Abstract
A comparative analysis of the phytoplankton of 27 lakes of three Lake Districts (Karelian Isthmus, Latgalian Elevation and Bolshezemelskaja Tundra), all situated at high temperate (60 and 56 ° N) and subarctic (67–68 °N) latitudes with a wide range of the trophy, is presented. A direct correlation between TP content and phytoplankton biomass was observed in all three regions. As the mean annual TP concentrations range from 10 to 137 mg m-3, the variation of average biomass for a growing season was 0.4–20 g m-3. The total number of phytoplankton species found in individual lakes varied from 25 to 160, increasing along the trophic gradient. The largest number of phytoplankton species was found in lakes supporting mean biomass in the range 10–20 g m-3. Taxonomic diversity decreased in some hypertrophic polluted lakes and in acidic lakes. In lakes of all regions, the number of species of chlorophyte, blue-green and euglenophyte algae increased with lake trophy. Analyses of distribution and ecology of mass species shows that in spite of the influence of latitudinal factors, such as the mineral content of lake waters the succession of dominant phytoplankton species show consistent trends: more cosmopolitan species with wide ecological amplitudes accompany the trophic gradient. Step-wise regression analyses showed that trophic factor had the greatest influence on the total phytoplankton biomass and biomass of blue-greens, chlorophytes and euglenophytes. Biomass of dinoflagellates and chrysophytes was influenced considerably more by total ionic concentration than by the trophic factor. The most important factor for diatoms was lake morphometry. Biomass of nanoplankton algae was influenced by trophic factors but also by lake depth.
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References
Ahlgren, G., 1978. Response of phytoplankton and primary production to reduced nutrient loading in Lake Norrviken. Verh. int. Ver. Limnol. 20: 840–845.
Brook, A. J., 1965. Planktonic algae as indicators of lake types with special reference to the Desmidiaceae. Limnol. Oceanogr. 10: 403–411.
Eloranta, P., 1978. Effects of size of sample counted in phytoplankton analyses. Ann. bot. fenn. 15: 169–176.
Edmondson, W. T., 1969. Eutrophication in North America. In Eutrophication, causes, consequences, correctives. Washington: 124–149.
Gibson, C. E., 1986. Preliminary results on phosphorus reduction in Lough Neagh – Assessing the effect against a background of change. Hydrobiol. Bull. 20: 173–182.
Guseva, K. A., 1952. ‘Water-bloom’, its causes, prediction and measures of prevention. Tr. Vses. Gidrobiol. Obsch. Moscow: 3–94 (In Russian).
Guseva, K. A., 1959. Methods of phytoplankton counting. Tr. Inst. Biol. Vodochr. 2: 44–51 (In Russian).
Guseva, K. A., 1965. Role of bluegreen algae in water-bodies and factors of their mass development. In Ecology and physiology of bluegreen algae. Nauka Publ. House, Moskow: 36–42 (in Russian).
Heinonen, P., 1980. Quantity and composition of phytoplankton in Finnish Inland waters. Vesihallitus – National Board of waters, Finland, Helsinki. 91 pp.
Hutchinson, G. E., 1967. A Treatise on Limnology, II. Introduction to lake biology and the limnoplankton. Wiley Intersci. Publ., New York, 1115 pp.
Järnefelt, H., 1953. Plankton als Indikator der Trophiegruppen der Seen. Ann. Acad. Sci. Fenn, 18: 1–29.
Kalff, J. & R. Knoechel, 1978. Phytoplankton and their dynamics in oligotrophic and eutrophic lakes. Ann. Rev. Ecol. Syst. 9: 475– 495.
Kalf, J. & S. Watson, 1986. Phytoplankton and its dynamics in two tropical lakes: a tropical and temperate zone comparison. Hydrobiologia 138: 161–176.
Kristiansen, J., 1977. A survey of investigation of freshwater phytoplankton in Denmark. Folia Limnol. Scand. 17: 37–44.
Kristiansen, J., 1986. Phytoplankton in eutrophic lakes – community structure and succession. In Riemann B. & M. Sondergaard (eds), Carbon Dynamics in Eutrophic Temperate Lakes. Elsevier: 28– 40.
Lund, J. W. G., 1969. Phytoplankton. In Eutrophication, causes, consequences, correctives. Washington: 306–330.
Mikheeva, T. M., 1975. Evaluation of phytoplankton biomass values in lakes of the whole world. Hydrobiol. J. Kiev 11: 90–104 (In Russian).
Nygaard, G., 1956. Phytoplankton. Folia Limnol. scand. 8: 32–144.
Odum, E. P., 1971. Fundamentals of ecology. Saunders, Philadelphia.
Pavoni, M., 1963. Die Bedeutung des Nannoplanktons im Vergleich zum Netzplankton. Schweiz. Z. Hydrol. 25: 219–341.
Pearsall, W. H., 1932. Phytoplankton in the English lakes. II. The composition of the phytoplankton in relation to dissolved substances. J. Ecol. 20: 241–262.
Reynolds, C. S., 1984. The ecology of freshwater phytoplankton. Cambridge University press, Cambridge, 384 pp.
Rodhe, W., 1969. Crystallisation of eutrophication concept in northern Europe. In Eutrophication, causes, consequenses, correctives. Washington: 50–64.
Rott, E., 1984. Phytoplankton as biological parameter for the trophic characterisation of lakes. Verh. int. Ver. Limnol. 22: 1078–1085.
Sakamoto, M., 1966. Primary production by phytoplankton community in some Japanese lakes and its dependence on lake depth. Arch. Hydrobiol. 62: 1–28.
Safonova T. A. & V. I. Ermolaev, 1983. Algae of water-bodies of the lake Tchani system. Nauka Publ. House, Novosibirsk (in Russian).
Smith, V. N., 1982. The nitrogen and phosphorus dependence of algal biomass in lakes: an empirical and theoretical analysis. Limnol. Oceanogr. 27: 1101–1112.
Sommer, U., 1986. The periodicity of phytoplankton in Lake Constance (Bodensee) in comparison to other deep lakes of central Europe. Hydrobiologia 138: 1–7.
Skulberg, O. M., 1980. Blue-green algae in lake Mj∅sa and other Norwegian lakes. Progr. Water Technol. 12: 121–140.
Spodniewska, I., 1978. Phytoplankton as the indicator of lake eutrophication. I. Summer situation in 34 Masurian lakes in 1973. Ekol. Polska 26: 53–70.
Stoermer, E. F., 1978. Phytoplankton assemblages as indicators of water quality in Laurentian Great Lakes. Trans. am. Microsc. Soc. 97: 2–16.
Trifonova, I. S., 1979. Species composition and productivity of phytoplankton in Karelian Isthmus lakes of different type. Nauka Publ. House, Leningrad, 168 pp. (In Russian).
Trifonova, I. S., 1986. Seasonal and general succession of lake phytoplankton. Hydrobiol. J. Kiev, 23: 21–28 (In Russian).
Trifonova, I. S., 1988. Oligotrophic-eutrophic succession of lake phytoplankton. In: Round F. (ed), Algae and aquatic environment. Biopress, Bristol: 107–124.
Trifonova, I. S., 1989. Changes in community structure and productivity of phytoplankton as indicators of lake and reservoirs eutrophication. Arch. Hydrobiol. Beih. Ergebn. Limnol. 33: 363– 371.
Trifonova, I. S., 1990. Ecology and succession of lake phytoplankton. Nauka Publ. House, Leningrad, 174 pp. (In Russian).
Vollenweider, R. A. & J. Kerekes, 1980. The loading concept as basis for controlling eutrophication phylosophy and preliminary results of the OECD programme on eutrophication. Progr. Wat. Technol. 12: 5–38.
Willén, E., 1979. Water quality and phytoplankton in two large Swedish lakes. Acta Bot. Fenn. 110: 81–85.
Willén, T., 1975. Biological long-term investigation of Swedish lakes. Verh. int. Ver. Limnol. 19: 1117–1124.
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Trifonova, I. Phytoplankton composition and biomass structure in relation to trophic gradient in some temperate and subarctic lakes of north-western Russia and the Prebaltic. Hydrobiologia 369, 99–108 (1998). https://doi.org/10.1023/A:1017074615932
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DOI: https://doi.org/10.1023/A:1017074615932