Benavente Javiera N, Seeb Lisa W, Seeb James E, Arismendi Ivan, Hernández Cristián E, Gajardo Gonzalo, Galleguillos Ricardo, Cádiz Maria I, Musleh Selim S, Gomez-Uchida Daniel
Department of Zoology, Universidad de Concepcion, Casilla 160-C, Concepcion, Chile.
School of Aquatic and Fishery Sciences, University of Washington, Box 355020, Seattle, WA, 98195-5020, United States of America.
PLoS One. 2015 Nov 6;10(11):e0142040. doi: 10.1371/journal.pone.0142040. eCollection 2015.
Knowledge about the genetic underpinnings of invasions-a theme addressed by invasion genetics as a discipline-is still scarce amid well documented ecological impacts of non-native species on ecosystems of Patagonia in South America. One of the most invasive species in Patagonia's freshwater systems and elsewhere is rainbow trout (Oncorhynchus mykiss). This species was introduced to Chile during the early twentieth century for stocking and promoting recreational fishing; during the late twentieth century was reintroduced for farming purposes and is now naturalized. We used population- and individual-based inference from single nucleotide polymorphisms (SNPs) to illuminate three objectives related to the establishment and naturalization of Rainbow Trout in Lake Llanquihue. This lake has been intensively used for trout farming during the last three decades. Our results emanate from samples collected from five inlet streams over two seasons, winter and spring. First, we found that significant intra- population (temporal) genetic variance was greater than inter-population (spatial) genetic variance, downplaying the importance of spatial divergence during the process of naturalization. Allele frequency differences between cohorts, consistent with variation in fish length between spring and winter collections, might explain temporal genetic differences. Second, individual-based Bayesian clustering suggested that genetic structure within Lake Llanquihue was largely driven by putative farm propagules found at one single stream during spring, but not in winter. This suggests that farm broodstock might migrate upstream to breed during spring at that particular stream. It is unclear whether interbreeding has occurred between "pure" naturalized and farm trout in this and other streams. Third, estimates of the annual number of breeders (Nb) were below 73 in half of the collections, suggestive of genetically small and recently founded populations that might experience substantial genetic drift. Our results reinforce the notion that naturalized trout originated recently from a small yet genetically diverse source and that farm propagules might have played a significant role in the invasion of Rainbow Trout within a single lake with intensive trout farming. Our results also argue for proficient mitigation measures that include management of escapes and strategies to minimize unintentional releases from farm facilities.
尽管非本地物种对南美洲巴塔哥尼亚生态系统的生态影响已有详尽记录,但有关入侵的遗传基础这一入侵遗传学学科所关注的主题,目前仍知之甚少。巴塔哥尼亚淡水系统及其他地区最具入侵性的物种之一是虹鳟(Oncorhynchus mykiss)。该物种于20世纪初被引入智利用于放养和促进休闲渔业;在20世纪后期又被重新引入用于养殖目的,如今已归化。我们利用基于单核苷酸多态性(SNP)的群体和个体推断,来阐明与虹鳟在兰基胡埃湖的定殖和归化相关的三个目标。在过去三十年里,该湖一直被密集用于鳟鱼养殖。我们的结果来自于在冬季和春季两个季节从五条入湖溪流采集的样本。首先,我们发现种群内(时间上的)显著遗传方差大于种群间(空间上的)遗传方差,这淡化了归化过程中空间分化的重要性。不同批次之间的等位基因频率差异,与春季和冬季采集的鱼的长度变化一致,这可能解释了时间上的遗传差异。其次,基于个体的贝叶斯聚类分析表明,兰基胡埃湖内的遗传结构在很大程度上是由春季在一条溪流中发现的假定养殖繁殖体驱动的,而冬季则没有。这表明养殖亲鱼可能在春季上游到那条特定溪流繁殖。目前尚不清楚在这条溪流及其他溪流中,“纯种”归化鳟鱼和养殖鳟鱼之间是否发生了杂交。第三,在一半的样本中,繁殖者数量(Nb)的年度估计值低于73,这表明种群在遗传上规模较小且是近期建立的,可能会经历显著的遗传漂变。我们的结果强化了这样一种观点,即归化的鳟鱼最近起源于一个规模小但遗传多样的来源,并且养殖繁殖体可能在一个有密集鳟鱼养殖的单一湖泊中虹鳟的入侵过程中发挥了重要作用。我们的结果还支持采取有效的缓解措施,包括管理逃逸以及尽量减少养殖设施无意放流的策略。
