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Partitioning benthic nitrogen cycle processes among three common macrofauna holobionts
Zilius, M.; Daunys, D.; Bartoli, M.; Marzocchi, U.; Bonaglia, S.; Cardini, U.; Castaldelli, G. (2022). Partitioning benthic nitrogen cycle processes among three common macrofauna holobionts. Biogeochemistry 157(2): 193-213. https://dx.doi.org/10.1007/s10533-021-00867-8
In: Biogeochemistry. Springer: Dordrecht; Lancaster; Boston. ISSN 0168-2563; e-ISSN 1573-515X, more
Peer reviewed article  

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Keyword
    Marine/Coastal
Author keywords
    Benthic functioning; Invertebrate-microbe associations; Nitrogen cycle; Nitrate reduction; Sediments; Baltic Sea

Authors  Top 
  • Zilius, M.
  • Daunys, D., more
  • Bartoli, M.
  • Marzocchi, U., more
  • Bonaglia, S.
  • Cardini, U.
  • Castaldelli, G.

Abstract
    The effects of single macrofauna taxa on benthic nitrogen (N) cycling have been extensively studied, whereas how macrofaunal communities affect N-related processes remains poorly explored. In this study, we characterized benthic N-cycling in bioturbated sediments of the oligotrophic Öre Estuary (northern Baltic Sea). Solute fluxes and N transformations (N2 fixation, denitrification and dissimilative nitrate reduction to ammonium [DNRA]) were measured in sediments and macrofauna-associated microbes (holobionts) to partition the role of three dominant taxa (the filter feeder Limecola balthica, the deep deposit feeder Marenzelleria spp., and the surface deposit feeder Monoporeia affinis) in shaping N-cycling. In the studied area, benthic macrofauna comprised a low diversity community with dominance of the three taxa, which are widespread and dominant in the Baltic. The biomass of these taxa in macrofaunal community explained up to 30% of variation in measured biogeochemical processes, confirming their important role in ecosystem functioning. The results also show that these taxa significantly contributed to the benthic metabolism and N-cycling (direct effect) as well as to sediments bioturbation with positive feedback to dissimilative nitrate reduction (indirect effect). Taken together, these functions promoted a reuse of nutrients at the benthic level, limiting net losses (e.g. denitrification) and effluxes to bottom water. Finally, the detection of multiple N transformations in macrofauna holobionts suggested a community-associated versatile microbiome, however, its role was of minor importance as compared to the activity of sediment-associated microbial communities. The present study highlights hidden and interactive effects among microbes and macrofauna, which should be considered analysing benthic functioning.

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