Abstract
The seasonal variation in periphyton dynamics has been studied upon artificial substratum (microscopic glass slides) under various light conditions during the periods May–October 1986 and May–September 1987, in Lake Veluwe. Some additional observations on the periphyton development upon leaves of Potamogeton pectinatus L. have been made simultaneously. Four different light conditions were created in an experimental setup by manipulating the photon flux density through artificial shading.
Periphyton upon artificial substratum exhibited a relatively high abundance with a distinct seasonal pattern. Periphyton accrual rates were highest at the beginning of June and in August and September upon slides which were incubated for two weeks. Periphyton mass increased during May and June, decreased or remained about the same during July and subsequently increased until an upper plateau was reached upon slides which were incubated from the beginning of May onwards.
Generally, periphyton mass was lower upon slides than upon P. pectinatus. The seasonal variation in periphyton mass was more pronounced upon P. pectinatus leaves than upon the slides.
Attenuation by periphyton upon slides ranged from 5 to 65% after two weeks of incubation. Periphyton upon slides which had been incubated for more than two weeks demonstrated an attenuation of more than 85%.
Water quality parameters other than photon flux density were probably more important in determining the periphyton dynamics, since only minor differences were observed in periphyton mass between the various light conditions. Chlorophyll-a content was higher with increased shading on various sampling dates.
Periphyton, especially ‘older’ periphyton consisted largely of settled silt and clay particles and to a lesser extent of detrital matter on both substrata. Living epiphytes were only a relatively small fraction.
It is concluded that a reduction of resuspension of sediment particles, giving less suspended matter in the water column, will result in lower periphytic mass. Consequently, the quantity of photosynthetically active radiation reaching the submerged macrophytes is expected to increase considerably.
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References
Anderson, M. G., 1978. Distribution and production of sago pondweed (Potamogeton pectinatus L.) on a northern prairie marsh. Ecology 59: 154–160.
Blindow, I., 1987. The composition and density of epiphyton on several species of submerged macrophytes — the neutral substrate hypothesis tested. Aquat. Bot. 29: 157–168.
Borum, J., 1985. Development of epiphytic communities on eelgrass (Zostera marina) along a nutrient gradient in a Danish estuary. Mar. Biol. 87: 211–218.
Borum, J. & S. Wium-Andersen, 1980. Biomass and production of epiphytes on eelgrass (Zostera marine L.) in the Oresund, Denmark. Ophelia, suppl. 1: 57–64.
Bothwell, M. L., 1988. Growth rate responses of lotic periphytic diatoms to experimental phosphorus enrichment: the influence of temperature and light. Can. J. Fish. aquat. Sci. 45: 261–270.
Brönmark, C., 1985. Interactions between macrophytes, epiphytes and herbivores: an experimental approach. Oikos 45: 26–30.
Bulthuis, D. A. & W. J. Woelkerling, 1983. Biomass accumulation and shading effects of epiphytes on the leaves of Heterozostera tasmanica, in Victoria, Australia. Aquat. Bot. 16: 137–140.
Bushong, S. J. & R. W. Bachmann, 1989. In situ nutrient enrichment experiments with periphyton in agricultural streams. Hydrobiologia 178: 1–10.
Castenholz, R. W., 1961. An evaluation of a submerged glass method of estimating production of attached algae. Verh. int. Ver. Limnol. 14: 155–159.
Cattaneo, A. & J. Kalff, 1978. Seasonal changes in the epiphytic community of natural and artificial aquatic plants: a study of interactions between epiphytes and their substrate. Limnol. Occanogr. 24: 1031–1037.
Cattaneo, A. & J. Kalff, 1979. Primary production of algae growing on natural and artificial aquatic plants: a study of interactions between epiphytes and their substrate. Limnol. Oceanogr. 24: 1034–1037.
Cattaneo, A., 1987. Periphyton in lakes of different trophy. Can. J. Fish. aquat. Sci. 44: 296–303.
Dor, I., 1970. Production rate of the periphyton in Lake Tiberias as measured by the glass-slide method. Israel J. Bot. 19: 1–15.
Eminson, D. & G. Phillips, 1978. A laboratory experiment to examine the effects of nutrient enrichment on macrophyte and epiphyte growth. Verb. int. Ver. Limnol. 20: 82–87.
Eminson, D. & B. Moss, 1980. The composition and ecology of periphyton communities in freshwaters 1. The influence of host type and external environment on community composition. Br. Phycol. J. 15: 429–446.
Gons, H. J., 1982. Structural and functional characteristics of epiphyton and epipelon in relation to their distribution in Lake Vechten. In R. D. Gulati & S. Parma (eds), Studies on Lake Vechten and Tjeukemeer, The Netherlands. Developments in Hydrobiology 11. Dr W. Junk Publishers, The Hague: 79–114.
Gough, S. B. & L. P. Gough, 1981. Comment on ‘Primary production of algae growing on natural and artificial plants: a study of interactions between epiphytes and their substrate’ (Cattaneo & Kalff). Limnol. Occanogr. 26: 987–988.
Hansson, L. A., 1989. The influence of a periphytic biolayer on phosphorus exchange between substrate and water. Arch. Hydrobiol. 115: 21–26.
Hooper-Reid, N. M. & G. G. C. Robinson, 1978. Seasonal dynamics of epiphytic algal growth in a marsh pond: productivity, standing crop, and community composition. Can. J. Bot. 56: 2434–2440.
Hootsmans, M. J. M. & J. E. Vermaat, 1985. The effect of periphyton-grazing by three epifaunal species on the growth of Zostera marina L. under experimental conditions. Aquat. Bot. 22: 83–88.
Howard-Williams, C. & B. R. Davies, 1978. The influence of periphyton on the surface structure of a Potamogeton pectinatus L. leaf (a hypothesis). Aquat. Bot. 5: 87–91.
Hunter, R. D., 1980. Effects of grazing on the quantity and quality of freshwater aufwuchs. Hydrobiologia 69: 251–259.
Hurlbert, S. H., 1984. Pseudoreplication and the design of ecological field experiments. Ecol. Monogr. 54: 187–211.
Jenkerson, C. G. & M. Hickman, 1986. Interrelationships between the epipelon, epiphyton and phytoplankton in a eutrophic lake. Int. Revue ges. Hydrobiol. 71: 557–579.
Kaireselo, T., 1983. Photosynthesis and respiration within an Equisetum fluviatile L. stand in Lake Päädjärvi southern Finland. Arch. Hydrobiol. 96: 317–328.
Kaireselo, T., 1984. The seasonal succession of epiphytic communities within an Equisetum fluviatile L. stand in Lake Pääjärvi, Southern Finland. Int. Revue ges. Hydrobiol. 69: 475–505.
Kirk, J. T. O., 1983. Light and photosynthesis in aquatic ecosystems. Cambridge University Press, 401 pp.
Losee, R. F. & R. G. Wetzel, 1983. Selective light attenuation by the periphyton complex. In Wetzel, R. G. (ed.), Periphyton of Freshwater Ecosystems. Developments in Hydrobiology 17. Dr W. Junk Publishers, The Hague.
Mason, C. F. & R. J. Bryant, 1975. Periphyton production and grazing by chironomids in Alderfen Broad, Norfolk. Freshwat. Biol. 5: 271–277.
Meier, P. G., D. O'Connor & D. Dilks, 1983. Artificial substrata for reducing periphytic variability on replicated samples. In Wetzel, R. G. (ed.), Periphyton of Freshwater Ecosystems. Developments in Hydrobiology 17. Dr W. Junk Publishers, The Hague.
Meulemans, J. T. & F. Heinis, 1983. Biomass and production of periphyton attached to dead reed stems in Lake Maarsseveen. In Wetzel, R. G. (ed.), Periphyton of Freshwater Ecosystems. Developments in Hydrobiology 17. Dr W. Junk Publishers, The Hague.
Meulemans, J. T. & P. J. Roos, 1985. Structure and architecture of the periphytic community on dead reed stems in Lake Maarsseveen. Arch. Hydrobiol. 102: 487–502.
Meulemans, J. T., 1988. Seasonal changes in biomass and production of periphyton growing upon reed in Lake Maarsseveen I. Arch. Hydrobiol. 112: 21–42.
Meulemans, J. T., 1989. A method for measuring selective light attenuation within a periphytic community. In Meulemans, J. T. (ed.), Reed and periphyton in Lake Maarsseveen I, structural and functional aspects. Thesis, University of Amsterdam, The Netherlands, 129 pp.
Moed, J. R. & G. M. Hallegraef, 1978. Some problems in the estimation of chlorophyll-a and pheopigments from pre- and post-acidification spectrophotometric measurements. Int. Revue ges. Hydrobiol. 63: 787–800.
Moss, B., 1981. The composition and ecology of periphyton communities in freshwaters. II. Inter-relationships between water chemistry, phytoplankton populations and periphyton populations in a shallow lake and associated experimental reservoirs (‘Lund tubes’). Br. phycol. J. 16: 59–76.
Munn, D. J., I. L. Osborne & M. J. Wiley, 1989. Factors influencing periphyton growth in agricultural streams of central Illinois. Hydrobiologia 174: 89–97.
Otten, J. H. & M. T. M. Willemse, 1988. First steps: periphyton. Arch. Hydrobiol. 112: 127–195.
Phillips, G. L., D. Eminson & B. Moss, 1978. A mechanism to account for macrophyte decline in progressively eutrophicated freshwaters. Aquat. Bot. 4: 103–126.
Roos, P. J., 1983. Dynamics of periphytic communities. In Wetzel, R. G. (ed.), Periphyton of Freshwater Ecosystems. Developments in Hydrobiology 17. Dr W. Junk Publishers, The Hague.
Sand-Jensen, K., 1977. Effects of epiphytes on eelgrass photosynthesis. Aquat. Bot. 3: 55–63.
Sand-Jensen, K., 1983. Physical and chemical parameters regulating growth of periphytic communities. In Wetzel, R. G. (ed.), Periphyton of Freshwater Ecosystems. Developments in Hydrobiology 17. Dr W. Junk Publishers, The Hague: 89–96.
Sand-Jensen, K. & M. Søndergaard, 1981. Phytoplankton and epiphytic development and their shading effect on submerged macrophytes in lakes of different nutrient status. Int. Revue ges. Hydrobiol. 66: 529–552.
SAS Institute Inc., 1985. SAS/STATtm Guide for personal computers, version 6 Edition. SAS Institute Inc. Cary, NC USA, 378 pp.
Schiemer, F. & M. Prosser, 1976. Distribution and biomass of submerged macrophytes in Neusiedlersee. Aquat. Bot. 2: 289–307.
Sumner, W. T. & C. D. McIntire, 1982. Grazer- periphyton interactions in laboratory streams. Arch. Hydrobiol. 93: 135–157.
Van Dijk, G. M., 1992. Impact of light climate history on seasonal dynamics of a field population of Potamogeton pectinatus L. during a three year period (1986–1988). Aquat. Bot. (in press).
Van Dijk, G. M. & E. P. Achterberg, 1992. Light climate in the water column of a shallow eutrophic lake (Lake Veluwe) in The Netherlands. Arch. Hydrobiol. (in press).
Vernon, L. P., 1960. Spectrophotometric determination of chlorophyll and pheophytins in plant extracts. Anal. Chem. 32: 1144–1150.
Wetzel, R. G., 1983. Opening remarks. In Wetzel, R. G. (ed.), Periphyton of Freshwater Ecosystems. Developments in Hydrobiology 17. Dr W. Junk Publishers, The Hague.
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van Dijk, G.M. Dynamics and attenuation characteristics of periphyton upon artificial substratum under various light conditions and some additional observations on periphyton upon Potamogeton pectinatus L.. Hydrobiologia 252, 143–161 (1993). https://doi.org/10.1007/BF00008152
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DOI: https://doi.org/10.1007/BF00008152