Maternal inheritance influences homing and growth of hybrid offspring between wild and farmed Atlantic salmon

Jönsson, Bror; Jönsson, Nina

doi:10.3354/aei00232

Cited by 17 publications

(25 citation statements)

References 58 publications

(36 reference statements)

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“…Based upon results from these simulations, together with existing knowledge, we suggest that a combination of reduced spawning success of domesticated escapees, natural selection purging maladapted phenotypes/genotypes from the wild population, and phenotypic plasticity buffer the rate and magnitude of change in phenotypic and demographic characteristics of wild populations subject to spawning intrusion of domesticated escapees. These suggestions are in line with empirical data demonstrating that domesticated escapees display reduced spawning success in comparison with wild salmon (Fleming et al., , ), the offspring of domesticated salmon display reduced survival in the wild when compared to wild fish (Fleming et al., ; McGinnity et al., , ; Skaala et al., ) and that differences between domesticated and wild salmon in phenotypic traits, such as growth rate, are much less pronounced in the wild than in the hatchery (Besnier et al., ; Jonsson & Jonsson, ; Reed et al., ; Skaala et al., ).…”

Section: Discussionsupporting

confidence: 70%

“…Within regions displaying a mosaic of small and large populations, straying and the degree of genetic connectivity may be skewed, whereby large populations can act as net‐exporters of strayers to smaller neighboring wild populations (Hansen, Skaala, Jensen, Bekkevold, & Mensberg, ). Straying of wild fish between rivers (Stabell, ) also varies in time and space for Atlantic salmon (Jonsson & Jonsson, ; Jonsson et al., ; Pedersen et al., ; Skilbrei & Holm, ) and other salmonids (Bett, Hinch, Burnett, Donaldson, & Naman, ; Ford, Murdoch, & Hughes, ; King, Hillman, Elsmere, Stockley, & Stevens, ). Recent experimental work has also indicated that introgression of domesticated salmon may increase straying rates in impacted wild Atlantic salmon populations (Jonsson & Jonsson, ).…”

Section: Discussionmentioning

confidence: 99%

“…Domesticated Atlantic salmon display a wide range of genetic differences to wild salmon, and of these, growth and size at age are the traits displaying the greatest difference detected thus far (Glover et al., ). However, while very large (several fold or more in many cases) differences in growth and size at age are detected among domesticated, hybrid and wild salmon under controlled hatchery conditions (Debes, Fraser, Yates, & Hutchings, ; Fleming, Agustsson, Finstad, Johnsson, & Bjornsson, ; Glover et al., ; Harvey, Glover, Taylor, Creer, & Carvalho, ; Solberg, Glover et al., ; Solberg, Zhang et al., ), in the wild, growth rates and size at age differences between domesticated and wild salmon are much less distinct and overlap (Besnier et al., ; Fleming et al., ; Jonsson & Jonsson, ; Reed et al., ; Skaala et al., ). For example, size differences between domesticated and wild salmon in the river Burrishoole egg planting experiments conducted in Ireland in the late 1990s and early 2000s were reported to range from 5% to 20% (Reed et al., ), and the smolt size at age differences between domesticated, hybrid, and wild salmon from the egg planting experiments conducted in the river Guddal in Norway in the middle 2000s was typically only 0%–10% (Skaala et al., ).…”

Section: Discussionmentioning

confidence: 99%

“…However, differences between the domestication‐admixed and wild salmon (both magnitude and direction) were dependent both upon the age category of the fish, and also, the geographic region in which admixture occurred (i.e., northern Norway contra middle/southern Norway). Others have concluded that growth differences between domesticated, hybrid, and wild salmon in the marine phase are not necessarily very clear, with small differences in maximum size at age but significant differences in minimum size at age (Jonsson & Jonsson, ). While the response in adult size in the IBSEM outputs reported here is low in comparison with the observations between domestication‐admixed and nonadmixed salmon (Figure vs. results by Bolstad et al., ), it is pertinent to point out that the model outputs here reflect the population average.…”

Section: Discussionmentioning

confidence: 99%

“…In order to achieve this, strayers were set at 5% of the N ‐adults returning to the focal population (scenarios 1, 2, 5, 6), or fixed to 25, corresponding to 5% of the N ‐adults returning to the focal population in the first year of intrusion (scenarios 3, 4, 7, 8). This level of straying is within the variation displayed between Atlantic salmon populations (Jonsson & Jonsson, ; Jonsson, Jonsson, & Hansen, ; Pedersen, Rasmussen, Nielsen, Karlsson, & Nyberg, ; Skilbrei & Holm, ; Stabell, ) and was designed to reflect situations where the neighbor population remained demographically stable over time and thus provided a constant number of strayers to the focal wild population, or alternatively, varied in tandem with the focal wild population, reflecting a situation where it is ecologically connected to the focal wild population.…”

Section: Methodsmentioning

confidence: 99%

See 4 more Smart Citations

Modeling fitness changes in wild Atlantic salmon populations faced by spawning intrusion of domesticated escapees

Castellani

Heino

Gilbey

et al. 2018

Evolutionary Applications

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Genetic interaction between domesticated escapees and wild conspecifics represents a persistent challenge to an environmentally sustainable Atlantic salmon aquaculture industry. We used a recently developed eco‐genetic model (IBSEM) to investigate potential changes in a wild salmon population subject to spawning intrusion from domesticated escapees. At low intrusion levels (5%–10% escapees), phenotypic and demographic characteristics of the recipient wild population only displayed weak changes over 50 years and only at high intrusion levels (30%–50% escapees) were clear changes visible in this period. Our modeling also revealed that genetic changes in phenotypic and demographic characteristics were greater in situations where strayers originating from a neighboring wild population were domestication‐admixed and changed in parallel with the focal wild population, as opposed to nonadmixed. While recovery in the phenotypic and demographic characteristics was observed in many instances after domesticated salmon intrusion was halted, in the most extreme intrusion scenario, the population went extinct. Based upon results from these simulations, together with existing knowledge, we suggest that a combination of reduced spawning success of domesticated escapees, natural selection purging maladapted phenotypes/genotypes from the wild population, and phenotypic plasticity, buffer the rate and magnitude of change in phenotypic and demographic characteristics of wild populations subject to spawning intrusion of domesticated escapees. The results of our simulations also suggest that under specific conditions, natural straying among wild populations may buffer genetic changes in phenotypic and demographic characteristics resulting from introgression of domesticated escapees and that variation in straying in time and space may contribute to observed differences in domestication‐driven introgression among native populations.

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Section: Discussionsupporting

confidence: 70%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 3 more Smart Citations

Modeling fitness changes in wild Atlantic salmon populations faced by spawning intrusion of domesticated escapees

Castellani

Heino

Gilbey

et al. 2018

Evolutionary Applications

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Telemetry and genetics reveal asymmetric dispersal of a lake‐feeding salmonid between inflow and outflow spawning streams at a microgeographic scale

Finlay

Poole

Coughlan

et al. 2020

Ecology and Evolution

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The degree of natal philopatry relative to natal dispersal in animal populations has important demographic and genetic consequences and often varies substantially within species. In salmonid fishes, lakes have been shown to have a strong influence on dispersal and gene flow within catchments; for example, populations spawning in inflow streams are often reproductively isolated and genetically distinct from those spawning in relatively distant outflow streams. Less is known, however, regarding the level of philopatry and genetic differentiation occurring at microgeographic scales, for example, where inflow and outflow streams are separated by very small expanses of lake habitat. Here, we investigated the interplay between genetic differentiation and fine‐scale spawning movements of brown trout between their lake‐feeding habitat and two spawning streams (one inflow, one outflow, separated by <100 m of lake habitat). Most (69.2%) of the lake‐tagged trout subsequently detected during the spawning period were recorded in just one of the two streams, consistent with natal fidelity, while the remainder were detected in both streams, creating an opportunity for these individuals to spawn in both natal and non‐natal streams. The latter behavior was supported by genetic sibship analysis, which revealed several half‐sibling dyads containing one individual that was sampled as a fry in the outflow and another that was sampled as fry in the inflow. Genetic clustering analyses in conjunction with telemetry data suggested that asymmetrical dispersal patterns were occurring, with natal fidelity being more common among individuals originating from the outflow than the inflow stream. This was corroborated by Bayesian analysis of gene flow, which indicated significantly higher rates of gene flow from the inflow into the outflow than vice versa. Collectively, these results reveal how a combination of telemetry and genetics can identify distinct reproductive behaviors and associated asymmetries in natal dispersal that produce subtle, but nonetheless biologically relevant, population structuring at microgeographic scales.

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The effect of surveillance fishing on migration distance of Atlantic Salmon during the spawning period

Munkeby,

Davidsen,

Havn

et al. 2024

N American J Fish Manag

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ObjectiveSurveillance fishing surveys can be performed to estimate the proportion of farmed salmon represented in the spawning stock of native Atlantic Salmon Salmo salar populations. These surveys take place after the recreational fishing period and therefore closer to the spawning period than the open recreational fishing season. Although catch‐and‐release angling has been demonstrated to affect salmon migration during the summer months, surveillance fishing that is conducted close to the spawning time could have more severe effects.MethodsTo test this, the migration distance of Atlantic Salmon (n = 74) caught in the Orkla River, Norway, was tracked by use of radiotelemetry. One group was tagged during the regular fishing season in the summer (control group), whereas another group was tagged in autumn during surveillance fishing (surveillance group).ResultSixty‐one salmon remained for analysis after we excluded fish that were recaptured, died, or migrated to other rivers. Relocation of the salmon during autumn (October 11–31) was used to compare movements and test for differences in migration using negative binomial regression because distances were nonnegative integers. During the tracking period, the surveillance group moved 12 ± 14 km (mean ± standard deviation) and the control group moved 13 ± 15 km; both groups moved 1 ± 2 km/day on average. There was no evidence that surveillance fishing impacted movement of the salmon compared to controls. However, one salmon died after tagging and three were not released due to injuries; total mortality of 9% during surveillance fishing could be unsustainable for smaller populations. Consequently, factors such as surveillance sample size, the status of the salmon population, and the population size should be assessed for each river individually when deciding the necessity of and approach to surveillance fishing.ConclusionThe results support existing recommendations to use careful handling and to end surveillance at least 2 weeks prior to the expected onset of spawning, thus providing a sufficiently long period for recovery after surveillance fishing.

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Maternal inheritance influences homing and growth of hybrid offspring between wild and farmed Atlantic salmon

Cited by 17 publications

References 58 publications

Modeling fitness changes in wild Atlantic salmon populations faced by spawning intrusion of domesticated escapees

Modeling fitness changes in wild Atlantic salmon populations faced by spawning intrusion of domesticated escapees

Telemetry and genetics reveal asymmetric dispersal of a lake‐feeding salmonid between inflow and outflow spawning streams at a microgeographic scale

The effect of surveillance fishing on migration distance of Atlantic Salmon during the spawning period

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