Effects of different primary producers (Cyanobacteria and Macrophyte) on the spatio-temporal distribution of phosphorus forms and concentrations in a lake

• Autorzy: Xiaoming C. , Haixia Z. , Xiaofeng C. , Liuyan Y. , Jin Z.
• Języki publikacji: EN

Abstrakty

EN

Lake eutrophication is concerning because of its harmful effects on water ecosystems. The field samplings were collected to investigate various forms of phosphorus in the water columns, clarifying the relationship between phosphorus levels and types of primary producers (cyanobacteria and macrophytes) in the different regions of Lake Taihu in China. High phosphorus levels were observed in Meiliang Bay suffering from cyanobacterial bloom, while phosphorus concentrations were relative lower in Xukou Bay and East Lake Taihu, where many macrophytes grow. Thus, cyanobacteria and macrophytes could significantly affect phosphorus forms and contents in the different lake regions. In Meiliang Bay, aqueous total phosphorus (TPaquesous) concentrations (0.312±0.158 mg·L⁻¹), total dissolved phosphorus concentrations (0.108±0.072 mg·L⁻¹), and dissolved inorganic phosphorus concentrations (0.018±0.022 mg·L⁻¹) were much higher in July under the action of cyanobacteria than in any other period. Aqueous phosphorus concentrations in Xukou Bay and East Lake Taihu were much lower in July due to macrophyte growth. However, macrophyte decomposition made TPaquesous concentrations in Xukou Bay extremely high in December. Furthermore, Exchangeable phosphorus (Ex-P), Al-combined phosphorus (Al-P), Fe-combined phosphorus (Fe-P), Autogenetic calcium phosphorus (ACa-P), detritus calcium phosphorus (De-P), and organic phosphorus (Or-P) in Meiliang Bay were much lower in July due to the action of cyanobacteria. However, only Ex-P, ACa-P, and Or-P contents in the sediments of macrophyte-dominated lake regions were much lower in July due to the growth of macrophytes. Therefore, interactions between phosphorus contents and types of primary producers were simultaneously observed in a single lake.

• Wydawca: -
• Czasopismo: Polish Journal of Environmental Studies
• Rocznik: 2013
• Tom: 22
• Numer: 6
• Opis fizyczny: p.1649-1659,fig.,ref.

Twórcy

autor

Xiaoming C.

• Safety and Emergency Management Research Center, Emergency Management School, Henan Polytechnic University 454000, China

autor

Haixia Z.

• Safety and Emergency Management Research Center, Emergency Management School, Henan Polytechnic University 454000, China

autor

Xiaofeng C.

• State Key Laboratory of Pollution Control and Resource Reuse, School of the Environment, Nanjing University, Nanjing 210093, China

autor

Liuyan Y.

• Safety and Emergency Management Research Center, Emergency Management School, Henan Polytechnic University 454000, China
• State Key Laboratory of Pollution Control and Resource Reuse, School of the Environment, Nanjing University, Nanjing 210093, China

autor

Jin Z.

• State Key Laboratory of Pollution Control and Resource Reuse, School of the Environment, Nanjing University, Nanjing 210093, China

Bibliografia

• 1. MARTINS I., MARQUES J.C., JØRGENSEN S.E., NIELSEN S.N. Modelling the effects of green macroalgae blooms on the population dynamics of Cyathura carinata (Crustacea: Isopoda) in an eutrophied estuary. Ecol. Model., 102, 33, 1997.
• 2. PINTO-COELHO R.M., GRECO M.K.B. The contribution of water hyacinth (Eichhornia crassipes) and zooplankton to the internal cycling of phosphorus in the eutrophic Pampulha Reservoir, Brazil. Hydrobiol., 411, 115, 1999.
• 3. PEREIRA R., SOARES A.W.V.M., RIBEIRO R., GONCALVES F. Assessing the trophic state of Linhos lake: a first step towards ecological rehabilitation. J. Environ. Manag., 64, 285, 2002.
• 4. SMITH J., HANEY J. Foodweb transfer, accumulation, and depuration of microcystins, a cyanobacterial toxin, in pumpkinseed sunfish (Lepomis gibbosus). Toxicon., 48, 580, 2006.
• 5. PERRONE U., FACCHINELLI A., SACCHI E. Phosphorus dynamics in a small eutrophic Italian lake. Wat. Air Soil Pollut., 189, 335, 2008.
• 6. XIE P. Historical development of cyanobacteria with bloom disaster in Lake Taihu. Beijing, China. Science Press, 2008 [In Chinese].
• 7. LI H.L., MURPHY T., GUO J., PARR T., NALEWAJKO C. Iron-stimulated growth and microcystin production of Microsystis novacekii UAM 250. Limnol., 39, 255, 2009.
• 8. STEINMAN A., CHU X.F., OGDAHL M. Spatial and temporal variability of internal and external phosphorus loads in Mona Lake, Michigan. Aquat. Ecol., 43, 1, 2009.
• 9. QIN B.Q., HU W.P., CHEN W.M. The evolution process and mechanism of water environment in Lake Taihu. Beijing, China. Science Press, 2004.
• 10. HAVENS K.E., SCHELSKE C.L. The importance of considering biological processes when setting total maximum daily loads (TMDL) for phosphorus in shallow lakes and reservoirs. Environ. Pollut., 113, 1, 2001.
• 11. CHEN Y.W., FAN C.X., TEUBNER K., DOKULIL M. Changes of nutrients and phytoplankton chlorophyll-a in a large shallow lake, Taihu, China: an 8-year investigation. Hydrobiol., 506-509, 273, 2003.
• 12. GUO H.Y. WANG X.R., ZHU G. J. Quantification and index of non-point source pollution in Lake Taihu region with GIS. Environ. Geochem. Health., 26, 147, 2004.
• 13. YANG L.Y., QIN B.Q., HU W.P., LUO L.C., SONG Y.Z. The atmospheric deposition of nitrogen and phosphorus nutrients in Taihu Lake. Oceanol. Et. Limnol. Sin., 38, 104, 2007.
• 14. HE J., GU X.H., LIU G.F. Aquatic macrophytes in East Lake Taihu and its interaction with water environment. J. Lak. Sci., 20, 790, 2008 [In Chinese].
• 15. XU H., YANG L.Z., ZHAO G.M., JIAO J.G., YIN S.X., LIU Z.P. Anthropogenic impact on surface water quality in Taihu Lake region, China. Pedosphere, 19, 765, 2009.
• 16. XU H., PAERL H.W., QIN B.Q., ZHU G.W., GAO G. Nitrogen and phosphorus inputs control phytoplankton growth in eutrophic Lake Taihu, China. Limnol. Oceanogr., 55, 420, 2010.
• 17. YANG C.X., WANG S.R., JIN X.C., WU F.C. Nitrogen and phosphorus mineralization in sediments of Taihu Lake after the removal of light fraction organic matter. Environ. Earth Sci., 59, 1437, 2010.
• 18. SCHINDLER D.W. Evolution of phosphorus limitation in lakes. Sci., 195, 260, 1977.
• 19. ZHANG J.Z. HUANG X. L. Relative importance of solidphase phosphorus and iron on the sorption behavior of sediments. Environ. Sci. Technol., 41, 2789, 2007.
• 20. ZHOU Q., GIBSON C.E., ZHU Y. Evaluation of phosphorus bioavailability in sediments of three contrasting lakes in China and the UK. Chemosphere, 42, 221, 2001.
• 21. SØNDERGAARD M., JENSEN J.P., JEPPESEN E. Role of sediment and internal loading of phosphorus in shallow lakes. Hydrobiol., 506-509, 135, 2003.
• 22. ZHU G.W., QIN B.Q., GAO G., ZHANG L., FAN C.X. Fractionation of phosphorus in sediments and its relation with soluble phosphorus contents in shallow lakes located in the middle and lower reaches of Changjiang River, China. Acta Sci. Circumst., 24, 381, 2004 [In Chinese].
• 23. JIN X.C., WANG S.R., PANG Y., ZHAO H.C., ZHOU X.N. The adsorption of phosphate on different trophic lake sediments. Colloids Surf., 254, 241, 2005.
• 24. WANG S.R., JIN X.C., PAN Y., ZHAO H.C., ZHOU X.N., WU F.C. Phosphorus fractions and phosphate sorption characteristics in relation to the sediment compositions of shallow lakes in the middle and lower reaches of Yangtze River region, China. Colloid Interface Sci., 289, 339, 2005.
• 25. WANG S.R., JIN X.C., ZHAO H.C., WU F.C. Phosphorus fractions and its release in the sediments from the shallow lakes in the middle and lower reaches of Yangtze River area in China. Colloids Surf., 273, 109, 2006.
• 26. WANG S.R., JIN X.C., ZHAO H.C., WU F.C. Effect of organic matter on the sorption of dissolved organic and inorganic phosphorus in lake sediments. Colloids Surf. A., Physicochem. Eng. Asp., 297, 154, 2007.
• 27. KAISERLI A., VOUTSA D., SAMARA C. Phosphorus fractionation in lake sediment-lakes Volvi and Koronia, N. Greece. Chemosphere, 46, 1147, 2002.
• 28. QIN B.Q., XU P.Z. WU Q.L., LUO L.C., ZHANG Y.L. Environmental issues of Lake Taihu, China. Hydrobiol., 581, 3, 2007.
• 29. QIN B.Q., HU W.P., GAO G., LUO L.C., ZHANG J.S. Dynamic of sediment resuspension and the conceptual schema of nutrient release in the large shallow Lake Taihu, China. Chinese Sci. Bull., 49, 54, 2004.
• 30. GUO L. Doing battle with the green monster of Taihu Lake. Sci., 317, 1166, 2007.
• 31. LEI Z.X., CHEN G.R., XIE Y.F., LIU Z.W. Management of aquatic macrophytes in Taihu Lake. Environ. Sci. Technol., 32, 187, 2009 [In Chinese].
• 32. ZHU G.W., QIN B.Q., GAO G., ZHANG L., LUO L.C., ZHANG Y.L. Effects of hydrodynamics on phosphorus concentrations in water of Lake Taihu, a large, shallow, eutrophic lake of China. Hydrobiol., 581, 53, 2007.
• 33. CHEN M.J., CHEN F.Z., ZHAO B.Y., WU Q.L., KONG F.X. Seasonal variation of microbial eukaryotic community composition in the large, shallow, subtropical Taihu Lake, China. Aquat. Ecol., 44, 1, 2010.
• 34. LEI Z.X., XU D.L., GU J.G., LIU Z.W. Distribution characheristics of aquatic macrophytes and their effects on the nutrients of water and sediment in Taihu Lake. J. Agro-Environ. Sci., 27, 698, 2008 [In Chinese].
• 35. APHA, AWWA, WPCF. Standard Methods for the Examination of Water and Waste Water (19th ed). Washington DC: American Public Health Association, 1995.
• 36. ZHOU A.M., TANG H.X. WANG D.S. Phosphorus adsorption on natural sediment: Modeling and effects of pH and sediment composition. Wat. Res., 39, 1245, 2005.
• 37. WILLIAMS J.D.H., SYERS J.K., HARRIS R.F., ARMSTRONG D.E. Fractionation of inorganic phosphate in calcareous lake sediment. Soil Sci. Soc. America., 35, 250, 1971.
• 38. HIELTJES A.H.M., LIJKLEMA L. Fractionation of inorganic phosphates in calcareous sediment. J. Environ. Qual., 9, 405, 1980.
• 39. PSENNER R., BOSTRÖM B., DINKA M., PETTERSSON K., PUCSKO R., SAGER M. Fractionation of phosphorus in suspended matter and sediment. Arch. Hydrobiol. Beih. Ergebn. Limnol., 30, 98, 1988.
• 40. GOLTERMAN H.L., BOOMAN A. Sequential extraction of iron-phosphate and calcium-phosphate from sediments by chelating agents. Verh. Int. Vereinigung. Theor. Angew. Limnnol., 23, 904, 1988.
• 41. RUTTENBERG K.C. Development of a sequential extraction method for different forms of phosphorus in marine sediments. Limnol. Oceanogr., 37, 1460, 1992.
• 42. CAO X.Y., SONG C.L., LI Q.M., ZHOU Y.Y. Dredging effects on P status and phytoplankton density and composition during winter and spring in Lake Taihu, China. Hydrobiol., 581, 287, 2007.
• 43. HU W.P., ZHAI S.J., ZHU Z.C., HAN H.J. Impacts of the Yangtze River water transfer on restoration of Lake Taihu. Ecol. Eng., 34, 30, 2008.
• 44. KE Z.X. XIE P., GUO L.G. Controlling factors of spring-summer phytoplankton succession in Lake Taihu (Meiliang Bay, China). Hydrobiol., 607, 41, 2008.
• 45. SHI X.L., YANG L.Y., NIU X.J., XIAO L., KONG Z.M., QIN B.Q., GAO G. Intracellular phosphorus metabolism of Microcystis aeruginosa under various redox potential in darkness. Microbiol. Res., 158, 345, 2003.
• 46. SHI X.L., YANG L.Y., WANG F.P., XIAO L., JIANG L.J., KONG Z.M., GAO G., QIN B.Q. Growth and phosphate uptake kinetics of Microcystis aeruginosa under various environmental conditions. J. Environ. Sci., 16, 288, 2004.
• 47. SHI X.L., YANG L.Y., YU Z.Y., PENG N.Y., XIAO L., YIN D.Q., QIN B.Q. Intracellular phosphorus metabolism and growth of Microcystis aeruginosa in dark/light cycles under various redox potential difference conditions. Hydrobiol., 581, 167, 2007.
• 48. COTNER J.J.B., WETZEL R.G. Uptake of dissolved inorganic and organic phosphorus compounds by phytoplankton and bacterioplankton. Limnol. Oceanogr., 37, 232, 1992.
• 49. SUDO R., FUJIMOTO N., SUGIURA N., INAMORI Y. Nutrient-limited growth of Microcystis aeruginosa and Phormidium tenue and competition under various N:P supply ratios and temperatures. Limnol. Oceanogr., 42, 250, 1997.
• 50. BALDIA S.F., EVANGELISTA A.D., ARALAR E.V., SANTIAGO A.E. Nitrogen and phosphorus utilization in the cyanobacterium Microcystis aeruginosa isolated from Laguna de Bay, Philippines. J. Appl. Phycol., 19, 607, 2007.
• 51. TOIVONEN H., HUTTUNEN P. Aquatic macrophytes and ecological gradients in 57 small lakes in southern Finland. Aquat. Bot., 51, 197, 1995.
• 52. ASAEDA T., TRUNG V.K., MANATUNGE J. Modeling the effects of macrophyte growth and decomposition on the nutrient budget in Shallow Lakes. Aquat. Botany., 68, 217, 2000.
• 53. LOPEZ P., LLUCH X., VIDAL M., MORGUí J.A. Adsorption of phosphorus on sediments of the Balearic islands (Spain) related to their composition. Estuar. Coast. Shelf. Sci., 42, 185, 1996.
• 54. LEWIS G.N., AUER M.T., XIANG X.Y., PENN M.R. Modeling phosphorus flux in the sediment of Onondaga Lake: Insights on the timing of lake response and recovery. Ecol. Model., 209, 121, 2007.
• 55. ZENG J., YANG L.Y., LIANG Y., LI J.Y., XIAO L., JIANG L.J., ZHAO D.Y. Spatial distribution of bacterial communities in sediment of a eutrophic lake revealed by denaturing gradient gel electrophoresis and multivariate analysis. Canadian J. Microbiol., 54, 1053, 2008.
• 56. ZENG J., YANG L.Y., LIANG Y., XIAO L., JIANG L.J., ZHAO D.Y. Vertical distribution of bacterial community structure in the sediments of two eutrophic lakes revealed by denaturing gradient gel electrophoresis (DGGE) and multivariate analysis techniques. World J. Microbiol. Biotechnol., 25, 225, 2009.
• 57. ZENG J., YANG L.Y., DU H.W., XIAO L., JIANG L.J., WU J.,WANG X.L., Bacterioplankton community structure in a eutrophic lake in relation to water chemistry. World J. Microbiol. Biotechnol., 25, 763, 2009.
• 58. XIE L.Q., XIE P., TANG H.J. Enhancement of dissolved phosphorus release from sediment to lake by Microcystis blooms – an enclosure experiment in a hypereutrophic, subtropical Chinese lake. Environ. Pollut., 122, 391, 2003.
• 59. LIJKLEMA L. Interaction of orthophosphate with iron III and aluminium hydroxides. Environ. Sci. Technol., 14, 537, 1980.