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Effects of drift algae accumulation and nitrate loading on nitrogen cycling in a eutrophic coastal sediment

The permeable (sandy) sediments that dominate the world's coastlines and continental shelves are highly exposed to nitrogen pollution, predominantly due to increased urbanisation and inefficient agricultural practices. This leads to eutrophication, accumulation of drift algae and changes in the...

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Bibliographic Details
Published in:The Science of the total environment 2021-10, Vol.790, p.147749-147749, Article 147749
Main Authors: Wong, Wei Wen, Greening, Chris, Shelley, Guy, Lappan, Rachael, Leung, Pok Man, Kessler, Adam, Winfrey, Brandon, Poh, Seng Chee, Cook, Perran
Format: Article
Language:English
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Summary:The permeable (sandy) sediments that dominate the world's coastlines and continental shelves are highly exposed to nitrogen pollution, predominantly due to increased urbanisation and inefficient agricultural practices. This leads to eutrophication, accumulation of drift algae and changes in the reactions of nitrogen, including the potential to produce the greenhouse gas nitrous oxide (N2O). Nitrogen pollution in coastal systems has been identified as a global environmental issue, but it remains unclear how this nitrogen is stored and processed by permeable sediments. We investigated the interaction of drift algae biomass and nitrate (NO3−) exposure on nitrogen cycling in permeable sediments that were impacted by high nitrogen loading. We treated permeable sediments with increasing quantities of added macroalgal material and NO3− and measured denitrification, dissimilatory NO3− reduction to ammonium (DNRA), anammox, and nitrous oxide (N2O) production, alongside abundance of marker genes for nitrogen cycling and microbial community composition by metagenomics. We found that the presence of macroalgae dramatically increased DNRA and N2O production in sediments without NO3− treatment, concomitant with increased abundance of nitrate-ammonifying bacteria (e.g. Shewanella and Arcobacter). Following NO3− treatment, DNRA and N2O production dropped substantially while denitrification increased. This is explained by a shift in the relative abundance of nitrogen-cycling microorganisms under different NO3− exposure scenarios. Decreases in both DNRA and N2O production coincided with increases in the marker genes for each step of the denitrification pathway (narG, nirS, norB, nosZ) and a decrease in the DNRA marker gene nrfA. These shifts were accompanied by an increased abundance of facultative denitrifying lineages (e.g. Pseudomonas and Marinobacter) with NO3− treatment. These findings identify new feedbacks between eutrophication and greenhouse gas emissions, and in turn have potential to inform biogeochemical models and mitigation strategies for marine eutrophication. [Display omitted] •Drift algae and nitrate treatments shift microbial community and function.•Drift algae abundance drives nitrate reduction and N2O emissions.•Nitrate treatment enhances denitrification and N2O reduction.•Lack of nitrate treatment enhances nitrogen recycling and N2O production.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2021.147749