环境对遗传变异的影响可能会制约对新环境的适应。

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
ACS Applied Electronic Materials Pub Date : 2024-01-18 eCollection Date: 2024-06-01 DOI:10.1093/evlett/qrad065
Greg M Walter, Keyne Monro, Delia Terranova, Enrico la Spina, Maria Majorana, Giuseppe Pepe, James Clark, Salvatore Cozzolino, Antonia Cristaudo, Simon J Hiscock, Jon Bridle
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引用次数: 0

摘要

适应性可塑性使种群能够应对环境变化,但当环境变得陌生时,适应性可塑性就会失效。在新的条件下,种群可能会依靠快速适应来提高适应能力,避免灭绝。当可塑性和选择都发生在含有丰富遗传变异的多变量表型方向时,适应应该是最快的。然而,通过野外实验对这一预测进行检验的情况并不多见。在这里,我们量化了多元表型的加性遗传变异在海拔梯度上的变化,并检验了可塑性和选择是否与遗传变异一致。我们利用适应埃特纳火山高海拔和低海拔地区的西西里雏菊(菊科 Senecio)的两个亲缘关系密切但生态学上截然不同的姊妹种来进行研究。我们采用定量遗传育种设计,在跨越每个物种原生海拔高度的海拔梯度上产生并相互种植了约 19,000 颗两个物种的种子,然后对幼苗的死亡率和五种叶片特征进行了定量分析。我们发现,叶片性状的遗传变异在不同海拔高度之间的变化比在不同物种之间的变化更大。新的低海拔高海拔物种的叶片性状遗传变异分布发生了变化,这减少了选择方向和原生表型的遗传变异量。相比之下,低海拔物种主要在新的高海拔处表现出遗传变异量的变化,遗传变异集中在原生表型方向。对于这两个物种来说,叶片性状在不同海拔的可塑性都是朝着包含适量遗传变异的多元表型方向发展的。这些数据共同表明,在可塑性是适应性的情况下,对最初可塑性反应的遗传变异的选择可以促进适应性。然而,环境对遗传变异的巨大影响可能会降低在新环境中的适应潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Environmental effects on genetic variance are likely to constrain adaptation in novel environments.

Adaptive plasticity allows populations to cope with environmental variation but is expected to fail as conditions become unfamiliar. In novel conditions, populations may instead rely on rapid adaptation to increase fitness and avoid extinction. Adaptation should be fastest when both plasticity and selection occur in directions of the multivariate phenotype that contain abundant genetic variation. However, tests of this prediction from field experiments are rare. Here, we quantify how additive genetic variance in a multivariate phenotype changes across an elevational gradient, and test whether plasticity and selection align with genetic variation. We do so using two closely related, but ecologically distinct, sister species of Sicilian daisy (Senecio, Asteraceae) adapted to high and low elevations on Mt. Etna. Using a quantitative genetic breeding design, we generated and then reciprocally planted c. 19,000 seeds of both species, across an elevational gradient spanning each species' native elevation, and then quantified mortality and five leaf traits of emergent seedlings. We found that genetic variance in leaf traits changed more across elevations than between species. The high-elevation species at novel lower elevations showed changes in the distribution of genetic variance among the leaf traits, which reduced the amount of genetic variance in the directions of selection and the native phenotype. By contrast, the low-elevation species mainly showed changes in the amount of genetic variance at the novel high elevation, and genetic variance was concentrated in the direction of the native phenotype. For both species, leaf trait plasticity across elevations was in a direction of the multivariate phenotype that contained a moderate amount of genetic variance. Together, these data suggest that where plasticity is adaptive, selection on genetic variance for an initially plastic response could promote adaptation. However, large environmental effects on genetic variance are likely to reduce adaptive potential in novel environments.

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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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