Fisheries-induced disruptive selection

Landi, Pietro; Hui, Cang; Dieckmann, Ulf

doi:10.1016/j.jtbi.2014.10.017

Cited by 33 publications

(25 citation statements)

References 63 publications

(73 reference statements)

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“…Trait adaptation can also be modelled and give rise to complex trophic interaction networks (Brännström et al 2011(Brännström et al , 2012Landi et al 2013Landi et al , 2015Hui et al 2018), and their complexity-stability relationship assessed (Kondoh 2007;Ingram et al 2009). In particular, Kondoh (2007) studied adaptation in predator-specific defence traits, reporting its unimodal effect on the complexity-stability (connectance-persistence and robustness) relationship, while species richness always has a negative impact on stability.…”

Section: Trait-mediated Interactions and Adaptive Network: Food Websmentioning

confidence: 99%

Complexity and stability of ecological networks: a review of the theory

et al. 2018

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Our planet is changing at paces never observed before. Species extinction is happening at faster rates than ever, greatly exceeding the five mass extinctions in the fossil record. Nevertheless, our lives are strongly based on services provided by ecosystems, thus the responses to global change of our natural heritage are of immediate concern. Understanding the relationship between complexity and stability of ecosystems is of key importance for the maintenance of the balance of human growth and the conservation of all the natural services that ecosystems provide. Mathematical network models can be used to simplify the vast complexity of the real world, to formally describe and investigate ecological phenomena, and to understand ecosystems propensity of returning to its functioning regime after a stress or a perturbation. The use of ecological-network models to study the relationship between complexity and stability of natural ecosystems is the focus of this review. The concept of ecological networks and their characteristics are first introduced, followed by central and occasionally contrasting definitions of complexity and stability. The literature on the relationship between complexity and stability in different types of models and in real ecosystems is then reviewed, highlighting the theoretical debate and the lack of consensual agreement. The summary of the importance of this line of research for the successful management and conservation of biodiversity and ecosystem services concludes the review.

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Section: Trait-mediated Interactions and Adaptive Network: Food Websmentioning

confidence: 99%

Complexity and stability of ecological networks: a review of the theory

et al. 2018

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“…Anthropogenic impacts on the world's marine ecosystems and associated biodiversity are widespread, including overfishing (Pauly, Christensen, Dalsgaard, Froese, & Torres, ), pollution (Tewfik, Rasmussen, & McCann, ) and climate change (Brander, ), which can cause interacting negative consequences for wild populations (Collier, Probert, & Jeffries, ), livelihoods and food security (Andrew et al, ). In some cases, overfishing has been shown to change contemporary life history, resulting in reduced adult body size, altered demographics and associated fecundity, most often in size‐selective fisheries (Allendorf & Hard, ; Haarr, Sainte‐Marie, Comeau, Tremblay, & Rochette, ; Landi, Hui, & Dieckmann, ; Valles & Oxenford, ). This in turn can undermine future recruitment and economic returns with possible broader ecological and evolutionary consequences (Allendorf, England, Luikart, Ritchie, & Ryman, ; Allendorf & Hard, ; Audzijonyte, Kuparinen, Gorton, & Fulton, ; Kuparinen & Festa‐Bianchet, ; Landi et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…In some cases, overfishing has been shown to change contemporary life history, resulting in reduced adult body size, altered demographics and associated fecundity, most often in size‐selective fisheries (Allendorf & Hard, ; Haarr, Sainte‐Marie, Comeau, Tremblay, & Rochette, ; Landi, Hui, & Dieckmann, ; Valles & Oxenford, ). This in turn can undermine future recruitment and economic returns with possible broader ecological and evolutionary consequences (Allendorf, England, Luikart, Ritchie, & Ryman, ; Allendorf & Hard, ; Audzijonyte, Kuparinen, Gorton, & Fulton, ; Kuparinen & Festa‐Bianchet, ; Landi et al, ). At the same time a number of researchers have also explored the influence of climate change‐induced rising sea surface temperatures on the size of marine consumers, their distribution and productivity (Baudron, Needle, Rijnsdorp, & Marshall, ; Haarr et al, ; Pauly & Cheung, ; Tu, Chen, & Hsieh, ; Wilson‐Brodie, MacLean, & Fenberg, ).…”

Section: Introductionmentioning

confidence: 99%

Declining size of adults and juvenile harvest threatens sustainability of a tropical gastropod, Lobatus gigas, fishery

Tewfik

Babcock

Appeldoorn

et al. 2019

Aquatic Conservation

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Queen conch (Lobatus gigas) is a large herbivorous gastropod, found across the Caribbean, which forms the basis of important dive fisheries. Conch have a two‐phase shell growth pattern, first in shell length (SL), which ceases well before maturity, followed by growth in shell lip thickness (LT) into maturity. This growth pattern must be considered in determining the ideal size and associated maturity for sustainable harvest. Shell morphology, sex organ development and soft tissue masses indicated that mature adult conchs at Glover's Atoll, Belize, were those with thick shell lips (≥10 mm), eroded shells and heavier soft tissue masses. Therefore, SL‐based regulations cannot serve as a proxy for maturity and harvest. The use of inappropriate minimum size limits (SL = 178 mm, 85 g market clean meat mass) has allowed significant juvenile harvest and the fishery appears to have truncated the SL size distribution of conchs with a flared shell lip (i.e. adults) over the last 15 years. The reduced SL observed in lipped conchs may lead to a significant impact on the reproductive success of the population as well as diminished economic yield from the fishery, as smaller adult conchs of the same age have lower gonad and meat weight. We believe this to be the first documentation of a decline in the SL of adult queen conchs, and that the SL‐based size limits have contributed to this decline. Refinement of the individual size‐based regulations for conch in Belize to LT will probably facilitate local recovery as well as regional harmonization of regulations. Future research in Belize should include movement dynamics of conch in relation to replenishment zone size and spillover as well as the importance of deep‐water conch to shallow‐water recruitment, which is thought to be limited.

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“…Pike phenotypic trait variance was seen to increase along with intensive fishing, and this was speculated to arise as a combination of selection for, on the one hand, late entry to fisheries but, on the other hand, fast growth of fish vulnerable to fisheries [25]. Similar indications of fisheries selectivity being disruptive have also been provided by theoretical analyses of adaptive fish population dynamics [26]. While these studies suggest that fisheries-induced evolution can indeed be disruptive due to counteracting components of fisheries selection [27,28], our study goes further by demonstrating that fisheries-induced disruptive evolution can arise also as a consequence of the genetic architecture of the trait targeted by fishing.…”

Section: Discussionmentioning

confidence: 70%

Genetic architecture of age at maturity can generate divergent and disruptive harvest-induced evolution

Kuparinen

Hutchings

2017

Phil. Trans. R. Soc. B

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One contribution of 18 to a theme issue 'Human influences on evolution, and the ecological and societal consequences'. Life-history traits are generally assumed to be inherited quantitatively. Fishing that targets large, old individuals is expected to decrease age at maturity. In Atlantic salmon (Salmo salar), it has recently been discovered that sea age at maturity is under strong control by a single locus with sexually dimorphic expression of heterozygotes, which makes it less intuitive to predict how life histories respond to selective fishing. We explore evolutionary responses to fishing in Atlantic salmon, using eco-evolutionary simulations with two alternative scenarios for the genetic architecture of age at maturity: (i) control by multiple loci with additive effects and (ii) control by one locus with sexually dimorphic expression. We show that multi-locus control leads to unidirectional evolution towards earlier maturation, whereas single-locus control causes largely divergent and disruptive evolution of age at maturity without a clear phenotypic trend but a wide range of alternative evolutionary trajectories and greater trait variability within trajectories. Our results indicate that the range of evolutionary responses to selective fishing can be wider than previously thought and that a lack of phenotypic trend need not imply that evolution has not occurred. These findings underscore the role of genetic architecture of life-history traits in understanding how human-induced selection can shape target populations.This article is part of the themed issue 'Human influences on evolution, and the ecological and societal consequences'.

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Fisheries-induced disruptive selection

Cited by 33 publications

References 63 publications

Complexity and stability of ecological networks: a review of the theory

Complexity and stability of ecological networks: a review of the theory

Declining size of adults and juvenile harvest threatens sustainability of a tropical gastropod, Lobatus gigas, fishery

Genetic architecture of age at maturity can generate divergent and disruptive harvest-induced evolution

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