P. & RIGBY, M. C. ( 2000). Dr. Pangloss restrained by the Red Queen – steps towards a unified defence. Oikos 89, 267274.Google Scholar
JOKELA, J., VALTONEN, E. T. & LAPPALAINEN, M. ( 1991). Development of glochidia of Anodonta piscinalis and their infection of fish in a small lake in northern Finland. Archiv für Hydrobiologie 120, 345356.Google Scholar
KRIST, A. C., JOKELA, J., WIEHN, J. & LIVELY, C. M. ( 2004). Effects of host condition on susceptibility to infection, parasite developmental rate, and parasite transmission in a snail-trematode interaction. Journal of Evolutionary Biology 17, 3340.CrossRefGoogle Scholar
LACOSTE, A., MALHAM, S. K., CÉLÉBART, F., CUEFF, A. & POULET, S. A. ( 2002). Stress-induced immune changes in the oyster Crassostrea gigas. Developmental and Comparative Immunology 26, 19.CrossRefGoogle Scholar
LAFFERTY, K. D. & KURIS, A. M. ( 1999). How environmental stress affects the impacts of parasites. Limnology and Oceanography 44, 925931.CrossRefGoogle Scholar
LEHMAN, T. ( 1993). Ectoparasites: direct impact on host fitness. Parasitology Today 9, 813.CrossRefGoogle Scholar
MURRAY, P. J. & YOUNG, R. A. ( 1992). Stress and immunological recognition in host–pathogen interactions. Journal of Bacteriology 174, 41934196.CrossRefGoogle Scholar
PIPE, R. ( 1990). Hydrolytic enzymes associated with granular haemocytes of the marine mussel Mytilus edulis. Histochemical Journal 22, 595603.CrossRefGoogle Scholar
PRICE, P. W. ( 1980). Evolutionary Biology of Parasites. Princeton University Press, Princeton, New Jersey.
PRUETT, S. B., ENSLEY, D. K. & CRITTENDEN, P. L. ( 1993). The role of chemical-induced stress responses in immunosuppression: A review of quantitative associations and cause-effect relationships between chemical-induced stress responses and immunosuppression. Journal of Toxicology and Environmental Health 39, 163192.CrossRefGoogle Scholar
SAARINEN, M. & TASKINEN, J. ( 2003). Reduction in the level of infection of the bivalve Anodonta piscinalis by the copepod Paraergasilus rylovi using high temperature and low oxygen. Journal of Parasitology 89, 11671171.CrossRefGoogle Scholar
SAARINEN, M. & TASKINEN, J. ( 2004). Aspects of the ecology and natural history of Paraergasilus rylovi (Copepoda, Ergasilidae) parasitic in unionids of Finland. Journal of Parasitology 90, 948952.CrossRefGoogle Scholar
SOUSA, W. P. & GLEASON, M. ( 1989). Does parasitic infection compromise host survival under extreme environmental conditions? The case for Cerithidea californica (Gastropoda: Prosobranchia). Oecologia 80, 456464.CrossRefGoogle Scholar
TASKINEN, J. ( 1998). Cercarial production of the trematode Rhipidocotyle fennica in clams kept in the field. Journal of Parasitology 84, 345349.CrossRefGoogle Scholar
TASKINEN, J. & SAARINEN, M. ( 1999). Increased parasite abundance associated with reproductive maturity of the clam Anodonta piscinalis. Journal of Parasitology 85, 588591.CrossRefGoogle Scholar
TASKINEN, J., VALTONEN, E. T. & MÄKELÄ, T. ( 1994). Quantity of sporocysts and seasonality of two Rhipidocotyle species (Digenea: Bucephalidae) in Anodonta piscinalis (Mollusca: Bivalvia). International Journal for Parasitology 24, 877886.CrossRefGoogle Scholar
WETZEL, R. G. ( 1983). Limnology, 2nd Edn. Saunders College Publishing, a division of Holt, Rinehart & Winston, Inc., Orlando, Florida, USA.