一种非常成功的城市蝴蝶的热极限有可塑性,但没有进化分化的证据。

IF 2.3 2区 农林科学 Q1 ENTOMOLOGY
Angie Lenard, Sarah E. Diamond
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引用次数: 0

摘要

尽管城市化对昆虫的生物多样性普遍产生负面影响,但一些昆虫物种仍在城市栖息地生存。鉴于土地利用变化对全球昆虫数量下降的影响,了解昆虫耐受城市栖息地能力的基本机制至关重要。表型可塑性和热生理特征的进化变化等补偿机制可以使城市种群在城市栖息地改变的热环境中存活下来。了解可塑性和进化对城市化梯度过程中性状变化的贡献非常重要,因为这两种机制是在不同的限制条件和时间尺度下运行的。在此,我们利用双温共同花园实验研究了来自城市和非城市(农村)栖息地的菜粉蝶种群的耐热性和耐寒性(临界最大热量[CTmax]和临界最小热量[CTmin])对气候变暖的可塑性和进化反应。尽管我们预计经历城市变暖的种群会通过可塑性和进化机制表现出更大的 CTmax 和更小的 CTmin,但我们的研究只发现了两种热耐受性特征在预期方向上的可塑性证据。我们没有发现耐热性或耐寒性出现进化分化的证据,尽管这两种性状都具有进化潜力。我们的研究结果表明,耐热可塑性是该系统中城市持续存在的原因之一。然而,由于可塑性反应的程度较低,而且与其他昆虫物种相当,其他补偿机制可能进一步巩固了该物种在城市栖息地的成功。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Evidence of plasticity, but not evolutionary divergence, in the thermal limits of a highly successful urban butterfly

Evidence of plasticity, but not evolutionary divergence, in the thermal limits of a highly successful urban butterfly

Evidence of plasticity, but not evolutionary divergence, in the thermal limits of a highly successful urban butterfly

Despite the generally negative impact of urbanization on insect biodiversity, some insect species persist in urban habitats. Understanding the mechanisms underpinning the ability of insects to tolerate urban habitats is critical given the contribution of land-use change to the global insect decline. Compensatory mechanisms such as phenotypic plasticity and evolutionary change in thermal physiological traits could allow urban populations to persist under the altered thermal regimes of urban habitats. It is important to understand the contributions of plasticity and evolution to trait change along urbanization gradients as the two mechanisms operate under different constraints and timescales. Here, we examine the plastic and evolutionary responses of heat and cold tolerance (critical thermal maximum [CTmax] and critical thermal minimum [CTmin]) to warming among populations of the cabbage white butterfly, Pieris rapae, from urban and non-urban (rural) habitats using a two-temperature common garden experiment. Although we expected populations experiencing urban warming to exhibit greater CTmax and diminished CTmin through plastic and evolutionary mechanisms, our study revealed evidence only for plasticity in the expected direction of both thermal tolerance traits. We found no evidence of evolutionary divergence in either heat or cold tolerance, despite each trait showing evolutionary potential. Our results suggest that thermal tolerance plasticity contributes to urban persistence in this system. However, as the magnitude of the plastic response was low and comparable to other insect species, other compensatory mechanisms likely further underpin this species’ success in urban habitats.

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来源期刊
Journal of insect physiology
Journal of insect physiology 生物-昆虫学
CiteScore
4.50
自引率
4.50%
发文量
77
审稿时长
57 days
期刊介绍: All aspects of insect physiology are published in this journal which will also accept papers on the physiology of other arthropods, if the referees consider the work to be of general interest. The coverage includes endocrinology (in relation to moulting, reproduction and metabolism), pheromones, neurobiology (cellular, integrative and developmental), physiological pharmacology, nutrition (food selection, digestion and absorption), homeostasis, excretion, reproduction and behaviour. Papers covering functional genomics and molecular approaches to physiological problems will also be included. Communications on structure and applied entomology can be published if the subject matter has an explicit bearing on the physiology of arthropods. Review articles and novel method papers are also welcomed.
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