Physiological and structural traits contribute to thermotolerance in wild Australian cotton species.

IF 3.6 2区生物学 Q1 PLANT SCIENCES Annals of botany Pub Date : 2025-02-19 DOI:10.1093/aob/mcae098

Garima Dubey, Aaron L Phillips, Darrell J Kemp, Brian J Atwell

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Abstract

Background and aims: Five species of cotton (Gossypium) were exposed to 38 °C days during early vegetative development. Commercial cotton (Gossypium hirsutum) was contrasted with four wild cotton species (Gossypium australe, G. bickii, G. robinsonii and G. sturtianum) that are endemic to central and northern Australia.

Methods: Plants were grown at daytime maxima of 30 or 38 °C for 25 days, commencing at the four-leaf stage. Leaf areas and shoot biomass were used to calculate relative rates of growth and specific leaf areas. Leaf gas exchange measurements revealed assimilation and transpiration rates, in addition to electron transport rates and carboxylation efficiency in steady-state conditions. Finally, leaf morphological traits (mean leaf area and leaf shape) were quantified, along with leaf surface decorations, imaged using scanning electron microscopy.

Key results: Shoot morphology was differentially affected by heat, with three of the four wild species growing faster at 38 than at 30 °C, whereas early growth in G. hirsutum was severely inhibited by heat. Areas of individual leaves and the number of leaves both contributed to these contrasting growth responses, with fewer, smaller leaves at 38 °C in G. hirsutum. CO2 assimilation and transpiration rates of G. hirsutum were also dramatically reduced by heat. Cultivated cotton failed to achieve evaporative cooling, contrasting with the transpiration-driven cooling in the wild species. Heat substantially reduced electron transport rates and carboxylation efficiency in G. hirsutum, with much smaller effects in the wild species. We speculate that leaf shape, as assessed by invaginations of leaf margins, and leaf size contributed to heat dispersal differentially among the five species. Likewise, reflectance of light radiation was also highly distinctive for each species.

Conclusions: These four wild Australian relatives of cotton have adapted to hot days that are inhibitory to commercial cotton, deploying a range of physiological and structural adaptations to achieve accelerated growth at 38 °C.

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澳大利亚野生棉花物种的生理和结构特征有助于提高耐热性。

背景和目的：五种棉花（Gossypium）在无性发育早期暴露于 38°C 天。将商用棉花（Gossypium hirsutum）与澳大利亚中部和北部特有的四个野生棉花品种（G. australe、G. bickii、G. robinsonii 和 G. sturtianum）进行对比：方法：从四叶期开始，植物在 30°C 或 38°C 的日间最高温度下生长 25 天。叶面积和嫩枝生物量用于计算相对生长率和特定叶面积。叶片气体交换测量显示了同化和蒸腾速率，以及稳态条件下的电子传输速率（ETR）和羧化效率（CE）。最后，利用扫描电子显微镜对叶片形态特征（平均叶面积和叶形进行了量化）以及叶片表面装饰进行了成像：嫩枝形态受高温的影响各不相同，四个野生物种中的三个在 38°C 下的生长速度快于 30°C，而 G. hirsutum 的早期生长受到高温的严重抑制。单个叶片的面积和叶片数量都是造成这些不同生长反应的原因，在 38°C 时，G. hirsutum 的叶片更少、更小。高温还显著降低了 G. hirsutum 的二氧化碳同化率和蒸腾率。栽培棉花未能实现蒸发冷却，这与野生棉花的蒸腾冷却形成了鲜明对比。高温大大降低了 G. hirsutum 的 ETR 和 CE，而野生物种受到的影响要小得多。我们推测，根据叶缘内陷情况评估的叶片形状和叶片大小对五个物种的热量散布有不同的影响。同样，每个物种的光辐射反射率也大不相同：这四种棉花的澳大利亚野生近缘种已经适应了对商业棉花有抑制作用的炎热天气，它们通过一系列生理和结构适应措施来实现在 38°C 温度条件下的加速生长。

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来源期刊

Annals of botany 生物-植物科学

CiteScore

7.90

自引率

4.80%

发文量

138

审稿时长

3 months

期刊介绍： Annals of Botany is an international plant science journal publishing novel and rigorous research in all areas of plant science. It is published monthly in both electronic and printed forms with at least two extra issues each year that focus on a particular theme in plant biology. The Journal is managed by the Annals of Botany Company, a not-for-profit educational charity established to promote plant science worldwide. The Journal publishes original research papers, invited and submitted review articles, ''Research in Context'' expanding on original work, ''Botanical Briefings'' as short overviews of important topics, and ''Viewpoints'' giving opinions. All papers in each issue are summarized briefly in Content Snapshots , there are topical news items in the Plant Cuttings section and Book Reviews . A rigorous review process ensures that readers are exposed to genuine and novel advances across a wide spectrum of botanical knowledge. All papers aim to advance knowledge and make a difference to our understanding of plant science.