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Copepod community structure over a marine outfall area in the north-eastern South China Sea

Published online by Cambridge University Press:  24 June 2008

Li-Chun Tseng ,
Ram Kumar ,
Hans-Uwe Dahms ,
Chun-Te Chen ,
Sami Souissi ,
Qing-Chao Chen  and
Jiang-Shiou Hwang
Li-Chun Tseng
Affiliation:
Institute of Marine Biology, National Taiwan Ocean University, Keelung, Taiwan, ROC
Ram Kumar
Affiliation:
Institute of Marine Biology, National Taiwan Ocean University, Keelung, Taiwan, ROC
Hans-Uwe Dahms
Affiliation:
Institute of Marine Biology, National Taiwan Ocean University, Keelung, Taiwan, ROC
Chun-Te Chen
Affiliation:
Department of Tourism and Leisure Management, Tung Fang Institute of Technology, Kaohsiang County, Taiwan, ROC
Sami Souissi
Affiliation:
Université des Sciences et Technologies de Lille-Lille 1, Laboratoire d'Océanologie et de Géosciences —UMR LOG 8187—Station Marine—28
Qing-Chao Chen
Affiliation:
South China Sea Institute of Oceanography, Academia Sinica, Guangzhou, China
Jiang-Shiou Hwang*
Affiliation:
Institute of Marine Biology, National Taiwan Ocean University, Keelung, Taiwan, ROC
*
Correspondence should be addressed to: Jiang-Shiou Hwang Institute of Marine BiologyNational Taiwan Ocean University, Keelung Taiwan, ROC email: [email protected]
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Abstract

This study focuses on the dynamics of copepod abundances and species composition in the upper water column of a marine outfall area Tso-Ying (T-Y) in the boundary waters of the north-eastern South China Sea and the Taiwan Strait as an example. Zooplankton samples were collected in March, June and September 2002. Mean copepod abundance at all stations ranged from a minimum of 9.4 (individuals m−3) in March to a maximum of 1685 (individuals m−3) in June. A total of 66 copepod species belonging to 31 genera and 19 families were identified during three cruises. Copepod assemblages were dominated by Temora turbinata which occurred in >97% samples with a relative abundance of 75.46% combining all three sampling cruises. The ordination diagram derived from non-metric multidimensional scaling separated samples on the basis of season and revealed that different sampling stations clustered differently during each cruise. The second and third most dominant species were Acrocalanus gracilis and Acrocalanus gibber, representing 1.73% and 1.65% of the total copepod abundance respectively. The outfall area studied here correlates with lower copepod densities represented by a few species that show a higher relative abundance in comparison with non-affected areas. We provide here the first example where plankton assemblages indicate useful information about environmental changes in the course of sewage disposal at a stable outlet site.

Keywords

zooplanktonunderwater outfall systemsewage abatementTaiwan Strait
Type
Research Article
Information
Journal of the Marine Biological Association of the United Kingdom , Volume 88 , Issue 5 , August 2008 , pp. 955 - 966
Copyright
Copyright © Marine Biological Association of the United Kingdom 2008

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References

REFERENCES

APHA (American Public Health Association, American Water Works Association and Water Pollution Control Federation) (1995) Standard methods for the examination of water and waste water. 19th edition. Washington, DC: APHA.Google Scholar
Arashkevich, E., Wassmann, P., Pasternak, A. and Riser, C.W. (2002) Seasonal and spatial changes in biomass, structure, and development progress of the zooplankton community in the Barents Sea. Journal of Marine Systems 38, 125145.Google Scholar
Barbara, L.S. and Nancy, N.M. (2002) The effects of Orimulsion and Fuel Oil #6 on the hatching success of copepod resting eggs in the seabed of Tampa Bay, Florida. Environmental Pollution 120, 787795.Google Scholar
Barka, S., Pavillon, J.F. and Amiard, J.C. (2001) Influence of different essential and non-essential metals on MTLP levels in the copepod Tigriopus brevicornis. Comparative Biochemistry and Physiology Part C 128, 479493.Google Scholar
Bianchi, F., Acri, F., Bernardi, A., Berton, A., Boldrin, A., Camatti, E., Cassin, D. and Comaschi, A. (2003) Can plankton communities be considered as bioindicators of water quality in the lagoon of Venice? Marine Pollution Bulletin 46, 964971.CrossRefGoogle ScholarPubMed
Bligh, E.G. and Dyer, W.J. (1959) A rapid method of total lipid extraction and purification. Canadian Journal of Biochemical Physiology 37, 911917.Google Scholar
Bothner, M.H., Casso, M.A., Rendigs, R.R. and Lamothe, P.J. (2002) The effect of the new Massachusetts Bay sewage outfall on concentrations of metals and bacterial spores in nearby bottom and suspended sediments. Marine Pollution Bulletin 44, 10631070.Google Scholar
Box, G.E.P. and Cox, D.R. (1964) An analysis of transformations (with discussion). Journal of the Royal Statistical Society, Series B 26, 211246.Google Scholar
Chang, W.B. and Fang, L.S. (2004) Temporal and spatial variation in the species composition, distribution and abundance of copepods in Kaohsiung Harbor, Taiwan. Zoological Studies 43, 454463.Google Scholar
Chen, C.C., Shiah, F.K., Chung, S.W. and Liu, K.K. (2006) Winter phytoplankton blooms in the shallow mixed layer of the South China Sea enhanced by upwelling. Journal of Marine Systems 59, 97110.CrossRefGoogle Scholar
Chen, Q.C. (1992) Zooplankton of China Seas (1). Beijing: Science Press.Google Scholar
Chen, Q.C., Huang, L.M., Yin, J.Q. and Zhang, G.X. (1996) Characteristics of zooplanktonic biodiversities in the waters around Nansha Islands in autumn 1994. In Tseng, E.S. (ed.) Studies on marine biodiversity of the Nansha Islands and neighboring water. Volume II. Beijing: Ocean Press, pp. 3843. [In Chinese.]Google Scholar
Chen, Q.C. and Zhang, S.Z. (1965) The planktonic copepods of the Yellow Sea and the East China Sea. I. Calanoida. Studia Marina Sinica 7, 20131. [In Chinese, with English summary.]Google Scholar
Chen, Q.C., Zhang, S.Z. and Zhu, C.S. (1974) On planktonic copepods of the Yellow Sea and the East China Sea. II. Cyclopoida and Harpacticoida. Studia Marina Sinica 9, 2776. [In Chinese, with English summary.]Google Scholar
Chen, Q.C., Zhang, G.X., Yin, J.O., Chen, X.M., Li, A.S. and Zou, Z.Y. (1991) The distribution of zooplankton from eastern and southern waters of the Nansha Islands in summer months 1998. In Chen, Q.C. (ed.) Contributions on marine biological research of the Nansha Islands. Volume II. Beijing: Ocean Press, pp. 186193. [In Chinese.]Google Scholar
Chihara, M. and Murano, M. (1997) An illustrated guide to marine plankton in Japan. Tokyo, Japan: Tokyo University Press.Google Scholar
Clarke, K.R. and Gorley, R.N. (1997) Primer user mannual. Bournemouth, UK: Bourne Press Limited.Google Scholar
Cornils, A., Schnack-Schiel, S.B., Hagen, W., Dowidar, M., Stambler, N. and Plahn, O.Richter, C. (2005) Spatial and temporal distribution of mesozooplankon in the Gulf of Aquaba and the northern Red Sea in February/March 1999. Journal of Plankton Research 27, 505518.Google Scholar
Dufrêne, M. and Legendre, P. (1997) Species assemblages and indicator species: the need for a flexible asymmetrical approach. Ecological Monographs 67, 345366.Google Scholar
Dur, G., Hwang, J.S., Souissi, S., Tseng, L.C., Wu, C.H., Hsiao, S.H. and Chen, Q.C. (2007) An overview of the influence of hydrodynamics on the spatial and temporal patterns of calanoid copepod communities around Taiwan. Journal of Plankton Research 29, i97i116.Google Scholar
Emery, A.R. (1968) Preliminary observations on coral reef plankton. Limnology and Oceanography 13, 293303.Google Scholar
EPA (1996) Environmental Protection Administration. River water sampling methods and water quality examining technical handbook. Republic of China: Industrial Development Bureau Executive Yuen.Google Scholar
Fang, T.H., Hwang, J.S., Hsiao, S.H. and Chen, H.Y. (2006) Trace metals in seawater and copepods in the ocean outfall area off the northern Taiwan coast. Marine Environmental Research 61, 224243.Google Scholar
Gonzalez, H., Pomares, M., Ramirez, M. and Torres, I. (1999) Heavy metals in organisms and sediments from the discharge zone of the submarine sewage outfall of Havana city, Cuba. Marine Pollution Bulletin 38, 10481051.Google Scholar
Gray, J.S., Ashcan, M., Carr, M.R., Clarke, K.R., Paterson, T.H., Rosenberg, R. and Warwick, R.M. (1988) Analysis of community attributes of the benthic macrofauna of Frierfjord/Langesundfjord and in a mesocosm experiment. Marine Ecology Progress Series 46, 151165.Google Scholar
Hamner, W.M. and Carleton, J.H. (1979) Copepod swarms: attributes and role in coral reef ecosystems. Limnology and Oceanography 24, 114.Google Scholar
Hook, S.E. and Fisher, N. (2001a) Reproductive toxicity of metals in calanoid copepods. Marine Biology 138, 11411152.Google Scholar
Hook, S.E. and Fisher, N. (2001b) Sublethal toxicity of silver in zooplankton: importance of exposure pathways and implications for toxicity testing. Environmental Toxicology and Chemistry 20, 568574.Google Scholar
Hook, S.E. and Fisher, N. (2002) Relating the reproductive toxicity of five ingested metals in calanoid copepods with sulfur affinity. Marine Environmental Research 51, 161174.Google Scholar
Hsieh, C.H. and Chiu, T.S. (1997) Copepod abundance and species composition of the Tanshui River estuary and adjacent waters. Acta Zoologica Taiwanica 8, 7583.Google Scholar
Hsieh, C.H., Chiu, T.S. and Shih, C.T. (2004) Copepod diversity and composition as indicators of intrusions of the Kuroshio Branch Current into the northern Taiwan Strait in Spring 2000. Zoological Studies 43, 393403.Google Scholar
Hung, T.C. (1986) Monitoring and assessment of the quality of coastal environment. Journal of Environment Protection Society 9, 6080.Google Scholar
Huys, R. and Boxshall, G. (1991) Copepod evolution. London: The Ray Society.Google Scholar
Hwang, J.S. and Wong, C.K. (2005) The China Coastal Current as a driving force for transporting Calanus sinicus (Copepoda: Calanoida) from its population centers to waters of Taiwan and Hong Kong during the winter northeast monsoon period. Journal of Plankton Research 27, 205210.Google Scholar
Hwang, J.S., Chen, Q.C. and Wong, C.K. (1998) Taxonomic composition and grazing rate of Calanoid copepods in coastal waters of northern Taiwan. Crustaceana 71, 378389.Google Scholar
Hwang, J.-S., Souissi, S., Tseng, L.-C., Seuront, L., Schmitt, F.G., Fang, L.-S., Peng, S.-H., Wu, C.-H., Hsiao, S.-H., Twan, W.-H., Wei, T.-P., Kumar, R., Fang, T.-H., Chen, Q.-C. and Wong, C.K. (2006) A 5-year study of the influence of the northeast and southwest monsoons on copepod assemblages in the boundary coastal waters between the East China Sea and the Taiwan Strait. Journal of Plankton Research 28, 943958.Google Scholar
Hwang, J.-S., Tu, Y.-Y., Tseng, L.C., Fang, L.-S., Souissi, S., Fang, T.-H., Lo, W.-T., Twan, W.-H., Hsaio, S.-H., Wu, C.-H., Peng, S.-H., Wei, T.-P. and Chen, Q.-C. (2004) Taxonomic composition and seasonal distribution of copepod assemblages from waters adjacent to nuclear power plant I and II in Northern Taiwan. Journal of Marine Science and Technology 12, 380391.Google Scholar
Hwung, H.H., Wen, CG., Chen, Y.F., Fu, S.I., Wen, J.T. and Hwung, W.T. (1990) Field surveys and environmental assessments on Chung-Chou, Da-Lin-Pu and Tso-Ying ocean outfalls. Tainan Hydraulics Laboratory, National Chung Kung University, Tainan, Taiwan, Bulletin No. 121.Google Scholar
Industrial Development Bureau, Ministry of Economic Affairs (2002) Field surveys and environmental assessments on Tso-Ying ocean outfalls. Taipei, Taiwan: Industrial Development Bureau Press, pp. 447.Google Scholar
Kahle, J. and Zauke, G.P. (2003) Trace metals in Antarctic copepods from the Weddell Sea (Antarctica). Chemosphere 51, 409417.CrossRefGoogle ScholarPubMed
Koop, K. and Hutchings, P. (1996) Disposal of sewage to the ocean—a sustainable solution? Marine Pollution Bulletin 33, 712.Google Scholar
Lee, C.L. and Fang, M.D. (1997) Sources and distribution of chlorobenzenes and hexachlorobutadiene in surficial sediments along the coast of southwestern Taiwan. Chemosphere 35, 20392050.Google Scholar
Lee, C.L., Fang, M.D. and Hsieh, M.T. (1998) Characterization and distribution of metals in surficial sediments in southwestern Taiwan. Marine Pollution Bulletin 36, 464471.Google Scholar
Lee, C.L., Song, H.J. and Fang, M.D. (2000) Concentrations of chlorobenzenes, hexachlorobutadiene and heavy metals in surficial sediments of Kaohsiung coast, Taiwan. Chemosphere 41, 889899.Google Scholar
Liang, W.D., Tang, T.Y., Yang, Y.J., Ko, M.T. and Chuang, W.S. (2003) Upper-ocean currents around Taiwan. Deep-Sea Research II 50, 10851105.Google Scholar
Liu, A.K., Chang, Y.S., Hsu, M.K. and Liang, N.K. (1998) Evolution of nonlinear internal waves in the east and South China Sea. Journal of Geophysical Research 103, 79958008.Google Scholar
Lo, W.T. and Hwang, J.S. (2000) The diel vertical distribution of zooplankton in the northeastern South China Sea. National Taiwan Museum Special Publication Series 10, 5973.Google Scholar
Lo, W.T., Chung, C.L. and Shih, C.T. (2004a) Seasonal distribution of copepods in Tapong Bay, southwestern Taiwan. Zoological Studies 43, 464474.Google Scholar
Lo, W.T., Hwang, J.S. and Chen, Q.C. (2004b) Spatial distributions of copepods in surface waters of the southeastern Taiwan Strait. Zoological Studies 43, 218228.Google Scholar
Lo, W.T., Shih, C.T. and Hwang, J.S. (2004c) Diel vertical migration of the planktonic copepods at an upwelling station north of Taiwan, western North Pacific. Journal of Plankton Research 26, 8997.Google Scholar
Mackas, D.L. (1992) Seasonal cycle of zooplankton off southwestern British Columbia: 1979–89. Canadian Journal of Fisheries and Aquatic Sciences 49, 903921.Google Scholar
Michaels, A.F. and Knapp, A.H. (1996) Overview of the U.S. JGOFS Bermuda Atlantic Time-series Study and the Hydrostation S program. Deep-Sea Research II 43, 157198.Google Scholar
Naes, K. and Oug, E. (1997) Multivariate approach to distribution patterns and fate of polycyclic aromatic hydrocarbons in sediments from smelter-affected Norwegian fjords and coastal waters. Environmental Science and Technology 31, 12531258.Google Scholar
Novitsky, J.A. and Karl, D.M. (1985) Influence of deep ocean sewage outfalls on the microbial activity of the surrounding sediment. Applied and Environmental Microbiology 50, 14641473.Google Scholar
Paffenhöfer, G.A. and Flagg, C.N. (2002) Interannual variability of metazooplankton biomass in ocean margin: late winter vs. summer. Deep-Sea Research II 49, 45334552.Google Scholar
Pai, S.C. and Yang, C.C. (1990a) Effects of acidity and molybdate concentration on the kinetics of the formation of the phosphoantimonmolybdenum blue complex. Analytica Chimica Acta 229, 115120.Google Scholar
Pai, S.C. and Yang, C.C. (1990b) Formation kinetics of the pink azo dye in the determination of nitrite in natural waters. Analytica Chimica Acta 232, 345349.Google Scholar
Peterson, W. and Keister, J.E. (2003) Interannual variability in copepod community composition at a coastal station in the northern California Current: a multivariate approach. Deep-Sea Research II 50, 24992517.Google Scholar
Ritterhoff, J. and Zauke, G.P. (1997) Trace metals in field samples of zooplankton from the Fram Strait and the Greenland Sea. The Science of the Total Environment 199, 255270.Google Scholar
Servais, P., Garnier, J., Demarteau, N., Brion, N. and Billen, G. (1999) Supply of organic matter and bacteria to aquatic ecosystems through waste water effluents. Water Research 33, 35213531.CrossRefGoogle Scholar
Shaw, P.T., Chao, S.Y., Liu, K.K., Pai, S.C. and Liu, C.T. (1996) Winter upwelling off Luzon in the northeastern South China Sea. Journal of Geophysical Research 101, 1643516448.Google Scholar
Shih, C.T. and Young, S.S. (1995) A checklist of free-living copepods, including those associated with invertebrates, reported from the adjacent seas of Taiwan. Acta Zoologica Taiwanica 6, 6581.Google Scholar
Shih, C.T. and Chiu, T.S. (1998) Copepod diversity in the water masses of the southern East China Sea north of Taiwan. Journal of Marine Systems 15, 533542.CrossRefGoogle Scholar
Shih, C.T., Hwang, J.S. and Huang, W.B. (2000) Planktonic copepods from an upwelling station north of Taiwan, Western North Pacific. Journal of Taiwan Museum 10, 1935.Google Scholar
Trante, D.J. and George, J. (1972) Zooplankton abundance at Kavaratti and Kalpeni atolls in the Laccadives. In Mukandan, C. and Pillai, C.S.G. (eds) Proceedings of the Symposium on Corals and Coral Reefs, 1969. Journal of the Marine Biological Association of India. Cochin, India: Marine Biological Association of India Press, pp. 239256.Google Scholar
Tseng, L.-C., Kumar, R., Dahms, H.-U., Chen, Q.C. and Hwang, J.-S. (in press) Monsoon-driven succession of copepod assemblages in coastal waters of the northeastern Taiwan Strait. Zoological Studies.Google Scholar
Turner, J.T. (1994) Planktonic copepods of Boston Harbor, Massachusetts Bay and Cape Cod Bay. Hydrobiologia 292/293, 405413.Google Scholar
Wang, S.B., Cheng, H.Y., Wu, C.K., Hsu, C.H., Wang, W.H. and Li, Y.H. (1990) Monitor and survey of the marine environment of Da-Lin-Pu and Tso-Ying marine outfall fields in Kaoshiung. (3rd report). Republic of China: Bureau of Industry, Department of Economic Executive Yuen.Google Scholar
Wang, W.X. and Fisher, N.S. (1998) Accumulation of trace elements in marine copepods. Limnology and Oceanography 43, 273283.CrossRefGoogle Scholar
Waniek, J.J. (2003) The role of physical forcing in the initiation of spring blooms in the northeast Atlantic. Journal of Marine Systems 39, 5782.Google Scholar
Wong, C.K., Hwang, J.S. and Chen, Q.C. (1998) Taxonomic composition and grazing impact of calanoid copepods in coastal waters near nuclear power plants in northern Taiwan. Zoological Studies 37, 330333.Google Scholar
Yang, L. (1995) Review of marine outfall systems in Taiwan. Water Science and Technology 32, 257264.Google Scholar
Yang, L., Chang, W.S. and Lo Huang, M.N. (2000) Natural disinfection of wastewater in marine outfall fields. Water Research 34, 743750.Google Scholar