Successive extreme climatic events lead to immediate, large‐scale, and diverse responses from fish in the Arctic

Husson, Bérengère; Lind, Sigrid; Fossheim, Maria; Kato-Solvang, Hiroko; Skern‐Mauritzen, Mette; Pécuchet, Laurène; Ingvaldsen, Randi; Dolgov, Andrey V.; Primicerio, Raul

doi:10.1111/gcb.16153

Cited by 20 publications

(22 citation statements)

References 156 publications

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“…Note that in 2014 no ecological metrics data is available for the two western clusters (red and purple) and that in 2012 the sampling for megabenthos was irregular in the two eastern clusters (green and blue) due to the use of a different gear. The years 2012 and 2016 are highlighted by a vertical dashed line as these years were characterized by extreme environmental conditions in the Barents Sea, with very warm sea bottom temperature and very low ice‐cover, as identified in (Husson et al, 2022; Mohamed et al, 2022)…”

Section: Resultsmentioning

confidence: 99%

“…Some peaks, or dips, in the ecological metrics were noticeable, but not exclusively, in 2012 and 2016. During 2011–2012 and 2016, the Barents Sea experiences extreme climatic events with marine heatwaves and very low ice‐cover (Husson et al, 2022; Mohamed et al, 2022). Several fish populations in the Barents Sea reacted to these extreme years by changing their spatial distribution (Husson et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

“…During 2011–2012 and 2016, the Barents Sea experiences extreme climatic events with marine heatwaves and very low ice‐cover (Husson et al, 2022; Mohamed et al, 2022). Several fish populations in the Barents Sea reacted to these extreme years by changing their spatial distribution (Husson et al, 2022). These extreme climatic events might have also impacted the recruitment and survival of early stages of fish and invertebrates.…”

Section: Discussionmentioning

confidence: 99%

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Spatio‐temporal turnover and drivers of bentho‐demersal community and food web structure in a high‐latitude marine ecosystem

Pécuchet

Jørgensen

Dolgov

et al. 2022

Diversity and Distributions

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Aim: Assess the spatial and temporal turnover of bentho-demersal marine fauna by integrating ecological metrics at the community and food web levels and evaluate their main environmental and anthropogenic drivers.Location: Barents Sea. Method:We analysed data of benthic and bentho-pelagic fish and megabenthic invertebrates caught in the Barents Sea ecosystem survey in August-September 2009-2017 to characterize the spatial and temporal variability of bentho-demersal communities and food webs. We used a trait dataset and highly resolved benthodemersal food web to calculate community and food web metrics in space and time.We spatially clustered the community and food web based on their properties using archetypal analysis and investigated their co-variation with environmental and fishing pressure using (hierarchical) redundancy analysis. Result:The community and food web metrics partitioned the Barents Sea into four sub-regions where different pressures act on the bentho-demersal fauna, such as sea ice loss and fisheries. Multiple community metrics (e.g. mean body length and trophic level) varied along an environmental gradient of annual mean sea bottom temperature, trawling intensity and ice-cover, whereas multiple food web metrics (e.g. nestedness and connectance) varied along an environmental gradient of depth and sediment composition. Communities had higher biomass-weighted variability in body size and omnivory values in areas where the Atlantic and Arctic water masses mix. Several food web and community metrics co-varied (e.g. food chain length and mean trophic level). We found no clear temporal trends in the ecological metrics in any of the four sub-regions, but the metrics had large inter-annual variability with some local minima or maxima coinciding with high sea temperature and ice-cover anomalies. Conclusion:Analyses at the community and food web level are seldom integrated in ecological studies, while this integration gives complementary information to assess patterns and drivers of ecosystem state and to better prioritize conservation efforts.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Spatio‐temporal turnover and drivers of bentho‐demersal community and food web structure in a high‐latitude marine ecosystem

Pécuchet

Jørgensen

Dolgov

et al. 2022

Diversity and Distributions

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“…Extreme climate events are on the rise in polar regions, including marine and terrestrial heatwaves (Robinson et al, 2020) and drought and fires (Bokhorst et al, 2022). The long‐term biological effects of these extreme climatic events on polar biodiversity are being recognized (Bokhorst et al, 2022; Husson et al, 2022; Weydmann et al, 2018) and the implications for conservation of these ecosystems starting to be discussed (Bergstrom et al, 2021; Bokhorst et al, 2022; Chown et al, 2022). Future impacts of climate change are complex and challenging to quantify especially given lags in ecological expression of change (Constable et al, 2022).…”

Section: Biological Change At the Polesmentioning

confidence: 99%

Climate change and extreme events are changing the biology of Polar Regions

Robinson

2022

Global Change Biology

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“…While some methodological details need to be tailored to be suitable for specific taxa, ecosystems and geographical conditions, large heterogeneity in other variables potentially affecting accuracy such as population sampling effort, temporal resolution and statistical approaches remain. For example, redistribution inferences may be affected by sampling methods including choice of proxy for distribution measurement (Brown et al, 2011;Wernberg et al, 2012), including the 'center of distribution' (COD) which constitutes the mean latitude of the spatial extent (e.g., Li et al, 2019;Hsieh et al, 2009;Husson et al, 2022), or a population's most extreme boundaries of longitude, latitude or depth, inferred, for example, by presence-absence data (e.g., Fredston-Hermann et al, 2020). How these distribution indices are obtained also affects the predictions that are produced (Brown et al, 2016): popular data sources include abundance data from survey trawls by long term fisheries or research programs (Perry et al, 2005;Yemane et al, 2014), tagging-recapture data (Hammerschlag et al, 2022;Neat and Righton, 2007), historical records (Kumagai et al, 2018), or genetic-molecular methods (Knutsen et al, 2013;Spies et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Temperature change effects on marine fish range shifts: a meta-analysis of ecological and methodological predictors

Dahms¹,

Killen²

2022

Preprint

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The current effects of global warming on marine ecosystems are predicted to increase, with species responding by changing their spatial distributions. Marine ectotherms such as fish experience elevated distribution shifts, as temperature plays a key role in physiological functions and delineating population ranges through thermal constraints. Distributional response predictions necessary for population management have been complicated by high heterogeneity in magnitude and direction of movements, which may be explained by both biological as well as methodological study differences. To date, however, there has been no comprehensive synthesis of the interacting ecological factors influencing fish distributions in response to climate change and the confounding methodological factors that can affect their estimation. In this study we analyzed published studies meeting criteria of reporting range shift responses to global warming in 115 taxa spanning all major oceanic regions, totaling 569 three-dimensional population responses (latitudinal, longitudinal and depth), with temperature identified as a significant driver. Overall, studies on marine fish distributional responses have generally been of limited spatial and temporal scope, with comparisons among studies being complicated by large variation in methodology. We identified varying degrees of heterogeneity in latitudinal range shifts (km year-1) across ecological and methodological predictors, with multivariate regression analysis revealing response rate differences due to niche affinity, depth changes, as well as methodological biases due to different approaches in estimating and reporting latitudinal range shifts. Finally, we found strong geographical publication bias and limited taxonomical scope, highlighting the need for more representative and standardized research in order to address heterogeneity in distribution responses and improve predictions in face of changing climate.

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Successive extreme climatic events lead to immediate, large‐scale, and diverse responses from fish in the Arctic

Cited by 20 publications

References 156 publications

Spatio‐temporal turnover and drivers of bentho‐demersal community and food web structure in a high‐latitude marine ecosystem

Spatio‐temporal turnover and drivers of bentho‐demersal community and food web structure in a high‐latitude marine ecosystem

Climate change and extreme events are changing the biology of Polar Regions

Temperature change effects on marine fish range shifts: a meta-analysis of ecological and methodological predictors

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