Fast–slow life history is correlated with individual differences in movements and prey selection in an aquatic predator in the wild

Nakayama, Shinnosuke; Rapp, Tobias; Arlinghaus, Robert

doi:10.1111/1365-2656.12603

Cited by 45 publications

(28 citation statements)

References 94 publications

(183 reference statements)

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“…It is possible the differences in space use at different temperatures by proactive and reactive fish may be due to the existence of physiological constraints. Indeed, evidence that behavioural, physiological and life-history traits are correlated under a pace of life syndrome (POLS) is gaining ground (Nakayama, Rapp, & Arlinghaus, 2016;Réale et al, 2010). Proactive fish, having larger levels of boldness, activity and aggressiveness, may have a bigger metabolic engine and therefore higher energetic needs (Careau, Thomas, Humphries, & Réale, 2008;Rey, Digka, & MacKenzie, 2015).…”

Section: Discussionmentioning

confidence: 99%

Personalities influence spatial responses to environmental fluctuations in wild fish

Villegas‐Ríos

Réale

Freitas

et al. 2018

Journal of Animal Ecology

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Although growing evidence supports the idea that animal personality can explain plasticity in response to changes in the social environment, it remains to be tested whether it can explain spatial responses of individuals in the face of natural environmental fluctuations. This is a major challenge in ecology and evolution as spatial dynamics link individual‐ and population‐level processes.In this study, we investigated the potential of individual personalities to predict differences in fish behaviour in the wild. Specifically, our goal was to answer if individual differences in plasticity of space use to sea surface temperature could be explained by differences in personality along the reactive–proactive axis.To address this question, we first conducted repeated standard laboratory assays (i.e., open‐field test, novel object test and mirror stimulation test) to assess the personality type of 76 wild‐caught Atlantic cod (Gadus morhua). Next, we released the fish back into the sea and monitored their spatial behaviour over large temporal (16 months) and spatial (a whole fjord) scales, using high‐resolution acoustic tracking.We demonstrate that (a) cod personality traits are structured into a proactive–reactive syndrome (proactive fish being more bold, exploratory and aggressive), (b) mean depth use of individuals is mainly driven by sea temperature and (c) personality is a significant predictor of home range changes in the wild, where reactive, but not proactive, individuals reduced their home range as sea temperature increased.These findings expand our understanding of the ecological consequences of animal personality and the mechanisms shaping spatial dynamics of animals in nature.

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Section: Discussionmentioning

confidence: 99%

Personalities influence spatial responses to environmental fluctuations in wild fish

Villegas‐Ríos

Réale

Freitas

et al. 2018

Journal of Animal Ecology

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“…High-resolution telemetry has been applied in many research fields, such as animal personality in the wild (Harrison et al, 2015;Nakayama, Laskowski, Klefoth, & Arlinghaus, 2016;Taylor & Cooke, 2014) and correlations between movement and life history traits (Nakayama, Rapp, & Arlinghaus, 2017). When coupled with environmental data, high-resolution telemetry affords an opportunity to re-evaluate our current knowledge about the behaviour of free-ranging fishes in the wild and offer new insights.…”

Section: Discussionmentioning

confidence: 99%

Fine‐scale movement ecology of a freshwater top predator, Eurasian perch (Perca fluviatilis), in response to the abiotic environment over the course of a year

Nakayama

Doering-Arjes

Linzmaier

et al. 2018

Ecology of Freshwater Fish

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Fine‐scale underwater telemetry affords an unprecedented opportunity to understand how aquatic animals respond to environmental changes. We investigated the movement patterns of an aquatic top predator, Eurasian perch (Perca fluviatilis), using a three‐dimensional acoustic telemetry system installed in Kleiner Döllnsee (25 ha), a small, shallow, mesotrophic natural lake. Adult piscivorous perch (N = 16) were tagged and tracked in the whole lake at a minimum of 9‐s intervals over the course of one year. Perch increased swimming activity with higher water temperature and light intensity. Air pressure, wind speed and lunar phase also explained perch movements, but the effects were substantially smaller compared to temperature and light. Perch showed a strong diel pattern in activity, with farther swimming distances and larger activity spaces during the daytime, compared to the night‐time. To investigate the influence of prey distribution, we sampled the prey fish in both littoral and pelagic zones in both day and night monthly using gill nets. We found that the prey fish underwent diel horizontal migration, using the littoral zone during the day and the pelagic zone during the night. However, perch showed the opposite patterns, suggesting either that the prey fish avoided predation risk or that the horizontal diel migration of perch was driven by other mechanisms. Our results collectively suggest that the movement ecology of piscivorous perch is mainly governed by a foraging motivation as a function of abiotic variables, especially temperature and light.

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“…Repeatable behaviours can also correlate with age, growth rate, fecundity, morphology or metabolism [49,50]. Positive size selectivity is common feature in recreational angling [51] and there are several examples in which fast growing fish [31,52–54], as well as fish with high metabolism [48] are harvested preferentially by anglers.…”

Section: Introductionmentioning

confidence: 99%

Encountering a bait is necessary but insufficient to explain individual variability in vulnerability to angling in two freshwater benthivorous fish in the wild

Monk

Arlinghaus

2017

PLoS ONE

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Fish personality traits, such as swimming activity, or personality related emergent behavioural properties, such as the degree of space use shown by an individual fish, should affect encounter rates between individual fish and fishing gear. Increased encounters should in turn drive vulnerability to capture by passively operated gears. However, empirical evidence documenting a relationship between activity-based behaviours and vulnerability to capture by passive fishing gear in the wild is limited. Using whole-lake acoustic telemetry, we first documented significant repeatabilities over several months in a suite of encounter rate-associated behaviours (swimming distance, activity space size, time on baited feeding sites, switching frequency among baited feeding sites, distance to the lake bottom) in two recreationally important benthivorous cyprinid species, the common carp (Cyprinus carpio) and tench (Tinca tinca). We then experimentally targeted both species using stationary angling on baited feeding sites. Individual fish regularly visited the angling sites, documenting that the fishes encountered the angling baits. When attempting to explain individual variation in vulnerability as a function of repeatable behavioural traits, we found no evidence of a significant relationship among various encounter-based behaviours and vulnerability to angling for both species. There was also no evidence for size selection or for energetically less conditioned fish to be more vulnerable. The data cumulatively suggest that fine-scale behaviours after encountering a bait (e.g., frequency of bait intake) may be ultimately decisive for determining vulnerability to angling in benthivorous fish. Based on our work, fishing-induced selection on encounter-based behaviours in recreational angling for benthivorous fish in the wild appears unlikely.

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Fast–slow life history is correlated with individual differences in movements and prey selection in an aquatic predator in the wild

Cited by 45 publications

References 94 publications

Personalities influence spatial responses to environmental fluctuations in wild fish

Personalities influence spatial responses to environmental fluctuations in wild fish

Fine‐scale movement ecology of a freshwater top predator, Eurasian perch (Perca fluviatilis), in response to the abiotic environment over the course of a year

Encountering a bait is necessary but insufficient to explain individual variability in vulnerability to angling in two freshwater benthivorous fish in the wild

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