季节性遗传变异是部分候鸟早年迁徙的基础。

IF 3.8 1区 生物学 Q1 BIOLOGY Proceedings of the Royal Society B: Biological Sciences Pub Date : 2024-10-01 Epub Date: 2024-10-16 DOI:10.1098/rspb.2024.1660
Rita Fortuna, Paul Acker, Cassandra R Ugland, Sarah J Burthe, Michael P Harris, Mark A Newell, Carrie Gunn, Timothy I Morley, Thomas R Haaland, Robert L Swann, Sarah Wanless, Francis Daunt, Jane M Reid
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引用次数: 0

摘要

生态进化对环境诱导选择的反应从根本上取决于促进种群持久性的性状的遗传变异幅度。加性遗传变异和相关遗传率会因环境条件而异,尤其是对于生命早期表现出来的易变表型性状。然而,在野生种群中,遗传变异的短期季节性动态很少被量化,因此无法推断季节性动态系统中的生态进化结果。这种限制适用于季节性迁徙与居住,这是快速微进化可以拯救部分迁徙种群免受季节性环境变化影响的一个关键特征。我们将新的定量遗传 "捕获-再捕获动物模型 "与欧洲雉(Gulosus aristotelis)11个群组的多代血统和全年复视数据相匹配,以估算幼体在第一个秋冬季节迁徙能力和迁徙表现的季节性遗传变异。我们证明了生命早期迁徙的遗传变异不可忽略,秋季的加性遗传变异和遗传率是冬季的两倍。由于迁徙的早期生存选择通常发生在冬季,因此最高的遗传变异和最强的选择在季节上是不同步的。我们的研究结果揭示了生命早期遗传和表型变异在年内和年际间的复杂动态,表明要充分推断生态进化的结果,需要在适当的尺度和季节时间范围内量化微观进化潜力。
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Season-specific genetic variation underlies early-life migration in a partially migratory bird.

Eco-evolutionary responses to environmentally induced selection fundamentally depend on magnitudes of genetic variation underlying traits that facilitate population persistence. Additive genetic variances and associated heritabilities can vary across environmental conditions, especially for labile phenotypic traits expressed through early life. However, short-term seasonal dynamics of genetic variances are rarely quantified in wild populations, precluding inference on eco-evolutionary outcomes in seasonally dynamic systems. This limitation applies to seasonal migration versus residence, constituting one key trait where rapid microevolution could rescue partially migratory populations from changing seasonal environments. We fitted novel quantitative genetic 'capture-recapture animal models' to multi-generational pedigree and year-round resighting data from 11 cohorts of European shags (Gulosus aristotelis), to estimate season-specific additive genetic variances in liabilities to migrate, and in resulting expression of migration, in juveniles' first autumn and winter. We demonstrate non-negligible genetic variation underlying early-life migration, with twice as large additive genetic variances and heritabilities in autumn than winter. Since early-life survival selection on migration typically occurs in winter, highest genetic variation and strongest selection are seasonally desynchronized. Our results reveal complex within- and among-year dynamics of early-life genetic and phenotypic variation, demonstrating that adequate inference of eco-evolutionary outcomes requires quantifying microevolutionary potential on appropriate scales and seasonal timeframes.

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来源期刊
CiteScore
7.90
自引率
4.30%
发文量
502
审稿时长
1 months
期刊介绍: Proceedings B is the Royal Society’s flagship biological research journal, accepting original articles and reviews of outstanding scientific importance and broad general interest. The main criteria for acceptance are that a study is novel, and has general significance to biologists. Articles published cover a wide range of areas within the biological sciences, many have relevance to organisms and the environments in which they live. The scope includes, but is not limited to, ecology, evolution, behavior, health and disease epidemiology, neuroscience and cognition, behavioral genetics, development, biomechanics, paleontology, comparative biology, molecular ecology and evolution, and global change biology.
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