Genetic discrimination of wild versus farmed gilthead sea bream Sparus aurata using microsatellite markers associated with candidate genes

IF 1.5 4区农林科学 Q3 FISHERIES

Aquatic Living Resources Pub Date : 2022-03-08 DOI:10.1051/alr/2022009

Iva Žužul , Leon Grubišić , Tanja Šegvić-Bubić , Costas Tsigenopoulos

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引用次数: 0

Abstract

Farm escapees and their offspring impose a significant impact on the environment and may therefore alter the future evolutionary trajectories of wild populations. To date, there is no management plan in place in Mediterranean countries to prevent fish escapes. Here, we investigate microsatellite length variations in three candidate genes, including prolactin (PRL), growth hormone (GH), and the receptor activity modifying protein 3 gene (RAMP3), to study the genetic structure of the main fish species farmed in the Mediterranean, gilthead seabream (Sparus aurata). We also evaluate the performance of microsatellites in discriminating fish origin (wild or farmed). Results from 298 individuals, including farmed, wild adult and juvenile fish were compared with results from 19 neutral markers used in a previous study. All loci were polymorphic, selectively neutral, and had the statistical power to detect significant population differentiation. Global FST was similar to that estimated using 19 loci (0.019 and 0.023, respectively), while pairwise comparisons identified farmed populations as the main drivers of genetic divergence, with a much higher magnitude of overall genetic differentiation within farmed populations (0.076) than that estimated using the 19 neutral microsatellite loci (0.041). Bayesian structural analysis showed that the PRL, GH, and RAMP3 markers were able to distinguish farmed from wild populations, but were not able to distinguish different wild groups as 19 neutral microsatellite markers did. Farmed populations of different origins were assigned to a separate cluster with a high individual assignment score (>88%). It appears that the candidate markers are more influenced by artificial selection compared to neutral markers. Further validation of their efficiency in discriminating wild, farmed, and mixed fish origins using a more robust sample size is needed to ensure their potential use in an escaped fish monitoring programme.

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利用候选基因相关微卫星标记进行野生与养殖鳙鱼的遗传鉴别

农场逃亡者及其后代对环境造成重大影响，因此可能改变野生种群未来的进化轨迹。迄今为止，地中海国家还没有制定管理计划来防止鱼类逃逸。在此，我们研究了三个候选基因的微卫星长度变化，包括催乳素(PRL)、生长激素(GH)和受体活性修饰蛋白3基因(RAMP3)，以研究地中海养殖的主要鱼类——gilhead seabream (Sparus aurata)的遗传结构。我们还评估了微卫星在辨别鱼类来源(野生或养殖)方面的性能。来自298条鱼的结果，包括养殖、野生成鱼和幼鱼，比较了之前研究中使用的19种中性标记的结果。所有的位点都是多态的，选择性中性的，并且具有检测显着群体分化的统计能力。全球FST与使用19个基因座估算的结果相似(分别为0.019和0.023)，而配对比较发现，养殖群体是遗传分化的主要驱动因素，养殖群体内部的总体遗传分化幅度(0.076)远高于使用19个中性微卫星基因座估算的结果(0.041)。贝叶斯结构分析表明，PRL、GH和RAMP3标记能够区分养殖群体和野生群体，但不能像19个中性微卫星标记那样区分不同的野生群体。不同来源的养殖种群被分配到一个单独的集群，个体分配得分高(>88%)。与中性标记相比，候选标记受人工选择的影响更大。需要使用更强大的样本量进一步验证它们在区分野生、养殖和混合鱼类来源方面的效率，以确保它们在逃逸鱼类监测计划中的潜在用途。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Aquatic Living Resources 农林科学-海洋与淡水生物学

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

>24 weeks

期刊介绍： Aquatic Living Resources publishes original research papers, review articles and propective notes dealing with all exploited (i.e. fished or farmed) living resources in marine, brackish and freshwater environments. Priority is given to ecosystem-based approaches to the study of fishery and aquaculture social-ecological systems, including biological, ecological, economic and social dimensions. Research on the development of interdisciplinary methods and tools which can usefully support the design, implementation and evaluation of alternative management strategies for fisheries and/or aquaculture systems at different scales is particularly welcome by the journal. This includes the exploration of scenarios and strategies for the conservation of aquatic biodiversity and research relating to the development of integrated assessment approaches aimed at ensuring sustainable and high quality uses of aquatic living resources.