Periphyton response to nitrogen and phosphorus enrichment in a eutrophic shallow aquatic ecosystem
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- 作者:Xiufeng Zhang (1) (2)
Xueying Mei (1) (3) - 关键词:periphyton ; eutrophic ; nutrients ; aquatic ecosystem
- 刊名:Chinese Journal of Oceanology and Limnology
- 出版年:2013
- 出版时间:January 2013
- 年:2013
- 卷:31
- 期:1
- 页码:59-64
- 全文大小:338KB
- 参考文献:1. Axler R P, Reuter J E. 1996. Nitrate uptake by phytoplankton and periphyton: whole-lake enrichments and mesocosm 15N experiments in an oligotrophic lake. / Limnology and Oceanography, 41(4): 659-71. CrossRef
2. APHA. 1992. Standard methods: for examination of water and wastewater, 18th ed. American Public Health Association.
3. Biggs B J F. 2000. Eutrophication of streams and rivers: dissolved nutrient-chlorophyll relationships for benthic algae. / Journal of the North American Benthological Society, 19(1): 17-1. CrossRef
4. Biggs B J F, Kilroy C. 2004. Periphyton. / In: Harding J S, Mosely M P, Pearson C, Sorrell B eds. Freshwaters of New Zealand Christchurch. Caxton Press. p.15.1-5.21.
5. Bolas P M, Lund J W G. 1974. Some factors affecting the growth of / Cladophora glomerata in the Kentish Stour. / Water Treatment and Examination, 23: 25-1.
6. Borchardt M A. 1996. Nutrients. / In: Stevenson R J, Bothwell M L, Lowe R L eds. Algal Ecology: Freshwater Benthic Ecosystems. Academic Press, San Diego. p.183-27.
7. Bowes M J, Smith J T, Hilton J, Sturt M M, Armitage P D. 2007. Periphyton biomass response to changing phosphorus concentrations in a nutrient impacted river: a new methodology for phosphorus target setting. / Canadian Journal of Fisheries and Aquatic Sciences, 64(2): 227-38. CrossRef
8. Cattaneo A. 1987. Periphyton in lakes of different trophy. / Canadian Journal of Fisheries and Aquatic Sciences, 44(2): 296-03. CrossRef
9. Dodds W K. 1995. Availability, uptake and regeneration of phosphate in mesocosms with varied levels of P-deficiency. / Hydrobiologia, 297(1): 1-. CrossRef
10. Dodds W K. 2003. The role of periphyton in phosphorus retention in shallow freshwater aquatic systems. / Journal of Phycology, 39(5): 840-49. CrossRef
11. Dodds W K, Smith V H, Lohman K. 2002. Nitrogen and phosphorus relationships to benthic algal biomass in temperate streams. / Canadian Journal of Fisheries and Aquatic Sciences, 59(5): 865-74. CrossRef
12. Ferragut C, Bicudo D de C. 2012. Effect of N and P enrichment on periphytic algal community succession in a tropical oligotrophic reservoir. / Limnology, 13: 131-41. CrossRef
13. Gaiser E E. 2009. Periphyton as an indicator of restoration in the Florida Everglades. / Ecological Indicators, 9(6): 37-5. CrossRef
14. Gaiser E E, Childers D L, Jones R D, Richards J F, Scinto L J, Trexler J C. 2006. Periphyton responses to eutrophication in the Florida Everglades: cross-system patterns of structural and compositional change. / Limnology and Oceanography, 51(1): 617-30. CrossRef
15. Galloway J N, Schlesinger W H, Levy H II, Michaels A, Schnoor J L. 1995. Nitrogen fixation: anthropogenic enhancement-environmental response. / Global Biogeochemical Cycles, 9(2): 235-52. CrossRef
16. Giorgi A D N. 1995. Response of periphyton biomass to high phosphorus concentrations in laboratory experiments. / Bulletin of Environmental Contamination and Toxicology, 55(6): 825-32. CrossRef
17. Greenwood J L, Rosemond A D. 2005. Periphyton response to long-term nutrient enrichment in a shaded headwater stream. / Canadian Journal of Fisheries and Aquatic Sciences, 62(9): 2 033- 045. CrossRef
18. Hansson L A. 1992. Factors regulating periphytic algal biomass. / Limnology and Oceanography, 37(2): 322-28. CrossRef
19. Happey-Wood V M. 1988. Ecology of freshwater planktonic green algae. / In: Sandgreen CD ed. Growth and Reproductive Strategies of Freshwater Phytoplankton. Cambridge University Press, Cambridge, p.175-26.
20. Havens K E, East T L, Rodusky A J, Sharfstein B. 1999. Littoral periphyton responses to nitrogen and phosphorus: an experimental study in a subtropical lake. / Aquatic Botany, 63(3): 267-90. CrossRef
21. Hawes I, Smith R. 1993. Effect of localized nutrient enrichment on the shallow epilithic periphyton of oligotrophic Lake Taupo, New Zealand. / New Zealand Journal of Marine and Freshwater Research, 27(3): 365-72. CrossRef
22. Hill W R. 1996. Effects of light. / In: Stevenson R J, Bothwell M L, Lowe R L eds. Algal Ecology. Academic Press, California. p.121-48. CrossRef
23. Hill W R, Ryon M G, Schilling E M. 1995. Light limitation in a stream ecosystem: responses by primary producers and consumers. / Ecology, 76(4): 1 297- 309. CrossRef
24. Hu H J, Wei Y X. 2006. The Freshwater Algae of China: Systematics, Taxonomy and Ecology. Science Press, Beijing.
25. Jespersen A M, Christoffersen K. 1987. Measurements of chlorophyll / a from phytoplankton using ethanol as extraction solvent. / Archiv für Hydrobiologie, 109: 445-54.
26. Jones J I, Moss B, Young J O. 1998. The interactions between periphyton, non-molluscan invertebrates, and fish in standing freshwaters. / I n: Jeppesen E, Sndergaard M, Sndergaard M, Christophersen K eds. The Structuring Role of Submerged Macrophytes in Lakes. Springer-Verlag, New York, USA. p.69-0. CrossRef
27. Jones J I, Sayer C D. 2003. Does the fish-invertebrate-periphyton cascade precipitate plant loss in shallow lakes / Ecology, 84(8): 2 155- 167. CrossRef
28. Jones J I, Young J O, Eaton J W, Moss B. 2002. The influence of nutrient loading, dissolved inorganic carbon and higher trophic levels on the interaction between submerged plants and periphyton. / Journal of Ecology, 90: 12-4. CrossRef
29. Jones R C, Mayer K B. 1983. Season changes in the taxonomic composition of epiphytic algal communities in Lake Wingra, Wisconsin, U.S.A. / In: Wetzel R G ed. Periphyton of Freshwater Ecosystems. Dr. W. Junk Publishers, Boston.
30. Larned S T. 2010. A prospectus for periphyton: recent and future ecological research. / Journal of the North American Benthological Society, 29(1): 182-06.
31. Le C, Zha Y, Li Y, Sun D, Lu H, Yin B. 2010. Eutrophication of lake waters in China: cost, causes, and control. / Environmental Management, 45: 662-68. CrossRef
32. Liboriussen L, Jeppesen E. 2006. Structure, biomass, production and depth distribution of periphyton on artificial substratum in shallow lakes with contrasting nutrient concentrations. / Freshwater Biol ogy, 51(1): 95-09. CrossRef
33. Luttenton M R, Lowe R L. 2006. Response of a lentic periphyton community to nutrient enrichment at low N:P ratios. / Journal of Phycology, 42(5): 1 007- 015. CrossRef
34. Marks J C, Lowe R L. 1993. Interactive effects of nutrient availability and light levels on the periphyton composition of a large oligotrophic lake. / Canadian Journal of Fisheries and Aquatic Sciences, 50(6): 1 270- 278. CrossRef
35. McCormick P V, O’Dell M B, Shuford III R B E, Backus J G, Kennedy W C. 2001. Periphyton responses to experimental phosphorus enrichment in a subtropical wetland. / Aquatic Botany, 71(2): 119-39. CrossRef
36. McCormick P V, Shuford III R B E, Backus J G, Kennedy W C. 1998. Spatial and seasonal patterns of periphyton biomass and productivity in the northern Everglades, Florida, USA. / Hydrobiologia, 362(1-3): 185-10. CrossRef
37. McCormick P V, Stevenson R J. 1998. Periphyton as a tool for ecological assessment and management in the Florida Everglades. / Journal of Phycology, 34(5): 726-33. CrossRef
38. McDougal R L, Goldsborough G L, Hann B J. 1997. Responses of a prairie wetland to press and pulse additions of inorganic nitrogen and phosphorus: production by planktonic and benthic algae. / Archiv für Hydrobiologie, 140(2): 145-67.
39. Mulholland P J, Rosemond A D. 1992. Periphyton response to longitudinal nutrient depletion in a woodland stream: evidence of upstream-downstream linkage. / Journal of the North American Benthological Society, 11(4): 405-19. CrossRef
40. Notestein S K, Frazer T K, Hoyer M V, Canfield D E. 2003. Nutrient limitation of periphyton in a Spring-Fed, coastal stream in Florida, USA. / Journal of Aquatic Plant Management, 41: 57-0.
41. Qin B Q, Song Y Z, Gao G. 2006. The role of periphyton in the shift of eutrophic lake ecosystems between turbid states dominated by phytoplankton and clear-water states dominated by macrophytes. / Science in China Ser. C, 36(3): 283-88.
42. Qin P, Mayer C M, Schulz K L, Ji X, Ritchie M E. 2007. Ecological stoichiometry in benthic food webs: effect of light and nutrients on periphyton food quantity and quality in lakes. / Limnology and Oceanography, 52(4): 1 728- 734. CrossRef
43. Sand-Jensen K, Borum J. 1991. Interactions among phytoplankton, periphyton, and macrophytes in temperate freshwaters and estuaries. / Aquatic Botany, 41(1-): 137-75. CrossRef
44. Scott J T, Doyle R D, Filstrup C T. 2005. Periphyton nutrient limitation and nitrogen fixation potential along a wetland nutrient-depletion gradient. / Wetlands, 25(2): 439-48. CrossRef
45. Smith S M, Lee K D. 2006. Responses of periphyton to artificial nutrient enrichment in freshwater kettle ponds of Cape Cod National Seashore. / Hydrobiologia, 571(1): 201-11. CrossRef
46. Song Y Z, Qin B Q, Gao G. 2007. Effect of nutrient on periphytic algae and phytoplankton. / Journal of Lake Sciences, 19(2): 125-30.
47. Stelzer R S, Lamberti G A. 2001. Effects of N:P ratio and total nutrient concentration on stream periphyton community structure, biomass, and elemental composition. / Limnology and Oceanography, 46(2): 356-67. CrossRef
48. Stevenson R J. 2001. Using algae to assess wetlands with multivariate statistics, multimetric indices, and an ecological risk assessment framework. / In: Rader R R, Batzger D P, Wissinger S A eds. Biomonitoring and Management of North American Freshwater Wetlands. John Wiley and Sons, New York. p.113-40.
49. Tank J L, Dodds W K. 2003. Nutrient limitation of epilithic and epixylic biofilms in ten North American streams. / Freshwater Biol ogy, 48(6): 1 031- 049.
50. Vadeboncoeur Y, Lodge A D. 2000. Periphyton production on wood and sediment: substratum-specific response to laboratory and whole-lake nutrient manipulations. / Journal of the North American Benthological Society, 19(1): 68-1. CrossRef
51. Vitousek P M, Aber J, Howarth R W, Likens G E, Matson P A, Schindler D W, Schlesinger W H, Tilman G D. 1997. Human alteration of the global nitrogen cycle: causes and consequences. / Ecological Applications, 7: 737-50.
52. Wetzel R G. 2001. Limnology, Lake and River Ecosystems (Third Edition). Academic Press, London. 1 006p.
53. Wolfe J E III, Lind O T. 2010. Phosphorus uptake and turnover by periphyton in the presence of suspended clays. / Limnology, 11(1): 31-7. CrossRef - 作者单位:Xiufeng Zhang (1) (2)
Xueying Mei (1) (3)
1. Department of Ecology and Institute of Hydrobiology of Jinan University, Guangzhou, 510632, China
2. Institute of Geography and Limnology, Chinese Academy of Sciences, Nanjing, 210008, China
3. College of Resources and Environment, Anhui Agricultural University, Hefei, 230036, China - ISSN:1993-5005
文摘
We examined changes in biomass and species dominance of periphyton in response to nitrogen (N) and phosphorus (P) enrichment in 12 mesocosms representing eutrophic aquatic ecosystems. The 100-L mesocosms consisted of lake water and pond sediment, and N and P were applied weekly. Periphyton samples were taken to assess the biomass (as estimated by the concentration of chlorophyll a (chl a)) and to determine which species were dominant. The mean periphyton biomass (chl a) in the P-enriched treatment did not differ from that in the control group, but increased with N enrichment. Compared with that in the control group, the chl a concentration increased with N+P enrichment in the early stages of the experiment, but decreased in the later stages. The decline in periphyton biomass at the later stages of the experiment was due to limited light availability, which resulted from the increased phytoplankton density in the experiment. The nutrient enrichment treatments resulted in changes in the dominant algal species in the periphyton, suggesting that various algal species showed different responses to different nutrients. The results of this study have implications for nutrient management in aquatic ecosystems.