Legacies from early-season hot drought: how growth cessation alters tree water dynamics and modifies stress responses in Scots pine.

IF 4.2 3区生物学 Q1 PLANT SCIENCES

Plant Biology Pub Date : 2025-01-15 DOI:10.1111/plb.13760

N K Ruehr, D Nadal-Sala

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引用次数: 0

Abstract

Tree responses to drought are well studied, but the interacting effects of drought timing on growth, water use, and stress legacy are less understood. We investigated how a widespread conifer, Scots pine, responded to hot droughts early or late in the growing season, or to both. We measured sap flux, stem growth, needle elongation, and leaf water potential (Ψ_leaf) to assess the impacts of stress timing on drought resilience in Scots pine saplings. The early summer hot drought had peak temperatures of 36.5 °C, while the late summer hot drought peaked at 38.2 °C. Soil water content during both periods declined to ca. 50% of control values. The early-season hot drought caused growth cessation already at Ψ_leaf - 1.1 MPa, visible as an almost 30 days earlier end to needle elongation, resulting in needles 2.7 cm shorter, on average. This reduction in leaf area decreased productivity, resulting in a reduction of 50% in seasonal transpiration. However, the reduced water use of early-stressed saplings appeared to enhance resistance to a late-season drought, as reflected in a smaller decline in Ψ_leaf and lower tree water deficit compared to saplings that did not experience early-season stress. In summary, we observed persistant drought legacy effects from early-season hot-drought stress, as evident in a 35% reduction of leaf area, which impacted tree water use, stress resistance, and productivity. These structural adjustments of leaf development and reduced bud mass from early-season stress could be critical in evergreen conifers, whose long-lived foliage influences future water use and growth potential.

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从早期季热干旱的遗产：如何生长停止改变树木的水动力学和修改苏格兰松的应激反应。

树木对干旱的反应已经得到了很好的研究，但干旱时间对生长、水分利用和压力遗留的相互作用却知之甚少。我们调查了一种广泛分布的针叶树，苏格兰松，如何在生长季节的早期或晚期对炎热的干旱做出反应，或者两者兼有。我们测量了树液通量、茎生长、针尖伸长和叶片水势（Ψleaf）来评估胁迫时间对苏格兰松苗抗旱性的影响。初夏炎热干旱的峰值温度为36.5°C，而夏末炎热干旱的峰值温度为38.2°C。两期土壤含水量均降至对照值的50%左右。早季高温干旱已经导致生长停止在Ψleaf - 1.1 MPa，可见，几乎30天提前结束针伸长，导致针平均缩短2.7厘米。叶面积的减少降低了生产力，导致季节性蒸腾减少了50%。然而，与没有经历早期胁迫的树苗相比，早期胁迫的树苗减少了水分利用，似乎增强了对季末干旱的抵抗力，这反映在Ψleaf的下降幅度较小，树木水分亏缺也更低。总之，我们观察到早期季热干旱胁迫的持续干旱遗留效应，如叶面积减少35%，这影响了树木的水分利用、抗逆性和生产力。早季胁迫对常绿针叶树叶片发育的结构调整和芽质量的减少至关重要，因为常绿针叶树的长叶影响其未来的水分利用和生长潜力。

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来源期刊

Plant Biology 生物-植物科学

CiteScore

8.20

自引率

2.60%

发文量

109

审稿时长

3 months

期刊介绍： Plant Biology is an international journal of broad scope bringing together the different subdisciplines, such as physiology, molecular biology, cell biology, development, genetics, systematics, ecology, evolution, ecophysiology, plant-microbe interactions, and mycology. Plant Biology publishes original problem-oriented full-length research papers, short research papers, and review articles. Discussion of hot topics and provocative opinion articles are published under the heading Acute Views. From a multidisciplinary perspective, Plant Biology will provide a platform for publication, information and debate, encompassing all areas which fall within the scope of plant science.