Development and validation of an individual based Daphnia magna population model: The influence of crowding on population dynamics

An individual-based model was developed to predict the population dynamics of Daphnia magna at laboratory conditions from individual life-history traits observed in experiments with different feeding conditions. Within the model, each daphnid passes its individual life cycle including feeding on alg...

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Bibliographic Details
Published in:Ecological modelling 2009-02, Vol.220 (3), p.310-329
Main Authors: Preuss, Thomas Günter, Hammers-Wirtz, Monika, Hommen, Udo, Rubach, Mascha Nadine, Ratte, Hans Toni
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Biological and medical sciences
consequences
Crowding
Daphnia
Daphnia magna
Demecology
density
Density dependence
feeding rate
food concentration
Freshwater
Fundamental and applied biological sciences. Psychology
General aspects
General aspects. Techniques
growth
Individual-based
Methods and techniques (sampling, tagging, trapping, modelling...)
offspring size
Population
pulex
reproduction
Size distribution
Structure
toxicity tests
zooplankton
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Summary:An individual-based model was developed to predict the population dynamics of Daphnia magna at laboratory conditions from individual life-history traits observed in experiments with different feeding conditions. Within the model, each daphnid passes its individual life cycle including feeding on algae, aging, growing, developing and – when maturity is reached – reproducing. The modelled life cycle is driven by the amount of ingested algae and the density of the Daphnia population. At low algae densities the population dynamics is mainly driven by food supply, when the densities of algae are high, the limiting factor is “crowding” (a density-dependent mechanism due to chemical substances released by the organisms or physical contact, but independent of food competition). The model was calibrated using data from life cycle tests at flow-through conditions with different levels of algae concentrations. In addition to the average life cycle parameters for different food levels, the variability between the individuals was considered by stochastic assignment of values from the observed distributions in the experiments to each individual property. The model was tested on the individual and the population level. Individual growth and reproduction were tested based on the results of life cycle tests conducted under semi-batch conditions; the population level was considered by testing at different food levels under flow-trough and static conditions, including extinction at starvation conditions. The model was not only able to predict the total abundance of the population over time, but also predicted the size structure in good accordance with the observations. The population dynamics emerge directly from the life cycle of the individual daphnids. It depends on the available food and–this had not been considered in other Daphnia models–on crowding effects due to high Daphnia abundances.
ISSN:0304-3800
1872-7026
DOI:10.1016/j.ecolmodel.2008.09.018