Density-dependent responses of the brittlestar Amphiura filiformis to moderate hypoxia and consequences for nutrient fluxes

Calder-Potts, R, Spicer, JI, Calosi, P, Findlay, HS, Queiros, AM and Widdicombe, S 2018 Density-dependent responses of the brittlestar Amphiura filiformis to moderate hypoxia and consequences for nutrient fluxes. Marine Ecology Progress Series. https://doi.org/10.3354/meps12503

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Abstract/Summary

Within coastal marine habitats, intense nutrient cycling, and near seabed primary production rates are strongly influenced by the transport and transformation of materials within the sediment and across the sediment-water interface. Through processes such as bioturbation and bio-irrigation, benthic infauna play a significant role in mediating this transport and modify many chemical and physical reactions. However, coastal ecosystems are experiencing growing impacts from a number of environmental stresses, one of which is reduced dissolved oxygen (DO), known as hypoxia. Hypoxic events in coastal areas are predicted to increase as global warming and human-induced eutrophication intensify, with predicted consequences for infaunal community diversity and ecosystem function. Using a mesocosm experiment, we investigated the effects of short-term, sub-lethal hypoxia (14 d, 3.59 mg O2 L-1) and organism density (500, 900, 1300, 1700, and 2100 indiv. m-2) on the bioturbation activity of the brittlestar Amphiura filiformis. Nutrient fluxes were measured as an important contribution to ecosystem function. Hypoxia resulted in reduced brittlestar activity (in terms of sediment surface bioturbation), increased efflux of ammonium and silicate, and an increase in the ratio of NH4+:NOx when brittlestar densities were high. No significant effects of hypoxia were detected on brittlestar burrow depth. Our results illustrated that population density plays a crucial role in exacerbating the effects of hypoxia, possibly due to greater biological oxygen demands and increased waste products as organism density increases. Consequently, during moderate reductions in DO, densely populated communities may actually be more vulnerable to hypoxic stress and exhibit greater shifts in ecosystem function than sparsely populated communities.

Item Type: Publication - Article
Subjects: Biology
Ecology and Environment
Marine Sciences
Divisions: Plymouth Marine Laboratory > Science Areas > Marine Ecology and Biodiversity
Depositing User: Ruth Calder-Potts
Date made live: 14 Mar 2018 11:43
Last Modified: 25 Apr 2020 09:58
URI: https://plymsea.ac.uk/id/eprint/7754

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