Are Calanus spp. shifting poleward in the North Atlantic? A habitat modelling approach

Chust, Guillem; Castellani, Claudia; Licandro, Priscilla; Ibaibarriaga, Leire; Sagarmínaga, Yolanda; Irigoien, Xabier

doi:10.1093/icesjms/fst147

Cited by 86 publications

(83 citation statements)

References 61 publications

(80 reference statements)

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“…These attributes make them a key group for monitoring the impacts of climate change on biodiversity and ecosystem functioning (Richardson, 2008). So far, SDMs have seldom been applied to study plankton biogeography, with only a handful of studies on phytoplankton (Irwin et al, 2012;Pinkernell and Beszteri, 2014;Brun et al, 2015;Rivero-Calle et al, 2015;Barton et al, 2016) and some more on zooplankton (e.g., Reygondeau and Beaugrand, 2011;Chust et al, 2014b;Villarino et al, 2015;Brun et al, 2016;Benedetti et al, in press). This is due not only to the limited data availability for model development, but also due to several unaddressed methodological issues.…”

Section: Species Distribution Modeling-running Before We Can Walk?mentioning

confidence: 99%

“…Moreover, disentangling the effects of anthropogenic climate change on plankton distribution and phenology shifts from other drivers (e.g., climate variability, population dynamics) is equally challenging (Chust et al, 2014b). In particular, the combination of controlling factors, together with systematic biases in sampling effort can lead to biases in estimated trends.…”

Section: Adrift In An Ocean Of Changementioning

confidence: 99%

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Mare Incognitum: A Glimpse into Future Plankton Diversity and Ecology Research

et al. 2017

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With global climate change altering marine ecosystems, research on plankton ecology is likely to navigate uncharted seas. Yet, a staggering wealth of new plankton observations, integrated with recent advances in marine ecosystem modeling, may shed light on marine ecosystem structure and functioning. A EuroMarine foresight workshop on the "Impact of climate change on the distribution of plankton functional and phylogenetic diversity" (PlankDiv) identified five grand challenges for future plankton diversity and macroecology research: (1) What can we learn about plankton communities from the new wealth of high-throughput "omics" data? (2) What is the link between plankton diversity and ecosystem function? (3) How can species distribution models be adapted to represent plankton biogeography? (4) How will plankton biogeography be altered due to anthropogenic climate change? and (5) Can a new unifying theory of macroecology be developed based on plankton ecology studies? In this review, we discuss potential future avenues to address these questions, and challenges that need to be tackled along the way.

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Section: Species Distribution Modeling-running Before We Can Walk?mentioning

confidence: 99%

Section: Adrift In An Ocean Of Changementioning

confidence: 99%

Mare Incognitum: A Glimpse into Future Plankton Diversity and Ecology Research

et al. 2017

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“…Ongoing climate change, particularly seawater warming, is affecting and will continue to affect predominant copepods of the genus Calanus, resulting in distributional changes with consequences for higher trophic levels Chust et al, 2014;Olsen et al, 2011;Reygondeau and Beaugrand, 2011a). While a previous study has already revealed differences in the thermal stress response between closely related Calanus species , the degree of variation in responses of different Calanus populations is largely unknown.…”

Section: Discussionmentioning

confidence: 99%

“…The highest population densities of C. finmarchicus are found along the south-west to north-east axis of the North Atlantic where temperatures range between 4°C and 9°C (Planque and Batten, 2000;Sundby, 2000). Since the 1960s a consistent northward shift of C. finmarchicus distribution has been detected (Beaugrand et al, 2002;Chust et al, 2014). In the North Sea this decrease in the abundance of C. finmarchicus has been associated with an increase of the more southern species C. helgolandicus, which has a lower lipid content and different phenology than C. finmarchicus Bonnet et al, 2005).…”

Section: Introductionmentioning

confidence: 96%

“…The effects of temperature increase on C. finmarchicus distribution are documented by Chust et al (2014) and a further northward shift is predicted, particularly at the southern edge of distribution where seawater temperatures might exceed the thermal niche for C. finmarchicus for several months in a year by 2100 (Helaouët et al, 2011;Reygondeau and Beaugrand, 2011a). Thus, knowledge on physiological and gene expression plasticity among populations of C. finmarchicus to elevated temperatures may be of particular interest and importance to reduce uncertainties of climate change impacts.…”

Section: Introductionmentioning

confidence: 99%

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Reduced up-regulation of gene expression in response to elevated temperatures in the mid-Atlantic population of Calanus finmarchicus

Smolina

Harmer

Lindeque

et al. 2016

Journal of Experimental Marine Biology and Ecology

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Surface and subsurface oceanographic features drive forage fish distributions and aggregations: Implications for prey availability to top predators in the US Northeast Shelf ecosystem

Goetsch

Gulka

Friedland

et al. 2023

Ecology and Evolution

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Forage fishes are a critical food web link in marine ecosystems, aggregating in a hierarchical patch structure over multiple spatial and temporal scales. Surface-level forage fish aggregations (FFAs) represent a concentrated source of prey available to surface-and shallow-foraging marine predators. Existing survey and analysis methods are often imperfect for studying forage fishes at scales appropriate to foraging predators, making it difficult to quantify predator-prey interactions. In many cases, general distributions of forage fish species are known; however, these may not represent surface-level prey availability to predators. Likewise, we lack an understanding of the oceanographic drivers of spatial patterns of prey aggregation and availability or forage fish community patterns. Specifically, we applied Bayesian joint species distribution models to bottom trawl survey data to assess species-and community-level forage fish distribution patterns across the US Northeast Continental Shelf (NES) ecosystem.Aerial digital surveys gathered data on surface FFAs at two project sites within the NES, which we used in a spatially explicit hierarchical Bayesian model to estimate the abundance and size of surface FFAs. We used these models to examine the oceanographic drivers of forage fish distributions and aggregations. Our results suggest that, in the NES, regions of high community species richness are spatially consistent with regions of high surface FFA abundance. Bathymetric depth drove both patterns, while subsurface features, such as mixed layer depth, primarily influenced aggregation behavior and surface features, such as sea surface temperature, sub-mesoscale eddies, and fronts influenced forage fish diversity. In combination, these models help quantify the availability of forage fishes to marine predators and represent a novel application of spatial models to aerial digital survey data.

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Are Calanus spp. shifting poleward in the North Atlantic? A habitat modelling approach

Cited by 86 publications

References 61 publications

Mare Incognitum: A Glimpse into Future Plankton Diversity and Ecology Research

Mare Incognitum: A Glimpse into Future Plankton Diversity and Ecology Research

Reduced up-regulation of gene expression in response to elevated temperatures in the mid-Atlantic population of Calanus finmarchicus

Surface and subsurface oceanographic features drive forage fish distributions and aggregations: Implications for prey availability to top predators in the US Northeast Shelf ecosystem

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