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Warianty tytułu
Konferencja
All-Poland Scientific Conference "Interspecies Relationships at Levels of Organization" (2009 ; Krasnobród)
Języki publikacji
Abstrakty
Peatbogs have both horizontal and vertical differences in moisture, pH, light and nutrient availability. Micro-distribution of testate amoebae taxa has been observed along the Sphagnum stem but there is no data concerning the vertical micro-distribution of protozoa in water column under the peatbog surface and in the interstitial waters. The research was made in a small (ca 16 ha) peatbog complex in the eastern Poland. Vertical microzonation of testate amoebae and ciliates in relation to physical, chemical and biological parameters (peat porosity, temperature, dissolved oxygen, chlorophyll a, TN, TP, DOC and TOC) in Sphagnum hollows, mud bottom hollows and interstitial waters in peatbog were studied. Samples were taken once a month from April to November 2009 from three layers: free water mass up to 10 cm (FW), bottom water (BW) and interstitial, pore water - IW (water between particles of peat on depth 20-25 cm). During each sampling occasion 3 samples were collected from each site. At each type of micro-habitat and each sampling date water was sampled using a plexiglass core. The water column sampled from the top surface to the bottom was 25 cm high. Interstitial waters were collected from mini-piezometers located into the peat. Temperature, dissolved oxygen, conductivity, chlorophyll a and nutrients contents were always lower in interstitial water than in free and bottom waters. The highest numbers of testate amoebae and ciliates taxa occurred in the bottom water (31 and 13 taxa, respectively) and became much lower in interstitial water (17 and 5 taxa, respectively). The density and biomass of protozoa differed significantly between the studied layers, with the lowest numbers in the interstitial water and the highest in the bottom water. Ordination analysis indicated that chlorophyll a, TOC and TP can strongly regulate the abundance and species composition of protozoa. The RDA ordination showed that the testate amoebae species can be divided into three groups associated with: 1) free water mass, 2) bottom water and 3) interstitial water, while the ciliate species into two groups associated with: 1) interstitial water and 2) free water mass and bottom waters. The free water mass and bottom water were dominated by mixotrophic taxa, whereas the deepest layer showed the increase of the contribution of small, bacterivorous species. In all the examined micro-habitats the highest abundance and biomass of these microorganisms occurred in early spring and late autumn, while the lowest values were recorded in late summer.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
729--740
Opis fizyczny
Bibliogr. 42 poz.,Il., tab.,
Twórcy
autor
- Department of Hydrobiology, University of Life Sciences, Dobrzańskiego Str. 37, 20-262 Lublin, Poland, tomasz.mieczan@up.lublin.pl
Bibliografia
- 1. Amblard C., Carrias J.F., Bourdier G., Maurin N. 1995 – The microbial loop in a humic lake: seasonal and vertical variations in the structure of different communities – Hydrobiologia, 300: 71–84.
- 2. Andrushchyshyn P.O., Wilson P.K., Williams D.D. 2007 – Ciliate communities in shallow groundwater: seasonal and spatial characteristics – Freshwat. Biol. 52: 1745–1761.
- 3. Beaver J.R., Crisman L.T. 1990 – Seasonality of planktonic ciliated protozoa in 20 subtropical Florida lakes of varying trophic state - Hydrobiologia, 190: 127–135.
- 4. Bendell-Young L. 2003 – Peatland interstitial water chemistry in relation to that of surface pools along a peatland mineral gradient – Water, Air Soil Poll. 143: 367–375.
- 5. Błędzki L., Ellison M.A. 2003 – Diversity of rotifers from northeastern U.S.A. bogs with new species records for North America and New England – Hydrobiologia, 497: 53–62.
- 6. Borcard D., Vaucher von Ballmoos C. 1997 – Oribatid mites (Acari, Oribatida) of a primary peat bog-palustre transition in the Swiss Jura mountains – Ecoscience, 4: 470–479.
- 7. Booth R.K. 2002 – Testate amoebae as paleoindicators of surface-moisture changes on Michigan peatlands: modern ecology and hydrological calibration – J. Paleolimnol. 28: 329–348.
- 8. Charman D.J., Hendon D., Woodland W. 2000 – The identification of testate amoebae (Protozoa: Rhizopoda) in peats – Quatenary Research. Technical Guide, 9: 1–147.
- 9. Clarke K.J. 2003 – Guide to the identification of soil protozoa – Teatate Amoebae – Freshwater Biological Association, UK, 40 pp.
- 10. Cleven J.E. 2004 – Seasonal and spatial distribution of ciliates in the sandy hyporheic zone of lowland stream – Europ. J. Protistol. 40: 71–84.
- 11. Foissner W., Berger H., Kohmann F. 1994 - Taxonomische und ökologische Revision der Ciliaten des Saprobiensystems. Hymenostomatida, Prostomatida, Nassulida – Informationsberichte des Bayer. Landesamtes für Wasserwirtschaft, München, 548 pp.
- 12. Foissner W., Berger H. 1996 – A userfriendly guide to the ciliates (Protozoa, Ciliophora) commonly used by hydrobiologists as bioindicators in rivers, lakes and waste waters, with notes on their ecology – Freshwat. Biol. 35: 375–470.
- 13. Foissner W., Berger H., Schaumburg J. 1999 – Identification and Ecology of Limnetic Plankton Ciliates – Informationsberichte des Bayer. Landesamtes für Wasserwirtschaft, München, 777 pp.
- 14. Gilbert D., Amblard C., Bourdier G., Francez A.J. 1998 – The microbial loop at the surface of a peatland: structure, functioning and impact of nutrients inputs – Microb. Ecol. 35: 89–93.
- 15. Gilbert D., Mitchell E.A.D., Amblard Ch., Bourdier G., Francez A.J. 2003 – Population dynamics and food preferences of the Testate amoebae Nebela tincta major-bohemica-collaris Complex (Protozoa) in Sphagnum peatland – Acta Protozool. 42: 99–104.
- 16. Gilbert D., Mitchell E.A.D. 2006 – Microbial diversity in Sphagnum peatlands. (In: Peatlands: Evolution and records of environmental and climate changes, Eds: I.P. Martini, A. Martinez Cortizas, W. Chesworth) – Elsevier, pp. 287–318.
- 17. Golterman H.L. 1969 – Methods for chemical analysis of freshwaters – Blackwell Scientific Publications, Oxford, Edinburgh, 213 pp.
- 18. Gorham E. 1991 – Northern peatlands: role in the carbon cycle and probably responses to climatic warming – Ecol. Appl. 1: 182–195.
- 19. Grolière C.A. 1977 – Contribution à l’ètude de quelques ciliès des sphaignes: II – Dynamique des populations – Protistologica, 13: 335–352.
- 20. Heal O.W. 1964 – Observations on the seasonal and spatial distribution of testacea (Protozoa: Rhizopoda) in Sphagnum – J. Animal Ecol. 33: 395–412.
- 21. Hölting B. 1996 – Hydrogeologie 5th Edition – Enke-Verlag, Stuttgart, 479 pp.
- 22. Jacquet V., Lair N., Hoffmann L., Cauchie H.M. 2005 – Spatio-temporal patterns of protozoan communities in a meso-eutrophic reservoir (Esch-sur-Sure, Luxemburg) – Hydrobiologia, 551: 49–60.
- 23. Legendre P., Gallagher E.D. 2001 – Ecologically meaningful transformations for ordination of species data – Oecologia, 129: 271–280.
- 24. Mazei Yu.A., Tsyganov A.N., Bubnova O.A. 2007 – Structure of community of testate amoebae in a sphagnum dominated bog in upper sura flow (Middle Volga Territory) – Ecology, 4: 462–474.
- 25. Mieczan T. 2005 – Periphytic ciliates in littoral zone of three lakes of different trophic status – Pol. J. Ecol. 53: 489–502.
- 26. Mieczan T. 2007 – Seasonal patterns of testate amoebae and ciliates in three peabogs: relationship to bacteria and flagellates (Poleski National Park, Eastern Poland) – Ecohydrol. Hydrobiol. 7/1: 79–88.
- 27. Mieczan T. 2009a – Ecology of testate amoebae (Protists) in Sphagnum peatlands of eastern Poland: vertical micro-distribution and species assemblages in relation to environmental parameters – Ann. Limnol. Int. J. Lim. 45: 41–49.
- 28. Mieczan T. 2009b – Ciliates in Sphagnum peatlands: vertical micro-distribution, and elationships of species assemblages with environmental parameters – Zool. St. 1: 33–48.
- 29. Mieczan T. 2010a – Effect of vegetation patchiness and site factors on distribution and diversity of testate amoebae and ciliates in peatbogs - Pol. J. Ecol. 58: 93–102.
- 30. Mieczan T. 2010b – Vertical micro-zonation of testate amoebae and ciliates in peatland waters in relation to potential food resources and grazing pressure – Int. Rev. Hydrobiol. 95: 86–102.
- 31. Mitchell E.A.D., Buttler A., Grosvernier Ph., Hydin H., Albinsson C., Greenup A.L., Heijmans M.M.P.D., Hoosbeek M.R., Saarinen T. 2000 – Relationships among testate amoebae (Protozoa), vegetation and water chemistry in five Sphagnum-dominated peatlands in Europe – New Phytol. 145: 95–106.
- 32. Mitchell E.A.D., Charman D.J., Warner B.G. 2008 – Testate amoebae analysis in ecological and paleoecological studies of wetlands: past, present and future – Biodivers. Conserv. 17: 2115–2137.
- 33. Mitchell E.A.D., Gilbert D. 2004 – Vertical micro-distribution and response to nitrogen deposition in testate amoebae in Sphagnum – J. Eukaryot. Microbiol. 4: 480–490.
- 34. MVSP 2002 – Multivariate Statistical Package – Kovach Computering Services.
- 35. Opravilová V., Hájek M. 2006 – The variation of testacean assemblages (Rhizopoda) along the complete base-richness gradient in fens: a case study from the western Carpathians – Acta Protozool. 45:191–204.
- 36. Payne R.J., Mitchell E.A.D. 2007 – Ecology of testate amoebae from mires in the central Rhodope Mountains, Greece and development of a transfer function for paleohydrological reconstruction – Protist, 158: 159–171.
- 37. Rao C.R. 1995 – A review of canonical coordinates and an alternative to correspondence analysis using Hellinger distance – Qüestiiò, 19: 23–63.
- 38. Sarvala J., Kankaala P., Zingel P., Arvola L. 1999 – Food webs of humic waters. Zooplankton (In: Limnology of humic waters, Eds: J. Keskitalo, P. Eloranta) – Backhuys Publishers, Leiden, pp. 181–184.
- 39. SAS Institute Inc. 2001 – SAS Users Guide – Version 8.2 Edition, SA Cary.
- 40. Ter Braak CJF. 1988-1992 – CANOCO–FORTRAN program for Canonical Community Ordination (vers. 2.1) – Microcomputer Power, Ithaca.
- 41. Tolonen K., Warner B.G., Vasander H. 1994 – Ecology of Testaceans (Protozoa, Rhizopoda) in mires in Southern Finland. 2. Multivariate analysis – Arch. Protisten. 144: 97–112.
- 42. Watters J.R., Stanley E.H. 2006 – Stream channels in peatlands: the role of biological processes in controlling channel form – Geomorphology, 89: 97–110.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BGPK-3179-2333