Sandy Beaches as Biogeochemical Hotspots: The Metabolic Role of Macroalgal Wrack on Low-productive Shores

Sandy beaches, which represent the most common type of land–sea interface, harbor distinctive biotic communities and regulate the flow of energy between marine and terrestrial ecosystems. Accumulations of sea wrack on sandy beaches are of crucial importance for recycling beach nutrients and for regu...

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Bibliographic Details
Published in:Ecosystems (New York) 2019-01, Vol.22 (1), p.49-63
Main Authors: Rodil, Iván F., Lastra, Mariano, López, Jesús, Mucha, Ana P., Fernandes, Joana P., Fernandes, Sara V., Olabarria, Celia
Format: Article
Language:English
Subjects:
Algae
bacterial assemblages
Beaches
benthic macrofauna
Biogeochemistry
Biomedical and Life Sciences
Carbon dioxide
Carbon dioxide emissions
CO2 emissions
Communities
Ecological effects
Ecology
Environmental Management
Fluxes
Geoecology/Natural Processes
Grooming
Harbors
Hydrology/Water Resources
Life Sciences
Macrofauna
Marine ecosystems
metabolic hotspots
Metabolic rate
Metabolism
non-native species
nutrient inputs
Nutrients
Original Articles
Patches (structures)
Plant Sciences
Remineralization
Seaweeds
Sediments
Shores
Species
Terrestrial ecosystems
Zoology
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Summary:Sandy beaches, which represent the most common type of land–sea interface, harbor distinctive biotic communities and regulate the flow of energy between marine and terrestrial ecosystems. Accumulations of sea wrack on sandy beaches are of crucial importance for recycling beach nutrients and for regulating trophic connectivity and coastal functioning. We investigated the role of beaches as biogeochemical hotspots by examining the metabolic activity in accumulations of different species of wrack on two exposed beaches affected by different levels of human pressure. Experimental wrack patches provided large amounts of different sedimentary nutrients over time due to remineralization of the algae. Unsurprisingly, the variation in the nutrients present in the beach sediments was related to the species of wrack considered. Macroalgal wrack was metabolically very active and supported high respiration rates represented by intense CO₂ fluxes. Importantly, we demonstrated that the wrack metabolic rate differed significantly depending on the algal species considered. Different macrofauna and bacterial assemblages were identified in the different wrack patches and on the different beaches. We suggest that human activities such as beach grooming can modify the wrack-associated communities, thus contributing to the variability in the biogeochemical processes and metabolic rates. Significant changes in the type and amount of wrack deposited on beaches can change fundamental processes related to the marine-terrestrial transfer of nutrients and energy and to the marine-atmospheric transfer of CO₂ emissions, with ecological consequences for nearshore environments.
ISSN:1432-9840
1435-0629
1435-0629
DOI:10.1007/s10021-018-0253-1