Reversal of evolutionary downsizing caused by selective harvest of large fish

Conover, David O.; Munch, Stephan B.; Arnott, Stephen A.

doi:10.1098/rspb.2009.0003

Cited by 160 publications

(172 citation statements)

References 32 publications

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“…That is, time scales of evolutionary recovery are likely to be much longer than those on which undesirable evolutionary changes occur. Conover et al (101) provided the first experimental test of this expectation with laboratory populations of Menidia menidia. They found that the selective effects of fishing were reversible, but recovery took more than twice as many generations as the original period of fishery selection.…”

Section: Discussionmentioning

confidence: 99%

Human-induced evolution caused by unnatural selection through harvest of wild animals

Allendorf

Hard

2009

Proc. Natl. Acad. Sci. U.S.A.

475

417

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Human harvest of phenotypically desirable animals from wild populations imposes selection that can reduce the frequencies of those desirable phenotypes. Hunting and fishing contrast with agricultural and aquacultural practices in which the most desirable animals are typically bred with the specific goal of increasing the frequency of desirable phenotypes. We consider the potential effects of harvest on the genetics and sustainability of wild populations. We also consider how harvesting could affect the mating system and thereby modify sexual selection in a way that might affect recruitment. Determining whether phenotypic changes in harvested populations are due to evolution, rather than phenotypic plasticity or environmental variation, has been problematic. Nevertheless, it is likely that some undesirable changes observed over time in exploited populations (e.g., reduced body size, earlier sexual maturity, reduced antler size, etc.) are due to selection against desirable phenotypes-a process we call ''unnatural'' selection. Evolution brought about by human harvest might greatly increase the time required for over-harvested populations to recover once harvest is curtailed because harvesting often creates strong selection differentials, whereas curtailing harvest will often result in less intense selection in the opposing direction. We strongly encourage those responsible for managing harvested wild populations to take into account possible selective effects of harvest management and to implement monitoring programs to detect exploitation-induced selection before it seriously impacts viability.conservation ͉ genetic change ͉ human exploitation

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Section: Discussionmentioning

confidence: 99%

Human-induced evolution caused by unnatural selection through harvest of wild animals

Allendorf

Hard

2009

Proc. Natl. Acad. Sci. U.S.A.

475

417

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“…Several empirical studies on wild fish populations, however, have questioned the notion that larger fish generally exhibit higher reproductive fitness (14,15). As a result, although for many fisheries size-selective exploitation is well established (3)(4)(5)7), there is little empirical evidence from wild populations demonstrating that fishing truly targets reproductively more-fit individuals. One can speculate that certain fishing gear might even target less-fit individuals, that is, those that are either competitively inferior or in poorer condition and therefore more prone to attack fishing lures, more likely to encounter passive fishing gear, or less able to evade actively fished gear such as trawls.…”

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confidence: 97%

Recreational fishing selectively captures individuals with the highest fitness potential

Sutter

Suski

Philipp

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

146

164

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Fisheries-induced evolution and its impact on the productivity of exploited fish stocks remains a highly contested research topic in applied fish evolution and fisheries science. Although many quantitative models assume that larger, more fecund fish are preferentially removed by fishing, there is no empirical evidence describing the relationship between vulnerability to capture and individual reproductive fitness in the wild. Using males from two lines of largemouth bass (Micropterus salmoides) selectively bred over three generations for either high (HV) or low (LV) vulnerability to angling as a model system, we show that the trait "vulnerability to angling" positively correlates with aggression, intensity of parental care, and reproductive fitness. The difference in reproductive fitness between HV and LV fish was particularly evident among larger males, which are also the preferred mating partners of females. Our study constitutes experimental evidence that recreational angling selectively captures individuals with the highest potential for reproductive fitness. Our study further suggests that selective removal of the fittest individuals likely occurs in many fisheries that target species engaged in parental care. As a result, depending on the ecological context, angling-induced selection may have negative consequences for recruitment within wild populations of largemouth bass and possibly other exploited species in which behavioral patterns that determine fitness, such as aggression or parental care, also affect their vulnerability to fishing gear.ize-selective fishing, or even just an elevated level of fishing mortality, has the potential to induce rapid evolutionary change in a range of production-related traits in fish populations (1, 2). Theoretically predicted and empirically supported fisheriesinduced adaptive change involves the modification of life history traits, including reductions in age-and size-at-maturation, increases in reproductive investment, and changes in pre-and/or postmaturation growth rates (1-3). Changes in life history traits in response to fishing often collectively reduce adult size-at-age and fisheries yield and result in fish populations that only slowly rebound from overexploited states (4-7). There is little consensus, however, concerning the prevalence of fisheries-induced evolution and its relevance to management (1,(8)(9)(10). Perspectives range from calls for "evolutionarily enlightened management" (11) to positions that argue that evolutionary change induced by fishing is slow, thereby rendering it largely unimportant to fisheries management (9).One important tool to predict long-term population-level consequences of fisheries-induced evolution involves the construction and analysis of individual-based models (5, 12) or more simplified stage or age/size-structured (7) population models. Suitable models to study the potential for fisheries-induced evolution include ecological feedbacks resulting in density-and frequencydependent selection that shapes fitness landscapes and ev...

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“…It is therefore not surprising that harvesting may cause phenotypic changes in heritable life-history traits in both terrestrial (Allendorf et al, 2008;Coltman et al, 2003) and marine species (Jørgensen et al, 2007). Concerns are mounting about the time it may take to reverse such adaptive changes (Conover et al, 2009;Law and Grey, 1989), if such reversals are feasible at all (de Roos et al, 2006). At this time there is no conclusive genetic evidence of harvesting-induced evolution, however, a growing number of empirical and experimental studies suggest that anthropogenic size-selective mortality in exploited wild populations can cause adaptive changes in traits influencing growth and maturation (Coltman et al, 2003;Jørgensen et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

A Systematic Overview of Harvesting-Induced Maturation Evolution in Predator–Prey Systems with Three Different Life-History Tradeoffs

2012

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There are concerns that anthropogenic harvesting may cause phenotypic adaptive changes in exploited wild populations, in particular maturation at smaller size and younger age. In this paper, we study the evolutionarily stable size-atmaturation of prey subjected to size-selective harvesting in a simple predatorprey model, taking into account three recognized life-history costs of early maturation, namely reduced fecundity, reduced growth, and increased mortality. Our analysis shows that harvesting large individuals favors maturation at smaller size compared to the unharvested system, independent of life-history tradeoff and the predator's prey-size preference. In general, however, the evolutionarily stable maturation size can either increase or decrease relative to the unharvested system, depending on the harvesting regime, the life-history tradeoff, and the predator's preferred size of prey. Furthermore, we examine how the predator population size changes in response to adaptive change in size-at-maturation of the prey. Surprisingly, in some situations we find that the evolutionarily stable maturation size under harvesting is associated with an increased predator population size. This occurs, in particular, when early maturation trades off with growth rate. In total, we determine the evolutionarily stable size-at-maturation and associated predator population size for a total of forty-five different combinations of tradeoff, harvest regime, and predated size class.

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Reversal of evolutionary downsizing caused by selective harvest of large fish

Cited by 160 publications

References 32 publications

Human-induced evolution caused by unnatural selection through harvest of wild animals

Human-induced evolution caused by unnatural selection through harvest of wild animals

Recreational fishing selectively captures individuals with the highest fitness potential

A Systematic Overview of Harvesting-Induced Maturation Evolution in Predator–Prey Systems with Three Different Life-History Tradeoffs

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