H. F. Mgana; A. Herzig; Y. D. Mgaya

Authors

H. F. Mgana Tanzania Fisheries Research Institute, Box 90, Kigoma, Tanzania
A. Herzig Neusiedler See Biological Station, Illmitz, Austria
Y. D. Mgaya Department of Aquatic Sciences and Fisheries, University of Dar es Salaam, Box 35064, Dar es Salaam, Tanzania

Keywords:

zooplankton, vertical distribution, selective predation

Abstract

Tropocyclops simplex abundance, diel distribution and the impact of the planktivore fish Stolothrissa tanganicae on the T. simplex population were studied at a deep-water site in Kigoma Bay, Lake Tanganyika during the wet period (October 2008–February 2009). The top 40 m were examined using discrete depth samples, filtered through a 40-μm mesh. Ovigerous and copepodids of Tropodiaptomus simplex exhibited a very clear diel vertical migration. Ovigerous females of Tropodiaptomus were negligibly low in the 0–30 m depth during the day, while at night they stayed above 20 m. Tropodiaptomus nauplii did not show any clear diel vertical migration. The contribution of adults, copepodite and nauplii stages to the total numbers of Tropodiaptomus simplex was 8.2, 8.6 and 83.2%, respectively. Stolothrissa tanganicae stomachs were analysed to quantify the contribution of zooplankton in their diets, which revealed a dominance of Tropodiaptomus females and the electivity indices proved that T. simplex females (with or without eggs) were highly selected by S. tanganicae, which could probably be explained by size-selective feeding. Life table analysis indicated that approximately 60% of T. simplex nauplii did not develop into copepodites, a loss which could not be explained by the results of the present study. 68% of the fish gut contents were contributed by female Tropodiaptomus individuals and the contribution of shrimps and Cyclopidae increased substantially to almost 20%. S. tanganicae consumed largely ovigerous Tropodiaptomus females. However, eggs found in the guts were significantly smaller than those found in the zooplankton discrete samples, suggesting that digestion had started. The calculated electivity indices underline that ovigerous and non ovigerous females of T. simplex are being positively selected in the feeding process. It infers existence of selective predation in L. Tanganyika by S. tanganicae on females of T. simplex (with or without eggs) and as a result distinct vertical migration as a predation escape mechanism is performed.

References

Chèné, G. 1975. Etude des problemes relatifs aux fluctuations piscicoles du lac Tanganika. Memoire de licence, Belgium: Universite de Liege. (Study of problems related to fish fluctuations of Lake Tanganyika. Bachelor Thesis. In French)

Chitamweba, D. B. R. 1999. Meromixis, stratification and internal waves in Kigoma waters of Lake Tanganyika. Hydrobiologia, 407: 59–64.

Coulter, G. W. 1991. Lake Tanganyika and its Life, Oxford: British Museum (Natural History) and Oxford University Press.

Descy, J-P., Hardy, M-A., Sténuite, S., Pirlot, S., Leporcq, B., Kimirei, I., Sekadende, B., Mwaitega, S. R. and Sinyenza, D. 2005. Phytoplankton pigments and community composition in Lake Tanganyika. Freshwater Biology, 50(4): 668–684.

Descy, J.-P., Tarbe, A.-L., Stenuite, S., Pirlot, S., Stimart, J., Vanderheyden, J., Leporcq, B., Stoyneva, M. P., Kimirei, I., Sinyinza, D. and Plisnier, P.-D. 2010. Drivers of phytoplankton diversity in Lake Tanganyika. Hydrobiologia, 653: 29–44.

Dumont, H. J. 1986. The Tanganyika sardine in Lake Kivu: Another ecodisaster for Africa?. Environmental Conservation, 13(02): 143–148.

Dumont, H. J. and Maas, S. 1988. On nine Tropodiaptomus-species (Copepoda, Calanoida) from equatorial East Africa. Hydrobiologia, 167/168: 415–427.

Dussart, B. H. and Defaye, D. 1995. Copepoda: Introduction to the Copepoda, The Hague: SPB Academic Publishing.

Harding, J. P. 1957. Crustacea: Cladocera. Résultats scientifiques de 1’exploration hydrobiologique du Lac Tanganyika (1946-47). (Crustacea: Cladocera. Scientific results of hydro biological exploration of Lake Tanganyika (1946-1947) In French.). Institut Royal des Sciences Naturelles de Belgique, 3: 53–89.

Herzig, A. 1983. The ecological significance of the relationship between temperature and duration of embryonic development in planktonic freshwater copepods. Hydrobiologia, 100: 65–91.

Hyvönen, K. 1997. Study on zooplankton development time at Lake Tanganyika. FAO/FINNIDA Research for the Management of the Fisheries of Lake Tanganyika. GCP/RAF/271/FIN-TD/78

Jacobs, J. 1974. Qualitative measurements of food selection. Oecologia, 14: 413–417.

Kiefer, F. 1956. Ruderfußkrebse Tanganjikasee aus dem See. (Copepods from Lake Tanganyika. In German. Rev. Zool. Bot. Africana, 54(3–4): 241–266.

Kurki, H., Vuorinen, I., Bosma, E. and Bwebwa, D. 1999a. Spatial and temporal changes in copepod zooplankton communities of Lake Tanganyika. Hydrobiologia, 407: 105–114.

Kurki, H., Mannini, P., Vuorinen, I., Aro, E., Mölsä, H. and Lindqvist, O. V. 1999b. Macrozooplankton communities in Lake Tanganyika indicate food chain differences between the northern part and the main basins. Hydrobiologia, 407: 123–129.

Lewis, W. M. 1996. “Tropical lakes: How latitude makes a difference”. In Perspectives in Tropical Limnology, Edited by: Schiemer, F. and Boland, K. T. 43–65. Amsterdam: SPB Acad. Publ..

Liu, Z. and Herzig, A. 1996. Food and feeding behaviour of a planktivorous cyprinid, Pelecus cultratus (L.), in a shallow eutrophic lake, Neusiedler See (Austria). Hydrobiologia, 333: 71–77.

Lo, W-T., Shih, C-T. and Hwang, J-S. 2004. Diel vertical migration of the planktonic copepods at an upwelling station north of Taiwan, western North Pacific. Journal of Plankton Research, 26(1): 89–97.

Mannini, P., Katonda, I., Kissaka, B. and Verburg, P. 1999. Feeding ecology of Lates stappersii in Lake Tanganyika. Hydrobiologia, 407: 131–139.

Marlier, G. 1957. Le Ndagala, poisson pélagique du Lac Tanganyika. (The Ndagala, pelagic fish from Lake Tanganyika. In French.). Bulletin agricole du Congo belge, 48(2): 409–422.

Mölsä, H., Reynolds, J. E., Coenen, E. J. and Lindqvist, O. V. 1999. Fisheries research towards resource management on Lake Tanganyika. Hydrobiologia, 407: 1–24.

Owili, M. A. and Omondi, R. 2003. “Predator-prey relationship between zooplankton and Rastrineobola argentea and juvenile Lates niloticus in the lake-river interface habitats in the Nyanza Gulf of Lake Victoria, Kenya”. In Lake Victoria Fisheries: Status, biodiversity and management, Edited by: Van der Knaap, M. and Munawar, M. 16Ontario, , Canada: Aquatic Ecosystems Health and Management Society. http://www.aehms.org/glow_lake_victoria.html

Plisnier, P.-D, Chitamwebwa, D., Mwape, L., Tshibangu, K., Langenberg, V. and Coenen, E. 1999. Limnological annual cycle inferred from physical-chemical fluctuations at three stations of Lake Tanganyika. Hydrobiologia, 407: 45–58.

Plisnier, P.-D., Mgana, H., Kimirei, I., Chande, A., Makasa, L., Chimanga, J., Zulu, F., Cocquyt, C., Horion, S., Bergamino, N., Naithani, J., Deleersnijder, E., André, L., Descy, J.-P and Cornet, Y. 2009. Limnological variability and pelagic fish abundance (Stolothrissa tanganicae and Lates stappersii) in Lake Tanganyika. Hydrobiologia, 625(1): 117–134.

Southwood, T. R. E. 1978. Ecological methods with particular reference to the study of Insect populations. 2nd Ed., Cambridge: The University Printing House.

Vuorinen, I. 1993. Sampling and counting zooplankton of Lake Tanganyika. FAO/FINNIDA Research for the Management of the Fisheries in Lake Tanganyika. GCP/RAF/271/FIN-FM/06 (En):19 pp

Vuorinen, I., Kurki, H., Bosma, E., Kalangali, A., Mölsä, H. and Lindqvist, O. 1999. Vertical distribution and migration of pelagic Copepoda in Lake Tanganyika. Hydrobiologia, 407: 115–121.

Diel vertical distribution and life history characteristics of Tropodiaptomus simplex and its importance in the diet of Stolothrissa tanganicae, Kigoma, Tanzania

Authors

Keywords:

Abstract

References

Downloads

Published

Issue

Section

License

Info