Migratory species typically undertake demanding long‐distance journeys, across different habitat types during which they are exposed to multiple natural and anthropogenic stressors. Mortality during migration is typically high and may be human induced. Understanding individual responses to these selection pressures is rarely attempted because of the challenges of relating individual phenotypic and genetic data to migration success. Here, we show distinct single nucleotide polymorphism (SNP) sets significantly differentiated between Atlantic salmon smolts making successful migrations to sea and those that failed to migrate, in two different rivers. In contrast, morphological variation was not diagnostic of migration success. Populations from each river were genetically distinct, and while different genes were possibly implicated in migration success in each river, they related to common biological processes (e.g., osmoregulation and immune and stress response). Given that migration failure should quickly purge polymorphism at selected SNPs from a population, the question of how genetic diversity in these populations is maintained is an important one. Standing genetic variation could be maintained by different life history strategies and/or environmentally driven balancing selection. Our work highlights the importance of preserving genetic diversity to ensure evolutionary resilience at the population level and has practical implications for management.
展开▼
机译:迁徙物种通常进行艰苦的长途旅行,穿越不同的栖息地类型,在此期间,它们会受到多种自然和人为压力源的影响。迁徙过程中的死亡率通常很高,可能是人为引起的。由于将个体表型和遗传数据与迁移成功联系起来存在挑战,因此很少尝试了解个体对这些选择压力的反应。在这里,我们显示了在两条不同河流中成功洄游到大海的大西洋鲑鱼小鲑鱼和未能洄游的大西洋鲑鱼之间显着区分了不同的单核苷酸多态性 (SNP) 集。相比之下,形态学变异不能诊断迁移成功。每条河流的种群在遗传上是不同的,虽然不同的基因可能与每条河流的迁移成功有关,但它们与共同的生物过程(例如,渗透调节以及免疫和应激反应)有关。鉴于迁移失败应该会迅速清除种群中选定 SNP 的多态性,因此如何维持这些种群中的遗传多样性是一个重要的问题。常存遗传变异可以通过不同的生活史策略和/或环境驱动的平衡选择来维持。我们的工作强调了保护遗传多样性以确保种群水平进化弹性的重要性,并对管理具有实际意义。
展开▼
