Your search keyword '"Pinsky, Malin"' showing total 39 results

1. Genetic decline and recovery of a demographically rebuilt fishery species.

Author

Hoey JA, Able KW, and Pinsky ML

Subjects

Animals, Population Density, Population Dynamics, Genome, Genomics, Genetic Variation genetics, Fisheries, Flounder genetics

Abstract

The demographic history of a population is important for conservation and evolution, but this history is unknown for many populations. Methods that use genomic data have been developed to infer demography, but they can be challenging to implement and interpret, particularly for large populations. Thus, understanding if and when genetic estimates of demography correspond to true population history is important for assessing the performance of these genetic methods. Here, we used double-digest restriction-site associated DNA (ddRAD) sequencing data from archived collections of larval summer flounder (Paralichthys dentatus, n = 279) from three cohorts (1994-1995, 1997-1998 and 2008-2009) along the U.S. East coast to examine how contemporary effective population size and genetic diversity responded to changes in abundance in a natural population. Despite little to no detectable change in genetic diversity, coalescent-based demographic modelling from site frequency spectra revealed that summer flounder effective population size declined dramatically in the early 1980s. The timing and direction of change corresponded well with the observed decline in spawning stock census abundance in the late 1980s from independent fish surveys. Census abundance subsequently recovered and achieved the prebottleneck size. Effective population size also grew following the bottleneck. Our results for summer flounder demonstrate that genetic sampling and site frequency spectra can be useful for detecting population dynamics, even in species with large effective sizes., (© 2022 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.)

Published

2022

2. A long evolutionary reach for fishing nets.

Author

Therkildsen NO and Pinsky ML

Subjects

Biological Evolution, Fisheries, Hunting

Abstract

Earlier maturation of Atlantic salmon is linked to indirect effects of fisheries on its prey.

Published

2022

3. Mapping the climate risk for European fisheries.

Author

Pinsky ML

Subjects

Climate, Conservation of Natural Resources, Climate Change, Fisheries

Abstract

Competing Interests: The author declares no competing interest.

Published

2021

4. Global hotspots of coherent marine fishery catches.

Author

Ong JJL, Walter JA, Jensen OP, and Pinsky ML

Subjects

Animals, Biomass, Conservation of Natural Resources, Humans, Indian Ocean, Ecosystem, Fisheries

Abstract

Although different fisheries can be tightly linked to each other by human and ecosystem processes, they are often managed independently. Synchronous fluctuations among fish populations or fishery catches can destabilize ecosystems and economies, respectively, but the degree of synchrony around the world remains unclear. We analyzed 1,092 marine fisheries catch time series over 60 yr to test for the presence of coherence, a form of synchrony that allows for phase-lagged relationships. We found that nearly every fishery was coherent with at least one other fishery catch time series globally and that coherence was strongest in the northeast Atlantic, western central Pacific, and eastern Indian Ocean. Analysis of fish biomass and fishing mortality time series from these hotspots revealed that coherence in biomass or fishing mortality were both possible, though biomass coherence was more common. Most of these relationships were synchronous with no time lags, and across catches in all regions, synchrony was a better predictor of regional catch portfolio effects than catch diversity. Regions with higher synchrony had lower stability in aggregate fishery catches, which can have negative consequences for food security and economic wealth., (© 2021 The Authors. Ecological Applications published by Wiley Periodicals LLC on behalf of Ecological Society of America.)

Published

2021

5. Diversification spins a heatwave safety net for fisheries.

Author

Pinsky ML

Subjects

Infrared Rays, Climate, Fisheries

Abstract

Competing Interests: The author declares no competing interest.

Published

2021

6. Are we ready to track climate-driven shifts in marine species across international boundaries? - A global survey of scientific bottom trawl data.

Author

A Maureaud A, Frelat R, Pécuchet L, Shackell N, Mérigot B, Pinsky ML, Amador K, Anderson SC, Arkhipkin A, Auber A, Barri I, Bell RJ, Belmaker J, Beukhof E, Camara ML, Guevara-Carrasco R, Choi J, Christensen HT, Conner J, Cubillos LA, Diadhiou HD, Edelist D, Emblemsvåg M, Ernst B, Fairweather TP, Fock HO, Friedland KD, Garcia CB, Gascuel D, Gislason H, Goren M, Guitton J, Jouffre D, Hattab T, Hidalgo M, Kathena JN, Knuckey I, Kidé SO, Koen-Alonso M, Koopman M, Kulik V, León JP, Levitt-Barmats Y, Lindegren M, Llope M, Massiot-Granier F, Masski H, McLean M, Meissa B, Mérillet L, Mihneva V, Nunoo FKE, O'Driscoll R, O'Leary CA, Petrova E, Ramos JE, Refes W, Román-Marcote E, Siegstad H, Sobrino I, Sólmundsson J, Sonin O, Spies I, Steingrund P, Stephenson F, Stern N, Tserkova F, Tserpes G, Tzanatos E, van Rijn I, van Zwieten PAM, Vasilakopoulos P, Yepsen DV, Ziegler P, and T Thorson J

Subjects

Animals, Climate Change, Fishes, Surveys and Questionnaires, Ecosystem, Fisheries

Abstract

Marine biota are redistributing at a rapid pace in response to climate change and shifting seascapes. While changes in fish populations and community structure threaten the sustainability of fisheries, our capacity to adapt by tracking and projecting marine species remains a challenge due to data discontinuities in biological observations, lack of data availability, and mismatch between data and real species distributions. To assess the extent of this challenge, we review the global status and accessibility of ongoing scientific bottom trawl surveys. In total, we gathered metadata for 283,925 samples from 95 surveys conducted regularly from 2001 to 2019. We identified that 59% of the metadata collected are not publicly available, highlighting that the availability of data is the most important challenge to assess species redistributions under global climate change. Given that the primary purpose of surveys is to provide independent data to inform stock assessment of commercially important populations, we further highlight that single surveys do not cover the full range of the main commercial demersal fish species. An average of 18 surveys is needed to cover at least 50% of species ranges, demonstrating the importance of combining multiple surveys to evaluate species range shifts. We assess the potential for combining surveys to track transboundary species redistributions and show that differences in sampling schemes and inconsistency in sampling can be overcome with spatio-temporal modeling to follow species density redistributions. In light of our global assessment, we establish a framework for improving the management and conservation of transboundary and migrating marine demersal species. We provide directions to improve data availability and encourage countries to share survey data, to assess species vulnerabilities, and to support management adaptation in a time of climate-driven ocean changes., (© 2020 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2021

7. Response to Comment on "Impacts of historical warming on marine fisheries production".

Author

Free CM, Thorson JT, Pinsky ML, Oken KL, Wiedenmann J, and Jensen OP

Subjects

Population Dynamics, Temperature, Fisheries

Abstract

Szuwalski argues that varying age structure can affect surplus production and that recruitment is a better metric of productivity. We explain how our null model controlled for age structure and other processes as explanations for the temperature-production relationship. Surplus production includes growth, recruitment, and other processes and provides a more complete description of food production impacts than does recruitment alone., (Copyright © 2019, American Association for the Advancement of Science.)

Published

2019

8. Impacts of historical warming on marine fisheries production.

Author

Free CM, Thorson JT, Pinsky ML, Oken KL, Wiedenmann J, and Jensen OP

Subjects

Animals, Ecosystem, Fishes, Models, Theoretical, Population Dynamics, Temperature, Climate Change, Fisheries

Abstract

Climate change is altering habitats for marine fishes and invertebrates, but the net effect of these changes on potential food production is unknown. We used temperature-dependent population models to measure the influence of warming on the productivity of 235 populations of 124 species in 38 ecoregions. Some populations responded significantly positively ( n = 9 populations) and others responded significantly negatively ( n = 19 populations) to warming, with the direction and magnitude of the response explained by ecoregion, taxonomy, life history, and exploitation history. Hindcasts indicate that the maximum sustainable yield of the evaluated populations decreased by 4.1% from 1930 to 2010, with five ecoregions experiencing losses of 15 to 35%. Outcomes of fisheries management-including long-term food provisioning-will be improved by accounting for changing productivity in a warmer ocean., (Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2019

9. Path-dependent institutions drive alternative stable states in conservation.

Author

Tekwa EW, Fenichel EP, Levin SA, and Pinsky ML

Subjects

Humans, Conservation of Natural Resources, Fisheries, Models, Theoretical

Abstract

Understanding why some renewable resources are overharvested while others are conserved remains an important challenge. Most explanations focus on institutional or ecological differences among resources. Here, we provide theoretical and empirical evidence that conservation and overharvest can be alternative stable states within the same exclusive-resource management system because of path-dependent processes, including slow institutional adaptation. Surprisingly, this theory predicts that the alternative states of strong conservation or overharvest are most likely for resources that were previously thought to be easily conserved under optimal management or even open access. Quantitative analyses of harvest rates from 217 intensely managed fisheries supports the predictions. Fisheries' harvest rates also showed transient dynamics characteristic of path dependence, as well as convergence to the alternative stable state after unexpected transitions. This statistical evidence for path dependence differs from previous empirical support that was based largely on case studies, experiments, and distributional analyses. Alternative stable states in conservation appear likely outcomes for many cooperatively managed renewable resources, which implies that achieving conservation outcomes hinges on harnessing existing policy tools to navigate transitions., Competing Interests: The authors declare no conflict of interest., (Copyright © 2019 the Author(s). Published by PNAS.)

Published

2019

10. Preparing ocean governance for species on the move.

Author

Pinsky ML, Reygondeau G, Caddell R, Palacios-Abrantes J, Spijkers J, and Cheung WWL

Subjects

Animals, Atmosphere, Oceans and Seas, Policy, Temperature, Animal Migration, Fisheries trends, Fishes

Published

2018

11. Throwing back the big ones saves a fishery from hot water.

Author

Pinsky ML

Subjects

Water, Fisheries, Sports

Abstract

Competing Interests: The author declares no conflict of interest.

Published

2018

12. Range contraction enables harvesting to extinction.

Author

Burgess MG, Costello C, Fredston-Hermann A, Pinsky ML, Gaines SD, Tilman D, and Polasky S

Subjects

Animals, Costs and Cost Analysis, Ecosystem, Population Density, Extinction, Biological, Fisheries economics, Models, Biological

Abstract

Economic incentives to harvest a species usually diminish as its abundance declines, because harvest costs increase. This prevents harvesting to extinction. A known exception can occur if consumer demand causes a declining species' harvest price to rise faster than costs. This threat may affect rare and valuable species, such as large land mammals, sturgeons, and bluefin tunas. We analyze a similar but underappreciated threat, which arises when the geographic area (range) occupied by a species contracts as its abundance declines. Range contractions maintain the local densities of declining populations, which facilitates harvesting to extinction by preventing abundance declines from causing harvest costs to rise. Factors causing such range contractions include schooling, herding, or flocking behaviors-which, ironically, can be predator-avoidance adaptations; patchy environments; habitat loss; and climate change. We use a simple model to identify combinations of range contractions and price increases capable of causing extinction from profitable overharvesting, and we compare these to an empirical review. We find that some aquatic species that school or forage in patchy environments experience sufficiently severe range contractions as they decline to allow profitable harvesting to extinction even with little or no price increase; and some high-value declining aquatic species experience severe price increases. For terrestrial species, the data needed to evaluate our theory are scarce, but available evidence suggests that extinction-enabling range contractions may be common among declining mammals and birds. Thus, factors causing range contraction as abundance declines may pose unexpectedly large extinction risks to harvested species.

Published

2017

13. Fishing, fast growth and climate variability increase the risk of collapse.

Author

Pinsky ML and Byler D

Subjects

Animals, Extinction, Biological, Fishes growth & development, Oceans and Seas, Population Dynamics, Risk, Climate Change, Conservation of Natural Resources, Fisheries, Fishes physiology

Abstract

Species around the world have suffered collapses, and a key question is why some populations are more vulnerable than others. Traditional conservation biology and evidence from terrestrial species suggest that slow-growing populations are most at risk, but interactions between climate variability and harvest dynamics may alter or even reverse this pattern. Here, we test this hypothesis globally. We use boosted regression trees to analyse the influences of harvesting, species traits and climate variability on the risk of collapse (decline below a fixed threshold) across 154 marine fish populations around the world. The most important factor explaining collapses was the magnitude of overfishing, while the duration of overfishing best explained long-term depletion. However, fast growth was the next most important risk factor. Fast-growing populations and those in variable environments were especially sensitive to overfishing, and the risk of collapse was more than tripled for fast-growing when compared with slow-growing species that experienced overfishing. We found little evidence that, in the absence of overfishing, climate variability or fast growth rates alone drove population collapse over the last six decades. Expanding efforts to rapidly adjust harvest pressure to account for climate-driven lows in productivity could help to avoid future collapses, particularly among fast-growing species., (© 2015 The Author(s).)

Published

2015

14. Meta-analysis reveals lower genetic diversity in overfished populations.

Author

Pinsky ML and Palumbi SR

Subjects

Alleles, Animals, Computer Simulation, Linear Models, Microsatellite Repeats, Models, Genetic, Population Density, Fisheries, Fishes genetics, Genetic Variation, Genetics, Population

Abstract

While population declines can drive the loss of genetic diversity under some circumstances, it has been unclear whether this loss is a general consequence of overharvest in highly abundant marine fishes. We compiled data from 11 049 loci across 140 species and found that allelic richness was lower in overfished populations within 9 of 12 genera and families. A multiple linear regression showed that allelic richness was on average 12% lower (P < 0.0001) in overharvested populations after accounting for the effects of body size, latitude and other factors. Heterozygosity was on average 2% lower (P = 0.030). Simulations confirmed that these patterns are consistent with a recent bottleneck in abundant species and also showed that our analysis likely underestimates the loss of rare alleles by a factor of two or three. This evidence suggests that overharvest drives the decay of genetic diversity across a wide range of marine fishes. Such reductions of genetic diversity in some of the world's most abundant species may lead to a long-term impact of fishing on their evolutionary potential, particularly if abundance remains low and diversity continues to decay., (© 2013 John Wiley & Sons Ltd.)

Published

2014

15. Unexpected patterns of fisheries collapse in the world's oceans.

Author

Pinsky ML, Jensen OP, Ricard D, and Palumbi SR

Subjects

Animals, Body Size, Fishes, Food Chain, Oceans and Seas, Ecosystem, Endangered Species, Fisheries methods

Abstract

Understanding which species are most vulnerable to human impacts is a prerequisite for designing effective conservation strategies. Surveys of terrestrial species have suggested that large-bodied species and top predators are the most at risk, and it is commonly assumed that such patterns also apply in the ocean. However, there has been no global test of this hypothesis in the sea. We analyzed two fisheries datasets (stock assessments and landings) to determine the life-history traits of species that have suffered dramatic population collapses. Contrary to expectations, our data suggest that up to twice as many fisheries for small, low trophic-level species have collapsed compared with those for large predators. These patterns contrast with those on land, suggesting fundamental differences in the ways that industrial fisheries and land conversion affect natural communities. Even temporary collapses of small, low trophic-level fishes can have ecosystem-wide impacts by reducing food supply to larger fish, seabirds, and marine mammals.

Published

2011

16. FISHGLOB_data: an integrated dataset of fish biodiversity sampled with scientific bottom-trawl surveys.

Author

Maureaud, Aurore, Palacios-Abrantes, Juliano, Kitchel, Zoë, Mannocci, Laura, Pinsky, Malin, Fredston, Alexa, Beukhof, Esther, Forrest, Daniel, Frelat, Romain, Palomares, Maria, Pecuchet, Laurene, Thorson, James, van Denderen, P, and Mérigot, Bastien

Subjects

Animals, Biodiversity, Ecosystem, Fisheries, Fishes, Oceans and Seas

Abstract

Scientific bottom-trawl surveys are ecological observation programs conducted along continental shelves and slopes of seas and oceans that sample marine communities associated with the seafloor. These surveys report taxa occurrence, abundance and/or weight in space and time, and contribute to fisheries management as well as population and biodiversity research. Bottom-trawl surveys are conducted all over the world and represent a unique opportunity to understand ocean biogeography, macroecology, and global change. However, combining these data together for cross-ecosystem analyses remains challenging. Here, we present an integrated dataset of 29 publicly available bottom-trawl surveys conducted in national waters of 18 countries that are standardized and pre-processed, covering a total of 2,170 sampled fish taxa and 216,548 hauls collected from 1963 to 2021. We describe the processing steps to create the dataset, flags, and standardization methods that we developed to assist users in conducting spatio-temporal analyses with stable regional survey footprints. The aim of this dataset is to support research, marine conservation, and management in the context of global change.

Published

2024

17. The importance of oxygen for explaining rapid shifts in a marine fish

Author

Bandara, Rathnayaka Mudiyanselage Wajra Jeewantha, Curchitser, Enrique, and Pinsky, Malin L

Subjects

Climate Change Impacts and Adaptation, Biological Sciences, Environmental Sciences, Life Below Water, Animals, Ecosystem, Oxygen, Fishes, Biodiversity, Food Chain, Climate Change, Temperature, fisheries, marine biogeography, Metabolic Index, oxygen, physiology, species distribution modeling, species shifts, temperature, Ecology, Biological sciences, Earth sciences, Environmental sciences

Abstract

Large-scale shifts in marine species biogeography have been a notable impact of climate change. An effective explanation of what drives these species shifts, as well as accurate predictions of where they might move, is crucial to effectively managing these natural resources and conserving biodiversity. While temperature has been implicated as a major driver of these shifts, physiological processes suggest that oxygen, prey, and other factors should also play important roles. We expanded upon previous temperature-based distribution models by testing whether oxygen, food web productivity, salinity, and scope for metabolic activity (the Metabolic Index) better explained the changing biogeography of Black Sea Bass (Centropristis striata) in the Northeast US. This species has been expanding further north over the past 15 years. We found that oxygen improved model performance beyond a simple consideration of temperature (ΔAIC = 799, ΔTSS = 0.015), with additional contributions from prey and salinity. However, the Metabolic Index did not substantially increase model performance relative to temperature and oxygen (ΔAIC = 0.63, ΔTSS = 0.0002). Marine species are sensitive to oxygen, and we encourage researchers to use ocean biogeochemical hindcast and forecast products to better understand marine biogeographic changes.

Published

2024

18. Drivers of conflict and resilience in shifting transboundary fisheries

Author

Vogel, Jacqueline M, Longo, Catherine, Spijkers, Jessica, Palacios-Abrantes, Juliano, Mason, Julia, Wabnitz, Colette CC, Cheung, William, Sumaila, U Rashid, Munro, Gordon, Glaser, Sarah, Bell, Johann, Tian, Yongjun, Shackell, Nancy L, Selig, Elizabeth R, Le Billon, Philippe, Watson, James R, Hendrix, Cullen, Pinsky, Malin L, van Putten, Ingrid, Karr, Kendra, Papaioannou, Eva A, and Fujita, Rod

Subjects

Environmental Sciences, Environmental Management, Transboundary fisheries, Shifting stocks, Fisheries conflict, Ocean governance, High seas, Environmental Science and Management, Political Science, Law, Fisheries, Environmental management, Policy and administration, Political science

Abstract

Climate change is causing fish stocks to shift, upending the social-ecological systems that rely on the historic distributions of these stocks and creating or exacerbating fisheries conflicts. The movements of internationally shared stocks between Exclusive Economic Zones (EEZs) or between EEZs and the high seas are especially concerning because they bring into play a variety of geopolitical factors and equity issues surrounding missing or conflicting regulations of jurisdictional boundary zones. Though many studies have explored the responses to and repercussions of shifting stocks on fisheries management, there is a dearth of interdisciplinary case studies that provide insight into the complexity of conflict formation in shifting transboundary fisheries, and that highlight the initial response stages where inclusion of proactive and cooperative measures can greatly improve a system's resilience to conflict. Our study helps to fill this gap by drawing on the knowledge of a diverse group of experts to analyze four case studies where transboundary stock shifts, geopolitical or governance tensions, and uncertainty regarding the future of the marine environment collide. Through synthesis of case study findings, we create a causal model of fishery conflict, within which we highlight factors that may heighten or mitigate the risk of conflict over shifting resources such as complex histories of power imbalance, unequal access to resources, or a lack of consistent and transparent data collection. Cooperation and equitable decision-making processes are recognized as vital components of internationally shared stock management which can promote lasting, effective, and conflict-resilient fisheries.

Published

2023

19. Ocean warming alters the distributional range, migratory timing, and spatial protections of an apex predator, the tiger shark (Galeocerdo cuvier).

Author

Hammerschlag, Neil, McDonnell, Laura, Rider, Mitchell, Street, Garrett, Hazen, Elliott, Natanson, Lisa, McCandless, Camilla, Boudreau, Melanie, Gallagher, Austin, Pinsky, Malin, and Kirtman, Ben

Subjects

climate change, conservation, ecosystem impacts, fisheries, global change, predators, range shifts, sharks, Animals, Climate Change, Ecosystem, Fisheries, Humans, Oceans and Seas, Sharks

Abstract

Given climate change threats to ecosystems, it is critical to understand the responses of species to warming. This is especially important in the case of apex predators since they exhibit relatively high extinction risk, and changes to their distribution could impact predator-prey interactions that can initiate trophic cascades. Here we used a combined analysis of animal tracking, remotely sensed environmental data, habitat modeling, and capture data to evaluate the effects of climate variability and change on the distributional range and migratory phenology of an ectothermic apex predator, the tiger shark (Galeocerdo cuvier). Tiger sharks satellite tracked in the western North Atlantic between 2010 and 2019 revealed significant annual variability in the geographic extent and timing of their migrations to northern latitudes from ocean warming. Specifically, tiger shark migrations have extended farther poleward and arrival times to northern latitudes have occurred earlier in the year during periods with anomalously high sea-surface temperatures. A complementary analysis of nearly 40 years of tiger shark captures in the region revealed decadal-scale changes in the distribution and timing of shark captures in parallel with long-term ocean warming. Specifically, areas of highest catch densities have progressively increased poleward and catches have occurred earlier in the year off the North American shelf. During periods of anomalously high sea-surface temperatures, movements of tracked sharks shifted beyond spatial management zones that had been affording them protection from commercial fishing and bycatch. Taken together, these study results have implications for fisheries management, human-wildlife conflict, and ecosystem functioning.

Published

2022

20. Cold range edges of marine fishes track climate change better than warm edges

Author

Fredston‐Hermann, Alexa, Selden, Rebecca, Pinsky, Malin, Gaines, Steven D, and Halpern, Benjamin S

Subjects

Climate Action, Animals, Climate Change, Cold Temperature, Ecosystem, Fishes, Temperature, biogeography, ecophysiology, fisheries, Northwest Atlantic, range limit, spatial ecology, species distributions, thermal tolerance, Environmental Sciences, Biological Sciences, Ecology

Abstract

Species around the world are shifting their ranges in response to climate change. To make robust predictions about climate-related colonizations and extinctions, it is vital to understand the dynamics of range edges. This study is among the first to examine annual dynamics of cold and warm range edges, as most global change studies average observational data over space or over time. We analyzed annual range edge dynamics of marine fishes-both at the individual species level and pooled into cold- and warm-edge assemblages-in a multi-decade time-series of trawl surveys conducted on the Northeast US Shelf during a period of rapid warming. We tested whether cold edges show stronger evidence of climate tracking than warm edges (due to non-climate processes or time lags at the warm edge; the biogeography hypothesis or extinction debt hypothesis), or whether they tracked temperature change equally (due to the influence of habitat suitability; the ecophysiology hypothesis). In addition to exploring correlations with regional temperature change, we calculated species- and assemblage-specific sea bottom and sea surface temperature isotherms and used them to predict range edge position. Cold edges shifted further and tracked sea surface and bottom temperature isotherms to a greater degree than warm edges. Mixed-effects models revealed that for a one-degree latitude shift in isotherm position, cold edges shifted 0.47 degrees of latitude, and warm edges shifted only 0.28 degrees. Our results suggest that cold range edges are tracking climate change better than warm range edges, invalidating the ecophysiology hypothesis. We also found that even among highly mobile marine ectotherms in a global warming hotspot, few species are fully keeping pace with climate.

Published

2020

21. Fishing, fast growth and climate variability increase the risk of collapse.

Author

Pinsky, Malin and Byler, David

Subjects

conservation, coupled social–ecological systems, cumulative impacts, ecosystem-based management, population dynamics, Animals, Climate Change, Conservation of Natural Resources, Extinction, Biological, Fisheries, Fishes, Oceans and Seas, Population Dynamics, Risk

Abstract

Species around the world have suffered collapses, and a key question is why some populations are more vulnerable than others. Traditional conservation biology and evidence from terrestrial species suggest that slow-growing populations are most at risk, but interactions between climate variability and harvest dynamics may alter or even reverse this pattern. Here, we test this hypothesis globally. We use boosted regression trees to analyse the influences of harvesting, species traits and climate variability on the risk of collapse (decline below a fixed threshold) across 154 marine fish populations around the world. The most important factor explaining collapses was the magnitude of overfishing, while the duration of overfishing best explained long-term depletion. However, fast growth was the next most important risk factor. Fast-growing populations and those in variable environments were especially sensitive to overfishing, and the risk of collapse was more than tripled for fast-growing when compared with slow-growing species that experienced overfishing. We found little evidence that, in the absence of overfishing, climate variability or fast growth rates alone drove population collapse over the last six decades. Expanding efforts to rapidly adjust harvest pressure to account for climate-driven lows in productivity could help to avoid future collapses, particularly among fast-growing species.

Published

2015

22. Response to Comment on 'Impacts of historical warming on marine fisheries production'

Author

Free, Christopher M, Thorson, James T, Pinsky, Malin L, Oken, Kiva L, Wiedenmann, John, and Jensen, Olaf P

Subjects

General Science & Technology, Population Dynamics, Temperature, Fisheries, food and beverages

Abstract

Szuwalski argues that varying age structure can affect surplus production and that recruitment is a better metric of productivity. We explain how our null model controlled for age structure and other processes as explanations for the temperature-production relationship. Surplus production includes growth, recruitment, and other processes and provides a more complete description of food production impacts than does recruitment alone.

Published

2019

23. Adaptation strategies of coastal fishing communities as species shift poleward

Author

McCay, Bonnie, Pinsky, Malin L., Young, Talia, Fuller, Emma, Provost, Mikaela M., Coleman, Kaycee E., and St. Martin, Kevin

Subjects

Portfolio effect, Social-ecological system, Diversification, Climate Change, Fisheries, Communities-at-Sea

Abstract

In this period of environmental change, understanding how resource users respond to such changes is critical for effective resource management and adaptation planning. Extensive work has focused on natural resource responses to environmental changes, but less has examined the re- sponse of resource users to such changes. We used an interdisciplinary approach to analyse changes in resource use among commercial trawl fish- ing communities in the northwest Atlantic, a region that has shown poleward shifts in harvested fish species. We found substantial community- level changes in fishing patterns since 1996: southern trawl fleets of larger vessels with low catch diversity fished up to 400 km further north, while trawl fleets of smaller vessels with low catch diversity shrank or disappeared from the data set over time. In contrast, trawl fleets (of both large and small vessels) with higher catch diversity neither changed fishing location dramatically or nor disappeared as often from the data set. This analysis suggests that catch diversity and high mobility may buffer fishing communities from effects of environmental change. Particularly in times of rapid and uncertain change, constructing diverse portfolios and allowing for fleet mobility may represent effective adaptation strategies.

Published

2019

24. Impacts of historical warming on marine fisheries production

Author

Oken, Kiva L., Wiedenmann, John, Jensen, Olaf P., Free, Christopher M., Thorson, James T., and Pinsky, Malin L.

Subjects

Theoretical, Models, General Science & Technology, Climate Change, Population Dynamics, Fishes, Temperature, Fisheries, Animals, Ecosystem

Abstract

Climate change is altering habitats for marine fishes and invertebrates, but the net effect of these changes on potential food production is unknown. We used temperature-dependent population models to measure the influence of warming on the productivity of 235 populations of 124 species in 38 ecoregions. Some populations responded significantly positively (n = 9 populations) and others responded significantly negatively (n = 19 populations) to warming, with the direction and magnitude of the response explained by ecoregion, taxonomy, life history, and exploitation history. Hindcasts indicate that the maximum sustainable yield of the evaluated populations decreased by 4.1% from 1930 to 2010, with five ecoregions experiencing losses of 15 to 35%. Outcomes of fisheries management���including long-term food provisioning���will be improved by accounting for changing productivity in a warmer ocean.

Published

2019

25. Fish and fisheries in hot water: What is happening and how do we adapt?

Author

Pinsky, Malin L., Fenichel, Eli, Fogarty, Michael, Levin, Simon, McCay, Bonnie, St. Martin, Kevin, Selden, Rebecca L., and Talia Young

Subjects

OCEAN zoning, HOT water, FISHERY management, FISHERIES, MARINE biodiversity, BYCATCHES, MARINE resources conservation, ECOSYSTEM dynamics

Abstract

Rapid climate changes are currently driving substantial reorganizations of marine ecosystems around the world. A key question is how these changes will alter the provision of ecosystem services from the ocean, particularly from fisheries. To answer this question, we need to understand not only the ecological dynamics of marine systems, but also human adaptation and feedbacks between humans and the rest of the natural world. In this review, we outline what we have learned from research primarily in continental shelf ecosystems and fishing communities of North America. Key findings are that marine animals are highly sensitive to warming and are responding quickly to changes in water temperature, and that such changes are often happening faster than similar processes on land. Changes in species distributions and productivity are having substantial impacts on fisheries, including through changing catch compositions and longer distances traveled for fishing trips. Conflicts over access to fisheries have also emerged as species distributions are no longer aligned with regulations or catch allocations. These changes in the coupled natural-human system have reduced the value of ecosystem services from some fisheries and risk doing so even more in the future. Going forward, substantial opportunities for more effective fisheries management and operations, marine conservation, and marine spatial planning are likely possible through greater consideration of climate information over time-scales from years to decades. [ABSTRACT FROM AUTHOR]

Published

2021

26. Governing fisheries in the face of change: Social responses to long-term geographic shifts in a U.S. fishery.

Author

Dubik, Bradford A., Clark, Elizabeth C., Young, Talia, Zigler, Sarah Bess Jones, Provost, Mikaela M., Pinsky, Malin L., and St. Martin, Kevin

Subjects

SUSTAINABLE fisheries, BIODIVERSITY, AQUACULTURE, OCEAN zoning, MARINE resources conservation

Abstract

Abstract Change, adaptation, and resilience have emerged as central concerns in the study of natural resource governance. The mobility of fisheries makes them particularly dynamic and susceptible to long term drivers of movement, such as changing climatic conditions and human pressures. To explore how movement impacts resource systems, this paper presents a mixed-method empirical analysis of long-term geographic shifts and social response in the Northeast U.S. summer flounder fishery from 1996 to 2014. First, the paper describes changes in the distribution of summer flounder and the catch location of commercial fishing trips landing summer flounder. This is followed by a description of the institutional context of summer flounder fishery management and a narrative policy analysis of the ongoing regulatory process. Results indicate significant northward movement of both resource and resource users. Fisheries movement patterns are a result of both ecological change, and an institutional context that allows for some types of fishery mobility while constraining others. Significant conflict has emerged over the distribution of resource access and benefits as these fishery shifts occur within a spatially allocative, and relatively static management context. The analysis identifies competing policy narratives that have emerged to advocate for different forms of adaptation. Narratives offer contesting constructions of the nature and extent of locational shifts, and the fundamental goals of allocation. The differences in these narratives highlight how policy history shapes contemporary disagreements about appropriate response. This fishery serves as a case study for exploring human response to large scale, long-term movements of a natural resource. Highlights • Fishing activity for summer flounder, Paralichthys dentatus has shifted northward. • Amount of shift differs among participating states. • Shifts lead to conflict around management and basic assumptions about the fishery. • Actors employ policy narratives to advocate for institutional change. [ABSTRACT FROM AUTHOR]

Published

2019

27. Adaptation strategies of coastal fishing communities as species shift poleward.

Author

Young, Talia, Fuller, Emma C, Provost, Mikaela M, Coleman, Kaycee E, Martin, Kevin St., McCay, Bonnie J, Pinsky, Malin L, and Makino, Handling editor: Mitsutaku

Subjects

FISHING, FISHING villages, GLOBAL environmental change, RESOURCE management, NATURAL resources

Abstract

In this period of environmental change, understanding how resource users respond to such changes is critical for effective resource management and adaptation planning. Extensive work has focused on natural resource responses to environmental changes, but less has examined the response of resource users to such changes. We used an interdisciplinary approach to analyse changes in resource use among commercial trawl fishing communities in the northwest Atlantic, a region that has shown poleward shifts in harvested fish species. We found substantial community-level changes in fishing patterns since 1996: southern trawl fleets of larger vessels with low catch diversity fished up to 400 km further north, while trawl fleets of smaller vessels with low catch diversity shrank or disappeared from the data set over time. In contrast, trawl fleets (of both large and small vessels) with higher catch diversity neither changed fishing location dramatically or nor disappeared as often from the data set. This analysis suggests that catch diversity and high mobility may buffer fishing communities from effects of environmental change. Particularly in times of rapid and uncertain change, constructing diverse portfolios and allowing for fleet mobility may represent effective adaptation strategies. [ABSTRACT FROM AUTHOR]

Published

2019

28. Drivers of conflict and resilience in shifting transboundary fisheries.

Author

Vogel, Jacqueline M., Longo, Catherine, Spijkers, Jessica, Palacios-Abrantes, Juliano, Mason, Julia, Wabnitz, Colette C.C., Cheung, William, Sumaila, U. Rashid, Munro, Gordon, Glaser, Sarah, Bell, Johann, Tian, Yongjun, Shackell, Nancy L., Selig, Elizabeth R., Le Billon, Philippe, Watson, James R., Hendrix, Cullen, Pinsky, Malin L., van Putten, Ingrid, and Karr, Kendra

Subjects

FISHERIES, FISHERY management, CAUSAL models, FISH populations, NETWORK governance, CLIMATE change, INTERDISCIPLINARY education, ACQUISITION of data

Abstract

Climate change is causing fish stocks to shift, upending the social-ecological systems that rely on the historic distributions of these stocks and creating or exacerbating fisheries conflicts. The movements of internationally shared stocks between Exclusive Economic Zones (EEZs) or between EEZs and the high seas are especially concerning because they bring into play a variety of geopolitical factors and equity issues surrounding missing or conflicting regulations of jurisdictional boundary zones. Though many studies have explored the responses to and repercussions of shifting stocks on fisheries management, there is a dearth of interdisciplinary case studies that provide insight into the complexity of conflict formation in shifting transboundary fisheries, and that highlight the initial response stages where inclusion of proactive and cooperative measures can greatly improve a system's resilience to conflict. Our study helps to fill this gap by drawing on the knowledge of a diverse group of experts to analyze four case studies where transboundary stock shifts, geopolitical or governance tensions, and uncertainty regarding the future of the marine environment collide. Through synthesis of case study findings, we create a causal model of fishery conflict, within which we highlight factors that may heighten or mitigate the risk of conflict over shifting resources such as complex histories of power imbalance, unequal access to resources, or a lack of consistent and transparent data collection. Cooperation and equitable decision-making processes are recognized as vital components of internationally shared stock management which can promote lasting, effective, and conflict-resilient fisheries. [ABSTRACT FROM AUTHOR]

Published

2023

29. Projecting shifts in thermal habitat for 686 species on the North American continental shelf.

Author

Morley, James W., Selden, Rebecca L., Latour, Robert J., Frölicher, Thomas L., Seagraves, Richard J., and Pinsky, Malin L.

Subjects

CONTINENTAL shelf, BIOGEOGRAPHY, MARINE resource management, MARINE species diversity, OCEAN temperature

Abstract

Recent shifts in the geographic distribution of marine species have been linked to shifts in preferred thermal habitats. These shifts in distribution have already posed challenges for living marine resource management, and there is a strong need for projections of how species might be impacted by future changes in ocean temperatures during the 21st century. We modeled thermal habitat for 686 marine species in the Atlantic and Pacific oceans using long-term ecological survey data from the North American continental shelves. These habitat models were coupled to output from sixteen general circulation models that were run under high (RCP 8.5) and low (RCP 2.6) future greenhouse gas emission scenarios over the 21st century to produce 32 possible future outcomes for each species. The models generally agreed on the magnitude and direction of future shifts for some species (448 or 429 under RCP 8.5 and RCP 2.6, respectively), but strongly disagreed for other species (116 or 120 respectively). This allowed us to identify species with more or less robust predictions. Future shifts in species distributions were generally poleward and followed the coastline, but also varied among regions and species. Species from the U.S. and Canadian west coast including the Gulf of Alaska had the highest projected magnitude shifts in distribution, and many species shifted more than 1000 km under the high greenhouse gas emissions scenario. Following a strong mitigation scenario consistent with the Paris Agreement would likely produce substantially smaller shifts and less disruption to marine management efforts. Our projections offer an important tool for identifying species, fisheries, and management efforts that are particularly vulnerable to climate change impacts. [ABSTRACT FROM AUTHOR]

Published

2018

30. Marine assemblages respond rapidly to winter climate variability.

Author

Morley, James W., Batt, Ryan D., and Pinsky, Malin L.

Subjects

CLIMATE change, FISHERIES, TEMPERATURE, WINTER, BIOMASS

Abstract

Even species within the same assemblage have varied responses to climate change, and there is a poor understanding for why some taxa are more sensitive to climate than others. In addition, multiple mechanisms can drive species' responses, and responses may be specific to certain life stages or times of year. To test how marine species respond to climate variability, we analyzed 73 diverse taxa off the southeast US coast in 26 years of scientific trawl survey data and determined how changes in distribution and biomass relate to temperature. We found that winter temperatures were particularly useful for explaining interannual variation in species' distribution and biomass, although the direction and magnitude of the response varied among species from strongly negative, to little response, to strongly positive. Across species, the response to winter temperature varied greatly, with much of this variation being explained by thermal preference. A separate analysis of annual commercial fishery landings revealed that winter temperatures may also impact several important fisheries in the southeast United States. Based on the life stages of the species surveyed, winter temperature appears to act through overwinter mortality of juveniles or as a cue for migration timing. We predict that this assemblage will be responsive to projected increases in temperature and that winter temperature may be broadly important for species relationships with climate on a global scale. [ABSTRACT FROM AUTHOR]

Published

2017

31. Building confidence in projections of the responses of living marine resources to climate change.

Author

Cheung, William W. L., Frölicher, Thomas L., Asch, Rebecca G., Jones, Miranda C., Pinsky, Malin L., Reygondeau, Gabriel, Rodgers, Keith B., Rykaczewski, Ryan R., Sarmiento, Jorge L., Stock, Charles, and Watson, James R.

Subjects

MARINE resources, CLIMATE change, OCEAN acidification, OCEAN temperature, ATMOSPHERIC models

Abstract

The Fifth Assessment Report of the Intergovernmental Panel on Climate Change highlights that climate change and ocean acidification are challenging the sustainable management of living marine resources (LMRs). Formal and systematic treatment of uncertainty in existing LMR projections, however, is lacking. We synthesize knowledge of how to address different sources of uncertainty by drawing from climate model intercomparison efforts. We suggest an ensemble of available models and projections, informed by observations, as a starting point to quantify uncertainties. Such an ensemble must be paired with analysis of the dominant uncertainties over different spatial scales, time horizons, and metrics. We use two examples: (i) global and regional projections of Sea Surface Temperature and (ii) projection of changes in potential catch of sablefish (Anoplopoma fimbria) in the 21st century, to illustrate this ensemble model approach to explore different types of uncertainties. Further effort should prioritize understanding dominant, undersampled dimensions of uncertainty, as well as the strategic collection of observations to quantify, and ultimately reduce, uncertainties. Our proposed framework will improve our understanding of future changes in LMR and the resulting risk of impacts to ecosystems and the societies under changing ocean conditions. [ABSTRACT FROM AUTHOR]

Published

2016

32. Emerging Adaptation Approaches for Climate-Ready Fisheries Management.

Author

Pinsky, Malin L. and Mantua, Nathan J.

Subjects

*FISHERIES, *FISHERY management, *CLIMATE change, *MARINE resources, *FISH population measurement

Abstract

By 2100, ocean waters are expected to be substantially warmer and more acidic than they are today, with profound effects on coupled social-ecological fisheries systems. Despite broad recognition of impacts from both anthropogenic climate change and natural climate variability, incorporating climate and acidification considerations into management approaches has been difficult. However, clear opportunities exist for fostering "climate-ready" fisheries management, as evidenced by emerging research and implementation experiences that we review here. Approaches now exist for integrating climate change and variability into monitoring, vulnerability assessments, stock assessments, spatial management, annual harvest limits, international agreements, and management of emerging fisheries. While uncertainty, limited understanding, and the increased complexity of these new considerations have delayed more widespread implementation to date, these factors do not change the reality of climate change impacts on living marine resources. We conclude that, despite ongoing research needs, fisheries management can substantially expand capacity to respond to a changing climate. [ABSTRACT FROM AUTHOR]

Published

2014

33. Capital Investment for Optimal Exploitation of Renewable Resource Stocks in the Age of Global Change.

Author

Moberg, Emily A., Pinsky, Malin L., and Fenichel, Eli P.

Subjects

*CAPITAL investments, *RESOURCE exploitation, *NATURAL resources, *BIOTIC communities, *CAPITAL stock, *ENERGY harvesting, *RENEWABLE natural resources

Abstract

The world is rapidly changing, and biotic resources and their users are adapting. Determining how ecological and economic interactions determine the outcomes of this adaptation is critical to understanding the future of natural resources. We model a two-species fisheries as a stylized system to investigate the adaptation strategies of a harvester faced with shifting species composition in an ecological community. We explore how interspecies interactions and pricing effects jointly determine the optimal adaptation strategy. We consider two interacting species that are harvested jointly, but where the harvester may exert effort towards each species differentially provided she invests in reproducible capital that allows targeting. The possible adaptation strategies comprise changes in how people interact with natural capital (for example, changing harvest levels) and investment in reproducible or human capital, which may be a substitute or complement for natural capital stocks. We find that the market price of the harvested species exerts a particularly strong impact on the adaptation strategy; all else equal, unequal prices tends to drive extreme targeting or avoidance of a new species. Economic and ecological factors can necessitate investment at equilibrium, and early, transient management decisions for beneficial species may, like with nuisance species, produce large benefits. [ABSTRACT FROM AUTHOR]

Published

2019

34. Managing living marine resources in a dynamic environment: The role of seasonal to decadal climate forecasts

Author

Tomassi, Desiree, Delworth, Tom, Eakin, C. Mark, Haltuch, Mellisa A., S��f��rian, Roland, Spillman, Claire M., Samhouri, Jameal F., Werner, Francisco E., Payne, Mark R., Kristiansen, Trond, Lehodey, Patrick, Siedlecki, Samantha, Asch, Rebecca G., Kaplan, Isaac C., Stock, Charles, Hobday, Alistair J., Methot, Rick, Eveson, J. Paige, Holsman, Kirstin, Gaitan, Carlos F., Pinsky, Malin L., Saba, Vincent S., Kapnick, Sarah B., Rykaczewski, Ryan R., Pershing, Andrew, Miller, Timothy J., Gaichas, Sarah, Gehlen, Marion, Vecchi, Gabriel, Msadek, Rym, Lynch, Patrick, Hartog, Jason R., Muhling, Barbara, Alexander, Michael A., Xue, Yan, and Pegion, Kathleen V.

Subjects

Industry operations, Marine resource, Seasonal variation, Climate Change, Fisheries, Marine Biology, Oceanography, Climate prediction, Climate variables, Climate models, Weather forecasting, Marine Environment, Natural Resources, Stakeholder, Dynamic environments, Environmental conditions, 14. Life underwater, Climate forecasts, Climate variability, Ecosystem management, Research work, Climatology, Decadal predictions, Fishery management, FOS: Earth and related environmental sciences, Managers, Sustainable Development, Environmental variables, 13. Climate action, Decadal variation, Decision making, Forecasting

Abstract

Recent developments in global dynamical climate prediction systems have allowed for skillful predictions of climate variables relevant to living marine resources (LMRs) at a scale useful to understanding and managing LMRs. Such predictions present opportunities for improved LMR management and industry operations, as well as new research avenues in fisheries science. LMRs respond to climate variability via changes in physiology and behavior. For species and systems where climate-fisheries links are well established, forecasted LMR responses can lead to anticipatory and more effective decisions, benefiting both managers and stakeholders. Here, we provide an overview of climate prediction systems and advances in seasonal to decadal prediction of marine-resource relevant environmental variables. We then describe a range of climate-sensitive LMR decisions that can be taken at lead-times of months to decades, before highlighting a range of pioneering case studies using climate predictions to inform LMR decisions. The success of these case studies suggests that many additional applications are possible. Progress, however, is limited by observational and modeling challenges. Priority developments include strengthening of the mechanistic linkages between climate and marine resource responses, development of LMR models able to explicitly represent such responses, integration of climate driven LMR dynamics in the multi-driver context within which marine resources exist, and improved prediction of ecosystemrelevant variables at the fine regional scales at which most marine resource decisions are made. While there are fundamental limits to predictability, continued advances in these areas have considerable potential to make LMR managers and industry decision more resilient to climate variability and help sustain valuable resources. Concerted dialog between scientists, LMR managers and industry is essential to realizing this potential.

35. Building confidence in projections of the responses of living marine resources to climate change

Author

Cheung, William W. L., Fr��licher, Thomas L., Asch, Rebecca G., Jones, Miranda C., Pinsky, Malin L., Reygondeau, Gabriel, Rodgers, Keith B., Rykaczewski, Ryan R., Stock, Charles, Sarmiento, Jorge L., and Watson, James R.

Subjects

Multi-model ensembles, 13. Climate action, Marine resources, Climate Change, Fisheries, Uncertainty, 14. Life underwater, Projection

Abstract

The Fifth Assessment Report of the Intergovernmental Panel on Climate Change highlights that climate change and ocean acidification are challenging the sustainable management of living marine resources (LMRs). Formal and systematic treatment of uncertainty in existing LMR projections, however, is lacking. We synthesize knowledge of how to address different sources of uncertainty by drawing from climate model intercomparison efforts. We suggest an ensemble of available models and projections, informed by observations, as a starting point to quantify uncertainties. Such an ensemble must be paired with analysis of the dominant uncertainties over different spatial scales, time horizons, and metrics. We use two examples: (i) global and regional projections of Sea Surface Temperature and (ii) projection of changes in potential catch of sablefish (Anoplopoma fimbria) in the 21st century, to illustrate this ensemble model approach to explore different types of uncertainties. Further effort should prioritize understanding dominant, undersampled Dimensions of uncertainty, as well as the strategic collection of observations to quantify, and ultimately reduce, uncertainties. Our proposed framework will improve our understanding of future changes in LMR and the resulting risk of impacts to ecosystems and the societies under changing ocean conditions.

36. Stepping Up: A U.S. Perspective on the Ten Steps to Responsible Inland Fisheries.

Author

Carlson, Andrew K., Taylor, William W., DeVries, Dennis R., Ferreri, C. Paola, Fogarty, Michael J., Hartman, Kyle J., Infante, Dana M., Kinnison, Michael T., Levin, Simon A., Melstrom, Richard T., Newman, Raymond M., Pinsky, Malin L., Rubenstein, Daniel I., Sullivan, S. Mažeika P., Venturelli, Paul A., Weber, Michael J., Wuellner, Melissa R., and Zydlewski, Gayle B.

Subjects

*FISHERIES, *AQUACULTURE, *GOVERNMENT agencies, *MANAGEMENT science

Abstract

The Ten Steps to Responsible Inland Fisheries are global recommendations to address the subordinate position of inland fisheries in sustainability dialogues. Regional and local perspectives are essential for implementing global initiatives. Hence, we surveyed state fisheries agency administrators and American Fisheries Society Governing Board members about the importance, funding, and achievability of the Steps. Respondents rated Science, Communication, and Assessment as highly important, well funded, and achievable steps, unlike Aquaculture and a global Action Plan. Nutrition was rated the most inadequately supported yet achievable step, highlighting an opportunity to promote nutritional contributions of inland fisheries. Opinions were similar between administrators and Governing Board members across U.S. regions, suggesting a foundation for incorporating underemphasized steps into management programs by building multi‐organizational partnerships and applying lessons from better integrated steps (e.g., Science, Assessment). Overall, the Steps can advance freshwater science and management in the United States while increasing the visibility of inland fisheries that are rarely prioritized globally. [ABSTRACT FROM AUTHOR]

Published

2022

37. Disentangling tropicalization and deborealization in marine ecosystems under climate change.

Author

McLean, Matthew, Mouillot, David, Maureaud, Aurore A., Hattab, Tarek, MacNeil, M. Aaron, Goberville, Eric, Lindegren, Martin, Engelhard, Georg, Pinsky, Malin, and Auber, Arnaud

Subjects

*MARINE ecology, *CLIMATE change, *OCEAN temperature, *COLD adaptation, *FISH communities, *MARINE fishes, *GLOBAL warming

Abstract

As climate change accelerates, species are shifting poleward and subtropical and tropical species are colonizing temperate environments. 1–3 A popular approach for characterizing such responses is the community temperature index (CTI), which tracks the mean thermal affinity of a community. Studies in marine, 4 freshwater, 5 and terrestrial 6 ecosystems have documented increasing CTI under global warming. However, most studies have only linked increasing CTI to increases in warm-affinity species. Here, using long-term monitoring of marine fishes across the Northern Hemisphere, we decomposed CTI changes into four underlying processes—tropicalization (increasing warm-affinity), deborealization (decreasing cold-affinity), borealization (increasing cold-affinity), and detropicalization (decreasing warm-affinity)—for which we examined spatial variability and drivers. CTI closely tracked changes in sea surface temperature, increasing in 72% of locations. However, 31% of these increases were primarily due to decreases in cold-affinity species, i.e., deborealization. Thus, increases in warm-affinity species were prevalent, but not ubiquitous. Tropicalization was stronger in areas that were initially warmer, experienced greater warming, or were deeper, while deborealization was stronger in areas that were closer to human population centers or that had higher community thermal diversity. When CTI (and temperature) increased, species that decreased were more likely to be living closer to their upper thermal limits or to be commercially fished. Additionally, warm-affinity species that increased had smaller body sizes than those that decreased. Our results show that CTI changes arise from a variety of underlying community responses that are linked to environmental conditions, human impacts, community structure, and species characteristics. • From 1990 to 2015, mean thermal affinity increased in 72% of communities • One-third of these increases were primarily due to decreases in cold-affinity species • This was linked to temperature, depth, human pressure, and community structure • Species responses to warming were shaped by thermal limits and fishing status Using long-term monitoring of marine fishes across the Northern Hemisphere, McLean et al. show that one-third of increases in mean thermal affinity were primarily due to decreases in cold-affinity species. Cold-affinity decreases were stronger closer to human population centers; warm-affinity increases were stronger in warmer areas. [ABSTRACT FROM AUTHOR]

Published

2021

38. Ocean Recovery: A Sustainable Future for Global Fisheries?

Author

Kitchel, Zoë J., Bandara, R.M.W.J., Bos, Jaelyn T., Clark, René D., Forrest, Daniel L., and Pinsky, Malin L.

Subjects

*FISHERS, *FISHERIES, *MARINE resource management, *SMALL-scale fisheries, *OCEAN

Abstract

One of I Ocean Recovery's i more interesting discussions highlights the differences between seafood sustainability certifications, specifically by the Marine Stewardship Council (MSC) and the Monterey Bay Aquarium's Seafood Watch. The Hilborn duo take on the complexities of the past, present, and future of marine resource management from the perspective of optimistic fisheries scientists working in the developed world - a stark and intentional contrast to the more familiar doom and gloom narrative associated with the popular science genre. The Hilborns strongly advocate for process-based certifications like MSC because they should be more useful for projecting the future state of a fishery. [Extracted from the article]

Published

2021

39. TECHNICAL COMMENT ABSTRACTS.

Author

Szuwalski, Cody, Free, Christopher M., Thorson, James T., Pinsky, Malin L., Oken, Kiva L., Wiedenmann, John, and Jensen, Olaf P.

Subjects

*FISHERIES, *PRODUCTION (Economic theory)

Abstract

The article discusses a comment on the article "Impacts of historical warming on marine fisheries production" and mentions the response to the comment related to surplus production.

Published

2019