Effects of climate and overfishing on zooplankton dynamics and ecosystem structure: regime shifts, trophic cascade, and feedback loops in a simple ecosystem
Möllmann, C.; Müller-Karulis, B.; Kornilovs, G.; St. John, M.A. (2008). Effects of climate and overfishing on zooplankton dynamics and ecosystem structure: regime shifts, trophic cascade, and feedback loops in a simple ecosystem. ICES J. Mar. Sci./J. Cons. int. Explor. Mer 63(5): 302-310. http://dx.doi.org/10.1093/icesjms/fsm197
In: ICES Journal of Marine Science. Academic Press: London. ISSN 1054-3139; e-ISSN 1095-9289, more
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| Keywords |
ANE, Baltic
Climate
Organisms > Aquatic organisms > Animals > Aquatic animals > Marine animals > Fishes > Aquatic animals > Marine fishes > Osteichthyes > Cod
Overexploitation > Commercial fishing > Overfishing
Acartia Dana, 1846 [WoRMS]; Pseudocalanus acuspes (Giesbrecht, 1881) [WoRMS]; Sprattus sprattus (Linnaeus, 1758) [WoRMS]
Baltic Sea [Marine Regions]
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| Author keywords |
Acartia spp.; Prey-to-predator loops; Pseudocalanus acuspes; Regime shifts; Sprat; Trophic casade |
| Authors | | Top |
- Möllmann, C.
- Müller-Karulis, B.
- Kornilovs, G.
- St. John, M.A.
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| Abstract |
The Central Baltic Sea is the largest brackish waterbody in the world ocean, containing a highly productive but low-diversity ecosystem. Climate-induced changes in hydrography recently caused an ecosystem regime shift with changes at all trophic levels. The most pronounced changes in the ecosystem occurred at the zooplankton and fish trophic levels. In the zooplankton, dominance changed between the copepods Pseudocalanus acuspes and Acartia spp., a result of reduced salinities and increased temperatures. The change in hydrography also affected the reproductive success of the major fish species, resulting in a change in dominance from the piscivorous cod (Gadus morhua) to the planktivorous sprat (Sprattus sprattus). First, we investigate statistically the occurrence of regime shifts in time-series of key hydrographic variables and the biomass time-series of key species. Second, we demonstrate a three-level trophic cascade involving zooplankton. Finally, we model the ecosystem effects of the abiotic and biotic changes on copepod biomass and recruitment of fish stocks. Our results demonstrate the linkage between climate-induced zooplankton and fish regime changes, and how overfishing amplified the climate-induced changes at both trophic levels. Hence, our study demonstrates (i) the multiple pathways along which climatic and anthropogenic pressures can propagate through the foodweb; (ii) how both effects act synergistically to cause and stabilize regime changes; and (iii) the crucial role of zooplankton in mediating these ecosystem changes. |
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