Predicting climate effects on Pacific sardine

Deyle, Ethan R.; Fogarty, Michael J.; Hsieh, Chih‐hao; Kaufman, Les; MacCall, Alec D.; Munch, Stephan B.; Perretti, Charles T.; Hao, Yue; Sugihara, George

doi:10.1073/pnas.1215506110

Cited by 178 publications

(207 citation statements)

References 32 publications

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“…In fact, it has been suggested that to effectively manage aquatic resources that management needs to adapt to changes in the physical environment [35]. The ability to adapt to changing conditions is greatly constrained when long-term average conditions are solely evaluated.…”

Section: Comparison With Previous Researchmentioning

confidence: 99%

Annual Changes in Seasonal River Water Temperatures in the Eastern and Western United States

Wagner

Midway

Whittier

et al. 2017

Water

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Changes in river water temperatures are anticipated to have direct effects on thermal habitat and fish population vital rates, and therefore, understanding temporal trends in water temperatures may be necessary for predicting changes in thermal habitat and how species might respond to such changes. However, many investigations into trends in water temperatures use regression methods that assume long-term monotonic changes in temperature, when in fact changes are likely to be nonmonotonic. Therefore, our objective was to highlight the need and provide an example of an analytical method to better quantify the short-term, nonmonotonic temporal changes in thermal habitat that are likely necessary to determine the effects of changing thermal conditions on fish populations and communities. To achieve this objective, this study uses Bayesian dynamic linear models (DLMs) to examine seasonal trends in river water temperatures from sites located in the eastern and western United States, regions that have dramatically different riverine habitats and fish communities. We estimated the annual rate of change in water temperature and found little evidence of seasonal changes in water temperatures in the eastern U.S. We found more evidence of warming for river sites located in the western U.S., particularly during the fall and winter seasons. Use of DLMs provided a more detailed view of temporal dynamics in river thermal habitat compared to more traditional methods by quantifying year-to-year changes and associated uncertainty, providing managers with the information needed to adapt decision making to short-term changes in habitat conditions that may be necessary for conserving aquatic resources in the face of a changing climate.

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Section: Comparison With Previous Researchmentioning

confidence: 99%

Annual Changes in Seasonal River Water Temperatures in the Eastern and Western United States

Wagner

Midway

Whittier

et al. 2017

Water

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“…Implicitly, the stock-recruit relationship does not account for climate variability and change, although environmental terms can be added to expand this type of model. Equation-free models reconstruct the behavior of systems directly from time-series data without the standard assumption of equations for the relationships between variables and have been applied to the Pacific sardine (Deyle et al 2013). However, such models are unable to project the future state of ecosystems on the scale of climate change.…”

Section: Modelsmentioning

confidence: 99%

Climate, Anchovy, and Sardine

Checkley

Asch

Rykaczewski

2017

Annu. Rev. Mar. Sci.

175

129

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Anchovy and sardine populated productive ocean regions over hundreds of thousands of years under a naturally varying climate, and are now subject to climate change of equal or greater magnitude occurring over decades to centuries. We hypothesize that anchovy and sardine populations are limited in size by the supply of nitrogen from outside their habitats originating from upwelling, mixing, and rivers. Projections of the responses of anchovy and sardine to climate change rely on a range of model types and consideration of the effects of climate on lower trophic levels, the effects of fishing on higher trophic levels, and the traits of these two types of fish. Distribution, phenology, nutrient supply, plankton composition and production, habitat compression, fishing, and acclimation and adaptation may be affected by ocean warming, acidification, deoxygenation, and altered hydrology. Observations of populations and evaluation of model skill are essential to resolve the effects of climate change on these fish.

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“…Judgments regarding management performance should be made in the context of the system that produced those decisions. Relevant system features include whether the management process is based on best 10 Since 2012, sardine abundance, which is affected by ocean conditions as well as fi shing mortality (Deyle et al, 2013;CDFW, 2015), has declined precipitously in Oregon and Washington as well as California. California sardine landings are now lower than they have been since 1990, and northern anchovy is now the largest (albeit still modest) component of CPS fi nfi sh catch (PFMC, 2014b).…”

Section: Discussionmentioning

confidence: 99%