Your search keyword '"Vandersteen, Wendy"' showing total 10 results

1. Importance of Experimental Environmental Conditions in Estimating Risks and Associated Uncertainty of Transgenic Fish Prior to Entry into Nature

Author

Vandersteen, Wendy E., Leggatt, Rosalind, Sundström, L. Fredrik, and Devlin, Robert H.

Published

2019

2. Growth-enhanced coho salmon invading other salmon species populations: effects on early survival and growth

Author

Sundström, L. Fredrik, Vandersteen, Wendy E., Lõhmus, Mare, and Devlin, Robert H.

Published

2014

3. Quantitative trait loci for precocious parr maturation, early smoltification, and adult maturation in double-backcrossed trans-Atlantic salmon (Salmo salar)

Author

Pedersen, Stephanie, Berg, Paul R., Culling, Mark, Danzmann, Roy G., Glebe, Brian, Leadbeater, Steven, Lien, Sigbjørn, Moen, Thomas, Vandersteen, Wendy, and Boulding, Elizabeth G.

Published

2013

4. Timing of Postfertilization Pressure Shock Treatment for the Production of Mitotic Gynogens in Six Salmonid Species.

Author

Biagi, Carlo A., Leggatt, Rosalind A., Sakhrani, Dionne, Wetklo, Mike, Vandersteen, Wendy E., Christensen, Kris A., Rondeau, Eric B., Watson, Breanna M., Wellband, Kyle W., Koop, Ben F., Withler, Ruth E., and Devlin, Robert H.

Subjects

SHOCK therapy, SOCKEYE salmon, HAPLOIDY, CHINOOK salmon, COHO salmon, TIME pressure

Abstract

Doubled haploid gynogens are individuals whose genetic material consists of two identical maternal chromosome sets and who lack paternal genetic contributions. These individuals can be useful in whole‐genome sequence assembly to eliminate allelic variation in an individual that otherwise complicates the discrimination of SNPs and paralogs in regular diploids. This is particularly important in salmonid species, which have extensive remnants of an ancestral whole‐genome duplication. Further, doubled haploid individuals are fully homozygous and can be used to generate clonal lines. Here, successful timing was determined for late pressure shocking for producing doubled haploid gynogens in five Oncorhynchus species (Chinook Salmon O. tshawytscha, Coho Salmon O. kisutch, Chum Salmon O. keta, Pink Salmon O. gorbuscha, and Sockeye Salmon O. nerka) and one Salvelinus species (domesticated Artic Char Salvelinus alpinus). For this study, sperm was treated with UV irradiation to inactivate the paternal nuclear DNA and used to fertilize eggs. The resulting zygotes were pressure shocked at various times following fertilization to form doubled haploid embryos via inhibition of the first cell division (mitotic gynogenesis). At an incubation temperature of 10.5°C, successful postfertilization pressure shock times for maximal survival of confirmed gynogens were 2.41–2.83 accumulated thermal units (ATUs) for Coho Salmon, 2.63–2.84 ATUs for Chum Salmon, 2.84–3.06 ATUs for Pink Salmon, 2.19 ATUs for Sockeye Salmon, and 2.63–3.06 ATUs for Chinook Salmon, whereas for Arctic Char a shock time of 2.29–2.54 ATUs at 4°C incubation was successful. Survival to fry stage ranged from less than 1% to 11.7%. Survivors were genotyped using microsatellite markers to assess nonpaternity and maternal homozygosity and were found to be 92.5% gynogens when averaged across all treatments and species. Mitotic gynogenetic individuals were produced in all six salmonid species and were used in subsequent studies to generate whole‐genome sequences for Chinook, Coho, Chum, and Sockeye salmons. [ABSTRACT FROM AUTHOR]

Published

2022

5. Alternate Directed Anthropogenic Shifts in Genotype Result in Different Ecological Outcomes in Coho Salmon Oncorhynchus kisutch Fry.

Author

Leggatt, Rosalind A., Sundström, L. Fredrik, Vandersteen, Wendy E., and Devlin, Robert H.

Subjects

HEALTH outcome assessment, COHO salmon, SOMATOTROPIN, PHENOTYPES, ENVIRONMENTAL impact analysis

Abstract

Domesticated and growth hormone (GH) transgenic salmon provide an interesting model to compare effects of selected versus engineered phenotypic change on relative fitness in an ecological context. Phenotype in domestication is altered via polygenic selection of traits over multiple generations, whereas in transgenesis is altered by a single locus in one generation. These established and emerging technologies both result in elevated growth rates in culture, and are associated with similar secondary effects such as increased foraging, decreased predator avoidance, and similar endocrine and gene expression profiles. As such, there is concern regarding ecological consequences should fish that have been genetically altered escape to natural ecosystems. To determine if the type of genetic change influences fitness components associated with ecological success outside of the culture environments they were produced for, we examined growth and survival of domesticated, transgenic, and wild-type coho salmon fry under different environmental conditions. In simple conditions (i.e. culture) with unlimited food, transgenic fish had the greatest growth, while in naturalized stream tanks (limited natural food, with or without predators) domesticated fish had greatest growth and survival of the three fish groups. As such, the largest growth in culture conditions may not translate to the greatest ecological effects in natural conditions, and shifts in phenotype over multiple rather than one loci may result in greater success in a wider range of conditions. These differences may arise from very different historical opportunities of transgenic and domesticated strains to select for multiple growth pathways or counter-select against negative secondary changes arising from elevated capacity for growth, with domesticated fish potentially obtaining or retaining adaptive responses to multiple environmental conditions not yet acquired in recently generated transgenic strains. [ABSTRACT FROM AUTHOR]

Published

2016

6. Early Life-History Consequences of Growth-Hormone Transgenesis in Rainbow Trout Reared in Stream Ecosystem Mesocosms.

Author

Crossin, Glenn T., Sundström, L. Fredrik, Vandersteen, Wendy E., and Devlin, Robert H.

Subjects

SOMATOTROPIN receptors, RAINBOW trout, FISH growth, FISH ecology, FISH feeds

Abstract

There is persistent commercial interest in the use of growth modified fishes for shortening production cycles and increasing overall food production, but there is concern over the potential impact that transgenic fishes might have if ever released into nature. To explore the ecological consequences of transgenic fish, we performed two experiments in which the early growth and survival of growth-hormone transgenic rainbow trout (Oncorhynchus mykiss) were assessed in naturalized stream mesocosms that either contained predators or were predator-free. We paid special attention to the survival bottleneck that occurs during the early life-history of salmonids, and conducted experiments at two age classes (first-feeding fry and 60 days post-first-feeding) that lie on either side of the bottleneck. In the late summer, the first-feeding transgenic trout could not match the growth potential of their wild-type siblings when reared in a hydrodynamically complex and oligotrophic environment, irrespective of predation pressure. Furthermore, overall survival of transgenic fry was lower than in wild-type (transgenic = 30% without predators, 8% with predators; wild-type = 81% without predators, 31% with predators). In the experiment with 60-day old fry, we explored the effects of the transgene in different genetic backgrounds (wild versus domesticated). We found no difference in overwinter survival but significantly higher growth by transgenic trout, irrespective of genetic background. We conclude that the high mortality of GH-transgenic trout during first-feeding reflects an inability to sustain the basic metabolic requirements necessary for life in complex, stream environments. However, when older, GH-transgenic fish display a competitive advantage over wild-type fry, and show greater growth and equal survival as wild-type. These results demonstrate how developmental age and time of year can influence the response of genotypes to environmental conditions. We therefore urge caution when extrapolating the results of GH-transgenesis risk assessment studies across multiple life-history or developmental stages. [ABSTRACT FROM AUTHOR]

Published

2015

7. Rearing in Seawater Mesocosms Improves the Spawning Performance of Growth Hormone Transgenic and Wild-Type Coho Salmon.

Author

Leggatt, Rosalind A., Hollo, Tanya, Vandersteen, Wendy E., McFarlane, Kassandra, Goh, Benjamin, Prevost, Joelle, and Devlin, Robert H.

Subjects

SEAWATER, SALMON, RISK assessment, ENVIRONMENTAL engineering, TRANSGENIC fish

Abstract

Growth hormone (GH) transgenes can significantly accelerate growth rates in fish and cause associated alterations to their physiology and behaviour. Concern exists regarding potential environmental risks of GH transgenic fish, should they enter natural ecosystems. In particular, whether they can reproduce and generate viable offspring under natural conditions is poorly understood. In previous studies, GH transgenic salmon grown under contained culture conditions had lower spawning behaviour and reproductive success relative to wild-type fish reared in nature. However, wild-type salmon cultured in equal conditions also had limited reproductive success. As such, whether decreased reproductive success of GH transgenic salmon is due to the action of the transgene or to secondary effects of culture (or a combination) has not been fully ascertained. Hence, salmon were reared in large (350,000 L), semi-natural, seawater tanks (termed mesocosms) designed to minimize effects of standard laboratory culture conditions, and the reproductive success of wild-type and GH transgenic coho salmon from mesocosms were compared with that of wild-type fish from nature. Mesocosm rearing partially restored spawning behaviour and success of wild-type fish relative to culture rearing, but remained lower overall than those reared in nature. GH transgenic salmon reared in the mesocosm had similar spawning behaviour and success as wild-type fish reared in the mesocosm when in full competition and without competition, but had lower success in male-only competition experiments. There was evidence of genotype×environmental interactions on spawning success, so that spawning success of transgenic fish, should they escape to natural systems in early life, cannot be predicted with low uncertainty. Under the present conditions, we found no evidence to support enhanced mating capabilities of GH transgenic coho salmon compared to wild-type salmon. However, it is clear that GH transgenic salmon are capable of successful spawning, and can reproduce with wild-type fish from natural systems. [ABSTRACT FROM AUTHOR]

Published

2014

8. Introgression of domesticated alleles into a wild trout genotype and the impact on seasonal survival in natural lakes.

Author

Vandersteen, Wendy, Biro, Pete, Harris, Les, and Devlin, Robert

Subjects

*INTROGRESSION (Genetics), *ALLELES, *TROUT, *FISH genetics, *OUTCROSSING (Biology), *BIOLOGICAL adaptation

Abstract

We tested the fitness consequences of introgression of fast-growing domesticated fish into a wild population. Fry from wild and domesticated rainbow trout ( Oncorhynchus mykiss) crosses, F1 hybrids, and first- and second-generation backcrosses were released into two natural lakes. Parentage analysis using microsatellite loci facilitated the identification of survivors, so fitness was estimated in nature from the first-feeding stage. Results indicated that under certain conditions, domesticated fish survived at least as well as wild fish within the same environment. Relative growth and survival of the crosses, however, were highly dependent on environment. During the first summer, fastest-growing crosses had the highest survival, but this trend was reversed after one winter and another summer. Although the F1 hybrids showed evidence of outbreeding depression because of the disruption of local adaptation, there was little evidence of outbreeding depression in the backcrosses, and the second-generation backcrosses exhibited a wild-type phenotype. This information is relevant for assessing the multigenerational risk of escaped or released domesticated fish should they successfully interbreed with wild populations and provides information on how to minimize detrimental impacts of a conservation breeding and/or management programme. These data also further understanding of the selection pressures in nature that maintain submaximal rates of growth. [ABSTRACT FROM AUTHOR]

Published

2012

9. Induction of Vitellogenin and Histological Effects in Wild Fathead Minnows from a Lake Experimentally Treated with the Synthetic Estrogen, Ethynylestradiol.

Author

Palace, Vince P., Evans, Robert E., Wautier, Kerry, Baron, Christopher, Vandenbyllardt, Lenore, Vandersteen, Wendy, and Kidd, Karen

Subjects

FATHEAD minnow, WATER pollution, ETHINYL estradiol

Abstract

Studies the potential effects of exposure to contaminants with estrogenic activity on wild fathead minnows from a lake experimentally treated with the synthetic estrogen ethynylestradiol (EE2). Addition of EE2 to Lake 260 in the Experimental Lakes Area, Ontario from May to October 2001; Range of EE2 concentrations in epilimnetic waters; Presence of widespread fibrosis and inhibition of testicular development in winnows.

Published

2002

10. Detecting gene expression profiles associated with environmental stressors within an ecological context.

Author

Vandersteen, Wendy

Subjects

*GENE expression, *GENOMICS, *CLIMATE change research, *ORGANISMS, *PHYSIOLOGICAL adaptation, *MACHINE learning, *ENVIRONMENTAL engineering, *ARTIFICIAL neural networks

Abstract

Prior to the development of any conservation strategies to mitigate deleterious impacts of environmental change and contamination, there must be a method to make meaningful predictions of the effect of environmental change on organisms. Assessment of relative transcriptomic expression patterns can provide a link between the environment and the physiological response of the organism by identifying genes that respond to environmental stressors; this information could also assist in teasing apart the molecular basis of toxicological effects vs. physiological adaptation. Molecular responses to environmental stressors are probably not restricted to single or few genes, and therefore a more integrative approach is required to examine broad-scale patterns of transcriptomic response. To address this objective, used machine learning tools to link the mechanisms of physiological response to environmental stress; although widely used in clinical applications, such as finding the genetic basis of diseases (), ecological genomics applications of artificial neural networks are just beginning to emerge. Analyses such as these are important to help identify limitations on the adaptive capacity of organisms and to predict impacts of climate change, ocean acidification and anthropogenic contaminants on aquatic organisms. [ABSTRACT FROM AUTHOR]

Published

2011