Changing Physical Conditions and Lower and Upper Trophic Level Responses on the US Northeast Shelf

Friedland, Kevin D.; Morse, Ryan E.; Shackell, Nancy L.; Tam, Jamie C.; Morano, Janelle L.; Moisan, John R.; Brady, Damian C.

doi:10.3389/fmars.2020.567445

Cited by 19 publications

(14 citation statements)

References 108 publications

(112 reference statements)

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“…Morphological microscopic examination of zooplankton samples from NEFSC surveys has allowed analysis and interpretation of temporal and spatial patterns of variability across the region (Kane, 2007;Kane, 2011;O'Brien et al, 2013). The time-series records have provided clear evidence that the region is experiencing rapid climate change (O'Brien et al, 2013;Friedland et al, 2020). Regime shifts (i.e., persistent changes in the structure and function of ecosystems) have been documented during the 1990s and 2000s in pelagic community structure (Pershing et al, 2005;Walsh et al, 2015;Morse et al, 2017), including zooplankton diversity (Head and Sameoto, 2007;Record et al, 2010;Johnson et al, 2011;Bi et al, 2014).…”

Section: Monitoring the Nw Atlantic Continental Shelfmentioning

confidence: 99%

“…Patterns of species diversity of the many taxonomic groups of marine zooplankton are key characteristics of ocean ecosystems, determining their function, sustainability, and responses to environmental variation and anthropogenic impacts, including climate change (Sherman et al, 2002;Friedland et al, 2020). Pelagic ecosystems of the NW Atlantic Ocean have been monitored and studied over many decades, providing an invaluable time-series record of zooplankton diversity and abundance (Wiebe et al, 2012;O'Brien et al, 2013).…”

Section: Introduction Metabarcoding Of Zooplankton Diversitymentioning

confidence: 99%

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COI Metabarcoding of Zooplankton Species Diversity for Time-Series Monitoring of the NW Atlantic Continental Shelf

et al. 2022

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Marine zooplankton are rapid-responders and useful indicators of environmental variability and climate change impacts on pelagic ecosystems on time scales ranging from seasons to years to decades. The systematic complexity and taxonomic diversity of the zooplankton assemblage has presented significant challenges for routine morphological (microscopic) identification of species in samples collected during ecosystem monitoring and fisheries management surveys. Metabarcoding using the mitochondrial Cytochrome Oxidase I (COI) gene region has shown promise for detecting and identifying species of some – but not all – taxonomic groups in samples of marine zooplankton. This study examined species diversity of zooplankton on the Northwest Atlantic Continental Shelf using 27 samples collected in 2002-2012 from the Gulf of Maine, Georges Bank, and Mid-Atlantic Bight during Ecosystem Monitoring (EcoMon) Surveys by the NOAA NMFS Northeast Fisheries Science Center. COI metabarcodes were identified using the MetaZooGene Barcode Atlas and Database (https://metazoogene.org/MZGdb) specific to the North Atlantic Ocean. A total of 181 species across 23 taxonomic groups were detected, including a number of sibling and cryptic species that were not discriminated by morphological taxonomic analysis of EcoMon samples. In all, 67 species of 15 taxonomic groups had ≥ 50 COI sequences; 23 species had >1,000 COI sequences. Comparative analysis of molecular and morphological data showed significant correlations between COI sequence numbers and microscopic counts for 5 of 6 taxonomic groups and for 5 of 7 species with >1,000 COI sequences for which both types of data were available. Multivariate statistical analysis showed clustering of samples within each region based on both COI sequence numbers and EcoMon counts, although differences among the three regions were not statistically significant. The results demonstrate the power and potential of COI metabarcoding for identification of species of metazoan zooplankton in the context of ecosystem monitoring.

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Section: Monitoring the Nw Atlantic Continental Shelfmentioning

confidence: 99%

Section: Introduction Metabarcoding Of Zooplankton Diversitymentioning

confidence: 99%

COI Metabarcoding of Zooplankton Species Diversity for Time-Series Monitoring of the NW Atlantic Continental Shelf

et al. 2022

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“…We also increased the atmospheric pCO 2 to 550 ppm in accordance with estimates from RCP 8.5 (IPCC, 2014). The temperature of the Gulf of Maine has been increasing rapidly this century (Friedland et al, 2020a;Friedland et al, 2020b;Gonçalves Neto et al, 2021) and is expected to continue warming. Brickman et al (2021) also used the same downscaled global models as Siedlecki et al (2021) to estimate that the Gulf of Maine will warm by an additional 0.5 C by 2050 compared to average 2018 temperatures using the RCP 8.5 emissions scenario.…”

Section: Model Strategymentioning

confidence: 99%

The impact of oyster aquaculture on the estuarine carbonate system

Liberti

Gray

Mayer

et al. 2022

Elementa: Science of the Anthropocene

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Many studies have examined the vulnerability of calcifying organisms, such as the eastern oyster (Crassostrea virginica), to externally forced ocean acidification, but the opposite interaction whereby oysters alter their local carbonate conditions has received far less attention. We present an exploratory model for isolating the impact that net calcification and respiration of aquacultured eastern oysters can have on calcite and aragonite saturation states, in the context of varying temperature, ocean-estuary mixing, and air-sea gas exchange. We apply the model to the Damariscotta River Estuary in Maine which has experienced rapid expansion of oyster aquaculture in the last decade. Our model uses oyster shell growth over the summer season and a previously derived relationship between net calcification and respiration to quantify impacts of net oyster calcification and gross metabolism on carbonate saturation states in open tidal waters. Under 2018 industry size and climate conditions, we estimate that oysters can lower carbonate saturation states by up to 5% (i.e., 0.17 and 0.11 units on calcite and aragonite saturation states, respectively) per day in late summer, with an average of 3% over the growing season. Perturbations from temperature and air-sea exchange are similar in magnitude. Under 2050 climate conditions and 2018 industry size, calcite saturation state will decrease by up to an additional 0.54 units. If the industry expands 3-fold by 2050, the calcite and aragonite saturation states may decrease by 0.73 and 0.47 units, respectively, on average for the latter half of the growing season when compared to 2018 climate conditions and industry size. Collectively, our results indicate that dense aggregations of oysters can have a significant role on estuarine carbonate chemistry.

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“…Changes in trophic ecology in the GOM have been observed in recent years (e.g. [6,[91][92][93]); however, these seem unlikely to have resulted in a catastrophic decline of post-juvenile northern shrimp given the generalist feeding strategy of the shrimp [23].…”

Section: Plos Onementioning

confidence: 99%

“…Climate change has led to well-documented changes in marine, terrestrial and freshwater ecological communities stemming from a diversity of processes, including productivity changes, shifts in species distributions, and changes in timing of seasonal events (phenology) [1][2][3][4][5][6][7][8]. These in turn have the potential to alter competitive and predator-prey interactions, with consequences for species dominance, biodiversity and population persistence.…”

Section: Introductionmentioning

confidence: 99%

Northern shrimp Pandalus borealis population collapse linked to climate-driven shifts in predator distribution

Richards

Hunter

2021

PLoS ONE

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The northern shrimp (Pandalus borealis Krøyer) population in the Gulf of Maine collapsed during an extreme heatwave that occurred across the Northwest Atlantic Ocean in 2012. Northern shrimp is a boreal species, and reaches its southern limit in the Gulf of Maine. Here we investigate proximate causes for the population collapse using data from fishery-independent surveys, environmental monitoring, and the commercial fishery. We first examined spatial data to confirm that the decline in population estimates was not due to a major displacement of the population, and then tested hypotheses related to fishing mortality and shifts in predation pressure. Fishing mortality may have contributed but could not explain the magnitude of the decline or the disappearance of pre-exploitable size individuals. Stomach contents analysis and biomass trends revealed no new fish predators of shrimp. However, longfin squid (Doryteuthis pealeii Lesueur) was unique among all species in showing time-series biomass peaks during spring, summer and fall of 2012, and spatial overlap with northern shrimp was unusually high in 2012. Longfin squid is a voracious and opportunistic predator that consumes crustaceans as well as fish. We hypothesize that the warmer temperatures of 2012 not only led to expansion of longfin squid distribution in Gulf of Maine, but had differential effects on migration phenology that further increased spatial overlap with northern shrimp. The weight of our evidence suggests that longfin squid predation was likely a significant factor in the collapse of northern shrimp in the Gulf of Maine.

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Changing Physical Conditions and Lower and Upper Trophic Level Responses on the US Northeast Shelf

Cited by 19 publications

References 108 publications

COI Metabarcoding of Zooplankton Species Diversity for Time-Series Monitoring of the NW Atlantic Continental Shelf

COI Metabarcoding of Zooplankton Species Diversity for Time-Series Monitoring of the NW Atlantic Continental Shelf

The impact of oyster aquaculture on the estuarine carbonate system

Northern shrimp Pandalus borealis population collapse linked to climate-driven shifts in predator distribution

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