Nonlinearity in interspecific interactions in response to climate change: Cod and haddock as an example

Durant, Joël M.; Ono, Kotaro; Stenseth, Nils Christian; Langangen, Øystein

doi:10.1111/gcb.15264

Cited by 13 publications

(16 citation statements)

References 76 publications

(135 reference statements)

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“…Indeed, changes of population structure linked to overexploitation have been shown to affect how a population responds to climate and exploitation forcing (Brosset et al, 2019;Durant & Hjermann, 2017;Hidalgo, Rouyer, et al, 2012;Rouyer et al, 2011). In this study, we show that in addition, the occurrence of a collapse is creating a nonlinearity in the species interactions that may eventually impact the functioning of the food chain similar to what was observed for the effect of climate warming (Ciannelli et al, 2013;Dingsør et al, 2007;Durant et al, 2020).…”

Section: Discussionsupporting

confidence: 70%

“…Many marine ecosystems are increasingly susceptible to sudden nonlinear transformations due to climate warming (Hoegh‐Guldberg & Bruno, 2010). Nonadditive effect of the environment (i.e., climate) on population dynamics has been observed in both terrestrial (Stenseth et al, 2004, 2015) and marine systems (Ciannelli et al, 2013; Dingsør et al, 2007) and may lead to different population equilibrium (Durant et al, 2020). This is particularly true for the Atlantic cod (Fauchald et al, 2011; Frank et al, 2011; Scheffer et al, 2001; Sguotti et al, 2019; Vasilakopoulos & Marshall, 2015).…”

Section: Discussionmentioning

confidence: 99%

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Stock collapse and its effect on species interactions: Cod and herring in the Norwegian‐Barents Seas system as an example

Durant

Langangen

2021

Ecology and Evolution

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At the stock level, the Norwegian Spring Spawning (NSS) herring (Clupea harengus) is a text book example of overexploitation of marine fish populations with a positive outcome. Due to overexploitation, the NSS herring stock collapsed in the 1960s from a biomass of more than 14 million tonnes in 1956 to less than 0.1 million tonnes in 1972 (Toresen & Østvedt, 2000), but is now counted as one of the largest herring stocks in the world (Engelhard & Heino, 2004). At the species level, the Atlantic cod (Gadus morhua) is a prime example for the overexploitation of marine fish populations (Sguotti et al., 2019), with the Northern cod collapse in the early 1990s being a major

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Section: Discussionsupporting

confidence: 70%

Section: Discussionmentioning

confidence: 99%

Stock collapse and its effect on species interactions: Cod and herring in the Norwegian‐Barents Seas system as an example

Durant

Langangen

2021

Ecology and Evolution

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“…In this study, we show that a nonlinearity in the species interactions has an impact on population dynamics and affects our understanding of the functioning of the food chain similar to what was observed for the effect of climate warming [6,12]. Stock assessment is conducted on a single species basis but increasingly incorporates some known interaction between the species of interest and climate or other species [44].…”

Section: Discussionmentioning

confidence: 95%

“…The analyses were based on a Gompertz state-space model [12] reparameterized as in Stenseth et al [4] incorporating competition (intra-and interspecific, respectively a i,i (with the intra-specific interaction set to 1 [4,28]) and a i,j ) and environmental variables (a i,st and a i,nao ) effects. The model (table 1: equation ( 1)) incorporated also a Gaussian distributed stochastic term (ε) to acknowledge our inadequate understanding of the complexity of the dynamics of population i (i.e.…”

Section: (A) Model Descriptionmentioning

confidence: 99%

Empirical evidence of nonlinearity in bottom up effect in a marine predator–prey system

2022

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The strength of species interactions may have profound effects on population dynamics. Empirical estimates of interaction strength are often based on the assumption that the interaction strengths are constant. Barents Sea (BS) cod and capelin are two fish populations for which such an interaction has been acknowledged and used, under the assumption of constant interaction strength, when studying their population dynamics. However, species interactions can often be nonlinear in marine ecosystems and might profoundly change our understanding of food chains. Analysing long-term time series data comprising a survey over 37 years in the Arcto-boreal BS, using a state-space modelling framework, we demonstrate that the effect of capelin on cod is not linear but shifts depending on capelin abundance: while capelin is beneficial for cod populations at high abundance; below the threshold, it becomes less important for cod. Our analysis therefore shows the importance of investigating nonlinearity in species interactions and may contribute to an improved understanding on species assemblages.

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“…Temperature variation can also affect the strength of the interaction between cod and haddock. An increase in cod abundance is associated with increased temperature, negatively affecting the haddock population abundance (Durant et al, 2020 ). However, the effect of temperature is less critical at age‐0 than for the other juvenile stages.…”

Section: Discussionmentioning

confidence: 99%

Mixed interactions among life history stages of two harvested related species

Bellier

2022

Ecology and Evolution

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Climate change and harvesting can affect the ecosystems' functioning by altering the population dynamics and interactions among species. Knowing how species interact is essential for better understanding potentially unintended consequences of harvest on multiple species in ecosystems. I analyzed how stage‐specific interactions between two harvested competitors, the haddock ( Melanogrammus aeglefinus ) and Atlantic cod ( Gadus morhua ), living in the Barents Sea affect the outcome of changes in the harvest of the two species. Using state‐space models that account for observation errors and stochasticity in the population dynamics, I run different harvesting scenarios and track population‐level responses of both species. The increasing temperature elevated the number of larvae of haddock but did not significantly influence the older age‐classes. The nature of the interactions between both species shifted from predator‐prey to competition around age‐2 to ‐3. Increased cod fishing mortality, which led to decreasing abundance of cod, was associated with an increasing overall abundance of haddock, which suggests compensatory dynamics of both species. From a stage‐specific approach, I show that a change in the abundance in one species may propagate to other species, threatening the exploited species' recovery. Thus, this study demonstrates that considering interactions among life history stages of harvested species is essential to enhance species' co‐existence in harvested ecosystems. The approach developed in this study steps forward the analyses of effects of harvest and climate in multi‐species systems by considering the comprehension of complex ecological processes to facilitate the sustainable use of natural resources.

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Nonlinearity in interspecific interactions in response to climate change: Cod and haddock as an example

Cited by 13 publications

References 76 publications

Stock collapse and its effect on species interactions: Cod and herring in the Norwegian‐Barents Seas system as an example

Stock collapse and its effect on species interactions: Cod and herring in the Norwegian‐Barents Seas system as an example

Empirical evidence of nonlinearity in bottom up effect in a marine predator–prey system

Mixed interactions among life history stages of two harvested related species

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