Hostname: page-component-848d4c4894-ndmmz Total loading time: 0 Render date: 2024-05-12T22:16:40.971Z Has data issue: false hasContentIssue false
  • English
  • Français

A loss of fecundity in a population of mudsnails Hydrobia ventrosa caused by larval trematodes does not measurably affect host population equilibrium level

Published online by Cambridge University Press:  23 January 2006

S. KUBE ,
J. KUBE  and
A. BICK
S. KUBE
Affiliation:
Baltic Sea Research Institute Warnemuende, Seestrasse 15, D-18119 Rostock-Warnemuende, Germany
J. KUBE
Affiliation:
Institute of Applied Ecology, Alte Dorfstrasse 11, D-18184 Neu Broderstorf, Germany
A. BICK
Affiliation:
University of Rostock, Department of Zoology, Universitätsplatz 2, D-18051 Rostock, Germany
Get access Rights & Permissions [Opens in a new window]

Abstract

Host snail demography and trematode parasitism were followed for one host generation in a shallow brackish lagoon of the western Baltic Sea. In addition, a laboratory experiment was simultaneously conducted to quantify the effects of parasitic infection on host fecundity. Hydrobia ventrosa of the cohort of 1996 had a maximum life-span of up to 2 years and reproduced between May and November of their second calendar year in 1997. Snails died after reproduction. The first trematode infections appeared in May 1997 when the snails started to mature. Total trematode prevalence peaked in summer and declined during winter to the lowest level in early spring 1998. Eight taxa of larval trematodes were found. Egg production of females with trematode infections was significantly reduced. Among females with pre-patent infections, about 20% were still able to produce eggs. Among females with patent infections merely 9% could lay eggs, compared to an average of about 51% in uninfected females. Taking into account a summer prevalence of about 25%, parasitic infections caused an overall reduction in egg production of the snail host population of about 15%. The reduction in host fecundity as a result of larval trematode infection did not measurably affect the population dynamics of H. ventrosa, because other environmental factors, especially winter severity and available food supply, were concluded to be much more relevant.

Keywords

Hydrobiatrematodeshost-parasite interactionfecundity
Type
Research Article
Information
Parasitology , Volume 132 , Issue 5 , May 2006 , pp. 725 - 732
Copyright
2006 Cambridge University Press

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Anderson, A. ( 1971). Intertidal activity, breeding and the floating habit of Hydrobia ulvae in the Ythan estuary. Journal of the Marine Biological Association, UK 51, 423437.CrossRefGoogle Scholar
Armonies, W. and Hartke, D. ( 1995). Floating of mud snails Hydrobia ulvae in tidal waters of the Wadden Sea, and its implications in distribution patterns. Helgoländer Meeresuntersuchungen 49, 529538.CrossRefGoogle Scholar
Baudoin, M. ( 1975). Host castration as a parasitic strategy. Evolution 29, 335352.CrossRefGoogle Scholar
Bayne, C. J. and Loker, E. S. ( 1987). Survival within the snail host. In The Biology of Schistosomes: from Genes to Latrines ( ed. Rollinson, D. and Simpson, A. J. G.), pp. 321346. Academic Press, London, UK.
Crews, A. E. and Esch, G. W. ( 1986). Seasonal dynamics of Halipegus occidualis (Trematoda: Hemiuridae) in Helisoma anceps and its impact on fecundity of the snail host. Journal of Parasitology 72, 646651.CrossRefGoogle Scholar
Dierschke, V. ( 1996). Verfügbarkeit benthischer Beutetiere und Habitatwahl von Watvögeln im Windwatt von Hiddensee. In Unterschiedliches Zugverhalten alter und junger Alpenstrandläufer Calidris alpina: Ökologische Untersuchungen an Rastplätzen der Ostsee, des Wattenmeeres und auf Helgoland, pp. 4970. Cuvillier Verlag, Göttingen.
Esch, G. W., Curtis, L. A. and Barger, M. A. ( 2001). A perspective on the ecology of trematode communities in snails. Parasitology 123, 5775.CrossRefGoogle Scholar
Fish, J. D. and Fish, S. ( 1981). The early life-cycle stages of Hydrobia ventrosa and Hydrobia neglecta with observations on Potamopyrgus jenkinsi. Journal of Molluscan Studies 47, 8998.CrossRefGoogle Scholar
Gandon, S., Agnew, P. and Michalakis, Y. ( 2002). Coevolution between parasite virulence and host life-history traits. The American Naturalist 160, 374388.Google Scholar
Gérard, C. and Théron, A. ( 1995). Spatial interaction between parasite and host within the Biomphalaria glabrata/Schistosoma mansoni system: influence of host size at infection time. Parasite 2, 345350.Google Scholar
Holmes, J. C. and Zohar, S. ( 1990). Pathology and host behaviour. In Parasitism and Host Behaviour ( ed. Barnard, C. J. and Behnke, J. M.), pp. 3463. Taylor and Francis, London, UK.
Hoskin, G. P. ( 1975). Light and electron microscopy of the host-parasite interface and histopathology of Nassarius obsoletus infected with rediae of Himasthla quissetensis. Annals of the New York Academy of Sciences 266, 497512.CrossRefGoogle Scholar
Hurd, H. ( 1990). Physiological and behavioural interactions between parasites and invertebrate hosts. Advances in Parasitology 29, 271318.CrossRefGoogle Scholar
James, B. L. ( 1965). The effects of parasitism by larval Digenea on the digestive gland of the intertidal prosobranch, Littorina saxatilis (Olivi) subsp. tenebrosa (Montagu). Parasitology 55, 93115.CrossRefGoogle Scholar
Jensen, K. T., Latama, G. and Mouritsen, K. N. ( 1996). The effect of larval trematodes on the survival rates of two species of mud snails (Hydrobiidae) experimentally exposed to desiccation, freezing and anoxia. Helgoländer Meeresuntersuchungen 50, 327335.CrossRefGoogle Scholar
Jokela, J., Dybdahl, M. F. and Lively, C. M. ( 1999). Habitat-specific variation in life history traits, clonal population structure and parasitism in a freshwater snail (Potamopyrgus antipodarum). Journal of Evolutionary Biology 12, 350360.CrossRefGoogle Scholar
Jong-Brink, M. de ( 1990). How trematode parasites interfere with reproduction of their intermediate hosts, freshwater snails. Journal of Medical and Applied Malacology 2, 101133.Google Scholar
Joosse, J. and van Elk, R. ( 1986). Trichobilharzia ocellata: physiological characterization of giant growth, glycogen depletion, and absence of reproductive activity in the intermediate snail host, Lymnaea stagnalis. Experimental Parasitology 62, 113.CrossRefGoogle Scholar
Keas, B. E. and Esch, G. W. ( 1997). The effect of diet and reproductive maturity on the growth and reproduction of Helisoma anceps (Pulmonata) infected by Halipegus occidualis (Trematoda). Journal of Parasitology 83, 96104.CrossRefGoogle Scholar
Khurshed Alam, S. M., Shahadat, A. and Gilman, R. H. ( 1992). Histology of Fasciolopsis buski (Lankester) in susceptible snails. Bangladesh Journal of Zoology 20, 97101.Google Scholar
Krist, A. C. ( 2001). Variation in fecundity among populations of snails is predicted by prevalence of castrating parasites. Evolutionary Ecology Research 3, 191197.Google Scholar
Kube, J., Kube, S. and Dierschke, V. ( 2002 a). Spatial and temporal variations in the trematode component community of the mudsnail Hydrobia ventrosa in relation to the occurrence of waterfowl as definitive hosts. Journal of Parasitology 88, 10751086.Google Scholar
Kube, S., Kube, J. and Bick, A. ( 2002 b). Component community of larval trematodes in the mudsnail Hydrobia ventrosa: Temporal variations in prevalence in relation to host life history. Journal of Parasitology 88, 730737.Google Scholar
Lafferty, K. D. ( 1993 a). Effect of parasitic castration on growth, reproduction and population dynamics of the marine snail Cerithidea californica. Marine Ecology Progress Series 96, 229237.Google Scholar
Lafferty, K. D. ( 1993 b). The marine snail, Cerithidea californica, matures at smaller sizes where parasitism is high. Oikos 68, 311.Google Scholar
Lassen, H. and Clark, M. E. ( 1979). Comparative fecundity in three Danish mudsnails (Hydrobiidae). Ophelia 18, 171178.Google Scholar
Levinton, J. S. ( 1979). The effect of density upon deposit-feeding populations: movement, feeding and floating of Hydrobia ventrosa Montagu (Gastropoda: Prosobranchia). Oecologia 43, 2739.CrossRefGoogle Scholar
Minchella, D. J. ( 1985). Host life-history variation in response to parasitism. Parasitology 90, 205216.CrossRefGoogle Scholar
Minchella, D. J. and LoVerde, P. T. ( 1981). A cost of increased early reproductive effort in the snail Biomphalaria glabrata. American Naturalist 118, 876881.CrossRefGoogle Scholar
Mouritsen, K. N. and Poulin, R. ( 2002). Parasitism, community structure and biodiversity in intertidal ecosystems. Parasitology 124, 11117.CrossRefGoogle Scholar
Probst, S. and Kube, J. ( 1999). Histopathological effects of larval trematode infections in mudsnails and their impact on host growth: what causes gigantism in Hydrobia ventrosa (Gastropoda: Prosobranchia). Journal of Experimental Marine Biology and Ecology 238, 4968.CrossRefGoogle Scholar
Probst, S., Kube, J. and Bick, A. ( 2000). Effects of winter severity on life history patterns and population dynamics of Hydrobia ventrosa (Gastropoda: Prosobranchia). Archiv für Hydrobiologie 148, 383396.CrossRefGoogle Scholar
Reimer, L. W. ( 1971). Neue Cercarien der Ostsee mit einer Diskussion ihrer möglichen Zuordnung und einem Bestimmungsschlüssel. Parasitologische Schriftenreihe 21, 125149.Google Scholar
Sokolova, I. M. ( 1995). Influence of trematodes on the demography of Littorina saxatilis (Gastropoda: Prosobranchia: Littorinidae) in the White Sea. Diseases of Aquatic Organisms 21, 91101.CrossRefGoogle Scholar
Sorensen, R. E. and Minchella, D. J. ( 2001). Snail-trematode life history interactions: past trends and future directions. Parasitology 123, 318.CrossRefGoogle Scholar
Sousa, W. P. and 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
Tétreault, F., Himmelman, J. H. and Measures, L. ( 2000). Impact of a castrating trematode, Neophasis sp., on the common whelk, Buccinum undatum, in the Northern Gulf of St. Lawrence. Biological Bulletin 198, 261271.Google Scholar
Théron, A. and Gérard, C. ( 1994). Development of accessory sexual organs in Biomphalaria glabrata (Planorbidae) in relation to timing of infection by Schistosoma mansoni: consequences for energy utilization patterns by the parasite. Journal of Molluscan Studies 60, 2531.CrossRefGoogle Scholar
Thompson, S. N. ( 1990). Physiological alterations during parasitism and their effects on host behaviour. In Parasitism and Host Behaviour ( ed. Barnard, C. J. and Behnke, J. M.), pp. 6494. Taylor and Francis, London, UK.
Thornhill, J. A., Jones, J. T. and Kusel, J. R. ( 1986). Increased oviposition and growth in immature Biomphalaria glabrata after exposure to Schistosoma mansoni. Parasitology 93, 443450.CrossRefGoogle Scholar
Wilson, R. A. and Denison, J. ( 1980). The parasitic castration and gigantism of Lymnaea truncatula infected with the larval stages of Fasciola hepatica. Zeitschrift für Parasitenkunde 61, 109119.CrossRefGoogle Scholar
Yamaguti, S. ( 1975). A Synoptical Review of Life Histories of Digenetic Trematodes of Vertebrates with Special Reference to the Morphology of their Larval Forms. Keigaku Publishing Co., Tokyo.