Bicskei Beatrix, Bron James E, Glover Kevin A, Taggart John B
Institute of Aquaculture, School of Natural Sciences, University of Stirling, Stirling FK9 4LA, UK.
BMC Genomics. 2014 Oct 9;15(1):884. doi: 10.1186/1471-2164-15-884.
Atlantic salmon have been subject to domestication for approximately ten generations, beginning in the early 1970s. This process of artificial selection will have created various genetic differences between wild and farmed stocks. Each year, hundreds of thousands of farmed fish escape into the wild. These escapees may interbreed with wild conspecifics raising concerns for both the fish-farming industry and fisheries managers. Thus, a better understanding of the interactions between domesticated and wild salmon is essential to the continued sustainability of the aquaculture industry and to the maintenance of healthy wild stocks.
We compared the transcriptomes of a wild Norwegian Atlantic salmon population (Figgjo) and a Norwegian farmed strain (Mowi) at two life stages: yolk sac fry and post first-feeding fry. The analysis employed 44 k oligo-microarrays to analyse gene expression of 36 farmed, wild and hybrid (farmed dam x wild sire) individuals reared under identical hatchery conditions. Although some of the transcriptional differences detected overlapped between sampling points, our results highlighted the importance of studying various life stages. Compared to the wild population, the Mowi strain displayed up-regulation in mRNA translation-related and down regulation in nervous and immune system -related pathways in the sac fry, whereas up-regulation of digestive and endocrine activities, carbohydrate, energy, amino acid and lipid metabolism and down-regulation of environmental information processing and immune system pathways were evident in the feeding fry. Differentially regulated pathways that were common among life stages generally belonged to environmental information processing and immune system functional groups. In addition, we found indications of strong maternal effects, reinforcing the importance of including reciprocal hybrids in the analysis.
In agreement with previous studies we showed that domestication has caused changes in the transcriptome of wild Atlantic salmon and that many of the affected pathways are life-stage specific We highlighted the importance of reciprocal hybrids to the deconvolution of maternal/paternal effects and our data support the view that the genetic architecture of the strains studied highly influences the genes differentially expressed between wild and domesticated fish.
自20世纪70年代初开始,大西洋鲑已经历了大约十代的驯化。这种人工选择过程在野生种群和养殖种群之间产生了各种遗传差异。每年,成千上万的养殖鱼类逃入野外。这些逃逸者可能与野生同种个体杂交,这引起了养鱼业和渔业管理者的担忧。因此,更好地了解驯化鲑鱼和野生鲑鱼之间的相互作用对于水产养殖业的持续可持续性以及维持健康的野生种群至关重要。
我们比较了挪威野生大西洋鲑种群(菲格约)和挪威养殖品系(莫维亚)在两个生命阶段的转录组:卵黄囊仔鱼和初次摄食后仔鱼。该分析采用44k寡核苷酸微阵列来分析在相同孵化条件下饲养的36个养殖、野生和杂交(养殖母本×野生父本)个体的基因表达。尽管在采样点之间检测到的一些转录差异存在重叠,但我们的结果突出了研究不同生命阶段的重要性。与野生种群相比,莫维亚品系在卵黄囊仔鱼中显示出与mRNA翻译相关的上调以及与神经和免疫系统相关途径的下调,而在摄食仔鱼中消化和内分泌活动、碳水化合物、能量、氨基酸和脂质代谢的上调以及环境信息处理和免疫系统途径的下调则很明显。在不同生命阶段中共同存在的差异调节途径通常属于环境信息处理和免疫系统功能组。此外,我们发现了强烈母体效应的迹象,这进一步强调了在分析中纳入正反交杂种的重要性。
与先前的研究一致,我们表明驯化导致了野生大西洋鲑转录组的变化,并且许多受影响的途径是特定于生命阶段的。我们强调了正反交杂种对于区分母体/父体效应的重要性,并且我们的数据支持这样的观点,即所研究品系的遗传结构高度影响野生和驯化鱼类之间差异表达的基因。
