Community structure, temporal and spatial changes of epiphytic algae on three different submerged macrophytes in a shallow lake

• Autorzy: Oterler B.
• Języki publikacji: EN

Abstrakty

EN

The aim of this study was to determine the composition, biodiversity, and relative abundance of epiphytic algal species on three submerged aquatic plant species (the macrophytes Ceratophyllum demersum, Myriophyllum spicatum, and Potamogeton crispus) in Lake Gala in Lake Gala National Park, Turkey, and the associations of the observed relationships with environmental variables. The aquatic plants were collected at monthly intervals between March 2014 and November 2014, and epiphytic algae on the plants were identified. In total, 98, 74, and 66 taxa of epiphytic algae were identified on C. demersum, M. spicatum, and P. crispus, respectively. The species composition of the epiphytic algae on the three macrophyte species showed a statistically significant difference (F = 7.07, p<0.05). There was also a statistically significant difference in epiphytic algae species diversity, depending on the sampled month (F = 3.59, p<0.05). The mean species richness and species diversity on C. demersum was 33 and 1.546, respectively. On M. spicatum, the mean species richness and species diversity was 23 and 1.407, respectively. On P. crispus, the mean species richness was 19, and the species diversity was 1.256. The following species were the dominant epiphytic taxa in Gala Lake: Cocconeis placentula, Anabaena constricta, Gomphonema acuminatum, Oscillatoria limosa, Cymbella cistula, and Epithemia sorex. Although the species composition of the epiphytic algae was different, the diversity values were similar on all the macrophyte species.

• Wydawca: -
• Czasopismo: Polish Journal of Environmental Studies
• Rocznik: 2017
• Tom: 26
• Numer: 5
• Opis fizyczny: p.2147-2158,fig.,ref.

Twórcy

autor

Oterler B.

• Faculty of Science Department of Biology,Trakya University, Balkan Campus, 22030

Bibliografia

• 1. PELICICE F.M., THOMAZ S.M., AGOSTINHO A.A. Simple relationships to predict attributes of fish assemblages in patches of submerged macrophytes. Neotropical Ichthyology, 6 (4), 543, 2008.
• 2. PADIAL A.A., THOMAZ S.M., AGOSTINHO A.A. Effects of structural heterogeneity provided by the floating macrophyte Eichhornia azurea on the predation efficiency and habitat use of the small Neotropical fish Moenkhausia sanctaefilomenae. Hydrobiologia, 624 (1), 161, 2009.
• 3. VADEBONCOEUR Y., STEINMAN A.D. Periphyton function in lake ecosystems. The Scientific World Journal, 29 (2), 1449, 2002.
• 4. STEINMAN A., ABDIMALIK M., OGDAHL M.E., OUDSEMA M. Understanding planktonic vs. benthic algal response to manipulation of nutrients and light in a eutrophic lake. Lake and Reservoir Management, 32 (4), 402, 2016.
• 5. CHAMBERS P.A., LACOUL P., MURPHY K. J., THOMAZ S.M. Global diversity of aquatic macrophytes in freshwater. Hydrobiologia 595 (1), 9, 2008.
• 6. CATTANEO A., GALANTI G., GENTİNETTA S., ROMO S. Epiphytic algae and macro invertebrates on submerged and floating-leaved macrophytes in an Italian lake. Freshwater Biology, 39 (4), 725, 1998.
• 7. POMAZKINA G., KRAVTSOVA L., SOROKOVIKOVA E. Structure of epiphyton communities on Lake Baikal submerged macrophytes. Limnological Review, 12, 19, 2012.
• 8. NEIF É.M., BEHREND R.D.L., RODRIGUEZ L. Seasonal Dynamics of the structure of epiphytic algal community on different substrates from a Neotropical floodplain. Brazilian Journal of Botany, 36, 169, 2013.
• 9. LETÁKOVÁ M., CANTONATI M., HAŠLER P., NICOLA A., POULÍČKOVÁ A. Substrate specificity and fine-scale distribution of epiphytic diatoms in a shallow tarn in the Brenta Dolomites (south-eastern Alps). Plant Ecology and Evolution, 149, 144, 2016.
• 10. WIKLUND J.A., BOZINOVSKI N., HALL R.I., WOLFE B.B. Epiphytic diatoms as flood indicators. Journal of Paleolimnology, 44, 25, 2010.
• 11. GAISER E.E., SCINTO L.J., RICHARDS J.H., JAYACHANDRAN K., CHILDERS D.L., TREXLER J.C., JONES R.D. Phosphorus in periphyton mats provides the best metric for detecting low-depth P enrichment in an oligotrophic wetland. Water Research, 38, 507, 2004.
• 12. ALBAY M., AKÇAALAN R. Effects Of Water Quality And Hydrologic Drivers On Periphyton Colonization On Sparganium Erectum In Two Turkish Lakes With Different Mixing Regimes, Environmental Monitoring and Assessment, 146, 171, 2008.
• 13. YANG H., FLOWER R.J. Effects of light and substrate on the benthic diatoms in an oligotrophic lake, a comparison between a natural and artificial substrates, Journal of Phycology, 48, 1166, 2012.
• 14. FOREHEAD H.I., THOMPSON P.A. Microbial communities of subtidal shallow sandy sediments change with depth and wave disturbance, but nutrient exchanges remain similar. Marine Ecology Progress Series, 414, 11, 2010.
• 15. VADEBONCOEUR Y., DEVLIN S.P., MCINTYRE P.B, VANDER ZANDEN M.J. Is there light after depth? Distribution of periphyton chlorophyll and productivity in lake littoral zones. Freshwater Science, 33 (2), 524, 2014.
• 16. FOREHEAD H.I., KENDRICK G.A., THOMPSON P.A. Effects of shelter and enrichment on the ecology and nutrient cycling of microbial communities of subtidal carbonate sediments. FEMS Microbiology Ecology, 80, 64, 2012.
• 17. VIS C., HUDON C., CARIGNAN R. GAGNON P. Spatial analysis of production by macrophytes, phytoplankton and epiphyton in a large river system under different water-level conditions. Ecosystems, 10 (1), 293, 2007.
• 18. ANONYMOUS. Environment Status Report of Edirne Province. Edirne Valiliği, Çevreve Şehircilik İl Müdürlüğü 2012. [In Turkish].
• 19. ELIPEK B.Ç., ARSLAN N., KIRGIZ T., ÖTERLER B., GÜHER H., ÖZKAN N. Analysis of Benthic Macroinvertebrates in Relation to Environmental Variables of Lake Gala, a National Park of Turkey. Turkish Journal of Fisheries and Aquatic Sciences, 10 (1), 235, 2010.
• 20. TOKATLI C. Drinking Water Quality of a Rice Land in Turkey by a Statistical and GIS Perspective, İpsala District. Polish Journal of Environmental Studies, 23 (6), 2247, 2014.
• 21. TOKATLI C. Assessment of the Water Quality in the Meriç River, As an Element of the Ecosystem in the Thrace Region of Turkey. Polish Journal of Environmental Studies, 24 (5), 2205, 2015.
• 22. NOGES N., LUUP H., FELDMANN T. Primary production of aquatic macrophytes and their epiphytes in two shallow lakes (Peipsi and Vortsjarv) in Estonia. Aquatic Ecology, 44, 83, 2010.
• 23. BENNION H., KELLY M.G., JUGGINS S., YALLOP M.L, BURGESS A, JAMIESON J., KROKOWSKI J. Assessment of ecological status in UK lakes using benthic diatoms. Freshwater Science, 33 (2), 639, 2015.
• 24. BLANCO S., CEJUDO-FIGUEIRAS C., ÁLVAREZ-BLANCO I., VAN DONK E., GROSS E.M., HANSSON L.-A., IRVINE K., JEPPENSEN E., KAIRESALO T., MOSS B., NÕGES T. BÉCARES E. Epiphytic diatoms along environmental gradients in western european shallow lakes. Clean soil air water, 42 (3), 229, 2014.
• 25. KING L., CLARKE G., BENNION H., KELLY M.G., YALLOP M.L. Recommendations for sampling littoral diatoms in lakes for ecological status assessments. Journal of Applied Phycology, 18, 15-25, 2006.
• 26. SZLAUER-LUKASZEWSKA, A. Succession of periphyton developing on artificial substrate immersed in polysaprobic wastewater reservoir. Polish Journal of Environmental Studies, 16 (5), 753, 2007.
• 27. CEN (Comité Européen de Normalisation). Water quality-Guidance standard for the identification, enumeration and interpretation of benthic diatom samples from running waters. EN 14407:2004. Comité Européen de Normalisation, Geneva, Switzerland, 2004.
• 28. UTERMÖHL H. Zur Vervollkommnung der quantitativen Phytoplankton Methodik. Mitteil. Verhandlungen der Internationalen Vereinigung für Theoretische und Angewandte Limnologie, 9, 1, 1958.
• 29. LANGE–BERTALOT H., BAK M., WITKOWSKI A., TAGLIAVENTI N. Diatoms of Europe. -In: Lange-Bertalot, H. (ed.): Eunotia and some related genera, A.R.G. Gantner Verlag K. G., Ruggel, 6, 747, 2011.
• 30. KOMAREK J., FOTT B. The internal waters. Volume 26, The phytoplankton of the freshwater. 7 part, 1st half, Chlorophyceae (green algae), order: Chlorococcales. E. Schweizerbart's publishing book. (Die binnnengewässer. Band 26, Das phytoplankton des süßwassers. 7 Teil, 1. Hälfte, Chlorophyceae (Grünalgen), Ordnung: Chlorococcales. E. Schweizerbart’sche Verlagsbuchhandlung), Stuttgart, 1, 1983 [In German]
• 31. KRAMMER K., LANGE-BERTALOT H. Bacillariophyceae. Part 1-4. Freshwater flora from middleeuropa. (Bacillariophyceae. 1-4 Teil. Süsswasserflora von Mitteleuropa). H. Ettl, J. Gerloff, H. Heynig, and D. Mollenhauer (editors). FischerVerlag, Stuttgart, Germany, 1986-2004 [In German].
• 32. KOMAREK J, ANAGNOSTIDIS K. Cyanoprokariota. 2. Teil: Oscillatoriales. In: Büdel B, Gärtner G, Krienitz L, Schagerl M(eds) Süßwasserflora von Mitteleuropa. Elsevier, Heidelberg, 2005.
• 33. HINDAK F. Colour Atlas of Cyanophytes. VEDA, Bratislava, 253, 2008.
• 34. KRISTIANSEN J., PREISIG H.R. Phylum Chrysophyta (Golden Algae). In: The freshwater algal flora of the British Isles. An identification guide to freshwater and terrestrial algae. Second edition. (John, D.M., Whitton, B.A. & Brook, A.J. Eds), Cambridge: Cambridge University Press 2011.
• 35. GUIRY M.D., GUIRY, G.M. AlgaeBase. World-wide electronic publication, National University of Ireland, Galway. http://www.algaebase.org; 2017. searched on 31 January 2017.
• 36. NUSCH E. Comparison of different methods for chlorophyll and phaeopigment determination. Archiv für Hydrobiologie -BeiheftErgebnisse der Limnologie, 14, 14-36. 1980.
• 37. APHA, AWWA, & WEF. 10300 Periphyton. Standard Methods for the Examination of Water and Wastewater, 22nd ed. American Public Health Association, Washington, D.C., 2012.
• 38. ROS J., Ecology Pratices (Práticas de ecologia). Barcelona, Editora Omega, 181, 1979 [in Portugese].
• 39. BICUDO C., MENEZES M. Genera of Brazilian freshwater algae (Gêneros de algas de águas continentais do Brasil. (Chave de identificação e descrições)). São Carlos, RIMA, 489, 2006 [in Portugese].
• 40. HILLEBRAND H., DÜRSELEN C., KIRSCHTEL D., POLLINGHER U., ZOHARY T. Biovolume calculation for pelagic and benthic microalgae. Journal of Phycology, 35 (2), 403, 1999.
• 41. SUN J., LIU D. Geometric models for calculating cell biovolume and surface area for phytoplankton. Journal of Plankton Research, 25 (11), 1331, 2003.
• 42. SPSS 22.0 IBM Corp. Released IBM SPSS Statistics for Windows, Version 22.0. Armonk, NY: IBM Corp., 2013.
• 43. ADDINSOFT, XLSTAT. Data analysis and statistics with MS Excel. Addinsoft, NY, USA. xlstat available at http://www.xlstat.com/en/home, 2015.
• 44. BAYLEY S.E. WONG A.S., THOMPSON J.E. Effects of agricultural encroachment and drought on wetlands and shallow lakes in the boreal transition zone of Canada. Wetlands, 33 (1), 17, 2013.
• 45. HANSON M.A., HERWIG B.R., ZIMMER K.D, HANSEL-WELCH N. Rehabilitation of shallow lakes: time to adjust expectations? Hydrobiologia, 787 (1), 45, 2017.
• 46. NIVOLIANITOU Z., SYNODINOU B. Environmental Management of Big Riverine Floods: The Case of Evros River in Greece. Advances in Environmental Science and Sustainability, 5th Proceedings Book; 15, 2012.
• 47. GRAHAM L.E., GRAHAM M., WILCOX L.W. Algae. Prentice-Hall, Inc., Upper Saddle River, New Jersey. 616, 2009.
• 48. ÖTERLER B., ALBAY M., ÇAMUR ELİPEK B., GÜHER H., KIRGIZ T. Spatial and temporal distribution of phytoplankton in Lake Gala (Edirne/TURKEY). Trakya University Journal of Natural Sciences, 16 (2), 71, 2015.
• 49. CANO M., CASCO M., CLAPS M. Effect of environmental variables on epiphyton in a Pampean lake with stable turbid-and clear-water states. Aquatic Biology, 15 (1), 47, 2012.
• 50. MESSYASZ B., RYBAK A. The distribution of green algae species from the Enteromorpha genera [syn. Ulva; Chlorophyta] in Polish inland waters. Oceanological and Hydrobiological Studies, 38 (1), 121, 2009.
• 51. HÁJEK F., POULÍČKOVA A., VAŠUTOVÁ M., SYROVÁTKA V., JIROUŠEK M., ŠTEPÁNKOVÁ J., OPRAVILOVÁ V., HÁJKOVÁ P. Small ones and big ones: cross-taxon congruence reflects organism body size in ombrotrophic bogs. Hydrobiologia, 726, 95, 2014.
• 52. KOLLÁR J., FRÁNKOVÁ M., HAŠLER P., LETÁKOVÁ M., POULÍČKOVÁ A. Epiphytic diatoms in lotic and lentic waters-diversity and representation of species complexes. Fottea, 15, 259, 2015.
• 53. TUNCA H., ONGUN-SEVİNDİK T., BAL D.N., ARABACI S. Community structure of epiphytic algae on different macrophytes ar Acarlar floodplain forest (Northern Turkey). Chinese Journal of Oceanology and Limnology, 32 (4), 845, 2014.
• 54. CANO M.G., CASCO M.A., CLAPS M.C. Epipelon dynamics in a shallow lake through a turbid-and a clear-water regime. Journal of Limnology, 75 (2), 355, 2016.
• 55. HINOJOSA-GARRO D., MASON C.F., UNDERWOOD G.J.C. Influence of macrophyte spatial architecture on periphyton and macroinvertebrate community in shallow water bodies under contrasting management. Fundamentals of Applied Limnology, 177 (1), 19, 2010.
• 56. CANTONATI M., ANGELI N., BERTUZZI E., SPITALE D., LANGE-BERTALOT H. Diatoms in springs of the Alps: spring types, environmental determinants, and substratum. Freshwater Science, 31, 499, 2012.
• 57. CANO M.G., CASCO M.A., CLAPS M.C. Epipelon dynamics in a shallow lake through a turbid-and a clear-water regime. PAGEPress Publications, 2016.
• 58. FERNANDES U.L., DE OLIVEIRA E.C.C., LACERDA S.R. Role of macrophyte life forms in driving periphytic microalgal assemblages in a Brazilian reservoir. Journal of limnology, 75 (1), 44, 2016.
• 59. VERHULST S. Response of the Epiphytic Algal Communities to Experimentally Elevated Nutrient Levels in Intertidal Salt Marsh Habitats. M.Sc. Thesis, University of North Florida, USA, 435, 2013.
• 60. De NICOLA D.M., KELLY M. Role of periphyton in ecological assessment of lakes. Freshwater Science, 33, 619, 2014.
• 61. TRIEST L., LUNGAYIA H., NDIRITU G., BEYENE A. Epilithic diatoms as indicators in tropical African rivers (Lake Victoria catchment). Hydrobiologia, 695 (1), 343, 2012.
• 62. ZHANG N, FAN Y., LIU Y. Relationship between diatom communities and environmental conditions at Honghe wetland, China. African Journal of Biotechnology, 10 (76), 17506, 2011.
• 63. LIU Y., HUI H.K., SUN C.M., FAN Y.W. Using diatom assemblage to assess the water quality in Heilongjiang river (Heihe part). Frontiers of Energy and Environmental Engineering, Edited by Wen-Pei Sung, Jimmy C. M. Kao and Ran Chen, CRC Press, 55, 2012.
• 64. BLINN D., HERBST D. Use of diatoms and soft algae as indicators of environmental determinants in the Lahontan Basin, USA. Annual Report for California State Water Resources Board Contract Agreement 704558.01CT766. - 25 + 10 pp., USA, 2003.
• 65. MIRANDA J., KRISHNAKUMAR G. Microalgal diversity in relation to the physicochemical parameters of some Industrial sites in Mangalore, South India. Environmental Monitoring and Assessment, 187 (11), 664, 2015.
• 66. FIDLEROVÁ D., HLÚBIKOVÁ D. Relationships between benthic diatom assemblages’ structure and selected environmental parameters in Slovak water reservoirs (Slovakia, Europe). Knowledge and management of aquatic ecosystems, 417, 27, 2016.
• 67. HÁJKOVÁ P., BOJKOVÁ J., FRÁNKOVÁ M., OPRAVILOVÁ V., HÁJEK M., KINTROVÁ K., HORSÁK M. Disentangling the effects of water chemistry and substrastum structure on moss-dwelling unicellular and multicellular microorganisms in spring fens, Journal of Limnology, 1, 54, 2011.

Identyfikatory

DOI

10.15244/pjoes/70232