Growth and feed utilization by F4human growth hormone transgenic carp fed diets with different protein levels

Fu, C

doi:10.1006/jfbi.1998.0686

Journal of Fish Biology

1998

DOI: 10.1006/jfbi.1998.0686

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Growth and feed utilization by F4human growth hormone transgenic carp fed diets with different protein levels

C Fu¹

Abstract: The F 4 generation of human growth hormone (hGH) transgenic red common carp Cyprinus carpio had significantly higher growth rates than the non-transgenic controls. Protein and energy intakes were significantly higher in the transgenic carp than in the controls fed the 20% protein diet, but were not different between the two strains fed diets with 30 and 40% protein.Faecal protein loss, as a proportion of protein intake, was significantly lower in the transgenics than in the controls fed diets with 20 and 30% p… Show more

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Cited by 4 publications

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“…Several species of fish have been modified genetically and currently are being explored as a way to increase the production efficiency and yield in aquaculture (24)(25)(26)(27)(28). These transgenic fish overexpress GH and require enhanced feed consumption to achieve the increased growth rates (29).…”

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Gene–environment interactions influence ecological consequences of transgenic animals

Sundström

Lõhmus

Tymchuk

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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Production of transgenic animals has raised concern regarding their potential ecological impact should they escape or be released to the natural environment. This concern has arisen mainly from research on laboratory-reared animals and theoretical modeling exercises. In this study, we used biocontained naturalized stream environments and conventional hatchery environments to show that differences in phenotype between transgenic and wild genotypes depend on rearing conditions and, critically, that such genotype-by-environment interactions may influence subsequent ecological effects in nature. Genetically wild and growth hormone transgenic coho salmon (Oncorhynchus kisutch) were reared from the fry stage under either standard hatchery conditions or under naturalized stream conditions. When reared under standard hatchery conditions, the transgenic fish grew almost three times longer than wild conspecifics and had (under simulated natural conditions) stronger predation effects on prey than wild genotypes (even after compensation for size differences). In contrast, when fish were reared under naturalized stream conditions, transgenic fish were only 20% longer than the wild fish, and the magnitude of difference in relative predation effects was much reduced. These data show that genotype-by-environment interactions can influence the relative phenotype of transgenic and wild-type organisms and that extrapolations of ecological consequences from phenotypes developed in the unnatural laboratory environment may lead to an overestimation or underestimation of ecological risk. Thus, for transgenic organisms that may not be released to nature, the establishment of a range of highly naturalized environments will be critical for acquiring reliable experimental data to be used in risk assessments.coho salmon ͉ phenotypic plasticity ͉ risk-assessment

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mentioning

confidence: 99%

Gene–environment interactions influence ecological consequences of transgenic animals

Sundström

Lõhmus

Tymchuk

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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Growth and feed utilization in two strains of gibel carp, Carassius auratus gibelio: paternal effects in a gynogenetic fish

2001

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SummaryGibel carp (Carassius auratus gibelio Bloch) is a natural gynogenetic ®sh which requires sperm of the same or related species to activate egg development. The eggs of one gibel carp were divided into two batches. One batch was ÔfertilizedÕ with sperm from gibel carp (strain DD), and the other ÔfertilizedÕ with sperm from red common carp (Cyprinus carpio red variety) (strain DR). The juveniles were transferred to the laboratory 36 days post-hatch. Triplicate groups of each strain were fed a formulated diet at either 3% or satiation ration for 8 weeks. At both the restricted and satiation rations, speci®c growth rate was signi®cantly higher in strain DR than in strain DD. At the 3% ration, there was no signi®cant di erence in feeding rate or feed conversion e ciency between the two strains. At the satiation ration, strain DR had a signi®cantly lower feeding rate but higher feed conversion e ciency than strain DD. At the satiation ration, strain DR had a signi®cantly lower intake protein, but higher recovered protein than strain DD. There was no signi®cant di erence in faecal protein loss between the two strains. At the 3% ration, strain had no signi®cant e ects on intake protein, faecal protein or recovered protein. Neither faecal energy loss nor recovered energy was a ected by strain or ration. At both the 3% and satiation ration, ®nal body contents of dry matter and lipid were signi®cantly lower in strain DR than strain DD, while there was no signi®cant di erence in protein and energy content between the two strains at either ration level. The results suggested that gibel carp ÔfertilizedÕ with sperm of common carp grew faster than those ÔfertilizedÕ with sperm of gibel carp through increased feed conversion e ciency and protein retention.

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Life history responses of fishes to culture

Thorpe

2004

Journal of Fish Biology

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The protected environment in culture permits fishes to reduce the proportion of energy normally channelled into the costs associated with competition for food, shelter and mates, avoidance of predators and counteracting parasites and diseases. The surplus energy so released is allocated to growth and reproduction, accelerating development through increased growth rate, earlier maturation and increased relative fecundity. Cultivators manipulate the rearing environment to remove seasonal variation in availability of resources, so that the fishes grow and develop through otherwise unproductive seasons. Such environmental manipulations exaggerate the basic accelerative effects. Since maturation deflects energy from growth, farmers also manipulate the fishes nutritionally, physiologically, hormonally and genetically to postpone maturation. As environmental regulators determine sex in many fish species, environmental manipulation in culture may have unintended effects on sex ratios. Mortality in culture should be very low, but survival of fishes released from culture is rarely as high as that of wild conspecifics. Finally, while short life-cycles and simplified population age-structures permit high rates of production in farms, they lead to ecological instability when the fishes are cultured for support of wild populations. # 2004 The Fisheries Society of the British IslesLife-history strategies provide solutions to the problem of reproducing successfully in varying environments. Life histories are accounts of how animals partition the food energy needed to survive, grow, develop to maturity and reproduce. The developmental programme is genetic but it runs under environmental instruction. Fishes are ectothermal animals, so their development depends on external temperature. Photoperiod signals synchronize development with appropriate temperature conditions. Hence the life histories of fishes are strongly seasonal. Developmental rhythms evolve in synchrony with opportunities offered by environmental rhythms, which are signalled to the animal most reliably by photoperiod. Culture simplifies the range of environmental signals to which fishes are exposed and permits the cultivator to manipulate the fishes as physiological machines for his chosen variant of their life history, e.g., for high growth rate or high gamete production.Whatever the life-history variant, the necessary food energy is allocated first to maintenance needs, and the surplus partitioned between growth and reproduction Tel./fax: þ44 (0) 1796 47 3886;

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Growth and feed utilization by F4human growth hormone transgenic carp fed diets with different protein levels

Cited by 4 publications

References 33 publications

Gene–environment interactions influence ecological consequences of transgenic animals

Gene–environment interactions influence ecological consequences of transgenic animals

Growth and feed utilization in two strains of gibel carp, Carassius auratus gibelio: paternal effects in a gynogenetic fish

Life history responses of fishes to culture

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