Signals of large scale climate drivers, hatchery enhancement, and marine factors in Yukon River Chinook salmon survival revealed with a Bayesian life history model

Cunningham, Curry J.; Westley, Peter A. H.; Adkison, Milo D.

doi:10.1111/gcb.14315

Cited by 56 publications

(83 citation statements)

References 80 publications

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“…Coupled with declines in abundance of spawners and especially in the abundance of older and larger multi‐sea‐winter females (Chaput, ), the quantitative differences shown in Figure could amount to significant biases in total egg production estimates and erroneous comparisons with conservation limits. The recent development and application of modelling approaches capable of incorporating temporal and geographic variability in a range of life history parameters, including fecundity, will help to provide improved predictions and inferences within management (Cunningham et al ., ; Massiot‐Granier et al ., ).…”

Section: Discussionmentioning

confidence: 99%

Hierarchical analysis of wild Atlantic salmon (Salmo salar) fecundity in relation to body size and developmental traits

Hanson

Ounsley

Burton

et al. 2019

Journal of Fish Biology

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Using data from wild Atlantic salmon Salmo salar returning to spawn in seven Scottish rivers, we developed a model of fecundity based on individual body size and key developmental traits. We used a novel approach to model selection which maximises predictive accuracy for application to target river stocks to select the best from a suite of Bayesian hierarchical models. This approach aims to ensure the optimal model within the candidate set includes covariates that best predict out-of-sample data to estimate fecundity in areas where no direct observations are available. In addition to body size, the final model included the developmental characteristics of age at smolting and years spent at sea. Using two independent long-term monitoring datasets, the consequences of ignoring these characteristics was revealed by comparing predictions from the best model with models that omitted them.

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Section: Discussionmentioning

confidence: 99%

Hierarchical analysis of wild Atlantic salmon (Salmo salar) fecundity in relation to body size and developmental traits

Hanson

Ounsley

Burton

et al. 2019

Journal of Fish Biology

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“…are ideal species for exploring fitness trade‐offs as a result of selection on traits, such as body size and migratory timing (Quinn, Doctor, Kendall, & Rich, 2009). For anadromous Oncorhynchus spp., high rates of mortality occur during a brief period after juveniles (i.e., “smolts”) enter the ocean (Healey, 1982; Parker, 1971), and correspondingly, population dynamics are largely influenced by this life stage (Cunningham, Westley, & Adkinson, 2018; Rogers & Schindler, 2011). Smolt size and ocean‐entry timing are two correlated traits that influence survival; however, with few exceptions, the ecological agents of selection (sensu MacColl, 2011) are usually unknown.…”

Section: Introductionmentioning

confidence: 99%

Direction and magnitude of natural selection on body size differ among age‐classes of seaward‐migrating Pacific salmon

Ulaski

Finkle

Westley

2020

Evolutionary Applications

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Due to the mediating role of body size in determining fitness, the “bigger‐is‐better” hypothesis still pervades evolutionary ecology despite evidence that natural selection on phenotypic traits varies in time and space. For Pacific salmon (genus Oncorhynchus), most individual studies quantify selection across a narrow range of sizes and ages; therefore, uncertainties remain concerning how selection on size may differ among diverse life histories. Here, we quantify the direction and magnitude of natural selection on body size among age‐classes of multiple marine cohorts of O. nerka (sockeye salmon). Across four cohorts of seaward migrants, we calculated standardized selection differentials by comparing observed size distributions of out‐migrating juvenile salmon to back‐calculated smolt length from the scales of surviving, returning adults. Results reveal the magnitude of selection on size was very strong (>90th percentile compared to a database of 3,759 linear selection differentials) and consistent among years. However, the direction of selection on size consistently varied among age‐classes. Selection was positive for fish migrating to sea after two years in freshwater (age 2) and in their first year of life (age 0), but negative for fish migrating after 1 year in freshwater (age 1). The absolute magnitude of selection was negatively correlated to mean ocean‐entry timing, which may underpin negative selection favoring small age‐1 fish, given associations between size and timing of seaward migration. Collectively, these results indicate that “bigger is not always better” in terms of survival and emphasize trade‐offs that may exist between fitness components for organisms with similarly diverse migratory life histories.

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“…In particular, the rapidly changing winter period is producing some of the greatest impacts on northern species, with potential benefits including improved overwintering survival, leading to increases in biodiversity and productivity (Heino et al, 2009;Reist et al, 2006b;Reynolds, 1997). Additionally, earlier spring break-up and warmer summer temperatures have been linked to increased growth opportunities for Alaskan juvenile salmon, promoting size-dependent overwintering survival and ultimately productivity (Cline, Ohlberger, & Schindler, 2019;Cunningham, Westley, & Adkison, 2018;Ohlberger, Scheuerell, & Schindler, 2016;Schindler, Rogers, Scheuerell, & Abrey, 2005). While many climate change impacts have the potential to produce positive effects on northern fishes in the short-term, continued warming may produce negative effects once species' warming tolerances are surpassed (Comte & Olden, 2017;Crozier & Hutchings, 2014;Heino et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

“…While many climate change impacts have the potential to produce positive effects on northern fishes in the short-term, continued warming may produce negative effects once species' warming tolerances are surpassed (Comte & Olden, 2017;Crozier & Hutchings, 2014;Heino et al, 2009). Further, changes to summer streamflow may negatively impact stream fishes if feeding or migration activities are compromised, and species are unable to adapt (Cunningham et al, 2018;Heim et al, 2015;Neuswanger, Wipfli, Evenson, Hughes, & Rosenberger, 2015).…”

Section: Introductionmentioning

confidence: 99%

Impacts of co‐occurring environmental changes on Alaskan stream fishes

2020

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Freshwater fishes are now facing unprecedented environmental changes across their northern ranges, especially due to rapid warming occurring at higher latitudes. However, empirical research that examines co‐occurring environmental effects on northern fish communities remains limited. We used fish community data from 1587 Alaskan stream sites to examine the potential combined and interacting effects of climate change, current weather, habitat, land use, and fire on two community‐level metrics (species richness, relative abundance), and on the distributions of three Alaskan fish species. Our models were 71–76% accurate in predicting the distribution of Alaskan stream fishes using a combination of climate and habitat variables. In contrast to other freshwater ecosystems that are most threatened by land use pressures, we did not detect any evidence for the potential stress of anthropogenic land use or fire on stream fishes. Warming temperatures increased overall community richness and abundance but produced differing responses at the species level. Juvenile salmon presence was positively associated with several climate variables including warmer spring and autumn temperatures and wetter summers. In comparison, warmer seasonal temperatures contributed to declines for northern‐adapted species such as Arctic grayling and Dolly Varden. This study highlights the overarching role of current and changing climate in regulating northern stream fish biodiversity. Although many fish species may benefit from climate change across their northern ranges, localised declines are likely to occur and may prove detrimental for communities with limited fishing portfolios. Climate change adaptation and mitigation strategies customised for rapidly changing northern ecosystems will play an essential role in preserving ecologically unique northern species.

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Signals of large scale climate drivers, hatchery enhancement, and marine factors in Yukon River Chinook salmon survival revealed with a Bayesian life history model

Cited by 56 publications

References 80 publications

Hierarchical analysis of wild Atlantic salmon (Salmo salar) fecundity in relation to body size and developmental traits

Hierarchical analysis of wild Atlantic salmon (Salmo salar) fecundity in relation to body size and developmental traits

Direction and magnitude of natural selection on body size differ among age‐classes of seaward‐migrating Pacific salmon

Impacts of co‐occurring environmental changes on Alaskan stream fishes

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