Seasonal Variations in the Toughness of Leaves: A Case Study Using Griselinia littoralis.

IF 2.2 3区 生物学 Q1 ZOOLOGY Integrative and Comparative Biology Pub Date : 2024-09-17 DOI:10.1093/icb/icae004
David Taylor
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Abstract

Potential effects of climate change include greater extremes of temperature and increased severity of storms. Many plants have evolved to resist the challenges of winter (freezing, dehydration, and wind) in a process known as cold hardening. Sensing reducing temperatures, they make structural changes at the cellular level to increase their mechanical resistance and prevent damage. Previous work on this topic, though extensive, has been conducted under laboratory conditions rather than in the field, and while many workers have observed changes to cell wall thickness and composition, which imply increased mechanical strength, few have actually measured strength or any other parameter describing structural integrity. This paper describes experiments on a model system designed to measure the structural integrity of leaf laminae from plants growing naturally in the field over extended periods, allowing seasonal variations to be captured. Standard engineering properties-tensile strength and fracture toughness-were measured for leaves of Griselinia littoralis on 19 separate occasions over a 12-month period. Toughness (rather than strength) was found to be the controlling mechanical property. Toughness values were found to change significantly during the year, by more than a factor of 2. Toughness correlated strongly with average daily soil temperature, but with a lag of about 1-2 weeks, suggesting that this is the time needed for structural adjustments to take place. Highest toughness values occurred in winter, confirming cold hardening. Increasing temperature in the spring was associated with decreasing toughness, but in the summer, when highest temperatures occurred, toughness increased again. This apparent "hot hardening" may be a response to dehydration. Results imply that a given leaf is able to both increase and decrease its toughness in response to temperature changes, demonstrating excellent plasticity of response. This case study of a single species establishes a method of reliably measuring changes in a plant's structural integrity due to cold hardening and other seasonal variations, which may be used to investigate the effects of climate change and other variables.

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叶片韧性的季节变化:以鸢尾为例的个案研究。
气候变化的潜在影响包括更极端的温度和更严重的风暴。许多植物在进化过程中都能抵御冬季的挑战(冰冻、脱水、大风),这一过程被称为冷硬化。感知到温度降低后,它们会在细胞水平上进行结构调整,以增强机械抵抗力,防止受损。虽然许多研究人员观察到了细胞壁厚度和成分的变化,这意味着机械强度的增加,但很少有人真正测量过强度或其他描述结构完整性的参数。本文介绍了一个模型系统的实验,该系统旨在测量长期在田间自然生长的植物叶片的结构完整性,从而捕捉季节性变化。在长达 12 个月的时间里,我们在 19 个不同的场合测量了 Griselinia littoralis 叶子的标准工程特性--拉伸强度和断裂韧性。结果发现,韧性(而不是强度)是控制机械性能的主要因素。韧性值在一年中变化很大,变化幅度超过 2 倍。韧性与土壤日平均温度密切相关,但滞后约 1-2 周,表明这是结构调整所需的时间。最高的韧性值出现在冬季,证实了低温硬化。春季气温升高,韧性下降,但夏季气温最高时,韧性再次上升。这种明显的 "热硬化 "可能是对脱水的反应。研究结果表明,特定叶片既能提高韧性,也能降低韧性,以应对温度变化,显示出极佳的可塑性。这项针对单一物种的案例研究确立了一种方法,可以可靠地测量植物结构完整性因冷硬化和其他季节性变化而发生的变化,该方法可用于研究气候变化和其他变量的影响。
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来源期刊
CiteScore
4.70
自引率
7.70%
发文量
150
审稿时长
6-12 weeks
期刊介绍: Integrative and Comparative Biology ( ICB ), formerly American Zoologist , is one of the most highly respected and cited journals in the field of biology. The journal''s primary focus is to integrate the varying disciplines in this broad field, while maintaining the highest scientific quality. ICB''s peer-reviewed symposia provide first class syntheses of the top research in a field. ICB also publishes book reviews, reports, and special bulletins.
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