Effect of oysters Crassostrea virginica and bottom shear velocity on benthic-pelagic coupling and estuarine water quality

Porter, Elka T.; Cornwell, Jeffrey C.; Sanford, Lawrence P.

doi:10.3354/meps271061

Cited by 66 publications

(45 citation statements)

References 66 publications

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“…The areal NH 4 fluxes we report here are from the low position only, and are likely to vary seasonally and spatially, and so more research is needed to characterize NH 4 fluxes or predict effects on N2 production rates. Rather, these results highlight the potential for altered N-cycling upon reef construction, and the importance of benthic algal uptake in mediating benthic-pelagic coupling [6,7]. This is likely to be especially important for intertidal reefs such as the one in this study, which receive abundant sunlight.…”

Section: Discussionmentioning

confidence: 94%

“…In addition to direct revenue from oyster harvesting, oysters provide hard substrate for sessile organisms, habitat complexity and refuge for small mobile organisms, and attenuation of wave energy for shoreline protection [1,2]. Furthermore, the filtering capacity of oysters is thought to improve water clarity and influence the structure of estuarine ecosystems with respect to recycling of organic matter and nutrients [3][4][5], benthicpelagic coupling, and energy flow to the microbial loop [6,7]. At the creek-level scale, oyster communities have been shown to significantly affect concentrations of particulate and dissolved nutrients and organic matter, though effects often depended on season and tidal state [5,8].…”

Section: Introductionmentioning

confidence: 99%

“…Finer particles and much higher organic matter (OM) content in oyster-associated sediments suggests a substantial role for carbon and nutrient removal by burial [8,17] and benthic algal uptake where light penetration is sufficient [6]. However, mesocosm experiments show that physical factors such as bottom shear can influence sediment resuspension and benthic micro-algal biomass, making the system more complex and the likelihood of OM burial versus remineralization more difficult to predict [7]. Several recent studies suggest that sediments associated with natural and restored oyster reefs have high rates of denitrification and may thus represent important sites for long term nitrogen removal [17][18][19][20].…”

mentioning

confidence: 99%

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Changes in Sediment Characteristics upon Oyster Reef Restoration, NE Florida, USA

Southwell¹,

Veenstra²,

Adams³

et al. 2017

J Coast Zone Manag

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debated [11,12,14,15], but less research has been devoted to the effect of oyster reefs on the surrounding sediment. Reefs act to attenuate wave energy, possibly facilitating deposition of fine sediment [8]; this process may work in concert with oyster filtration to increase light penetration that may then shift ecosystems towards more benthic primary producers [6]. Finer particles and much higher organic matter (OM) content in oyster-associated sediments suggests a substantial role for carbon and nutrient removal by burial [8,17] and benthic algal uptake where light penetration is sufficient [6]. However, mesocosm experiments show that physical factors such as bottom shear can influence sediment resuspension and benthic micro-algal biomass, making the system more complex and the likelihood of OM burial versus remineralization more difficult to predict [7]. Several recent studies suggest that sediments associated with natural and restored oyster reefs have high rates of denitrification and may thus represent important sites for long term nitrogen removal [17][18][19][20]. Whole-creek studies and some mesocosm studies do not parse the contributions of the oysters themselves versus the associated sediments but rather consider the reef-sediment system as a whole [3,5,17]. Indeed, it is difficult to separate these effects because the presence of the reef will likely alter the depositional environment and ultimately the biogeochemistry of the surrounding sediment.

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Section: Discussionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Changes in Sediment Characteristics upon Oyster Reef Restoration, NE Florida, USA

Southwell¹,

Veenstra²,

Adams³

et al. 2017

J Coast Zone Manag

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“…Temporal mismatching between phytoplankton production and peak oyster filtration may also limit the potential for oyster populations to have a regulating influence. Additionally, the impact of filtration on seston drawdown on large scales cannot be directly inferred from filtration rates due to the influences of wave action (Porter et al 2004), the unequal distribution of oysters (Cerco and Noel 2007), and imperfect mixing within the estuary (Pomeroy et al 2006). This in turn may lead to variable impacts of oyster filtration on nutrient cycling within the bay, as the biodeposition of seston may stimulate enhanced denitrification and anammox in the sediments (Dame 2011).…”

Section: Discussionmentioning

confidence: 99%

Quantifying the Loss of a Marine Ecosystem Service: Filtration by the Eastern Oyster in US Estuaries

Ermgassen

Spalding

Grizzle

et al. 2012

Estuaries and Coasts

168

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The oyster habitat in the USA is a valuable resource that has suffered significant declines over the past century. While this loss of habitat is well documented, the loss of associated ecosystem services remains poorly quantified. Meanwhile, ecosystem service recovery has become a major impetus for restoration. Here we propose a model for estimating the volume of water filtered by oyster populations under field conditions and make estimates of the contribution of past (c. 1880-1910) and present (c. 2000-2010) oyster populations to improving water quality in 13 US estuaries. We find that filtration capacity of oysters has declined almost universally (12 of the 13 estuaries examined) by a median of 85 %. Whereas historically, oyster populations achieved full estuary filtration (filtering a volume equivalent or larger than the entire estuary volume within the residence time of the water) in six of the eight estuaries in the Gulf of Mexico during summer months, this is now the case for only one estuary: Apalachicola Bay, Florida. By contrast, while all five estuaries on the North Atlantic coast showed large decreases in filtration capacity, none were achieving full estuary filtration at the time of our c. 1900 historic baseline. This apparent difference from the Gulf of Mexico is explained at least in part by our North Atlantic baseline representing a shifted baseline, as surveyed populations were already much reduced by exploitation in this region.

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“…Oysters are ecosystem engineers, constructing habitat for themselves as well as for a multitude of other organisms (Coen et al 1999, Peterson et al 2003, Grabowski et al 2005, Fulford et al 2010. They also provide important ecosystem services like nutrient cycling (Dame & Libes 1993, Fulford et al 2007) and benthic-pelagic coupling (Baird & Ulanowicz 1989, Porter et al 2004. Additionally, increasing oyster populations may have a substantial influence on reducing effects of anthropogenic eutro phication (Cerco & Noel 2007, Fulford et al 2010.…”

Section: Introductionmentioning

confidence: 99%

Overfishing, disease, habitat loss, and potential extirpation of oysters in upper Chesapeake Bay

Wilberg¹,

Livings²,

Barkman³

et al. 2011

Mar. Ecol. Prog. Ser.

139

100

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The fishery for eastern oyster Crassostrea virginica in Chesapeake Bay, USA, was the biggest oyster fishery in the world and the largest fishery in the US in the late 1800s. The population has declined substantially because of overfishing, disease, and habitat loss. We developed a statistical model to simultaneously estimate effects of fishing and disease on oysters in upper Chesapeake Bay during 1980 to 2009. We compared the model estimates of abundance in 2009 to that prior to large-scale commercial fishing. We found that oyster abundance declined 99.7% (90% credibility interval [CI], 98.3 to 99.9%) since the early 1800s and 92% (90% CI, 84.6 to 94.7%) since 1980. Habitat area declined nearly 70% (90% CI, 36.2 to 83.3%) during 1980 to 2009. Natural mortality (mortality from all non-fishing sources) of market-sized oysters varied substantially and increased during 1986 to 1987 and 2000 to 2002, and natural mortality of small oysters approximately doubled after 1986. The exploitation rate varied over time and averaged 25.1% yr -1 (90% CI, 16.1 to 33.1%) during 1980 to 2008. Fishing and disease have had substantial negative impacts on the population, but effects of fishing have been stronger than increased natural mortality. We recommend a moratorium on fishing to minimize the risk of extirpation and provide an opportunity for recovery.

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Effect of oysters Crassostrea virginica and bottom shear velocity on benthic-pelagic coupling and estuarine water quality

Cited by 66 publications

References 66 publications

Changes in Sediment Characteristics upon Oyster Reef Restoration, NE Florida, USA

Changes in Sediment Characteristics upon Oyster Reef Restoration, NE Florida, USA

Quantifying the Loss of a Marine Ecosystem Service: Filtration by the Eastern Oyster in US Estuaries

Overfishing, disease, habitat loss, and potential extirpation of oysters in upper Chesapeake Bay

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