Modelling the material uptake and deposition of the mytilus edulis in the Baltic coastal ecosystem

• Autorzy: Zemlys P. , Daunys D. , Razinkovas A.
• Języki publikacji: EN

Abstrakty

EN

A model was developed to describe the material uptake and biodeposition of bivalve Mytilus edulis. The existing blue mussel organism level models are based on contradictory assumptions and no agreement has still been found regarding the processes and environmental factors to be included into the model. A reconciliation of contradictory approaches was successfully done in the present model. Using seston concentration, seston organic content and mussel size as input data, the model is able to predict the uptake of suspended material, selection of organic particles and material allocation as pseudofaeces, ingested, assimilated fractions and faeces. The results of the model application to mussels in the south-eastern Baltic conditions are discussed.

Słowa kluczowe

EN

suspension feeding bivalves; filtration; biodeposition; modelling

• Wydawca: Institute of Oceanography University of Gdańsk
• Czasopismo: Oceanological and Hydrobiological Studies
• Rocznik: 2003
• Tom: Vol. 32, No. 2
• Strony: 53--79
• Opis fizyczny: Bibliogr. 61 poz., tab., wykr.

Twórcy

autor

Zemlys P.

• Coastal Research and Planning Institute, Klaipeda University H.Manto 84, 5808 Klaipeda, Lithuania.

autor

Daunys D.

• Coastal Research and Planning Institute, Klaipeda University H.Manto 84, 5808 Klaipeda, Lithuania.

autor

Razinkovas A.

• Coastal Research and Planning Institute, Klaipeda University H.Manto 84, 5808 Klaipeda, Lithuania.

Bibliografia

• [1]. Alimov A.F. 1981, Functional ecology of fresh water bivalves Leningrad. Nauka, 1981, 247 pp (in Russian).
• [2]. Bacher C., Duarte P., Ferreira J.G., Heral M., Raillard O. 1998, Assessment and comparison of the Marrrennes-Oleron Bay (France) and Carlingford Lough (Ireland) carrying capacity with ecosystem models, Aquat. Ecol., 31, 379-394.
• [3]. Bayne B.L. 1998, The physiology of suspension feeding bivalve molluscs: an introduction to the Plymouth `TROPHEE' workshop, J. exp. mar. Biol. Ecol., 219, 1-19.
• [4]. Bayne B.L., Iglesias J.I.P., Hawkins A.J.S., Navarro E., Hćral M., Deslous-Paoli J.M. 1993, Feeding behaviour of the mussel Mytilus edulis L. responses to variations in both quantity and organie content of seston, J. mar. biol. Assoc. U.K., 73, 813-829.
• [5]. Bayne B.L., Worali C.M. 1980, Growth and production of mussels Mytilus edulis from two populations, Mar. Ecol. Prog. Ser., 3, 317-328.
• [6]. Brylinsky M., Sephton T.W. 1991, Development of a computer simulation model of a cultured blue mussel (Mytilus edulis) population, Canadian Technical report of Fisheries and Ocean Sciences No.1805.
• [7]. Cranford P.J., Hill P.S. 1999, Seasonal variation in food utilization by suspension feeding bivalve molluscs Mytilus edulis and Placopecten magellanicus, Mar. Ecol. Prog. Ser., 190, 223-239.
• [8]. Cranford P.J. 2001, Evaluating the `reliability' offiltration rate measurements in bivalves, Mar. Ecol. Prog. Ser., 215, 303-305.
• [9]. Dame R.F., Patten B.C. 1981, Analysis of energy fiow in an intertidal oyster reef, Mar. Ecol. Prog. Ser., 5, 115-124.
• [10]. Dame R.F. 1996, Ecology of marine hivalves. An ecosystem approach, CRC Press, 254 pp.
• [11]. Defossez J.M., Hawkins A.J.S. 1997, Selective feeding in shellfish: size-dependent rejection of large particles within pseudofaeces from Mytilus edulis, Ruditapes philippinarum and Tapes decussates, Mar. Biol., 129, 139-147.
• [12]. Finn J.T., Leschine T.M. 1980, Does salt marsh fertilization enhance shellfish production? An application offlow analysis, Env. Manag., 4, 193-203.
• [13]. Galkus A., Joksas K. 1997, The sediment material in transit aquatic system, Lithuanian Institute of Geography, 198 pp (in Lithuanian).
• [14]. Gosling E. 1992, Systematics and geographic distribution of Mytilus, [in]: The Mussel Mytilus: Ecology, Physiology, Genetics and Culture, Gosling E. (ed.), 25, 1-20.
• [15]. Grant J., Dowd M., Thompson K. 1993, Perspectives on field studies and related biological models of bivalve growth and carrying capacity, [in]: Bivalve filter feeders in estuarine and coastal ecosystem processes, Dame RF (ed.), Springer Verlag, Berlin, 371-420.
• [16]. Haren van R.J.F., Kooijman S.L.M. 1993, Application of dynamit energy budget model to Mytilus edulis, Neth. J. Sea Res., 31(2), 119-133.
• [17]. Hawkins A.J.S., Smith R.F.M., Bayne B.L., Hóral M. 1996, Novell observations underlying the fast growth of suspension-feeding shellfish in turbid environments: Mytilus edulis. Mar. Ecol. Prog. Ser., 131, 170-190.
• [18]. Hawkins A.J.S., Bayne B.L., Bougrier S., Hćral M., Iglesias J.I.P., Navarro E. 1998, Some general relationships in comparing the feeding physiology of suspension-feeding bivalve molluscs, J. exp. mar. Biol. Ecol., 219, 87-103.
• [19]. Heip C.H.R., Goosen N.K., Herman P.M.J., Kromkamp J., Middelburg J.J., Soetaert K. 1995, Production and consumption of biological particles in temperate tidal estuaries, Oceanogr. Mar. Biol. Ann. Rev., 33, 1-149.
• [20]. Hćral M. 1993, Why carrying capacity models are useful tools for management of bivalve molluscs culture, Bivalve filter feeders in estuarine and coastal ecosystem processes, Dame R.F. (ed.), Springer Verlag, Heidelberg, 453-477.
• [21]. Herman P.M.J., Scholten H. 1990, Can suspension-feeders stabilise estuarine ecosystems? [in:] Trophic relationships in the marine environment Barnes M., Gibson R.N. (eds), Aberdeen University Press, Aberdeen, 104-116.
• [22]. Herman P.M.J. 1993, A set of models to investigate the role of benthic suspension feeders in estuarine ecosystems, [in:] Bivalve filier feeders in estuarine and coastal ecosystem processes, Dame RF (ed.), Springer Verlag, Berlin, 421-454.
• [23]. Jarvekulg A. 1979, Benthic fauna of the eastern Baltic Sea, Valgus, Tallin, 382 pp (In Russian).
• [24]. Jorgensen C.B. 1996, Bivalve feeder revisited, Mar. Ecol. Prog. Ser., 142, 287-302.
• [25]. Kautsky N. 1982, Growth and size structure in Baltic a Mytilus edulis population, Mar. Biol., 68, 117-133.
• [26]. Kautsky N., Evans S. 1987, Role of biodeposition by Mytilus edulis in the circulation of matter and nutrients in Baltic coastal ecosystem, Mar. Ecol. Prog. Ser., 38, 201-212.
• [27]. Kiorboe T., Molenberg F., Nohr O. 1980, Feeding, particle selection and carbon absorption in Mytilus edulis in different mixtures of algae and resuspended bottom material, Ophelia, 19, 193-205.
• [28]. Kiorboe T., Molenberg F. 1981, Particie selection in suspension-feeding bivalves, Mar. Ecol. Prog. Ser., 5, 291-296.
• [29]. Klepper O., Van der Tol M.W.M., Scholten H., Herman P.M.J. 1994, SMOES: a Simulation model for the Oosterschelde Ecosystem. Part I description and uncertainty analysis, Hydrobiologia, 282/283, 437-451.
• [30]. Kotta J. 2000, Impact of eutrophication and biological invasions on the structure and functions of benthic macrofauna, Ph.D. thesis, Tartu University.
• [31]. Kube J. 1996, The ecology of macrozoobenthos and sea ducks in the Pomeranian Bay, Mar. Sci. Rep., 18, 28-42.
• [32]. Molenberg F., Riisgard H.U. 1978, Efficiency of particie retention in 13 species of suspension feeding bivalves, Ophelia, 17, 239-246.
• [33]. Navarro E., Iglesias J.I.P. 1993, Infaunal filter-feeding bivalves and the physiological response to short-term fluctuations in food availability and composition, [in:] Bivalve filter feeders in estuarine and coastal ecosystem processes, Dame RF (ed.), Springer Verlag, Berlin, 25-56.
• [34]. Newell C.R., Campbell D.E., Gallagher S.M., 1998, Development of the mussel aquaculture lease site model MUSMOD©: a field program to calibrate model formulations, J. exp. mar. Biol. Ecol., 219, 143-169.
• [35]. Officer C.B., Smayda T.J., Mann R. 1982, Benthic filter feeding: a natural eutrophication control, Mar. Ecol. Prog. Ser., 9, 203-210.
• [36]. Olenin S. 1997, Comparative community study of the south-eastern Baltic coastal zone and Curonian lagoon bottom. Proceedings of the 13th symposium of Baltic Marine Biologists, 1996, 153-161.
• [37]. Prins T.C., Smaal A.C., Dame R.F. 1998, A review of the feedbacks between bivalve grazing and ecosystem processes, Aq. Ecol., 31, 349-359.
• [38]. Pustelnikov O. 1992, Biogeochemistry of semiclosed bays and human factor in the Baltic Sea sedimentation, Lithuania Academy of Science, Series Biochemistry, Geology and Paleogeography of the Baltic Sea, 3-4, 327 pp (in Russian).
• [39]. Railard O., Menesguen A. 1994, An ecosystem model for estimation the carrying capacity of macrotidal shellfish system, Mar. Ecol. Prog. Ser., 115, 117-130.
• [40]. Riisgard H.U. 2001, On measurements offiltration rates in bivalves - the stony road to reliable data: review and interpretation, Mar. Ecol. Prog. Ser., 211, 275-291
• [41]. Riisgard H.U., Randflow A. 1981, Energy budgets, growth and filtration rates in Mytilus edulis at digerent algal concentrations, Mar. Biol., 61, 227-234.
• [42]. Riisgard H.U., Randflow A., Kristensen P.S. 1980, Rates of water processing, oxygen consumption and efficiency of particie retention in veligers and youngpost-methamorphic Mytilus edulis, Ophelia, 19(1), 37-47.
• [43]. Ross A.H., Nisbet R.M. 1990, Dynamie models of growth and reproduction of t/w mussel Mytilus edulis L., Funct. Ecol., 4, 777-787.
• [44]. Rumohr H., Brey T., Ankar S. 1997, A compilation of biometrie conversion factors for benthic ivertebrates of the Baltic Sea, The Baltic marine biologist publication, 9, 56 pp.
• [45]. Seed R. 1992, Systematics, evolution and distribution of mussels belonging to the genus Mytilus: an overview, Amer. Malacol. Bull., 9, 123-137.
• [46]. Scholten H., Van der Tol M.W.M. 1994, SMOES: a simulation model for the Oosterschelde ecosystem. Part II: calibration and validation, Hydrobiologia, 282/283, 453-474.
• [47]. Scholten H., Smaal A.C. 1998, Responses of Mytilus edulis L to varying food concentrations: testing EMMY, an ecophysiological model, J. exp. mar. Biol. Ecol., 219, 217-239.
• [48]. Scholten H., Smaal A.C. 1999, The ecophysiological response of mussels (Mytilus edulis) in mesocosms to a range of inorganic nutrient loads: simulation with the model EMMY, Aquat. Ecol., 33, 83-100.
• [49]. Smaal A.C. 1997, Food supply and demand of bivalve suspension feeders in a tidal system, Ph.D. thesis, Groningen University.
• [50]. Smaal A.C., Scholten E.H. 1999, The ecophysiological response of mussels (Mytilus edulis) in mesocosms to a range of organic nutrient loads: simulations with model EMMY, Aquat. Ecol., 33, 83-100.
• [51]. Smaal A.C., Vonck A.P.M.A., Bakker A. 1997, Seasonal variation in physiological energetics of Mytilus edulis and Cerastoderma edule of different size classes, J. mar. biol. Ass. U.K., 77, 817-838.
• [52]. Stuart V., Klumpp D.W. 1984, Evidence for food-resource partitioning by kelp-bed filter feeders, Mar. Ecol. Prog. Ser., 16, 27-37.
• [53]. Ulanowich R.E., Tuttle J.H. 1992, The trophic consequences of oyster stock rehabilitation in Cheasapeake Bay, Estuaries 15: 298-306.
• [54]. Van der Tol M.W.M., Scholten H. 1998, A model analysis on the effect of decreasing nutrient loads on the biomass of benthic suspension feeders in Oosterschelde ecosystem (SW Netherlands), Aquat. Ecol., 31, 395-408.
• [55]. Tsuchiya M. 1980, Biodeposit production by the mussel Mytilus edulis L. on rocky shores, J. exp. mar. Biol. Ecol., 47, 203-222.
• [56]. Vahl O. 1972, Efficiency ofparticle retention in Mytilus edulis L., Ophelia, 10, 17-25.
• [57]. Ward J.E., Levinton J.S., Shumway S.E., Cucci T. 1998, Particie sorting in bivalves: in vivo determination of pallial organs of selection, Mar. Biol., 131, 283-292.
• [58]. Warzocha J., Gostkowska J. 1996, Macrofauna communities in the Gdansk basin: spatial and temporal variability, Proceedings of the 13th Symposium of the Baltic Marine Biologists, 141-146.
• [59]. Wiktor K. 1990, The role of common mussel Mytilus edulis L. in the biocenosis of the Gulf of Gdansk, Limnologica, 20(1), 187-190.
• [60]. Willows R.I. 1992, Optimal digestive investment: a model for filter feeders experiencing variable diets, Limnol. Oceanogr., 37, 829-847.
• [61]. Zemlys P., Daunys D., Razinkovas A. in print, Revision pre-ingestive selection efficiency definition for suspension feeding bivalves: facilitating the materialfluxes modelling, Ecol. Mod.