Behavior-dependent selectivity of yellowtail flounder (Limanda ferruginea) in the mouth of a commercial bottom trawl

Underwood, Melanie J.; Winger, Paul D.; Fernö, Anders; Engås, Arill

doi:10.7755/fb.113.4.6

Cited by 24 publications

(24 citation statements)

References 7 publications

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“…The relevance of this swim performance‐based mode of selectivity is dependent on fish engaging in an optomotor response (a reflexive behaviour thought to reorient a swimming fish after displacement from its desired horizontal course; Kim & Wardle, ) in which fish swim to maintain station with the trawl, often oriented adjacent to the trawl doors, until they drop back within the net. While this is often observed (Kim & Wardle, ; Rose, ), individual variation in the response to gears is also frequent (Underwood, Winger, Fernö, & Engås, ; Yanase, Eayrs, & Arimoto, ) and often predicts the chances of capture for individual fish. Whether these behavioural responses correlate with heritable physiological traits remains unclear, although individual's orientation prior interaction with the trawl gear, and density of conspecifics, can influence fish responses to trawls (Rose, ; Underwood et al., ).…”

Section: The Capture Process and Selection On Physiological Traitsmentioning

confidence: 99%

“…While this is often observed (Kim & Wardle, ; Rose, ), individual variation in the response to gears is also frequent (Underwood, Winger, Fernö, & Engås, ; Yanase, Eayrs, & Arimoto, ) and often predicts the chances of capture for individual fish. Whether these behavioural responses correlate with heritable physiological traits remains unclear, although individual's orientation prior interaction with the trawl gear, and density of conspecifics, can influence fish responses to trawls (Rose, ; Underwood et al., ). This would suggest that responses to trawls are influenced by external environment, which could dampen selection on traits correlated with swim performance.…”

Section: The Capture Process and Selection On Physiological Traitsmentioning

confidence: 99%

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A physiological perspective on fisheries‐induced evolution

Hollins

Thambithurai

Koeck

et al. 2018

Evolutionary Applications

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There is increasing evidence that intense fishing pressure is not only depleting fish stocks but also causing evolutionary changes to fish populations. In particular, body size and fecundity in wild fish populations may be altered in response to the high and often size‐selective mortality exerted by fisheries. While these effects can have serious consequences for the viability of fish populations, there are also a range of traits not directly related to body size which could also affect susceptibility to capture by fishing gears—and therefore fisheries‐induced evolution (FIE)—but which have to date been ignored. For example, overlooked within the context of FIE is the likelihood that variation in physiological traits could make some individuals within species more vulnerable to capture. Specifically, traits related to energy balance (e.g., metabolic rate), swimming performance (e.g., aerobic scope), neuroendocrinology (e.g., stress responsiveness) and sensory physiology (e.g., visual acuity) are especially likely to influence vulnerability to capture through a variety of mechanisms. Selection on these traits could produce major shifts in the physiological traits within populations in response to fishing pressure that are yet to be considered but which could influence population resource requirements, resilience, species’ distributions and responses to environmental change.

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Section: The Capture Process and Selection On Physiological Traitsmentioning

confidence: 99%

Section: The Capture Process and Selection On Physiological Traitsmentioning

confidence: 99%

A physiological perspective on fisheries‐induced evolution

Hollins

Thambithurai

Koeck

et al. 2018

Evolutionary Applications

View full text Add to dashboard Cite

show abstract

“…Exceptions that did look at differences in behaviour between captured fish and escapees in natural settings are Underwood, Winger, Fernö, and Engås's () study on yellowtail flounder, Limanda ferruginea , in Newfoundland and Kim and Wardle's () study on haddock, saithe, mackerel, cod and flatfish. Yellowtail flounders exhibited three different behavioural responses to an approaching trawl resulting in different catchability.…”

Section: Fishing Direct Selection On Behaviourmentioning

confidence: 99%

Behavioural responses to human‐induced change: Why fishing should not be ignored

Pauli

Sih

2017

Evolutionary Applications

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Change in behaviour is usually the first response to human‐induced environmental change and key for determining whether a species adapts to environmental change or becomes maladapted. Thus, understanding the behavioural response to human‐induced changes is crucial in the interplay between ecology, evolution, conservation and management. Yet the behavioural response to fishing activities has been largely ignored. We review studies contrasting how fish behaviour affects catch by passive (e.g., long lines, angling) versus active gears (e.g., trawls, seines). We show that fishing not only targets certain behaviours, but it leads to a multitrait response including behavioural, physiological and life‐history traits with population, community and ecosystem consequences. Fisheries‐driven change (plastic or evolutionary) of fish behaviour and its correlated traits could impact fish populations well beyond their survival per se, affecting predation risk, foraging behaviour, dispersal, parental care, etc., and hence numerous ecological issues including population dynamics and trophic cascades. In particular, we discuss implications of behavioural responses to fishing for fisheries management and population resilience. More research on these topics, however, is needed to draw general conclusions, and we suggest fruitful directions for future studies.

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“…Similarly, Albert et al (2003) classified fish in front of a survey trawl as "certain Greenland halibut," "certain flatfish," or "uncertain flatfish." Underwood et al (2011Underwood et al ( , 2015 classified flatfish in their video as either Yellowtail Flounder or "unidentified flatfish" and used the pointed snout of the Yellowtail Flounder as an identifying characteristic. Underwood et al (2011) achieved 72% and 46% classification accuracy for Yellowtail Flounder using an HD and standard-definition (SD) camera, respectively.…”

Section: Speciesmentioning

confidence: 99%

“…Optical approaches have been used to examine the behavior of fish in and around otter trawls and to estimate the efficiency of trawls (e.g., Godø et al 1999;Albert et al 2003;Piasente et al 2004;Churnside et al 2012;Bryan et al 2014;Underwood et al 2015). Recent studies have used cameras to identify, measure, and quantify fish passing through a trawl net.…”

mentioning

confidence: 99%

Development of a Video Trawl Survey System for New England Groundfish

et al. 2017

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Using an iterative approach and extensive field testing we developed a new video trawl survey system that used a live-feed video camera mounted in the cod end of a demersal trawl to record, identify, and quantify fish as they pass through the net. The majority of tows are made with an open cod end, allowing the fish to escape the net after being recorded by the camera. Periodically, closed cod end tows are made to collect biological samples and validate the video data. Eight field trials were conducted on Georges Bank and in the Gulf of Maine, and 229 h of video were recorded. The in-trawl camera system performed reliably under harsh conditions in the field. Preliminary data analysis showed that the in-trawl camera system can be used to count and identify roundfishes, such as Atlantic Cod Gadus morhua and Haddock Melanogrammus aeglefinus with a high degree of accuracy (97%), and the video can be used to calculate absolute abundance estimates. However, identifying flatfishes to the species level in the video was challenging, although improvements in identification rates were realized by modifying our camera system and lighting. This approach provides an alternative methodology to acquire abundance and distribution data for groundfish stocks. We described the iterative approach used to develop the video trawl system and discussed the future direction of the video processing and analysis.

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Behavior-dependent selectivity of yellowtail flounder (Limanda ferruginea) in the mouth of a commercial bottom trawl

Cited by 24 publications

References 7 publications

A physiological perspective on fisheries‐induced evolution

A physiological perspective on fisheries‐induced evolution

Behavioural responses to human‐induced change: Why fishing should not be ignored

Development of a Video Trawl Survey System for New England Groundfish

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