Influence of land use patterns on some limnological characteristics in the south-eastern part of Lake Victoria, Tanzania

Authors

  • Salome D. Shayo Tanzania Fisheries Research Institute (TAFIRI), P.O. Box 78850, Dar es Salaam, Tanzania
  • Charles Lugomela Department of Aquatic Sciences and Fisheries, University of Dar es Salaam, P.O. Box 35064, Dar es Salaam, Tanzania
  • John F. Machiwa Department of Aquatic Sciences and Fisheries, University of Dar es Salaam, P.O. Box 35064, Dar es Salaam, Tanzania

Keywords:

limnology, human activities, phytoplankton, eutrophication, East African Great Lakes

Abstract

To investigate the influence of human activities on limnological characteristics of Lake Victoria, we analyzed inorganic nutrient concentrations, phytoplankton diversity and biomass at three locations with different land use patterns: Mwanza (urban/industrial), Magu (agricultural) and Kayenze (sparsely populated). Mwanza had significantly higher ammonia concentration compared to Kayenze and Magu. At the shoreline stations, significantly higher nitrate concentration was observed at Mwanza compared to Kayenze and Magu. Similarly, Mwanza had significantly higher concentrations of soluble reactive phosphorous in the shoreline stations compared to Magu and Kayenze, but not in the open waters stations. Shoreline stations also showed significant differences in phytoplankton diversity among sites. The shoreline station at Mwanza also showed significantly higher levels of Chl. a compared to those at Magu and Kayenze. However, in the open water stations Chl. a concentrations did not differ significantly among sites. The results suggested that urban pollution in Mwanza and agricultural activities in River Simiyu catchment strongly influence the limnology of Lake Victoria and that the nearshore waters, which are the receiving points, were highly impacted compared to the waters outside bays. Thus, proper urban waste management and sustainable land management practices are critical for reducing point and non-point sources of pollution into Lake Victoria.

References

Akiyama, T., Kajumulo, A. A. and Olsen, S. 1977. Seasonal variations of plankton and physicochemical condition in Mwanza Gulf, Lake Victoria. Bulletin of Freshwater Fisheries Research Laboratory, 27(2): 49–61.

APHA. 1995. Standards methods for examination of water and wastewater, 19th Edition, Washington, D.C: American Public Health Association.

Cocquyt, C., Vyerman, W. and Compere, P. 1993. A check list of algal flora of East African Great Lakes: Lake Malawi, Lake Tanganyika and Lake Victoria. National Batanic Garden of Belgium, Meise, 8: 1–55.

Hecky, R. E. 1993. The eutrophication of Lake Victoria. Verhandlungen de Internationale Vereinigung fur Theoretische und Angewandte Limnologie, 25: 39–48.

Kite, G. W. 1982. Analysis of Lake Victoria levels. Hydrology Science Journal, 27: 99–110.

Kling, H. J., Mugidde, R. and Hecky, R. E. 2001. “Recent changes in the phytoplankton community of Lake Victoria in response to eutrophication”. In Great Lakes of the World (GLOW): Food web, health and integrity, Edited by: Munawar, M. and Hecky, R. E. 47–65. Leiden, , The Netherlands: Backhuys Publishers.

Komárek, J. and Anagnostidis, K. 1985. Modern approach to the classification system of cyanophytes. 2 – Chroococcales. Algological Studies, 43: 157–226.

Lung’ayia, H., Sitoki, L. and Kenyanya, M. 2001. The nutrient enrichment of Lake Victoria (Kenyan waters). Hydrobiologia, 458: 75–82.

Mosille, O. Phytoplankton species of Lake Victoria. Report from Haplochromis ecology survey team (HEST) operating in Mwanza area of Lake Victoria. Zoologisch Laboratorium, Morphology Department, Leiden University. Leiden, The Netherlands.

Mugidde, R. 1993. Changes in phytoplankton primary productivity and biomass in Lake Victoria (Uganda). Verhandlungen Internationalis Vereingung Für Limnologie, 25: 846–849.

Odada, E. O., Olagao, D. O., Kulindawa, K., Ntiba, M. and Wandiga, S. 2004. Mitigation of the environmental problems in Lake Victoria, East Africa: Casual Chain and Policy Option Analysis. Ambio, 33: 13–23.

Rwetabula, J. 2007. Modeling the fate and transport of organic micro-pollutants and phosphates in the Simiyu River and Speke Gulf (Lake Victoria), Tanzania. PhD Dissertation, Vrije Universiteit Brussel.

Seeley, G. R. and Jensen, R. G. 1965. Effect of solvent on the spectrum of chlorophyll. Spectroch. Acta, 21: 1835–1845.

Talling, J. F. 1965. The photosynthetic activity of phytoplankton in East African Lakes. Final review, 50: 3–32.

Tamatamah, R. A., Hecky, R. E. and Duthie, H. C. 2005. The atmospheric deposition of phosphorus in Lake Victoria (East Africa). Biogeochemistry, 73: 325–344.

Utermöhl, H. 1958. Zur Vervollkommnung der quantitativen Phytoplankton methodik. (Improvement of quantitative methodology for phytoplankton. In German). Verhandlungen der Internationale Vereinigung für. Theoretische und Angewandte Limnologie, 2: 1–38.

Van Meel, L. 1954. Le phytoplancton. Résultats scientifiques de l’éxploration hydrobiologique du Lac Tanganyika (1946–1947). (Scientific results of the hydrobiological exploration of Lake Tanganyika. In French). Institut Royal des Sciences Naturalles de Belgique, 5: 571–586.

Worthington, E. B. 1930. Observations on the temperature, hydrogen-ion concentration, and other physical conditions of the Victoria and Albert Nyanzas. Sonderdruck aus Internat. Revue der ges. Hydrobiol. u. Hydrographie, Bd, 24: 329–357.

Downloads

Published

2011-07-01

Issue

Vol. 14 No. 3 (2011)

Section

Research article

License

Manuscripts must be original. They must not be published or be under consideration for publication elsewhere, in whole or in part. It is required that the lead author of accepted papers complete and sign the MSU Press AEHM Author Publishing Agreement and provide it to the publisher upon acceptance.