Non-trophic interactions control benthic producers on intertidal flatsDonadi, S., Westra, J., Weerman, E. J., van der Heide, T., van der Zee, E. M., van de Koppel, J., Olff, H., Piersma, T., van der Veer, H. W. & Eriksson, B. K., Nov-2013, In : Ecosystems. 16, 7, p. 1325-1335 11 p.
Research output: Contribution to journal › Article › Academic › peer-review
The importance of positive effects of ecosystem engineers on associated communities is predicted to increase with environmental stress. However, incorporating such non-trophic interactions into ecological theory is not trivial because facilitation of associated species is conditional on both the type of engineer and the type of abiotic stress. We tested the influence of two allogenic ecosystem engineers (lugworms, Arenicola marina L. and cockles, Cerastoderma edule L.) on the main primary producers (microphytobenthos) of the tidal flats, under different abiotic stresses controlled by reefs of blue mussels (Mytilus edulis L.). We added 25,000 cockles or 2,000 lugworms to 5 x 5 m plots, both in a muddy site with high sedimentation rates located coastward of a mussel bed, and in a sandy site without mussels and characterized by high hydrodynamic stress. After a year, cockles increased algal biomass in the sandy area, but not in the mussel bed site, where high values were measured in all plots. However, lugworms did not affect algal biomass in any of the sites. Field measurements suggest that cockles outweighed negative effects of water currents in the site without mussels by locally increasing sediment stability, whereas mussels overruled the effects of cockles in the wake of the reefs through hydrodynamic stress alleviation and/or biodeposition. Our results suggest that non-trophic interactions by ecosystem engineering bivalves control primary production of intertidal areas, and that the sediment-stabilizing effect of cockles plays a crucial role where the overruling effects of mussel beds are not present.
|Number of pages||11|
|Publication status||Published - Nov-2013|
- ecosystem engineering, facilitation, hydrodynamic stress, microphytobenthos, Cerastoderma edule, Arenicola marina, Mytilus edulis, Wadden Sea, STRESS-GRADIENT HYPOTHESIS, DUTCH WADDEN SEA, CERASTODERMA-EDULE, PLANT-COMMUNITIES, SEDIMENT DYNAMICS, ARENICOLA-MARINA, TIDAL FLATS, POSITIVE INTERACTIONS, ECOSYSTEM FUNCTION, SW NETHERLANDS