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This study investigated relationships of hydrological variability and potential food resources for metazooplankton groups: rotifers, cladocerans, copepods and nauplii. Samples were collected monthly during ice-free season from March until November in 2006. Two sampling stations were chosen, the one located in Lake Sakadaš, as a segment of Kopački Rit floodplain (Croatia), and the other in the River Danube. Due to hydrological conditions we divided our samples into two hydrological groups which corresponded to: 1/ increased water level i.e. disturbed phase and 2/ decreased water level representing a more stable phase. Abundance of metazooplankton was not significantly different between hydrological groups in the River Danube. However, it was significantly different between hydrological groups in Lake Sakadaš (one-way ANOSIM R = 0.688, P = 0.024), where during a decreased water level higher abundance of metazooplankton was recorded. Rotifers were the most abundant metazooplankton group during the whole investigated period at both stations and between both hydrological groups comprising almost 99% of total metazooplankton abundance. Rotifers were significantly positively correlated with the total number of bacteria, as well as with ammonium and total phosphorous concentrations. The metazooplankton community in Lake Sakadas was negatively influenced by flooding, but not in the River Danube. Compared to the River Danube the investigated floodplain lake showed potential as a storage zone for metazooplankton development during more stable hydrological periods. During that time abundance of rotifers was related to the heterotrophic component of microbial food web. Hence, this investigation adds to the understanding of the metazooplankton dynamics in river-floodplain systems as well as of their relations with trophic levels under variable hydrological conditions.
Czasopismo
Rocznik
Tom
Strony
777--787
Opis fizyczny
Bibliogr. 50 poz., il.
Twórcy
autor
- Department of Biology, J.J. Strossmayer University, Trg Ljudevita Gaja 6, 31 000 Osijek, Croatia
autor
- Department of Biology, J.J. Strossmayer University, Trg Ljudevita Gaja 6, 31 000 Osijek, Croatia
Bibliografia
- 1. Akopian M., Garnier J., Pourriot R. 1999 A large reservoir as a source of zooplankton for the river: structure of the populations and influence of fish predation – J. Plankton Res. 21: 285–297.
- 2. Amoros C., Roux A.L. 1988 – Interaction between water bodies within the floodplain of large rivers: function and development of connectivity – Münstersche Geographische Arbeiten, 29: 125–130.
- 3. APHA 1985 – Standard methods for examination of water and wastewater – APHA, Washington DC, 1269 pp.
- 4. Arndt H. 1993 – Rotifers as predators on components of the microbial web (bacteria, heterotrophic flagellates, ciliates) - a review – Hydobiologia, 255/256: 231–246.
- 5. Baranyi C., Hein T., Holarek C., Keckeis S., Schiemer F. 2002 – Zooplankton biomass and community structure in a Danube River floodplain system: effects of hydrology Freshwater Biol. 47: 473–482.
- 6. Basu P.K., Pick F.R. 1996 – Factors regulating phytoplankton and zooplankton biomass in temperate rivers – Limnol. Oceanogr. 41: 1572–1577.
- 7. Blindow I., Hargeby A., Wagner B.M.A., Anderssons G. 2000 – How important is the crustacean plankton for the maintenance of water clarity in shallow lakes with abundant submerged vegetation? – Freshwater Biol. 44:185–197.
- 8. Bogut I., Vidaković J., Palijan G. 2003 – Stupanj trofije i kvaliteta voda Kopačkog rita tijekom 2002 godine [Trophic state and water quality in Kopački rit during 2002] (In: 3. Konferencija Hrvatskih voda, Hrvatske vode u 21. stoljeću [3rd Croatian conference on waters, Croat. Waters in the 21st century] – Osijek, Croatia, pp. 173–180 (in Croatian).
- 9. Brandl Z. 2005 – Freshwater copepods and rotifers: predators and their prey – Hydrobiologia, 546: 475–489.
- 10. Casanova S.M.C., Panarelli E.A., Henry R. 2009 – Rotifer abundance, biomass, and secondary production after the recovery of hydrologic connectivity between a river and two marginal lakes (São Paulo, Brazil) – Limnologica, 39: 292–301.
- 11. Clarke K.R., Gorley R.N. 2006 – PRIMER v.6: User manual/tutorial – Primer-E Ltd., Plymouth, UK, 92 pp.
- 12. Clarke K.R., Warwick R.M. 2001 – Change in marine communities: an approach to statistical analysis and interpretation – Primer-E Ltd., Plymuth, UK, 169 pp.
- 13. Eckert B., Walz N. 1998 – Zooplankton succession and thermal stratification in the polymictic shallow Müggelsee (Berlin, Germany): a case for the intermediate disturbance hypothesis? – Hydrobiologia, 377/378: 199–206.
- 14. Garcia de Emiliani M.O. 1997 – Effect of water level fluctuations on phytoplankton in a river-floodplain lake system (Parana River, Argentina) – Hydrobiologia, 357: 1–15.
- 15. Gosselain V., Descy J.-P., Joaquim-Justo C., Hammer A., Métens A., Schweitzer S. 1998 – Grazing by large river zooplankton: a key to summer potamoplankton decline? The case of the Meuse and Moselle rivers in 1994 and 1995 – Hydrobiologia, 369: 199–216.
- 16. Hein T., Baranyi C., Reckendorfer W., Schiemer F. 2004 – The impact of surface water exchange on the nutrient and particle dynamics in side-arms along the River Danube, Austria – Sci. Total Environ. 328: 207–218.
- 17. Hynes H.N.B. 1970 – The ecology of running waters – University of Toronto press: Toronto, 555 pp.
- 18. Illyová M. 2006 – Zooplankton of two arms in the Morava River floodplain in Slovakia – Biologia, Bratislava, 61: 531–539.
- 19. Illyová M., Bukvayová K., Némethová D. 2008 – Zooplankton in a Danube River Arm near Rusovce (Slovakia) – Biologia, 63: 566–573.
- 20. Junk W.J., Bayley P.B., Sparks R.E. 1989 The Flood pulse concept in river-floodplain systems – Can. Spec. Publ. Fish. Aquat. Sci. 106: 110–127.
- 21. Keckeis S., Baranyi C., Hein T., Holarek C., Riedler P., Schiemer F. 2003 – The significance of zooplankton grazing in a floodplain system of the River Danube – J. Plankton Res. 25: 243–253.
- 22. Kim H.W., Joo G.J. 2000 – The longitudinal distribution and community dynamics of zooplankton in a regulated river: a case study of the Nakdong River (Korea) – Hydrobiologia, 438: 171–184.
- 23. Kirk K.L. 1991 – Inorganic particles alter competition in grazing plankton: the role of sellective feeding – Ecology, 72: 915–923.
- 24. Mihaljević M., Stević F., Horvatić J., Hackenberger-Kutuzović B. 2009 – Dual impact of the flood pulses on the phytoplankton assemblages in a Danubian floodplain lake (Kopački rit Nature Park, Croatia) – Hydrobiologia, 618: 77–88.
- 25. Mihaljević M., Špoljarić D., Stević F., Cvijanović V., Hackenberger-Kutuzović B. 2010 – The influence of extreme floods from the River Danube in 2006 on phytoplankton communities in a floodplain lake: Shift to a clear state – Limnologica, 40: 260–268.
- 26. Paidere J. 2009 – Influence of flooding frequency on zooplankton in the floodplains of the Dugava river (Latvia) – Acta. Zool. Litu. 19: 306–313.
- 27. Palijan G. 2010 – Different impact of the flood dynamics on the development of culturable planktonic and biofilm bacteria in the floodplain lake – Pol. J. Ecol. 58: 439–448.
- 28. Palijan G. 2012 – Abundance and biomass responses of microbial food web components to hydrology and environmental gradients within a floodplain of the River Danube – Microb. Ecol. DOI 10.1007/s00248-012-0016-z.
- 29. Porter K.G., Feig Y.G. 1980 – The use of DAPI for identifying and counting aquatic microflora – Limnol. Oceanogr. 25: 943.
- 30. Pourriot R., Rougier C., Miquelis A. 1997 Origin and development of river zooplankton : example of the Marne – Hydrobiologia, 345: 143–148.
- 31. RAMSAR 2005 – The list of wetlands of international importance – The Secretariat of the Convention on Wetlands, Gland.
- 32. Rennella A.M., Quirós R. 2006 – The effects of hydrology on plankton biomass in shallow lakes of the Pampa Plain – Hydrobiologia, 556: 181–191.
- 33. Reckendorfer W., Keckeis H., Winkler G., Schiemer F. 1999 – Zooplankton abundance in the river Danube, Austria: the significance of inshore retention – Freshwater Biol. 41: 583–591.
- 34. Saunders III J.F., Lewis Jr. W.M. 1988 – Zooplankton abundance in the Caura River, Venezuela – Biotropica, 20: 206–214.
- 35. Saunders III J.F., Lewis Jr. W.M. 1989 – Zooplankton abundance in the lower Orinoco River, Venezuela – Limnol. Oceanogr. 34: 397–409.
- 36. Schiemer F., Hein T. 2007 – The ecological significance of hydraulic retention zones (In: Hydroecology and Ecohydrology: past, present and future, Eds: P.J. Wood, D.M. Hannah, J.P. Sadler) – John Wiley & Sons Ltd, pp. 405–420.
- 37. Schiemer F., Keckeis H., Reckendorfer W., Winkler G. 2001 – The „inshore retention concept“ and its significance to large rivers – Large Rivers, 12: 509–516.
- 38. Schöll K. 2009 – Diversity of planktonic rotifer assemblages in the water bodies of the Gemenc floodplain (Duna-Dráva National Park, Hungary) – Biologia, 64: 951–958.
- 39. Schöll K. 2010 – Spatial and temporal diversity patterns of planktonic rotifer assemblages in water bodies of the floodplain Gemenc (Duna-Dráva National Park, Hungary) – Internat. Rev. Hydrobiol. 95: 450–460.
- 40. Schöll K., Kiss A. 2008 – Spatial and temporal distribution patterns of zooplankton assemblages (Rotifera, Cladocera, Copepoda) in the water bodies of the Gemenc floodplain (Duna-Dráva National Park, Hungary) – Opusc. Zool. Budapest, 39: 65–76.
- 41. Smart M. 2000 – World heritage nomination – IUCN technical evaluation Kopački rit (Croatia) - IUCN – The World conservation Union, Cairns, Australia, pp. 39–48.
- 42. Strickland J.D., Parsons T.R. 1968 – A practical handbook of seawater analysis – Fish. Res. Board. Can. Bull. 168: 311.
- 43. Tadić D., Vidaček Ž. 1999 – Klimatske, hidrološke i pedološke značajke (In: Kopački rit – Pregled istraživanja i bibliografija [Kopački rit - Research survey and Bibliography], Eds: M. Mihaljević, D. Getz, Z. Tadić, B. Živanović, D. Gucunski, J. Topić, I. Kalinović, J. Mikuška) – Hrvatska akademija znanosti i umjetnosti, Zagreb, pp. 23–31 (in Croatian).
- 44. Thorp J.H., Thoms M.C., Delong M.D. 2006 – The riverine ecosystem synthesis: biocomplexity in river networks across space and time – River Res. Applic. 22: 123–147.
- 45. Vadadi-Fülöp C. 2009 – Zooplankton (Cladocera, Copepoda) dynamics in the River Danube upstream and downstream of Budapest, Hungary – Opusc. Zool. Budapest, 40: 87–98.
- 46. Verity P.G., Sieracki M.E. 1993 – Use of color image analysis and epifluorescence microscopy to measure plankton biomass (In: Handbook of Methods in Aquatic Microbial Ecology, Eds: P.F. Kemp, B.F. Sherr, E.B. Sherr, J.J. Cole) – Lewis Publishers, pp. 327–338.
- 47. Viroux L. 1997 – Zooplankton development in two large lowland rivers, the Moselle (France) and the Meuse (Belgium), in 1993 – J. Plankton Res. 11: 1743–1762.
- 48. Ward J.V. 1998 – Riverine landscapes: biodiversity patterns, disturbance regimes, and aquatic conservation – Biol. Conservat. 83: 267–278.
- 49. Ward J.V., Stanford J.A. 1995 – Ecological connectivity in alluvial river ecosystem and its disruption by flow regulation – Regulated rivers: Research and Management, 11: 105–119.
- 50. Wetzel R.G. 2001 – Limnology. Lake and river ecosystems – Academic press, San Diego, 1006 pp.
Typ dokumentu
Bibliografia
Identyfikator YADDA
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