一种多年生禾本科植物对温暖和潮湿环境的遗传反应与性状手段和可塑性相互影响、相互关联。

IF 2.1 3区 生物学 Q3 ECOLOGY Journal of Evolutionary Biology Pub Date : 2024-06-28 DOI:10.1093/jeb/voae060
Zuzana Münzbergová, Maria Šurinová, Filippo Biscarini, Eva Níčová
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引用次数: 0

摘要

快速进化的潜力是物种适应不断变化的气候条件的重要机制。虽然这种潜力在各种短寿命生物中得到了广泛的研究,但我们在长寿命植物物种中能观察到类似模式的程度还远远不够,而植物物种通常在自然系统中占主导地位。我们探索了在高山草地上广泛克隆生长的长寿草 Festuca rubra 的快速进化潜力。我们利用田间播种实验模拟了模型区域的预期气候变化。具体来说,我们将来自 5 个独立种源的种子沿着自然气候网格移动,使其暴露在新的气候条件下,并探索 3 年后成活幼苗的遗传特征。在不同新条件下被选中的植物的基因图谱数据表明,不同的气候转变会从共同的种子库中选择出明显不同的基因型。土壤湿度的增加比温度的增加或两种气候因素的相互作用更重要。这可能表明在综合效应下存在负遗传交互作用,或者不同气候的效应是交互的而不是相加的。所选等位基因位于基因组区域,可能影响特定基因的功能或表达。其中许多等位基因还与形态特征(主要是性状可塑性)有关,表明这些变化可能会影响植物的表现。总之,这些数据表明,即使是寿命较长的植物物种也可能受到气候的强烈选择,因此它们的种群有可能迅速适应这些新的条件。
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Genetic response of a perennial grass to warm and wet environments interacts and is associated with trait means as well as plasticity.

The potential for rapid evolution is an important mechanism allowing species to adapt to changing climatic conditions. Although such potential has been largely studied in various short-lived organisms, to what extent we can observe similar patterns in long-lived plant species, which often dominate natural systems, is largely unexplored. We explored the potential for rapid evolution in Festuca rubra, a long-lived grass with extensive clonal growth dominating in alpine grasslands. We used a field sowing experiment simulating expected climate change in our model region. Specifically, we exposed seeds from five independent seed sources to novel climatic conditions by shifting them along a natural climatic grid and explored the genetic profiles of established seedlings after 3 years. Data on genetic profiles of plants selected under different novel conditions indicate that different climate shifts select significantly different pools of genotypes from common seed pools. Increasing soil moisture was more important than increasing temperature or the interaction of the two climatic factors in selecting pressure. This can indicate negative genetic interaction in response to the combined effects or that the effects of different climates are interactive rather than additive. The selected alleles were found in genomic regions, likely affecting the function of specific genes or their expression. Many of these were also linked to morphological traits (mainly to trait plasticity), suggesting these changes may have a consequence on plant performance. Overall, these data indicate that even long-lived plant species may experience strong selection by climate, and their populations thus have the potential to rapidly adapt to these novel conditions.

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来源期刊
Journal of Evolutionary Biology
Journal of Evolutionary Biology 生物-进化生物学
CiteScore
4.20
自引率
4.80%
发文量
152
审稿时长
3-6 weeks
期刊介绍: It covers both micro- and macro-evolution of all types of organisms. The aim of the Journal is to integrate perspectives across molecular and microbial evolution, behaviour, genetics, ecology, life histories, development, palaeontology, systematics and morphology.
期刊最新文献
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