在本地和引进地区的比较显示很少有证据表明发芽性状的气候适应

Harold N. Eyster , Elizabeth M. Wolkovich
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引用次数: 4

摘要

由于全球化和环境变化,包括人为气候变化,植物入侵正在增加。然而,我们缺乏对一些物种如何成为广泛的入侵者而另一些物种却没有的理解。有两种相互竞争的机制被提出:引进后对引进范围的新环境的快速进化和本地种群的广泛环境耐受性,使入侵者对不同的引进环境具有耐受性。每种机制都暗示着入侵者如何应对气候变化:要么随着未来气候的变化而进化,要么已经能够忍受当前/未来的各种气候。解开这些机制需要研究进化和耐受性如何驱动入侵性状(发芽成功率和时间;增长率)。在这里,我们测试了这些特征快速进化的证据,通过使用生长室为7种草本植物物种提供共同气候,这些植物物种从其本地(欧洲)和引进(北美)范围的多个种群中取样。室提供了两个层次的分层来模拟不同的冬季长度,分层后提供了四个层次的温度来模拟不同的春季条件。我们使用贝叶斯多层模型来检验响应,同时控制种群和种子家族。在所有物种中,本地种群和引进种群之间的性状反应在很大程度上是相似的,除了对特定气候的反应,如寒冷的冬天和温暖的春天,在这些气候中,引进种群发芽较晚,生长较快。我们的研究结果表明,广泛的环境耐受性,而不是快速的进化,可能是这些入侵者入侵成功的基础,并且可能在持续变暖的情况下维持它们的传播,但是物种可能会对冬季和春季气候制度的特定组合做出反应。
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Comparisons in the native and introduced ranges reveal little evidence of climatic adaptation in germination traits

Plant invasions are increasing due to globalization and environmental change, including through anthropogenic climate change. Yet we lack an understanding of how some species become widespread invaders while others do not. Two competing mechanisms have been posited: post-introduction rapid evolution to the novel environments of the introduced range and broad environmental tolerance in the native population that makes invaders tolerant of diverse introduced environments. Each mechanism has implications for how invaders respond to climate change: either by evolving with future climates, or already being tolerant of diverse current/future climates. Disentangling these mechanisms requires investigating how evolution versus tolerance drive invasion traits (germination success and timing; growth rate). Here, we tested for evidence of rapid evolution in these traits by using growth chambers to provide common climates for seven herbaceous plant species sampled from multiple populations in their native (European) and introduced (North American) ranges. Chambers provided two levels of stratification—to simulate different winter lengths—and four temperature levels post-stratification—to simulate different spring conditions. We used Bayesian multilevel models to examine responses, while controlling for population and seed family. Across all species, trait responses were largely similar between native and introduced populations, except in response to particular climates representing cold winters and warm springs where introduced populations germinated later and grew faster. Our results suggest that broad environmental tolerance, not rapid evolution, likely underlies invasion success for these invaders—and may sustain their spread with continued warming—but species may evolve in response to specific combinations of winter and spring climatic regimes.

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