Abstract
The annual cycle of phytoplankton in saline, meromictic Ace Lake (68°2S.4′S, 78°11.1′E) in the Vestfold Hills, Antarctica, was studied from January, 1979 to January 1980. Ace Lake has permanent gradients of temperature, salinity, dissolved oxygen, and hydrogen sulphide, and is ice covered with up to 2 m of ice for 10–12 months each year. The phytoplankton community had low diversity, consisting of only four species, all flagellates — a prasinophyte Pyramimonas gelidicola McFadden et al., a cryptophyte of the genus Cryptomonas; an unidentified colourless microflagellate, and an unarmoured dinoflagellate. These were restricted to the oxic zone of the lake from the surface to 10 m.
The phytoplankton had a cycle of seven months of active growth over spring and summer. Low numbers of cells survived in the water column over winter. Spring growth was initiated below the ice by increased light penetration through the ice into the lake, enhanced at the time by the removal of surface snow which accumulated on the ice over winter. Peak phytoplankton biomass production was by the shade adapted P. gelidicola and occurred at the interface of the oxic and anoxic zones where substantial available nitrogen as ammonia is found.
The three dominant phytoplankton species displayed distinct vertical stratification over the oxic zone. This stratification was not static and developed over spring as the flagellates migrated to preferred light climate zones. Mean cell volume of two of the flagellates varied significantly over the year. Minimum volumes were recorded in winter and volume increased progressively over spring to reach maximum mean cell volume in summer. Mean cell volume was positively correlated with light intensity (maximum ambient PAR at the respective depth for date of sample). Low cell volume in winter may be related to winter utilization of carbohydrate reserves by slow respiration, and may represent a survival mechanism.
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References
Adams, W. A., 1978. Effects of ice cover on the solar radiation regime in Canadian lakes. Verh. int. Ver. Limnol. 20: 141–149.
APHA, 1981. Standard methods for the examination of water and wastewater. APHA-AWWA-WPCF, Washington; 1134 pp.
Bayly, I. A. E. & H. R. Burton, 1987. Vertical distribution of Paralabidocera antarctica (Copepoda: Calanoida) in Ace Lake, Antarctica, in summer. Aust. J. mar. Freshwat. Res. 38: 537–543.
Brettum, P., 1972. The phytoplankton of the Lake Övre Heimdalsvatn, central south Norway, 1969–70. Norw. J. Bot. 19: 79–90.
Burke, C. M. & H. R. Burton, this volume. The ecology of photosynthetic bacteria in Burton Lake, Vestfold Hills, Antarctica. Hydrobiologia.
Burton, H. R., 1980. Methane in a saline antarctic lake. In P. A. Trudinger & M. R. Walter (eds), Biogeochemistry of Ancient and Modern Environments. Proceedings of the Fourth International Symposium on Environmental Biogeochemistry (ISEB). Aust. Acad. Sci., Canberra: 243–251.
Burton, H. R. & R. J. Barker, 1979. Sulphur chemistry and microbiological fractionation of sulphur isotopes in a saline antarctic lake. Geomicrobiol. J. 1: 329–340.
Ferris, J. M. & H. R. Burton, this volume. The annual cycle of heat content and mechanical stability of hypersaline Deep Lake, Vestfold Hills, Antarctica. Hydrobiologia.
Goldman, C. R., D. T. Mason & J. E. Hobbie, 1967. Two antarctic desert lakes. Limnol. Oceanogr. 12: 295–310.
Hand, R. M., 1980. Bacterial populations of two saline antarctic lakes. In P. A. Trudinger & M. R. Walter (eds), Biogeochemistry of Ancient and Modern Environments. Proceedings of the Fourth International Symposium on Environmental Biogeochemistry (ISEB). Aust. Acad. Sci., Canberra: 123–129.
Hand, R. M. & H. R. Burton, 1981. Microbial ecology of an antarctic saline meromictic lake. Hydrobiologia 82: 363–374.
Hawes, I., 1983. Turbulence and its consequences for phytoplankton development in two ice covered antarctic lakes. Br. Antarct. Surv. Bull. 60: 69–81.
Heath, C. W., this volume. Annual primary productivity of an antarctic continental lake: phytoplankton and benthic algal mat production strategies. Hydrobiologia.
Heywood, R. B., 1977. Antarctic freshwater ecosystems: review and synthesis. In G. A. Llano (ed.), Adaptations within Antarctic Ecosystems. Smithsonian Institution, Wash. DC: 801–828.
Hobbie, J. E., 1973. Arctic limnology: A review. In M. E. Britton (ed.), Alaskan Arctic Tundra. Tech. paper No. 25, Arctic Inst. of N. Amer.: 127–168.
Ilmavirta, V., 1974. Diel periodicity in the phytoplankton community of the oligotrophic lake Pääjärvi, southern Finland. I. Phytoplanktonic primary production and related factors. Ann. bot. fenn. 11: 136–177.
Ilmavirta, V., 1975. Diel periodicity of the phytoplankton community of the oligotrophic lake Paajarvi, southern Finland. II Late summer phytoplanktonic biomass. Ann. bot. fenn. 12: 37–44.
Jeffrey, S. W. & G. F. Humphrey, 1975. New spectrophotometric equations for determining chlorophylls a, b, c1 and c2 in higher plants, algae and natural phytoplankton. Biochem. Physiol. Pflanzen. 167: 191–194.
Johnstone, G. W., D. J. Lugg & D. A. Brown, 1973. The biology of the Vestfold Hills, Antarctica. ANARE Sci. Rep. Publ. 123. Antarct. Div., Dept. Sci., Melbourne, 62 pp.
Journal of Glaciology, 1958. Instruments and methods: Ice drills and corers. J. Glaciol. 3: 30.
Kalff, J., H. E., Welch & S. K. Holmgren, 1972. Pigment cycles in two high-arctic Canadian lakes. Verh. int. Ver. Limnol. 18: 250–256.
Kalff, J. & H. E. Welch, 1974. Phytoplankton production in Char Lake, a natural polar lake, and in Meretta Lake, a polluted polar lake, Cornwallis Island, Northwest Territories. J. Fish. Res. Bd Can. 31: 621–636.
Kantha, L. H., 1979. Turbulent entrainment at the bouyancy interface due to convective turbulence. In H. J. Freeland, D. M. Farmer & C. D. Levings (eds), Fjord Oceanography. Plenum Press, NY: 205–213.
Kirk, J. T. O., 1977. Use of quanta meter to measure attenuation and underwater reflectance of photosynthetically active radiation in some inland and coastal south-eastern Australian waters. Aust. J. mar. Freshwat. Res. 28: 9–21.
Kirk, J. T. O., 1983. Light and photosynthesis in aquatic ecosystems. Cambridge University Press, Cambridge, 401 pp.
Light, J. J., 1977. Production and periodicity of antarctic freshwater phytoplankton. In G. A. Llano (ed.) Adaptations within Antarctic Ecosystems. Smithsonian Institution, Wash., DC: 829–837.
Light, J. J., J. C. Ellis-Evans & J. Priddle, 1981. Phytoplankton ecology in an antarctic lake. Freshwat. Biol. 11: 11–26.
Lund, J. W. G., C. Kipling & E. D. LeCren, 1958. The inverted microscope method of estimating algal numbers and the statistical basis of estimations by counting. Hydrobiologia 11: 143–170.
Maeda, O. & S. Ichimura, 1973. On the high density of a phytoplankton population found in a lake under ice. Int. Revue ges. Hydrobiol. 58: 673–689.
Maykut, G. A. & T. C. Grenfell, 1975. The spectral distribution of light beneath first-year sea ice in the Arctic Ocean. Limnol. Oceanogr. 20: 554–563.
Morgan, K. & J. Kalff, 1975. The winter dark survival of an algal flagellate Cryptomonas erosa (Skuja). Verh. int. Ver. Limnol. 19: 2734–2740.
Parker, B. C., G. M. Simmons Jr., K. G. Seaburg, D. D. Cathey & F. C. T. Allnutt, 1982. Comparative ecology of plankton communities in seven antarctic oasis lakes. J. Plankton Res. 4: 271–286.
Pechlaner, R., 1971. Factors that control the production rate and biomass of phytoplankton in high-mountain lakes. Verh. int. Ver. Limnol. 19: 125–145.
Priddle J., 1980. The production ecology of benthic plants in some antarctic lakes. II. Laboratory physiology studies. J. Ecol. 68: 155–166.
Rodhe, W., 1955. Can plankton production proceed during winter darkness in subarctic lakes? Verh. int. Ver. Limnol. 12: 117–122.
Rodhe, W., J. E. Hobbie & R. T. Wright, 1966. Phototrophy and heterotrophy in high mountain lakes. Verh. int. Ver. Limnol. 16: 302–313.
Strickland, J. D. H. & T. R. Parsons, 1972. A practical handbook of seawater analysis. 2nd. Edition. Bull. Fish. Res. Bd. Can. 167: 310 pp.
Tilzer, M. M., 1973. Diurnal periodicity in the phytoplankton assemblage of a high mountain lake. Limnol. Oceanogr. 18: 15–30.
UNESCO, 1966. Determination of photosynthetic pigments in seawater. Report of SCOR-UNESCO Working group 17. Monographs on Oceanographic Methodology 1. UNESCO, Paris, 69 pp.
Vincent, W. F., 1981. Production strategies in antarctic inland waters: phytoplankton eco-physiology in a permanently icecovered lake. Ecology 62: 1215–1224.
Vincent, W. F. & C. L. Vincent, 1982. Factors controlling phytoplankton production in Lake Vanda (77°S). Can. J. Fish. aquat. Sci. 39: 1602–1609.
Welch, H. E. & J. Kalff, 1974. Benthic photosynthesis and respiration in Char Lake. J. Fish Res. Bd Can. 31: 609–620.
Willen, E., 1976. A simplified method of phytoplankton counting. Br. phycol. J. 11: 265–278.
Wright, S. W. & H. R. Burton, 1981. The biology of antarctic saline lakes. Hydrobiologia 82: 319–338.
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Burch, M.D. Annual cycle of phytoplankton in Ace Lake, an ice covered, saline meromictic lake. Hydrobiologia 165, 59–75 (1988). https://doi.org/10.1007/BF00025574
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DOI: https://doi.org/10.1007/BF00025574