The simultaneous effect of water depth and algae on the growth rate of submersed macrophytes was investigated in this study. Ceratophyllum demersum L. and Myriophyllum verticillatum L. were used as submersed macrophytes. A total of 54, 10 cm length, weighted individual shoots of each species were planted in square plastic pots, filled with lake sediment. All planted plastic pots were positioned in 30 litre capacity plastic buckets, with dechlorinated tap water added to depths of 20, 30 or 40 cm (each depth had three replicates) above the soil surface; 36 buckets were used and each bucket held three pots.The experiment contained two groups; Group I (G I) with 18 buckets containing only planted plastic pots of each species, and Group II (G II) with 18 buckets with plant + algal inoculum. Scenedesmus quadricauda (Turpin) de Brebisson was used as the added test alga. The RGR of C. demersum was found to differ significantly with the depth of the water in both GI and GII. Likewise, significant differences in RGR were found for M. verticillatum for all treatments in both groups. For both species, the no algae added group (GI) had a greater growth rate than the algae added group (GII) in all treatments  

Agami M., Waisel Y. 1985. Interrelationship between Najas marina L. and three other species of aquatic macrophytes. Hydrobiologia, 126: 169-173.

Aliotta G., Della Greca M., Monaco P., Pinto G., Pollio A., Previtera L. 1990. In vitro algal growth inhibition by phytotoxins of Typha latifolia L. Journal of Chemical Ecology, 16: 2637-2646.

APHA. 1999. Standard methods for the examination of waste and wastewater. 19th ed. American Public Health Association, Washington, D.C.

Fitzgerald G.P. 1969. Some factors in the competition or antagonism among bacteria, algae and aquatic weeds. Journal of Phycology, 5: 531-539.

Grace J.B., Wetzel R.G. 1978. The production biology of Eurasian watermilfoil (Myriophyllum spicatum L.): a review. Journal of Aquatic Plant Management, 16: 1-11.

Gross E.M., Meyer H., Schilling G. 1996. Release and ecological impact of algicidal hydrolysable polyphenols in Myriophyllum spicatum. Phytochemistry, 41: 133-138.

Huisman J., Weissing F.J. 1995. Competition for nutrients and light in mixed water column: A theoretical analysis. The American Naturalist, 146:536-564.

Hunt R. 1990. Plant growth Analysis. Studies in Biology No. 96. Edward Arnold Ltd., London, 112 p.

Jasser I. 1994. Influence of Ceratophyllum demersum on phytoplankton community in experimental conditions. Verhandlungen des Internationalen Verein Limnologie, 25: 2291-2295.

Jasser I. 1995. The influence of macrophytes on phytoplankton community in experimental conditions. Hydrobiologia, 306: 21-32.

Jeppesen E., Søndergaard M., Søndergaard M., Christoffersen K. 1998. The structuring role of submerged macrophytes in lakes: Ecological Studies 131. Springer, New York.

Jeppesen E., Jensen J.P., Søndergaard M., Lauridsen T., Landkildehus F. 2000. Trophic structure, species richness and biodiversity in Danish lakes: changes along a phosphorus gradient. Freshwater Biology, 45: 201-218.

Jones J.I. 1994. An ecophysiological study of the Elodea nuttallii-epiphyton association. PhD. University of Liverpool.

Kogan S.I., Chinnova G.A. 1972. Relations between Ceratophyllum demersum (L.) and some blue-green algae. Hydrobiological Journal, 8: 14-19 (21-27).

Madsen J.D., Sutherland J.W., Bloomfield L.W. 1991. The decline of native vegetation under dense Eurasion watermilfoil canopies. Journal of Aquatic Plant Management, 29: 94-99.

Minitab. 1996. Minitab Release 11 for Windows. Minitab Inc.

Nakai S., Inoue Y., Hosomi M., Murakami A. 2000. Myriophyllum spicatum-released allelopathic polyphenols inhibiting growth of blue-green algae Microcystis aeruginosa. Water Resources, 34: 3026-3032.

Planas D., Sarhan F., Dube L., Godmaire H. 1981. Ecological significance of phenolic compounds of Myriophyllum spicatum. Verhandlungen des Internationalen Verein Limnologie, 21. 1492-1496.

Phillips G.L., Eminson D., Moss, B. 1978. A mechanism to account for macrophyte decline in progressively eutrophicated freshwaters. Aquatic Botany, 4: 103-126.

Saito K., Matsumota M., Sekine T., Murakoshi I. 1989. Inhibitory substances from Myriophyllum brasillense on growth of blue-green algae. J. Nat. Prod., 52: 1221-1226.

Sayer C.D., Davidson T.A., Jones J.I. 2010. Seasonal dynamics of macrophytes and phytoplankton in shallow lakes: a eutrophication-driven pathway from plants to plankton? Freshwater Biology, 55: 500-513.

Scheffer M., de Redelijkheid M.R., Noppert F. 1992. Distribution and dynamics of submersed vegetation in a chain of shallow eutrophic lakes. Aquatic Bot., 42: 199-216.

Scheffer M., Hosper S.H., Meijer M.C., Moss B., Jeppesen E. 1993. Alternative equilibria in shallow lakes. Trends Ecol. Evol., 8: 275-279.

Scheffer M., Van den Berg M., Breukelaar A.W., Breukers C., Coops H., Doef R.W., Meijer M.-L. 1994 .Vegetated areas with clear water in turbid shallow lakes. Aquatic Botany, 49: 193–196.

Scheffer M., Jeppesen E. 1998. Alternative stable states. In: E. Jeppesen, M. Søndergaard M., Søndergaard K. Christoffersen (Eds.). The Structuring Role of Submerged Macrophytes in Lakes, Springer, New York. pp: 397-406.

Smith C.S., Barko J.W. 1990. Ecology of Eurasian watermilfoil. Journal of Aquatic Plant Management, 28: 55-64.

Spence D.H.N. 1967. Factors controlling the distribution of freshwater macrophytes, with particular reference to Scottish lochs. Journal of Ecology, 55: 147-170.

Spence D.H.N. 1972. Light on freshwater macrophytes. Botanical Society of Edingburg Transactions, 41:491-505

Spence D.H.N. 1976. Light and plant response in freshwater. In: G.C. Evans, R. Bainbridge, O. Rackham (Eds.). Light as an ecological factor. Oxford, Blackwell.

Talling J.F., Driver D. 1961. Some problems in the estimation of chlorophyll a in a phytoplankton. Proceedings of a conference on a primary productivity measurement in Marine and Freshwaters. MS. Doty. University of Hawaii, US Atomic Energy Commission Publication TID 7633.

Van Donk E., Gulati R.D. 1995. Transition of a lake to the turbid state six years after biomanipulation: mechanisms and pathways. Water Science and Technology, 32: 197–206.

Weisner S.E.B., Strand J.A., Sandsten H. 1997. Mechanisms regulating abundance of vegetation in shallow eutrophic lakes. Oecologia, 109: 592-599.

Wium-Andersen S., Anthoni U., Houen G. 1983. Elemental sulphur, a possible allelopathic compound from Ceratophyllum demersum. Photochemistry, 22: 2613.