Ecosystem responses to the eradication of common carp Cyprinus carpio using rotenone from a reservoir in South Africa

The control of invasive alien fish populations using piscicides to alleviate impacts on native biota is a controversial conservation strategy because the collateral impacts on non‐target taxa are not well documented. This article documents the responses of water quality, plankton and macroinvertebra...

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Bibliographic Details
Published in:Aquatic conservation 2020-12, Vol.30 (12), p.2284-2297
Main Authors: Dalu, Tatenda, Bellingan, Terence A., Gouws, Jeanne, Impson, N. Dean, Jordaan, Martine S., Khosa, Dumisani, Marr, Sean M., Mofu, Lubabalo, Schumann, Mandy, Slabbert, Etienne, Walt, Johannes A., Wasserman, Ryan J., Weyl, Olaf L. F.
Format: Article
Language:English
Subjects:
Algae
Aquatic plants
Biological effects
Biota
Carp
Cyprinus carpio
Dynamics
ecosystem response
Environmental changes
Eutrophic environments
Eutrophic waters
Eutrophication
Fish
Fish populations
Freshwater fishes
Invertebrates
Macroinvertebrates
Marine invertebrates
Mineral nutrients
Nutrient concentrations
Nutrient status
Nutrients
Phytoplankton
Piscicides
Plankton
Reservoirs
Rotenone
Rotifera
South Africa
Stock assessment
Taxa
Water circulation
Water column
Water quality
Zoobenthos
Zooplankton
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Summary:The control of invasive alien fish populations using piscicides to alleviate impacts on native biota is a controversial conservation strategy because the collateral impacts on non‐target taxa are not well documented. This article documents the responses of water quality, plankton and macroinvertebrate communities to an eradication of the globally invasive common carp Cyprinus carpio Linnaeus 1758, using the piscicide rotenone in a small South African reservoir. Treated and untreated reservoirs were sampled before and at intervals following rotenone treatment. Sampling endpoints included water quality parameters, plankton, macroinvertebrates and fish. These endpoints were selected to gain an understanding of the ecological impacts of the treatment at various biological levels and to document possible recovery following treatment. The study showed that: (i) the common carp were successfully removed; (ii) water clarity improved following the removal of fish; (iii) invertebrate communities, including macroinvertebrates and large zooplankton, recovered within 6 months of treatment; and (iv) that small zooplankton (i.e. Rotifera) dynamics were complex but rotifer abundances had returned to pre‐treatment levels within 6 months of treatment. There was a 56% similarity between the macroinvertebrate assemblages before and 6 months after treatment, showing a substantial turnover in taxa following treatment. The phytoplankton community of the treated reservoir was dominated by blue‐green and green algae prior to the treatment. The blue‐green algal communities were not present 6 months after the treatment, possibly indicating a change in the nutrient status of the reservoir resulting from lower nutrient concentrations in the water column. The phytoplankton community of the reservoir changed from a community typical of eutrophic waters to a community typical of a lower nutrient state. Within each group, there were species changes, but we suggest these are likely to be part of the altered biological interaction dynamics resulting from fish removals, rather than a direct effect of rotenone.
ISSN:1052-7613
1099-0755
DOI:10.1002/aqc.3463