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生长激素转基因三文鱼为生长潜力付出了更高被捕食死亡率的代价。

Growth hormone transgenic salmon pay for growth potential with increased predation mortality.

作者信息

Sundström L Fredrik, Lõhmus Mare, Johnsson Jörgen I, Devlin Robert H

机构信息

Department of Zoology, Göteborg University, SE-405 30 Göteborg, Sweden.

出版信息

Proc Biol Sci. 2004 Aug 7;271 Suppl 5(Suppl 5):S350-2. doi: 10.1098/rsbl.2004.0189.

DOI:10.1098/rsbl.2004.0189
PMID:15504015
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1810071/
Abstract

Recent advances in gene technology have been applied to create fast-growing transgenic fish, which are of great commercial interest owing to their potential to shorten production cycles and increase food production. However, there is growing concern and speculation over the impact that escaped growth hormone (GH)-transgenic fish may have on the natural environment. To predict these risks it is crucial to obtain empirical data on the relative fitness of transgenic and non-transgenic fish under nature-like conditions. Using landscaped stream aquaria with live food and predators, we show that the predation mortality of newly hatched GH-transgenic coho salmon fry (Oncorhynchus kisutch) is much higher than in non-transgenic conspecifics, and that this difference is amplified when food abundance decreases. The growth rate of transgenic and non-transgenic fish is similar at high food levels, whereas transgenic fish grow more slowly than non-transgenic fish when food abundance is reduced. Our results suggest that the fitness of young GH-transgenic coho salmon in the wild will be determined by both predation pressure and food availability.

摘要

基因技术的最新进展已被用于培育生长迅速的转基因鱼,由于它们具有缩短生产周期和增加食物产量的潜力,因而具有巨大的商业价值。然而,人们越来越关注并猜测逃逸的生长激素(GH)转基因鱼可能对自然环境产生的影响。为了预测这些风险,至关重要的是要获得在类似自然条件下转基因鱼和非转基因鱼相对适合度的实证数据。我们使用带有活饵和捕食者的景观溪流水族箱,发现新孵化的GH转基因银大麻哈鱼幼鱼(Oncorhynchus kisutch)的捕食死亡率远高于非转基因同种个体,并且当食物丰度降低时,这种差异会放大。在食物水平较高时,转基因鱼和非转基因鱼的生长速度相似,而当食物丰度降低时,转基因鱼的生长速度比非转基因鱼慢。我们的结果表明,野生环境中幼年GH转基因银大麻哈鱼的适合度将由捕食压力和食物可利用性共同决定。

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