Abstract
Parasites are important structural components of marine communities that can affect organism fitness and ecological interactions, and the provision of ecosystem services. Here, we investigate the host association of Polydora ciliata with two ecologically and economically important oyster species (Ostrea edulis, Magallana gigas) and examine its impacts on two fitness aspects: condition and shell strength. Our results provide strong inferential evidence of host specificity by P. ciliata with a tendency towards infestation of the native O. edulis over the introduced M. gigas. Evidence suggests increasing prevalence of parasitism with organismal age, but no clear indication that parasitism leads to reduced condition or shell strength. The prevalence of infection of O. edulis by P. ciliata over M. gigas observed here holds potential implications for species competition and dominance, and their respective population maintenance, which could explain the much lower abundances of O. edulis compared to M. gigas at specific geographical locations. Additionally, these results hold significance for the aquaculture sector, with parasitism likely to lower production output and decrease the end-product market value.
This is a preview of subscription content, log in via an institution to check access.
References
Ambariyanto, and R. Seed. 1991. The infestation of Mytilus edulis (Linnaeus) by Polydora ciliata (Johnston) in the Conwy estuary, North Wales. Journal of Molluscan Studies 57 (4): 413–424.
Bergman, K., R. Elner, and M. Risk. 1982. The influence of Polydora websteri borings on the strength of the shell of the sea scallop, Placopecten magellanicus. Canadian Journal of Zoology 60 (11): 2551–2556.
Bishop, M.J., and P.J. Hooper. 2005. Flow, stocking density and treatment against Polydora spp.: influences on nursery growth and mortality of the oysters Crassostrea virginica and Crassostrea ariakensis. Aquaculture 246 (1-4): 251–261.
Blake, J.A., and J.W. Evans. 1973. Polydora and related genera as borers in mollusk shells and other calcareous substrates (Polychaeta: Spionidae): California Malacozoological Society.
Buschbaum, C., A. Cornelius, and M.A. Goedknegt. 2016. Deeply hidden inside introduced biogenic structures—Pacific oyster reefs reduce detrimental barnacle overgrowth on native blue mussels. Journal of Sea Research 117: 20–26.
Calvo, G.W., M.W. Luckenbach, and E.M. Burreson. 1999. A comparative field study of Crassostrea gigas and Crassostrea virginica in relation to salinity in Virginia: School of Marine Science, Virginia Institute of Marine Science, College of William and Mary.
Calvo, G.W., M.W. Luckenbach, S. Allen, and E.M. Burreson. 2000. A comparative field study of Crassostrea ariakensis and Crassostrea virginica in relation to salinity in Virginia. Special Report in Applied Marine Science and Ocean Engineering.
Carroll, J.M., K.A. O'Shaughnessy, G.A. Diedrich, and C.M. Finelli. 2015. Are oysters being bored to death? Influence of Cliona celata on Crassostrea virginica condition, growth and survival. Diseases of Aquatic Organisms 117 (1): 31–44.
Chambon, C., A. Legeay, G. Durrieu, P. Gonzalez, P. Ciret, and J.C. Massabuau. 2007. Influence of the parasite worm Polydora sp. on the behaviour of the oyster Crassostrea gigas: a study of the respiratory impact and associated oxidative stress. Marine Biology 152 (2): 329–338.
Clements, J.C., D. Bourque, J. McLaughlin, M. Stephenson, and L.A. Comeau. 2017. Siltation increases the susceptibility of surface-cultured eastern oysters (Crassostrea virginica) to parasitism by the mudworm Polydora websteri. Aquaculture Research 48 (9): 4707–4717. https://doi.org/10.1111/are.13292.
Diez, M.E., V.I. Radashevsky, J.M. Orensanz, and F. Cremonte. 2011. Spionid polychaetes (Annelida: Spionidae) boring into shells of molluscs of commercial interest in northern Patagonia, Argentina. Italian Journal of Zoology 78 (4): 497–504.
Diez, M.E., N. Vázquez, D. Urteaga, and F. Cremonte. 2014. Species associations and environmental factors influence activity of borers on Ostrea puelchana in northern Patagonia. Journal of Molluscan Studies 80 (4): 430–434.
Diez, M.E., N. Vázquez, P. da Cunha Lana, and F. Cremonte. 2016. Biogenic calcareous growth on the ribbed mussel Aulacomya atra (Bivalvia: Mytilidae) favours polydorid boring (Polychaeta: Spionidae). Hydrobiologia 766 (1): 349–355.
Dorsett, D. 1961. The behaviour of Polydora ciliata (Johnst.). Tube-building and burrowing. Journal of the Marine Biological Association of the United Kingdom 41: 577–590.
Firth, L.B., L.M. Grant, T.P. Crowe, J.S. Ellis, C. Wiler, C. Convery, and N.E. O'Connor. 2017. Factors affecting the prevalence of the trematode parasite Echinostephilla patellae (Lebour, 1911) in the limpet Patella vulgata (L.). Journal of Experimental Marine Biology and Ecology. 492: 99–104.
Hayward, P. J. and Ryland, J. S. (Eds.). 2017. Handbook of the marine fauna of North-West Europe. Oxford University Press.
Herbert, R.J.H., C. Robert, J. Humphreys, and S. Fletcher. 2012. The Pacific oyster (Crassostrea gigas) in the UK: economic, legal and environmental issues associated with its cultivation, wild establishment and exploitation. Report for the Shellfish Association of Great Britain.
Hoberg, E.P., and D.R. Brooks. 2008. A macroevolutionary mosaic: episodic host-switching, geographical colonization and diversification in complex host-parasite systems. Journal of Biogeography 35 (9): 1533–1550.
Hu, Y.-P., S.C. Fuller, M. Castagna, R.C. Vrijenhoek, and R.A. Lutz. 1993. Shell morphology and identification of early life history stages of congeneric species of Crassostrea and Ostrea. Journal of the Marine Biological Association of the United Kingdom 73 (03): 471–496.
Jones, C., J. Lawton, and M. Shachak. 1996. Organisms as ecosystem engineers. In Ecosystem Management, 130–147. New York: Springer.
Kent, R.M.L. 1977. The infestation of molluscs by Polydora spp. PhD thesis, University of Plymouth.
Kent, R. 1981. The effect of Polydora ciliata on the shell strength of Mytilus edulis. Journal du Conseil 39 (3): 252–255.
Knights, A.M. 2012. Spatial variation in body size and reproductive condition of subtidal mussels: considerations for sustainable management. Fisheries Research. 113 (1): 45–54. https://doi.org/10.1016/j.fishres.2011.09.002.
Kochmann, J., C. Buschbaum, N. Volkenborn, and K. Reise. 2008. Shift from native mussels to alien oysters: differential effects of ecosystem engineers. Journal of Experimental Marine Biology and Ecology 364 (1): 1–10.
Korringa, P. 1951. The shell of Ostrea edulis as a habitat. Archives neerlandaises de zoologie 10: 32–146.
Korringa, P. 1952. Recent advances in oyster biology. The Quarterly Review of Biology 27 (3): 266–308.
Lafferty, K.D., C.D. Harvell, J.M. Conrad, C.S. Friedman, M.L. Kent, A.M. Kuris, E.N. Powell, D. Rondeau, and S.M. Saksida. 2015. Infectious diseases affect marine fisheries and aquaculture economics. Annual Review of Marine Science 7 (1): 471–496.
Lemasson, A.J., S. Fletcher, J.M. Hall-Spencer, and A.M. Knights. 2017. Linking the biological impacts of ocean acidification on oysters to changes in ecosystem services: a review. Journal of Experimental Marine Biology and Ecology 492: 49–62.
Lucas, A., and P.G. Beninger. 1985. The use of physiological condition indices in marine bivalve aquaculture. Aquaculture 44 (3): 187–200. https://doi.org/10.1016/0044-8486(85)90243-1.
MacDonald, J., A. Freer, and M. Cusack. 2009. Alignment of crystallographic c-axis throughout the four distinct microstructural layers of the oyster Crassostrea gigas. Crystal Growth & Design 10: 1243–1246.
Marin, M.G., V. Moschino, M. Deppieri, and L. Lucchetta. 2003. Variations in gross biochemical composition, energy value and condition index of T. philippinarum from the lagoon of Venice. Aquaculture. 219 (1–4): 859–871. https://doi.org/10.1016/s0044-8486(03)00035-8.
Mouritsen, K.N., and R. Poulin. 2002. Parasitism, community structure and biodiversity in intertidal ecosystems. Parasitology 124 (07).
Naciri-Graven, Y., A.G. Martin, J.P. Baud, T. Renault, and A. Gerard. 1998. Selecting the flat oyster Ostrea edulis (L.) for survival when infected with the parasite Bonamia ostreae. Journal of Experimental Marine Biology and Ecology 224 (1): 91–107.
Nell J. A. 2007. Controlling mudworm in oysters, NSWDPI Primefact 590. NSW Department of Primary Industries, NSW, Australia.
Orton, J.H. 1937. Oyster biology and oyster culture. Butler and Tanner Ltd, London. UK.
Powell, E.N., Y. Kim, and D. Bushek. 2015. Temporal structure and trends of parasites and pathologies in U.S. oysters and mussels: 16 years of mussel watch. Journal of Shellfish Research. 34 (3): 967–993. https://doi.org/10.2983/035.034.0325.
R Core Team 2018. Language and environment for statistical computing. https://www.R-project.org/
Reise, K., C. Buschbaum, H. Büttger, and M.K. Wegner. 2017. Invading oysters and native mussels: from hostile takeover to compatible bedfellows. Ecosphere 8.
Riascos, J.M., O. Heilmayer, M.E. Oliva, J. Laudien, and W.E. Arntz. 2008. Infestation of the surf clam Mesodesma donacium by the spionid polychaete Polydora bioccipitalis. Journal of Sea Research 59 (4): 217–227.
Rinde, E., T. Tjomsland, D. Hjermann, M. Kempa, P. Norling, and V.S. Kolluru. 2016. Increased spreading potential of the invasive Pacific oyster (Crassostrea gigas) at its northern distribution limit in Europe due to warmer climate. Marine and Freshwater Research.
Royer, J., M. Ropert, M. Mathieu, and K. Costil. 2006. Presence of spionid worms and other epibionts in Pacific oysters (Crassostrea gigas) cultured in Normandy, France. Aquaculture 253 (1-4): 461–474.
Sato-Okoshi, W., K. Okoshi, B.S. Koh, Y.H. Kim, and J.S. Hong. 2012. Polydorid species (Polychaeta: Spionidae) associated with commercially important mollusk shells in Korean waters. Aquaculture 350-353: 82–90.
Simon, C.A. 2011. Polydora and Dipolydora (Polychaeta: Spionidae) associated with molluscs on the south coast of South Africa, with descriptions of two new species. African Invertebrates 52 (1): 39–50.
Simon, C.A., and W. Sato-Okoshi. 2015. Polydorid polychaetes on farmed molluscs: distribution, spread and factors contributing to their success. Aquaculture Environment Interactions 7 (2): 147–166.
Thomas, Y., S. Pouvreau, M. Alunno-Bruscia, L. Barillé, F. Gohin, P. Bryère, and P. Gernez. 2016. Global change and climate-driven invasion of the Pacific oyster (Crassostrea gigas) along European coasts: a bioenergetics modelling approach. Journal of Biogeography 43 (3): 568–579.
Townhill, B., J. Pinnegar, J. Tinker, M. Jones, S. Simpson, P. Stebbing, and S. Dye. 2017. Non-native marine species in north-West Europe: developing an approach to assess future spread using regional downscaled climate projections. Aquatic Conservation: Marine and Freshwater Ecosystems 27 (5): 1035–1050.
Woolmer, A.P., M. Syvret, and A. FitzGerald. 2011. Restoration of native oyster, Ostrea edulis, in South Wales: options and approaches, CCW Contract Science Report 960, p93.
Zwerschke, N., M.C. Emmerson, D. Roberts, and N.E. O’Connor. 2016. Benthic assemblages associated with native and non-native oysters are similar. Marine Pollution Bulletin 111 (1-2): 305–310.
Acknowledgements
We wish to thank the following staff and friends from the Marine Biology and Ecology Research Centre and Engineering Department at Plymouth University for their help with organism collection and their assistance during this experiment: Marie Palmer, Ann Torr, Richard Ticehurst, Roger Haslam, Dr. Zoltan Gombos, Lucy Jupe and Samuel Provstgaard-Morys. We are grateful to Mr. Brian Langley, the National Trust, and the Carew Pole Garden Charitable Trust for granting us access to the collection site. We are also grateful to Dr. Jeff Clements and one additional anonymous reviewer for their comments which helped improved this manuscript.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by Carles Ibanez Marti
Electronic Supplementary Material
Rights and permissions
About this article
Cite this article
Lemasson, A.J., Knights, A.M. Preferential Parasitism of Native Oyster Ostrea edulis Over Non-Native Magallana gigas by a Polydorid Worm. Estuaries and Coasts 42, 1397–1403 (2019). https://doi.org/10.1007/s12237-019-00560-y
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12237-019-00560-y