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2013 | 22 | 3 |

Tytuł artykułu

Biomass and abundance of aquatic fungi in a polyhumic dam reservoir

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
The aim of this study was to determine the biomass and abundance of fungi in the waters of the shallow and polyhumic reservoir located in northeastern Poland. It was shown that fungal biomass in water positively correlated with abundance (CFU/ml, colony-forming unit/ml) and negatively with the number of morphotypes. The largest biomass of fungi was recorded in October (0.55 μg/dm³) and the lowest in winter (0.22-0.28 μg/dm³), when fungal colonies had greater phenotypic diversity. The main river supplying the reservoir had greater average fungal biomass and abundance than the reservoir.

Słowa kluczowe

Wydawca

-

Rocznik

Tom

22

Numer

3

Opis fizyczny

p.819-824,fig.,ref.

Twórcy

  • Institute of Biology, University of Białystok, Świerkowa 20B, 15-950 Białystok, Poland
  • Institute of Biology, University of Białystok, Świerkowa 20B, 15-950 Białystok, Poland
autor
  • Institute of Biology, University of Białystok, Świerkowa 20B, 15-950 Białystok, Poland
autor
  • Institute of Biology, University of Białystok, Świerkowa 20B, 15-950 Białystok, Poland

Bibliografia

  • 1. WONG M.K.M., GOH T.K., HODGKISS I.J., HYDE K.D., RANGHOO V.M., TSUI C.K.M., HO W.H., WONG W.S.W., YUEN T.K. Role of fungi in freshwater ecosystems. Biodivers. Conserv. 7, 1187, 1998.
  • 2. PASCOAL C., CÁSSIO F., MARCOTEGUI A., SANZ B., GOMES P. Role of fungi, bacteria and invertebrates in leaf litter breakdown in a polluted river. J N Am. Benthol. Soc. 24, 784, 2005.
  • 3. KRAUSS G.J., SOLÉ M., KRAUSS G., SCHLOSSER D., WESENBERG D., BÄRLOCHER F. Fungi in freshwater s:ecology, physiology and biochemical potetntial. FEMS Microbiol. Rev. 35, 620, 2011.
  • 4. QI B., MOE W.. Biodegradation of volatile organic compounds by five fungal species. Appl. Microbiol. Bot. 58, 684, 2008.
  • 5. MIERSCH J.,GRANCHAROV K. Cadmium and heat response of the fungus Heliscus lugdunensis isolated from highly polluted and unpolluted areas. Amino Acids 34, 271, 2008.
  • 6. CRESSA C., SMITS G. Aquatic Hyphomycetes in two blackawater streams of Venezuela. Ecotropicos 20, 82, 2007.
  • 7. CZECZUGA B., GÓRNIAK A., KIZIEWICZ B., GODLEWSKA A., MUSZYŃSKA E., JEKATIERYNCZUK-RUDCZYK E., ZIELIŃSKI P., GROSFELD A.W., MICHALSKA J. Zoosporic fungi and fungus-like organisms in the Siemianówka dam reservoir. Nova Hedwiqia 91, (1-2), 137, 2010.
  • 8. JOBARD M., RASCONI S., SIME-NGANDO T. Diversity and functions of microscopic fungi: a missing component in pelagic food webs. Aquat. Sci. 72, 255, 2010.
  • 9. GÓRNIAK A., ZIELIŃSKI P. Influence of catchment characteristics and hydrology on DOC in rivers in the northeastern Poland. Verh. Intern. Verein. Limnol. 27, 1142, 2000.
  • 10. STEINBERG CH.E.W. Ecology of humic substances in freshwaters. Spribger, Berlin pp. 440, 2003.
  • 11. RASCONI S., NIQUIL N., SIME-NGANDO T. Phytoplankton chytridiomycosis: community structure and infectivity of fungal parasites in aquatic systems. Environ. Microbiol. 14, 2151, 2012.
  • 12. GÓRNIAK A. (Ed.) Ecosystem of the Siemianówka dam reservoir in 1990-2004 years and its recultivation. University of Białystok Press, Białystok, pp. 236, 2006 [In Polish].
  • 13. LORENZEN C. J. A note on the chlorophyll and phaeophytin content of the chlorophyll maximum. Limnol. Oceanog. 10, 482, 1965.
  • 14. NUSCH E. A. Comparison of different methods for chlorophyll and phaeopigment determination. Ergeb. Limnol. 14, 14, 1980.
  • 15. ZIELIŃSKI P., GÓRNIAK A., PIEKARSKI M.K. The effect of hydrological drought on chemical quality of water and dissolved organic carbon concentrations in lowland rivers. Pol. J. Ecol. 57, (2), 373, 2009.
  • 16. HERMANOWICZ W., DOJLIDO J., DOŻAŃSKA W., KOZIOROWSKI B., ZERBE J. Physico-chemical analysis of water and wastewater. Arkady, Warsaw, 1999 [In Polish].
  • 17. DESCALS E. Techniques for handling ingoldian fungi. In: Graça M.A.S., Bärlocher F. & Gessner M.O. [Ed] Methods to study litter decomposition. A practical guide., Springer-Verlag, 129, 2007.
  • 18. DAVIS M.W., LAMAR R. T. Evaluation of methods to extract ergosterol for quantitation of soil fungal biomass. Soil Biol. Biochem. 24, (3), 189, 1992.
  • 19. MILLE-LINDBLOM C., TRANVIK L.J. Antagonism between bacteria and fungi on decomposing aquatic plant litter. Microb Ecol 45, 173, 2003.
  • 20. JORGENSEN N.O.G., STEPANAUSKAS R. Biomass of pelagic fungi in Baltic rivers. Hydrobiologia 623, 105, 2009.
  • 21. GRABOWSKA M., GÓRNIAK A., JEKATIERYNCZUK-RUDCZYK E., ZIELIŃSKI P. The influence of hydrology and water quality on phytoplankton community composition and biomass in a homoeutrophic reservoir, Siemianówka reservoir (Poland). Ecohydrol. Hydrobiol. 3, (2), 185, 2003.
  • 22. ORŁOWSKA M., KULIKOWSKA-KARPIŃSKA E., OSTROWSKA H. Aquatic Hyphomycetes in the Narewka river. Ochr. Środ. Zasob. Nat. 40, 524, 2009 [In Polish].
  • 23. GESSNER M.O. Fungal biomass, production and sporulation associated with particular organic matter in streams. Limnetica 13, 33, 1997.
  • 24. NIEWOLAK S., FILIPKOWSKA Z., KORZENIEWSKA E. Spatial distribution and seasonal changes in the number of Actinomycetes, filamentous fungi and yeasts in water of an eutropic lake and its catchment basis. Water-Environment-Rural. Areas 9, 123, 2009 [In Polish].
  • 25. DANG C.K., SCHINDLER M., CHAUVET M., GESSNER M.O. Temperature oscillations couple with fungal communities can modulate warming effects on litter decomposition. Ecology 90, 122, 2009.
  • 26. SHARMA K., PARVEEN S. Ecological Study of Fungi Isolated from the Surface Water of Dudhawa Dam Dhamtari, Chhattisgarh, India. J. Phytol. 6, 03, 2011.
  • 27. SATI S.C., BISHT S. Utilization of various carbon sources for the growth of waterborne conidial fungi. Mycologia 98, (5), 678, 2006.
  • 28. COLOMBO V., VIEIRA A.A.H., MORAES G. Activity of glycosidases from freshwater heterotrophic microorganisms on the degradation of extracellular polysaccharide produced by Anabaena spiroides (Cyanobacteria). Braz. J. Microbiol. 35, 110, 2004.
  • 29. PASCOAL C., CÁSSIO F. Contribution of fungi and bacteria to leaf litter decomposition in a polluted river. Appl. Environ. Mocrob 70, 5266, 2004.
  • 30. SOLÉ M., FETZER I., WENNRICH R., SRIDHAR K.R., HARMS H., KRAUSS G. Aquatic hyphomycetes communities as potential bioindicators for assessing anthropogenic stress. Sci. Total Environ. 389, 557, 2008.
  • 31. MEDEIROS A.O., PASCOAL C., GRACA M.A.S. Diversity and activity of aquatic fungi under low oxygen conditions. Freshwater Biol. 54, 142, 2009.
  • 32. SUBERKROPP K. The influence of nutrients on fungal growth, productivity, and sporulation during leaf breakdown in streams. Can. J. Bot. 73, 1361, 1995.
  • 33. RAVIRAJA N.S., SRIDHAR R., BÄRLOCHER F. Breakdown of Ficus and Eucalyptus leaves in a organically polluted river in India: fungal diversity and ecological function. Freshwater Biol. 39, 537, 1998.
  • 34. LECERF A., CHAUVET E. Diversity and functions of leafdecaying fungi in human-altered streams. Freshwater Biol. 53, 1658, 2008.
  • 35. BÄHRS H., STEINBERG C.E.W. Impact of two different humic substances on selected coccal green algae and cyanobacteria – changes in growth and photosynthetic performance. Environ. Sci. Polut. Res. 19, (2), 335, 2011.

Typ dokumentu

Bibliografia

Identyfikatory

Identyfikator YADDA

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