Fate of 15N-enriched cyanobacteria feed for planktivorous fish in an enclosure experiment: a stable isotope tracer study

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• 作者：Yinping Wang ; Xiaohong Gu ; Qingfei Zeng ; Zhigang Mao ; Xiankun Gu…
• 关键词：Stable isotope ; Feces nitrogen ; Microcystis detritus ; Planktivorous fish
• 刊名：Fisheries Science
• 出版年：2015
• 出版时间：September 2015
• 年：2015
• 卷：81
• 期：5
• 页码：821-830
• 全文大小：723 KB
• 参考文献：1.Neil JMO, Davis TW, Burford MA, Gobler CJ (2012) The rise of harmful cyanobacteria blooms: the potential roles of eutrophication and climate change. Harmful Algae 14:313鈥?34CrossRef
  2.Slim K, Fadel A, Atoui A, Lemaire BJ, Leite BV, Tassin B (2014) Global warming as a driving factor for cyanobacterial blooms in Lake Karaoun, Lebanon. Desalin Water Treat 52:2094鈥?101CrossRef
  3.Paerl HW, Xu H, McCarthy MJ, Zhu GW, Qin BQ, Li YP, Gardner WS (2011) Controlling harmful cyanobacterial blooms in a hyper-eutrophic lake (Lake Taihu, China): the need for a dual nutrient (N & P) management strategy. Water Res 45:1973鈥?983CrossRef PubMed
  4.Paerl HW, Otten TG (2013) Harmful cyanobacterial blooms: causes, consequences, and controls. Microb Ecol 65:995鈥?010CrossRef PubMed
  5.Carey CC, Ibelings BW, Hoffmann EP, Hamilton DP, Brookes JD (2012) Eco-physiological adaptations that favour freshwater cyanobacteria in a changing climate. Water Res 46:1394鈥?407CrossRef PubMed
  6.Svir膷ev ZB, Tokodi N, Drobac D, Codd GA (2014) Cyanobacteria in aquatic ecosystems in Serbia: effects on water quality, human health and biodiversity. Syst Biodivers 12:261鈥?70CrossRef
  7.Carstensen J, Andersen JH, Gustafsson BG, Conley DJ (2014) Deoxygenation of the Baltic Sea during the last century. Proc Natl Acad Sci USA 111:5628鈥?633
  8.He H, Liu XB, Liu XL, Yu JL, Li KY, Guan BH, Jeppesen E, Liu ZW (2014) Effects of cyanobacterial blooms on submerged macrophytes alleviated by the native Chinese bivalve Hyriopsis cumingii: a mesocosm experiment study. Ecol Eng 71:363鈥?67CrossRef
  9.Turner AM, Chislock MF (2010) Blinded by the stink: nutrient enrichment impairs the perception of predation risk by freshwater snails. Ecol Appl 20:2089鈥?095CrossRef PubMed
  10.Lu KH, Jin CH, Dong SL, Gu BH, Bowen SH (2006) Feeding and control of blue-green algal blooms by tilapia (Oreochromis niloticus). Hydrobiologia 568:111鈥?20CrossRef
  11.Guo LG, Wang Q, Xie P, Tao M, Zhang J, Niu Y, Ma ZM (2014) A non-classical biomanipulation experiment in Gonghu Bay of Lake Taihu: control of Microcystis blooms using silver and bighead carp. Aquac Res 1:1鈥?
  12.Xie P (2001) Gut contents of bighead carp (Aristichthys nobilis) and the processing and digestion of algal cells in the alimentary canal. Aquaculture 195:149鈥?61CrossRef
  13.Chen SL, Liu XF, Hu CL (1990) Study on the digestion and utilization of fish feces by silver carp and bighead carp fingerlings (in Chinese). Acta Hydrobiol Sin 14:49鈥?9
  14.Burford MA, Preston NP, Glibert PM, Dennison WC (2002) Tracing the fate of 15N-enriched feed in an intensive shrimp system. Aquaculture 206:199鈥?16CrossRef
  15.Lacoste E, Gueguen Y, Moullac GL, Koua MS, Mazouni NG (2014) Influence of farmed pearl oysters and associated biofouling communities on nutrient regeneration in lagoons of French Polynesia. Aquac Environ Interact 5:209鈥?19CrossRef
  16.Burford MA, Williams KC (2001) The fate of nitrogenous waste from shrimp feeding. Aquaculture 198:79鈥?3CrossRef
  17.Zhang LY, Li KY, Liu ZW, Middelburg JJ (2010) Sedimented cyanobacterial detritus as a source of nutrient for submerged macrophytes (Vallisneria spiralis and Elodea nuttallii): an isotope labeling experiment using 15N. Limnol Oceanogr 55:1912鈥?917CrossRef
  18.Kluijver AD, Yu JL, Houtekamer M, Middelburg JJ, Liu ZW (2012) Cyanobacteria as a carbon source for zooplankton in eutrophic Lake Taihu, China, measured by 13C labeling and fatty acid biomarkers. Limnol Oceanogr 57:1245鈥?254CrossRef
  19.Yu JL, Li YM, Liu XL, Li KY, Chen FZ, Gulati R, Liu ZW (2013) The fate of cyanobacterial detritus in the food web of Lake Taihu: a mesocosm study using 13C and 15N labeling. Hydrobiologia 710:39鈥?6CrossRef
  20.Kostecki C, Le Loc鈥檋 F, Roussel JM, Desroy N, Huteau D, Riera P, LeBris H, Le Pape O (2010) Dynamics of an estuarine nursery ground: the spatio-temporal relationship between the river flow and the food web of the juvenile common sole (Solea solea, L.) as revealed by stable isotopes analysis. J Sea Res 64:54鈥?0CrossRef
  21.Lesutien臈 J, Bukaveckas PA, Gasi奴nait臈 ZR, Pilkaityt臈 R, Baziukas RA (2014) Tracing the isotopic signal of a cyanobacteria bloom through the food web of a Baltic Sea coastal lagoon. Estuar Coast Shelf Sci 138:47鈥?6CrossRef
  22.Delgado GJ, Poveda CM, Siordia DEG, Cavazos DV, Marie DR, Su谩rez LEC (2014) Application of stable isotope analysis to differentiate shrimp extracted by industrial fishing or produced through aquaculture practices. Can J Fish Aquat Sci 71:1520鈥?528CrossRef
  23.Johnston K, Robson BJ, Fairweather PG (2011) Trophic positions of omnivores are not always flexible: evidence from four species of freshwater crayfish. Austral Ecol 36:269鈥?79CrossRef
  24.Liberoff AL, Rossi CMR, Fogel ML, Ciancio JE, Pascual MA (2013) Shifts in 未15N signature following the onset of exogenous feeding in rainbow trout Oncorhynchus mykiss: importance of combining length and age data. J Fish Biol 82:1423鈥?432
  25.Patel PS, Cooper AJM, Connell TCO, Kuhnel GGC, Kneale CK, Mulligan AM, Luben RN, Brage S, Khaw KT, Wareham NJ, Forouhi NG (2014) Serum carbon and nitrogen stable isotopes as potential biomarkers of dietary intake and their relation with incident type 2 diabetes: the EPIC-Norfolk study. Am J Clin Nutr 100:708鈥?18PubMed Central CrossRef PubMed
  26.Fry B (2007) Stable isotope ecology. Springer, New York, pp 41鈥?5
  27.Tan YC, Cheng JW, Gu BH, Hong JM (2013) The sinks of dissolved inorganic nitrogen in surface water of wetland mesocosms. Ecol Eng 52:125鈥?29CrossRef
  28.Gribsholt B, Veuger B, Tramper A, Middelburg JJ, Boschker HTS (2009) Long-term 15N-nitrogen retention in tidal freshwater marsh sediment: elucidating the microbial contribution. Limnol Oceanogr 54:13鈥?2CrossRef
  29.Qin BQ, Xu PZ, Wu QL, Luo LC, Zhang YL (2007) Environmental issues of Lake Taihu, China. Hydrobiologia 581:3鈥?4
  30.Qin BQ, Hu WP, Gao G, Luo L, Zhang J (2004) The dynamics of resuspension and conceptual mode of nutrient releases from sediments in large shallow Lake Taihu, China. Chinese Sci Bull 49:54鈥?4CrossRef
  31.Nydahl F (1978) On the peroxodisulphate oxidation of total nitrogen in waters to nitrate. Water Res 12:1123鈥?130CrossRef
  32.Eaton A (1995) Measuring UV-absorbing organics-A standard method. J Am Water Works Assoc 87:86鈥?0
  33.Clesceri LS, Greenberg AE, Trussell RR (1989) Standard Methods for the Examination of Water and Wastewater. 17th edn. American Public Health Association, Washington, DC
  34.Prepas EE, Rigler FH (1982) Improvements in quantifying the phosphorus concentration in lake water. Can J Fish Aquat Sci 39:822鈥?29CrossRef
  35.Jeffrey SW, Welshmeyer NA (1997) Spectrophotometric and fluorometric equations in common use in oceanography. Phytoplankton Pigments in Oceanography, Monographs on Oceanographic Methodology, vol. 10. UNESCO Publishing, Paris, pp 597鈥?15
  36.Holmes RM, McClelland JW, Sigman DM, Fry B, Peterson BJ (1998) Measuring 15N-NH4 + in marine, estuarine and fresh waters: an adaptation of the ammonia diffusion method for samples with low ammonium concentrations. Mar Chem 60:235鈥?43CrossRef
  37.Sigman DM, Altabet MA, Michener R, McCorkle DC, Fry B, Holmes RM (1997) Natural abundance-level measurement of the nitrogen isotopic composition of oceanic nitrate: an adaptation of the ammonia diffusion method. Mar Chem 57:227鈥?42CrossRef
  38.Veuger B, Eyre BD, Maher D, Middelburg JJ (2007) Nitrogen incorporation and retention by bacteria, algae, and fauna in a subtropical intertidal sediment: an in situ 15N-labeling study. Limnol Oceanogr 52:1930鈥?942CrossRef
  39.Cai JN, Pan WB, Wang JH, Huang H, Qiu YL (2008) Impact on cyanobacteria blooms and water quality by silver carp (Hypophthalmichthys molitrix) and tilapia (Oreochromis niloticus聽脳聽O. aureus) in one eutrophic shallow pond (in Chinese). J Hydroecology 1:56鈥?1
  40.Ad谩mek Z, Stibranyiov谩 I, Siddiqui M (1996) The course of pH values in the alimentary tract of some commercial fishes. Bulletin Vyzkumneho Ustavu Rybarskeho a Hydrobiologickeho Jihoceske Univerzity, Vodnany (Czech Republic)
  41.Datta S, Jana BB (1998) Control of bloom in a tropical lake: grazing efficiency of some herbivorous fishes. J Fish Biol 53:12鈥?4CrossRef
  42.Semyalo R, Rohrlack T, Kayiira D, Kizito YS, Byarujali S, Nyakairu G, Larsson P (2011) On the diet of Nile tilapia in two eutrophic tropical lakes containing toxin producing cyanobacteria. Limnol Ecol Manag Inland Waters 41:30鈥?6CrossRef
  43.Xie P (1999) Gut contents of silver carp, Hypophthalmichthys molitrix, and the disruption of a centric diatom, Cyclotella, on passage through the esophagus and intestine. Aquaculture 180:295鈥?05
  44.Vavilin VA, Rytov SV, Lokshina LY (2014) Non-linear dynamics of nitrogen isotopic signature based on biological kinetic model of uptake and assimilation of ammonium, nitrate and urea by a marine diatom. Ecol Model 279:45鈥?3CrossRef
  45.Collos Y, Jauzein C, Ratmaya W, Souchu P, Abadie E, Vaquer A (2014) Comparing diatom and Alexandrium catenella/tamarense blooms in Thau lagoon: importance of dissolved organic nitrogen in seasonally N-limited systems. Harmful Algae 37:84鈥?1CrossRef
  46.Yang L, Zhang M, Liu Z (2011) Uptake of various forms of nitrogen by phytoplankton community in spring in Lake Taihu (in Chinese). J Lake Sci 23:605鈥?11CrossRef
  47.Habdija I, Lajtner J, Belini膰 I (1995) The contribution of gastropod biomass in macrobenthic communities of a karstic river. Int Rev Hydrobiol 80:103鈥?10CrossRef
  48.Johnson DS, Short MI (2013) Chronic nutrient enrichment increases the density and biomass of the mudsnail, Nassarius obsoletus. Estuar Coast 36:28鈥?5CrossRef
  49.Ruehl CB, Trexler JC (2013) A suite of prey traits determine predator and nutrient enrichment effects in a tri-trophic food chain. Ecosphere 4:1鈥?1CrossRef
  50.Ramskov T, Selck H, Banta G, Misra SK, Berhanu D, Jones EV, Forbes VE (2014) Bioaccumulation and effects of different-shaped copper oxide nanoparticles in the deposit-feeding snail Potamopyrgus antipodarum. Environ Toxicol Chem 33:1976鈥?987CrossRef PubMed
  51.Zukowski SH, Hill JM, Jones FW, Malone JB (1991) Development and validation of a soil-based geographic information system model of habitat of Fossaria bulimoides, a snail intermediate host of Fasciola hepatica. Prev Vet Med 11:221鈥?27CrossRef
  52.Gross A, Boyd CE, Wood CW (1999) Ammonia volatilization from freshwater fish ponds. J Environ Qual 28:793鈥?97CrossRef
  
• 作者单位：Yinping Wang (1) (2)
  Xiaohong Gu (1)
  Qingfei Zeng (1)
  Zhigang Mao (1)
  Xiankun Gu (1) (2)
  Xuguang Li (1) (2)
  
  1. State Key Laboratory of Lake Science and Environment, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences, Nanjing, 210008, People鈥檚 Republic of China
  2. University of Chinese Academy of Sciences, Beijing, 100049, People鈥檚 Republic of China
  
• 刊物主题：Fish & Wildlife Biology & Management; Freshwater & Marine Ecology; Food Science;
• 出版者：Springer Japan
• ISSN：1444-2906

文摘

A tracer experiment using isotope 15N was performed to study the assimilation and retention of nitrogen from feces by two planktivorous fish, silver carp Hypophthalmichthys molitrix and tilapia Oreochromis niloticus, in Lake Taihu (China). Microcystis was enriched with 15N-NH₄Cl, lyophilized to produce feed for fish, and traced to establish the fate of feces nitrogen. Samples of organisms and abiotic substances were analyzed for excess 15N and nutrient concentrations in the water column were determined on days 0, 1, 5, 10, 15, and 20. Nutrient concentration analyses indicated that TN and TP were about 4 times higher in the tilapia enclosure than in the silver carp enclosure due to the digestive capacity of Microcystis, which suggests that the ichthyoeutrophication potential of tilapia is greater than that of silver carp. 11.05 % of the 15N was assimilated by the tilapia whereas 3.58 % of the 15N was assimilated by the silver carp, suggesting that tilapia has a higher capacity to assimilate and retain Microcystis nitrogen than silver carp, although the absorptivities of both species were relatively low. At the end of the experiment, 8.48 % of the 15N was detected in sedimentary detritus in the tilapia enclosure, as compared to 6.07 % of the 15N in the silver carp enclosure, which suggests that only a small fraction of the Microcystis-derived nitrogen sank to the bottom. In conclusion, much of the Microcystis-derived nitrogen was neither assimilated by fish nor accumulated on the sediment floor. It presumably floated in the water column, contributing to phytoplankton propagation and thus degrading the water quality. Keywords Stable isotope Feces nitrogen Microcystis detritus Planktivorous fish