Short-term effects of nereid polychaete size and density on sediment inorganic nitrogen cycling under varying oxygen conditions

Bosch, Jennifer; Cornwell, Jeffrey C.; Kemp, William

doi:10.3354/meps11185

Cited by 14 publications

(3 citation statements)

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“…Either way, these changes can be due to increased remineralisation rates and/or increased animal consumption of detritus. These results are similar to those of another study where a deposit-feeding polychaete worm was found to increase oxygenation and denitrification rates in sediments ex-situ, suggesting potential for nutrient remediation (Bosch et al, 2015). Moreover, we observed a stronger effect of worms in-situ than ex-situ, with organic content reduced up to 50% in-situ accompanied by increases in biodiversity at the location with medium levels of pollution.…”

Section: Introducing Below-ground Ecosystem Engineers Can Influence F...supporting

confidence: 91%

Below‐ground ecosystem engineers enhance biodiversity and function in a polluted ecosystem

Bugnot

Gribben

O’Connor

et al. 2022

Journal of Applied Ecology

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Many important ecosystem functions are underpinned by below‐ground biodiversity and processes. Marine sediments, one of the most abundant habitats on earth, are essential to the mineralisation of organic matter. However, they are increasingly polluted by urban activities leading to the loss of biodiversity and the functions they provide. While traditional sediment remediation strategies are focussed on microbial and engineering solutions, we propose that the reintroduction of below‐ground ecosystem engineers (bioturbators) is important to rehabilitate polluted sediments and drive recovery of their functions in urban coastal ecosystems. We tested this notion by introducing bioturbators to nutrient polluted sediments to assess their survival, as well as their capacity to drive biodiversity and oxygenation and their potential to remediate nutrient pollution. Polychaete worms Diopatra aciculata and clams Katelysia sp. were added to mesocosms (ex‐situ), and the worms also added to experimental plots in‐situ. Potential for remediation was assessed with measures of nutrient content. All animals survived when introduced to polluted sediments and showed no evidence of sub‐lethal effects. Worms oxygenated sediments and reduced organic matter content by up to 50% in‐situ. The worms also drove shifts in the receiving communities at all locations and increased the number of taxa at one location. On the other hand, the effects of clams were variable, showing opposite effects in organic matter content at different sites and levels of pollution. Synthesis and applications. Global seafloor habitats are becoming increasingly degraded and novel strategies that combine biodiversity restoration with remediation are urgently needed to return function. Tube‐building bioturbators can stimulate nutrient processing in sediments proving multiple functional outcomes, but these effects are dependent on the receiving environment. In areas with medium levels of pollution, they can kick‐start recovery in a feedback loop whereby bioturbation increases oxygenation and nutrient remediation, shifting sediment biodiversity and contributing to further recovery. This can drive long‐term changes in sediment communities, particularly in urban areas where unvegetated sediments are conspicuous.

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Section: Introducing Below-ground Ecosystem Engineers Can Influence F...supporting

confidence: 91%

Below‐ground ecosystem engineers enhance biodiversity and function in a polluted ecosystem

Bugnot

Gribben

O’Connor

et al. 2022

Journal of Applied Ecology

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“…In such environments there tends to be a predominance of small species with opportunistic reproductive modes that are able to respond quickly post-disturbance and can reach high abundances, but these species are more likely to have a low bioturbation potential (Solan et al 2004a;Queirós et al 2013). As per capita effects on sediment-water nutrient fluxes are disproportionately greater for larger polychaetes (Bosch et al 2015), there is less capacity for most of the resident infauna to influence biogeochemical processes. A similar effect is also true for non-cohesive sediments which, due to their inherent mobility, host a high proportion of opportunistic species (Collie et al 2000), but these communities also harbour large deep-burrowing fauna (e.g.…”

Section: Discussionmentioning

confidence: 99%

Mediation of macronutrients and carbon by post-disturbance shelf sea sediment communities

et al. 2017

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Benthic communities play a major role in organic matter remineralisation and the mediation of many aspects of shelf sea biogeochemistry. Few studies have considered how changes in community structure associated with different levels of physical disturbance affect sediment macronutrients and carbon following the cessation of disturbance. Here, we investigate how faunal activity (sediment particle reworking and bioirrigation) in communities that have survived contrasting levels of bottom fishing affect sediment organic carbon content and macronutrient concentrations ([NH 4 [NH 4 -N] increases in noncohesive sediments that have experienced a higher frequency of fishing. Further analyses reveal that the way communities are restructured by physical disturbance differs between sediment type and with fishing frequency, but that changes in community structure do little to affect bioturbation and associated levels of organic carbon and nutrient concentrations. Our results suggest that in the presence of physical disturbance, irrespective of sediment type, the mediation of macronutrient and carbon cycling increasingly reflects the decoupling of organism-sediment relations. Indeed, it is the traits of the species that reside at the sediment-water interface, or that occupy deeper parts of the sediment profile, that are disproportionately expressed post-disturbance, that are most important for sustaining biogeochemical functioning.

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“…Deep burrowing macrofauna, during ventilation, pump N-and O 2 -rich bottom water downward (Nielsen et al 2004;Mermillod-Blondin and Rosenberg 2006;Renz and Foster 2013;Murphy and Reidenbach 2016). This stimulates microbial N-cycling pathways, including ammonification, nitrification and denitrification (Tuominen et al 1999;Bonaglia et al 2013;Stief 2013;Bosch et al 2015;Moraes et al 2018). Therefore, in macrofauna bioturbated sediments, the abundance and the activity of microbial communities often exceed those of surrounding, non-bioturbated sediments (Gilbertson et al 2012;Laverock et al 2014;Yazdani Foshtomi et al 2018;Samuiloviene et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Partitioning benthic nitrogen cycle processes among three common macrofauna holobionts

et al. 2021

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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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Short-term effects of nereid polychaete size and density on sediment inorganic nitrogen cycling under varying oxygen conditions

Cited by 14 publications

References 50 publications

Below‐ground ecosystem engineers enhance biodiversity and function in a polluted ecosystem

Below‐ground ecosystem engineers enhance biodiversity and function in a polluted ecosystem

Mediation of macronutrients and carbon by post-disturbance shelf sea sediment communities

Partitioning benthic nitrogen cycle processes among three common macrofauna holobionts

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