The fate of cyanobacterial detritus in the food web of Lake Taihu: a mesocosm study using 13C and 15N labeling

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• 作者：Jinlei Yu (1)
  Yanmin Li (2)
  Xiaoling Liu (2)
  Kuanyi Li (3)
  Feizhou Chen (3)
  Ramesh Gulati (4)
  Zhengwen Liu (1) (3) (5)
  
• 关键词：Microcystis ; Zooplankton ; Benthic animals ; Food source ; Labeling experiment
• 刊名：Hydrobiologia
• 出版年：2013
• 出版时间：June 2013
• 年：2013
• 卷：710
• 期：1
• 页码：39-46
• 全文大小：323KB
• 参考文献：1. Agrawal, M. K., D. Bagchi & S. N. Bagchi, 2001. Acute inhibition of protease and suppression of growth in zooplankter, / Moina macrocopa, by / Microcystis blooms collected in Central India. Hydrobiologia 464: 37鈥?4. CrossRef
  2. Berg, H. B., 1995. Larval food and feeding behaviour. In Armitage, P. D., P. S. Cranston & L. C. V. Pinder (eds), The Chironomidae: Biology and Ecology of Non-Biting Midges. Chapman & Hall, London: 136鈥?68.
  3. B枚ing, W. J., A. Wagner, H. Voigt, T. Deppe & J. Benndorf, 1998. Phytoplankton responses to grazing by / Daphnia galeata in the biomanipulated Bautzen reservoir. Hydrobiologia 389: 101鈥?14. CrossRef
  4. Chen, F. & P. Xie, 2003. The effects of fresh and decomposed / Microcystis aeruginosa on cladocerans from a subtropic Chinese lake. Journal of Freshwater Ecology 18: 97鈥?04. CrossRef
  5. Chen, Y., B. Qin, K. Teubner & M. T. Dokulil, 2003. Long-term dynamics of phytoplankton assemblages: / Microcystis-domination in Lake Taihu, a large shallow lake in China. Journal of Plankton Research 25: 445鈥?53. CrossRef
  6. Chen, W., L. Peng, N. Wan & L. Song, 2009. Mechanism study on the frequent variations of cell-bound microcystins in cyanobacterial blooms in Lake Taihu: implications for water quality monitoring and assessments. Chemosphere 77(11): 1585鈥?593. CrossRef
  7. Ch茅telat, J., L. Cloutier & M. Amyot, 2010. Carbon sources for lake webs in the Canadian High Arctic and other regions of Arctic North America. Polar Biology 33: 1111鈥?123. CrossRef
  8. Cummins, K. W. & M. J. Klug, 1979. Feeding ecology of stream invertebrates. Annual Review of Ecology and Systematics 10: 147鈥?72. CrossRef
  9. Dawidowicz, P., 1990. Effectiveness of phytoplankton control by large-bodied and small-bodied zooplankton. Hydrobiologia 200鈥?01: 43鈥?7. CrossRef
  10. Dawson, R. M., 1998. The toxicology of microcystins. Toxicon 36: 953鈥?62. CrossRef
  11. de Bernardi, R. & G. Giussani, 1990. Are blue-green algae a suitable food for zooplankton? An overview. Hydrobiologia 200鈥?01: 29鈥?1. CrossRef
  12. de Bernardi, R., G. Giussani & E. Lasso Pedretti, 1981. The significance of blue-green algae as food for filter-feeding zooplankton: experimental studies on / Daphnia spp. fed by / Microcystis aeruginosa. Verhandlungen der internationale Vereinigung fuer Theoretische und Angewandte Limnologie 21: 477鈥?83.
  13. de Kluijver, A., J. Yu, M. Houtekamer, J. J. Middelburg & Z. Liu, 2012. Cyanobacteria as carbon source for zooplankton in eutrophic Lake Taihu, China, measured by ¹³C labeling and fatty acid biomarkers. Limnology and Oceanography (in press).
  14. DeMott, W. R., 1988. Discrimination between algae and artificial particles by freshwater and marine copepods. Limnology and Oceanography 33: 397鈥?08. CrossRef
  15. DeMott, W. R., 1995. Food selection by calanoid copepods in response to between-lake variation in food abundance. Freshwater Biology 33: 171鈥?80. CrossRef
  16. DeMott, W. R. & W. C. Kerfoot, 1982. Competition among cladocerans: nature of the interaction between / Bosmina and / Daphnia. Ecology 63: 1949鈥?966. CrossRef
  17. DeMott, W. R. & F. Moxter, 1991. Foraging on cyanobacteria by copepods: responses to chemical defense and resource abundance. Ecology 72: 1820鈥?834. CrossRef
  18. DeMott, W. R., Q. X. Zhang & W. W. Carmichael, 1991. Effects of toxic cyanobacteria and purified toxins on the survival and feeding of a copepod and three species of / Daphnia. Limnology and Oceanography 36: 1346鈥?357. CrossRef
  19. Duan, H., R. Ma, X. Xu, F. Kong, S. Zhang, W. Kong, J. Hao & L. Shang, 2009. Two-decade reconstruction of algal blooms in China鈥檚 Lake Taihu. Environmental Science and Technology 43: 3522鈥?528. CrossRef
  20. Elser, J. J., 1999. The pathway to noxious cyanobacteria blooms in lakes: the food web as the final turn. Freshwater Biology 42: 537鈥?43. CrossRef
  21. Geller, W. & H. M眉ller, 1981. The filtration apparatus of Cladocera: filter mesh-sizes and their implications on food selectivity. Oecologia 49: 316鈥?21. CrossRef
  22. Gladyshev, M. I., A. Y. Emelianova, G. S. Kalachova, T. A. Zotina, N. A. Gaevsky & M. D. Zhilenkov, 2000. Gut content analysis of / Gammarus lacustris from a Siberian lake using biochemical and biophysical methods. Hydrobiologia 431: 155鈥?63. CrossRef
  23. Gophen, M. & W. Geller, 1984. Filter mesh size and food particle uptake by / Daphnia. Oecologia 64: 408鈥?12. CrossRef
  24. Grey, J., A. Kelly, S. Ward, N. Sommerwerk & R. I. Jones, 2004. Seasonal changes in the stable isotope values of lake-dwelling chironomid larvae in relation to feeding and life cycle variability. Freshwater Biology 49: 681鈥?89. CrossRef
  25. Gulati, R. D., M. Bronkhorst & E. van Donk, 2001. Feeding in / Daphnia galeata on / Oscillatoria limnetica and on detritus derived from it. Journal of Plankton Research 23: 705鈥?18. CrossRef
  26. Gullberg, K. R., W. Goedkoop & R. K. Johnson, 1997. The fate of diatom carbon within a freshwater benthic community 鈥?a microcosm study. Limnology and Oceanography 42: 452鈥?60. CrossRef
  27. Guo, N. & P. Xie, 2006. Development of tolerance against toxic / Microcystis aeruginosa in three cladocerans and the ecological implications. Environmental Pollution 143: 513鈥?18. CrossRef
  28. Gustafsson, S. & L. A. Hansson, 2004. Development of tolerance against toxic cyanobacteria in / Daphnia. Aquatic Ecology 38: 37鈥?4. CrossRef
  29. Hamill, K. D., 2001. Toxicity in a benthic freshwater cyanobacteria (blue-green algae): first observations in New Zealand. New Zealand Journal of Marine and Freshwater Research 35: 1057鈥?069. CrossRef
  30. Hanazato, T. & M. Yasuno, 1985. Population dynamics and production of cladoceran zooplankton in the highly eutrophic Lake Kasumigaura. Hydrobiologia 124: 13鈥?2. CrossRef
  31. Hanazato, T. & M. Yasuno, 1987. Evaluation of / Microcystis as food for zooplankton in a eutrophic lake. Hydrobiologia 144: 251鈥?59. CrossRef
  32. Hansson, L. A., S. Gustafsson, K. Rengefors & L. Bomark, 2007. Cyanobacterial chemical warfare affects zooplankton community composition. Freshwater Biology 52: 1290鈥?301. CrossRef
  33. Henriques-Oliveira, A. L., J. L. Nessimian & L. F. M. Dorvill茅, 2003. Feeding habits of Chironomid larvae (Insecta: Diptera) from a stream in the Floresta da Tijuca, Rio de Janeiro, Brazil. Brazilian Journal of Biology 63:269鈥?81.
  34. Infante, A. & W. Riehl, 1984. The effect of cyanophyta upon zooplankton in a eutrophic tropical lake (Lake Valencia, Venezuela). Hydrobiologia 113: 293鈥?98. CrossRef
  35. Jarvis, A. C., R. C. Hart & S. Combrink, 1987. Zooplankton feeding on size fractionated / Microcystis colonies and Chlorella in a hypertrophic lake (Hartbeespoort Dam, South Africa): implications to resource utilization and zooplankton succession. Journal of Plankton Research 9: 1231鈥?249. CrossRef
  36. Jones, R. I. & J. Grey, 2004. Stable isotope analysis of chironomid larvae from some Finnish forest lakes indicates dietary contribution from biogenic methane. Boreal Environment Research 9: 17鈥?3.
  37. Kiyashko, S. I., T. Narita & E. Wada, 2001. Contribution of methanotrophs to freshwater macroinvertebrates: evidence from stable isotope ratios. Aquatic Microbial Ecology 24: 203鈥?07. CrossRef
  38. Kurata, K., H. Minami & E. Kikuchi, 2001. Stable isotope analysis of food sources for salt marsh snails. Marine Ecology Progress Series 223: 167鈥?77. CrossRef
  39. Lampert, W., 1987. Laboratory studies on zooplankton鈥揷yanobacteria interactions. New Zealand Journal of Marine and Freshwater Research 21: 483鈥?90. CrossRef
  40. Li, K., Z. Liu, C. Li, Y. Li & M. Wen, 2008. Food sources of snail / Radix swinhoei in Lake Taihu. Journal of Lake Sciences 20: 339鈥?43 (in Chinese with English abstract).
  41. Li, K., Z. Liu & B. Gu, 2010. The fate of cyanobacterial blooms in vegetated and unvegetated sediments of a shallow eutrophic lake: a stable isotope tracer study. Water Research 44: 1591鈥?597. CrossRef
  42. Lindholm, T., J. E. Eriksson & J. A. O. Meriluoto, 1989. Toxic cyanobacteria and water quality problems 鈥?examples from a eutrophic lake on 脜land, South West Finland. Water Research 23: 481鈥?86. CrossRef
  43. Liu, Y., P. Xie & X. P. Wu, 2009. Grazing on toxic and non-toxic / Microcystis aeruginosa PCC7820 by / Unio douglasiae and / Corbicula fluminea. Limnology 10: 1鈥?. CrossRef
  44. Nandini, S. & S. S. S. Sarma, 2003. Population growth of some genera of cladocerans (Cladocera) in relation to algal food ( / Chlorella vulgaris) levels. Hydrobiologia 491: 211鈥?19. CrossRef
  45. Paerl, H. W., 1988. Nuisance phytoplankton blooms in coastal, estuarine, and inland waters. Limnology and Oceanography 33: 823鈥?47. CrossRef
  46. Piola, R. F., I. M. Suthers & D. Rissik, 2008. Carbon and nitrogen stable isotope analysis indicates freshwater shrimp / Paratya australiensis Kemp, 1917 (Atyidae) assimilate cyanobacterial accumulations. Hydrobiologia 608: 121鈥?32. CrossRef
  47. Qin, B., G. Zhu, G. Gao, Y. Zhang, W. Li, H. W. Paerl & W. W. Carmichael, 2010. A drinking water crisis in Lake Taihu, China: linkage to climatic variability and lake management. Environmental Management 45: 105鈥?12. CrossRef
  48. Raikow, D. F. & S. K. Hamilton, 2001. Bivalve diets in a midwestern U.S. stream: a stable isotope enrichment study. Limnology and Oceanography 46: 514鈥?22. CrossRef
  49. Rakshit, S. K., N. T. Loan & S. Johnsen, 1999. Fate of blue-green algae in the food web of flooded rice-field ecosystems. Biology and Fertility of Soils 29: 141鈥?45. CrossRef
  50. Reavell, P. E., 1980. A study of the diets of some British freshwater gastropods. Journal of Conchology 30: 253鈥?71.
  51. Reinikainen, M., M. Ketola & M. Walls, 1994. Effects of the concentrations of toxic / Microcystis / aeruginosa and an alternative food on the survival of / Daphnia pulex. Limnology and Oceanography 39: 424鈥?32. CrossRef
  52. Repka, S., M. van der Vlies & J. Vijverberg, 1998. Food quality of detritus derived from the filamentous cyanobacterium / Oscillatoria limnetica for / Daphnia galeata. Journal of Plankton Research 20: 2199鈥?205. CrossRef
  53. Rohrlack, T., K. Christoffersen, E. Dittmann, I. Nogueira, V. Vasconcelos & T. B枚rner, 2005. Ingestion of microcystins by / Daphnia: intestinal uptake and toxic effects. Limnology and Oceanography 50: 440鈥?48. CrossRef
  54. Sellner, K. G., D. C. Brownlee, M. H. Bundy, S. G. Brownlee & K. R. Braun, 1993. Zooplankton grazing in a Potomac river cyanobacteria bloom. Estuaries 16: 859鈥?72. CrossRef
  55. Sellner, K. G., M. M. Olson & K. Kononen, 1994. Copepod grazing in a summer cyanobacteria bloom in the Gulf of Finland. Hydrobiologia 292(293): 249鈥?54. CrossRef
  56. S酶ndergaard, M., L. Liboriussen, A. R. Pedersen & E. Jeppesen, 2008. Lake restoration by fish removal: long-term effects in 36 Danish lakes. Ecosystems 11: 1291鈥?305. CrossRef
  57. Wilson, A. E. & M. E. Hay, 2007. A direct test of cyanobacterial chemical defense: variable effects of microcystin-treated food on two / Daphnia pulicaria clones. Limnology and Oceanography 52: 1467鈥?479. CrossRef
  58. Yang, G., C. Zhong & H. Pan, 2009. Comparative studies on seasonal variations of metazooplankton in waters with different eutrophic states in Lake Taihu. Environmental Monitoring and Assessment 150: 445鈥?53. CrossRef
  59. Zhang, L., K. Li, Z. Liu & J. J. Middelburg, 2010. Sedimented cyanobacterial detritus as a source of nutrient for submerged macrophytes ( / Vallisneria spiralis and / Elodea nuttallii): an isotope labeling experiment using ¹⁵N. Limnology and Oceanography 55: 1912鈥?917. CrossRef
  60. Zheng, Y., M. Wen, K. Li & H. Wang, 2008. Effects of / Bellamya sp. on the growth of / Vallisneria atans in Lake Taihu. Research of Environmental Sciences 21: 94鈥?8 (in Chinese with English abstract).
  
• 作者单位：Jinlei Yu (1)
  Yanmin Li (2)
  Xiaoling Liu (2)
  Kuanyi Li (3)
  Feizhou Chen (3)
  Ramesh Gulati (4)
  Zhengwen Liu (1) (3) (5)
  
  1. Department of Ecology and Institute of Hydrobiology, Jinan University, Guangzhou, 510630, China
  2. Hua Zhong Agricultural University, Wuhan, 430070, China
  3. State Key Laboratory of Lake Science and Environment, Nanjing Institute of Geography & Limnology, Chinese Academy of Sciences, Nanjing, 210008, China
  4. Department of Aquatic Ecology, The Netherlands Institute of Ecology, 6708聽PB, Wageningen, The Netherlands
  5. Sino-Danish Center for Education and Research, Beijing, China
  
• ISSN：1573-5117

文摘

The ecosystem of the highly eutrophic Lake Taihu (China) is seriously affected by recurrent cyanobacterial blooms, but little is known about the contribution made by cyanobacteria to the food web. In this study, we investigated the fate of detritus of the cyanobacterium Microcystis in the food web of Lake Taihu through a 19-day mesocosm experiment using stable-isotopic tracers of carbon (13C) and nitrogen (15N). 13C- and 15N-labeled Microcystis detritus was added to the mesocosm tanks and tracked through different elements of the food web. We found clear enrichment with both 13C and 15N in some zooplankton species, including Daphnia, Diaphanosoma, and Sinocalanus, which suggests that these zooplankters can utilize cyanobacterial detritus as a food source. Benthic animals, chironomid larvae and Limnodrilus, also showed pronounced increases in 13C and 15N, but the isotope increase was relatively smaller in the gastropods, Radix sp. and Bellamya sp., implying that they either exploited this food source differently or responded slower than the zooplankton, which apparently grew faster than the snails. Our study suggests that cyanobacterial detritus, originating almost wholly from the bloom-forming Microcystis, is an important food source for both planktonic and benthic food webs in eutrophic lakes such as Lake Taihu.