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根据2004年5月和2007年5月长江口近海渔业资源调查数据,应用双向指示种分析(TWINSPAN)和典范对应分析(CCA)方法,分析了春季长江口鱼类群落特征,探讨了春季长江口鱼类群聚结构及其与环境因子的关系。结果表明,2个春季航次共捕获鱼类生物9目25科36种,其中带鱼(Trichiurus lepturus)、黄鲫(Setipinna taty)、鳀(Engraulis japonicas)、竹荚鱼(Trachurus japonicas)、小黄鱼(Larimichthys polyactis)和鲐(Scomber japonicas)为优势种。2004和2007年长江口近海鱼类存在4个生物群聚:以鲐为特征种的南部高温型、以带鱼为优势种的南部低温型、以竹荚鱼为代表的北部高温型和以黄鲫占绝对优势的北部低温型。影响2004和2007年长江口海域鱼类分布的主要环境因子为水深、底层总磷、表层悬浮体含量、底层盐度和表层温度。其中,水深、盐度和悬浮体含量驱动鱼类群聚空间变异,温度驱动了时间变异。与1999—2001年相比较,2004和2007年长江口鱼类群落发生显著变异,鱼类资源种类数量和生物量减少,优势种亦发生演替;水深、盐度、温度变异对鱼类群聚分布保持影响力,水域悬浮体含量成为鱼类群聚空间变异的重要驱动因素。
Abstract:Characteristics of fish assemblage structure were described according to data collected in the spring cruises of 2004and 2007in the adjacent sea of Changjiang Estuary,with the relationship between such a structure and the environmental factors determined with two-way indicator species(TWINSPAN) and canonical correspondence analysis(CCA).The fish captured in 2cruises were assigned to 36species belonging to 25families,9orders,of which Trichiurus lepturus,Setipinna taty,Engraulis japonicas,Trachurus japonicas,Larimichthys polyactis and Scomber japonicas dominantly inhabited the area.These fish species could be classified into south high-temp assemblage that was represented by Scomber japonicas;south low-temp assemblage that was dominated by Trichiurus lepturus;north high-temp assemblage that was featured by Trachurus japonicas and north low-temp assemblage that was predominated by Setipinna taty.Water depth,bottom total phosphorus,surface total suspended material(TSM),bottom salinity and surface temperature were major factors influencing the formation of fish assemblages in the area.Of these factors,depth,salinity and TSM drove the spatial variation of fish assemblage structure,and temperature impacted their temporal variation.Comparing to the described according to data collected during 1999—2001,fish community varied significantly in 2004and 2007;species and biomass decreased,the dominant species changed,and fish community succession was undergoing.
[1]庄平.长江口鱼类[M].上海:上海科学技术出版社,2006:1-2.
[2]罗秉征,沈焕庭.三峡工程与河口生态环境[M].北京:科学出版社,1994:31-33.
[3]Zhang J,Liu S M,Ren,J L,et al.Nutrient gradients from the eutrophic Changjiang(Yangtze River)Estuary to the oligotrophic Kuroshio waters and re-evaluation of budgets for the East China Sea Shelf[J].Progress in Oceanography,2007,74(4):449-478.
[4]McCarthy J J.Climate change 2001:impacts,adaptation,and vulnerability:contribution of Working Group II to the third assessment report of the Intergovernmental Panel on Climate Change[M].Britain:Cambridge Univ Pr,2001:1-10.
[5]Cardoso P G,Raffaelli D,Lillebo A I.The impact of extreme flooding events and anthropogenic stressors on the macrobenthic communities’dynamics[J].Estuarine Coastal and Shelf Science,2008,76(3):553-565.
[6]Martino E J,Able K W.Fish assemblages across the marine to low salinity transition zone of a temperate estuary[J].Estuarine Coastal and Shelf Science,2003,56(5-6):969-987.
[7]Menge B A,Olson A M.Role of scale and environmental factors in regulation of community structure[J].Trends in Ecology&Evolution,1990,5(2):52-57.
[8]Pessanha A L M,Araujo F G.Spatial,temporal and diel variations of fish assemblages at two sandy beaches in the Sepetiba Bay,Rio de Janeiro,Brazil[J].Estuarine,Coastal and Shelf Science,2003,57(5-6):817-828.
[9]Hajisamae S,Yeesin P.Pattens in community structure of trawl catches along coastal area of the SOUTH CHINA SEA[J].Raffles Bulletin of Zoology,2010,58(2):357-368.
[10]Vilar C C,Spach H L,Joyeux J C.Spatial and temporal changes in the fish assemblage of a subtropical estuary in Brazil:environmental effects[J].Journal of the Marine Biological Association of the United Kingdom,2011,91(3):635-648.
[11]Chagas L,Joyeux J,Fonseca F R.Small-scale spatial changes in estuarine fish:subtidal assemblages in tropical Brazil[J].J Mar Biol Ass UK,2006,86:861-875.
[12]Azevedo M C C,Araújo F G,Cruz-Filho A G.Demersal fishes in a tropical bay in southeastern Brazil:Partitioning the spatial,temporal and environmental components of ecological variation[J].Estuarine,Coastal and Shelf Science,2007,75(4):468-480.
[13]Whitfield A K.Ichthyofaunal assemblages in estuaries:A South African case study[J].Reviews in Fish Biology and Fisheries,1999,9(2):151-186.
[14]Pomfret J R,Elliott M,O’Reilly M G,et al.Spatial and temporal patterns in the fish communities in two UK North Sea estuaries[M]//Elliott M,Ducrotoy J P.Estuaries and Coasts:Spatial and Temporal Intercomparisons.Denmark:Olsen and Olsen Fredensborg,1991:277-284.
[15]Yoklavich M M,Cailliet G M,Barry J P,et al.Temporal and spatial patterns in abundance and diversity of fish assemblages in Elkhorn Slough,California[J].Estuaries and Coasts,1991,14(4):465-480.
[16]Yu H C,Xian W W.The environment effect on fish assemblage structure in waters adjacent to the Changjiang(Yangtze)River estuary(1998—2001)[J].Chinese Journal of Oceanology and Limnology,2009,27(3):443-456.
[17]李建生,李圣法,程家骅.长江口近海鱼类多样性的年际变化[J].中国水产科学,2007,14(4):637-643.
[18]于海成.长江口及邻近海域鱼类群落结构分析[D].青岛:中科院海洋研究所,2008.
[19]中华人民共和国国家质量监督检验检疫总局.GB/T12763.1~9—2007,海洋调查规范[S].北京:中国标准出版社,2008.
[20]张金屯.数量生态学[M].北京:科学出版社,2004.
[21]Chu C,Jones N E.Spatial variability of thermal regimes and other environmental determinants of stream fish communities in the Great Lake Basin,Ontario,Canada[J].River Research and Applications,2011,27(5):646-662.
[22]翟世奎,张怀静.长江口及其邻近海域悬浮物浓度和浊度的对应关系[J].环境科学学报,2005,25(5):693-699.
[23]Akin S,Buhan E.Fish assemblage structure of Koycegiz LagoonEstuary,Turkey:Spatial and temporal distribution patterns in relation to environmental variation[J].Estuarine,Coastal and Shelf Science,2005,64(4):671-684.
[24]沈国英,施并章.海洋生态学[M].北京:科学出版社,2002.
[25]翟世奎,孟伟,于志刚.三峡工程一期蓄水后的长江口海域环境[M].北京:科学出版社,2008.
[26]沈焕庭.长江河口物质通量[M].北京:海洋出版社,2001.
[27]田明诚,沈友石.长江口及临近海区鱼类区系研究[J].海洋科学,1992,33:265-280.
[28]Taylor R H.The St.Lucia Estuary:The aquatic environment:physical and chemical characteristics[C]//Taylor R H,St.Lucia Research Review.Proceedings of the Natal Parks 1982Symposium.Pietermaritzburg,South Africa:Game and Fish Preservation Board,1982:42-56.
[29]Kimmerer W J.Physical,Biological,and Management Responses to Variable Freshwater Flow into the San Francisco Estuary[J].Estuaries,2002,25(6B):1275-1290.
[30]Drinkwater K F,Frank K T.Effects of river regulation and diversion on marine?sh and invertebrates[J].Aquatic Conservation:Freshwater and Marine Ecosystems,1994,4:135-151.
[31]Grange N,Allanson B R.The influence of freshwater in?ow on the nature,amount and distribution of seston in estuaries of the Eastern Cape,South Africa[J].Estuarine,Coastal and Shelf Science,1995,40:403-420.
[32]丛宁,张振克,夏非.人类活动与全球变暖影响下长江口海岸地貌动态与灾害趋势研究[J].河南科学,2010,28(5):605-611.
基本信息:
DOI:10.16441/j.cnki.hdxb.2013.09.010
中图分类号:S932.4
引用信息:
[1]张迎秋,线薇微,李文龙.2004和2007年春季长江口近海鱼类群落特征及其与环境因子的关系[J],2013,43(09):67-74.DOI:10.16441/j.cnki.hdxb.2013.09.010.
基金信息:
国家自然科学基金项目(41176138;31272663);; 中国科学院知识创新工程重大项目(KZCX1-YW-08-01)资助