Growth, Condition, and Trophic Relations of Stocked Trout in Southern Appalachian Mountain Streams

Fischer, Jesse R.; Kwak, Thomas J.; Flowers, H. Jared; Cope, W. Gregory; Rash, Jacob M.; Besler, Douglas A.

doi:10.1002/tafs.10170

Cited by 3 publications

(5 citation statements)

References 48 publications

(95 reference statements)

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“…Our DNA‐based analysis, in its current form, can only provide presence/absence assessments of prey composition due to inherent stochasticity stemming from DNA extraction, amplification, and high‐throughput sequencing (Piñol et al., 2018). Therefore, if researchers wish to acquire the most comprehensive insights possible, they should supplement the findings from DNA‐based methods with those stemming from quantitative methods, such as morphologic or isotopic characterisation (Fischer et al., 2019). Second, the taxonomic breadth of DNA‐based analyses is limited by both the barcoding primers used in the study as well as the completeness of the prey species reference database.…”

Section: Discussionmentioning

confidence: 99%

“…Previous work at other sites has suggested that interspecific trophic competition with introduced salmonids, such as brown trout ( Salmo trutta ; Dewald & Wilzbach, 1992) and rainbow trout ( Oncorhynchus mykiss; Larson & Moore, 1985) may play a role in the extirpation of brook trout populations. However, studies that have investigated the feeding ecology of native brook trout coexisting with introduced brown and rainbow trout have either not documented the natural dietary composition of these species (Dewald & Wilzbach, 1992; Fausch & White, 1981; Larson & Moore, 1985) or have relied almost entirely upon morphological identification of digested prey to provide broad taxonomic classifications (Cunjak & Power, 1987; Fischer et al., 2019; Tebo & Hassler, 1963). To provide a more taxonomically‐precise classification for these trout species and to demonstrate the feasibility of DNA‐based dietary characterisations for other freshwater fish taxa, we performed DNA metabarcoding on gastric lavage samples collected from a stable, syntopic community of native brook trout, naturalised brown trout, and naturalised rainbow trout on the Laurel Ridge of Western Pennsylvania.…”

Section: Introductionmentioning

confidence: 99%

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Dietary DNA metabarcoding reveals seasonal trophic changes among three syntopic freshwater trout species

et al. 2020

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Providing taxonomically precise dietary characterisations for freshwater fish species is critical for gaining a deeper understanding of the trophic dynamics present in freshwater ecosystems. However, our current understanding of freshwater trophic ecology has relied almost entirely upon direct observation of foraging attempts or morphological identification of partially digested prey. Due to the limitations of morphological dietary characterisations of soft‐bodied arthropod prey, these techniques offer dietary descriptions that can lack satisfactory taxonomic resolution and may bias our interpretations of freshwater food webs. Recent advancements in DNA‐based prey identification have allowed for species‐level prey characterisations for many terrestrial insectivores, although these techniques have seldom been applied to understand the diets of freshwater fish. This study used DNA metabarcoding with high‐throughput, next‐generation sequencing to provide species‐level descriptions of prey composition for three naturally reproducing, syntopic freshwater trout species. Our study supports previous findings that suggested that brook trout (Salvelinus fontinalis), brown trout (Salmo trutta), and rainbow trout (Oncorhynchus mykiss) are generalist predators that display a high degree of seasonal dietary flexibility. Prey composition varied significantly across sampling periods, with detection frequency of terrestrial prey greater in the spring/summer period compared to the autumn period. Pollution‐sensitive aquatic macroinvertebrates were detected frequently across both sampling periods, highlighting the importance of high‐quality streams that support such arthropod prey. DNA metabarcoding also detected a high richness of soft‐bodied, Lepidoptera prey species, a taxonomic group that has been largely underrepresented in previous trout dietary studies that used traditional morphological techniques. This study demonstrates the applicability of dietary DNA metabarcoding for the detection and species‐level identification of arthropods found in freshwater fish lavage samples and highlights the importance of taxonomically precise techniques when attempting to better understand trophic interactions within freshwater communities.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dietary DNA metabarcoding reveals seasonal trophic changes among three syntopic freshwater trout species

et al. 2020

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“…Interbreeding between the historical groups was marginal, except for 2001E and F. Previous studies in salmonids found similarly low introgression levels from domestic fish into the native population 61 , 62 . Potential causes include both lower rates of survival and reproduction and changes in the timing of maturity and spawning introduced by captive-breeding programs 11 , 63 – 67 . Shifted spawning timing may also contribute to non-random mating or reproductive isolation by time (temporal assortative mating; 68 ), resulting in low admixture with wild populations 64 .…”

Section: Discussionmentioning

confidence: 99%

“…Importantly, genetic effects seem to be present even in F2 generation specimens that have lived their entire lives in natural environments 11 . Further, mortality rates may be higher in captivity-bred than wild fish because of less efficient foraging behaviour, leading to smaller body sizes and poor physical condition, and more risk-prone or exploratory behaviour that may result in higher predation and angling pressure 67 . The progeny of hatchery-raised trout may potentially also suffer from fewer resources at egg hatching in the wild, as early juvenile survival is positively correlated to egg size.…”

Section: Discussionmentioning

confidence: 99%

Temporal analysis shows relaxed genetic erosion following improved stocking practices in a subarctic transnational brown trout population

Klütsch

Maduna

Polikarpova

et al. 2021

Sci Rep

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Maintaining standing genetic variation is a challenge in human-dominated landscapes. We used genetic (i.e., 16 short tandem repeats) and morphological (i.e., length and weight) measurements of 593 contemporary and historical brown trout (Salmo trutta) samples to study fine-scale and short-term impacts of different management practices. These had changed from traditional breeding practices, using the same broodstock for several years, to modern breeding practices, including annual broodstock replacement, in the transnational subarctic Pasvik River. Using population genetic structure analyses (i.e., Bayesian assignment tests, DAPCs, and PCAs), four historical genetic clusters (E2001A-D), likely representing family lineages resulting from different crosses, were found in zone E. These groups were characterized by consistently lower genetic diversity, higher within-group relatedness, lower effective population size, and significantly smaller body size than contemporary stocked (E2001E) and wild fish (E2001F). However, even current breeding practices are insufficient to prevent genetic diversity loss and morphological changes as demonstrated by on average smaller body sizes and recent genetic bottleneck signatures in the modern breeding stock compared to wild fish. Conservation management must evaluate breeding protocols for stocking programs and assess if these can preserve remaining natural genetic diversity and morphology in brown trout for long-term preservation of freshwater fauna.

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“…Different DNA methylation patterns have been observed in the sperm of captive-reared Atlantic salmon (Salmo salar) when compared with wild-born ones (Barreto et al, 2019). The above DNA and DNA methylation changes may result in phenotypic changes (e.g., body shapes: see Fragkoulis et al, 2017;Sánchez-González and Nicieza, 2017), as well as adaptive changes (e.g., survival: see Stoner and Davis, 1994; the returned number for spawning: see Jonsson et al, 2019;reproductive success: see Janowitz-Koch et al, 2019; empty stomach rate: see Fischer et al, 2019; food items: see Davis et al, 2018) in hatchery-reared seed stocks, in comparison to their wild counterparts (Kitada, 2020). Consequently, continuous hatchery stocking allows introgression with the wild gene pool or even the replacement of wild genes, which causes a decline in adaptation and a decrease in the production of post-mixed wild populations when stock enhancement programs are undertaken (Jonsson et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Genetic Stock Identification and Adaptability of Hatchery-Reared Black Rockfish, Sebastes schlegelii, Released Into the North Yellow Sea waters

Liu

Wang

et al. 2022

Front. Mar. Sci.

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Successful stock enhancement refers to the maintenance of economic profit, whilst minimizing negative genetic and ecological effects. As hatchery environments differ from natural habitats, post-release identification of hatchery-reared juveniles, and estimation of their adaptability are essential steps in conducting responsible stock enhancement. The black rockfish is an important fishery species in Japan, South Korea and China. Overfishing has dramatically decreased natural resources and a stock enhancement program was first initiated in the Liaodong peninsula in 2019. We traced this program and used nine microsatellite markers to identify 279 individuals as being hatchery-reared, out of 710 captured fish, with a resource contribution rate of 39.30%. These results indicated that stock enhancement of this species is likely to maintain a positive economic performance. To understand the potential genetic impacts on the local wild population, the genetic patterns of S. schlegelii stocks (wild controls from 2017, wild controls from 2018, female broodstock from 2019, recaptured hatchery-reared fish from 2019 and recaptured non-hatchery-reared fish from 2019 stocks) from the same habitat were evaluated before and after artificial stocking. We found that the S. schlegelii population was able to maintain high genetic diversity and showed weak genetic differentiation, but potential genetic introgression derived from stock enhancement should be concerned. The hatchery-reared individuals showed good adaptability, as shown by feeding condition and growth status. There was no obvious morphology difference between hatchery-reared fish and their wild counterparts, but hatchery-reared fish seemed to be bigger in size (significantly higher in MDB and BW), had a larger head (significantly larger in PRL/HL and ID/HL) and smaller paired fins (significantly smaller PCFL/BL), when compared with wild individuals across all investigation months. Our results provided insights into management of black rockfish enhancement in the future.

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Growth, Condition, and Trophic Relations of Stocked Trout in Southern Appalachian Mountain Streams

Cited by 3 publications

References 48 publications

Dietary DNA metabarcoding reveals seasonal trophic changes among three syntopic freshwater trout species

Dietary DNA metabarcoding reveals seasonal trophic changes among three syntopic freshwater trout species

Temporal analysis shows relaxed genetic erosion following improved stocking practices in a subarctic transnational brown trout population

Genetic Stock Identification and Adaptability of Hatchery-Reared Black Rockfish, Sebastes schlegelii, Released Into the North Yellow Sea waters

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