Lower Far-Red Light Levels Improve Tolerance to High Evaporative Demand in Cucumber (Cucumis sativus L.) Seedlings by Increasing Leaf Hydraulic Conductance

IF 3.9 3区生物学 Q1 PLANT SCIENCES

Journal of Plant Growth Regulation Pub Date : 2024-08-14 DOI:10.1007/s00344-024-11442-4

Toshio Shibuya, Sana Kajikawa, Joichiro Kuroda, Ryosuke Endo

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Abstract

Under light with a low proportion of far-red (FR) light, plants perceive themselves as growing in open places, which may lead them to increase leaf hydraulic conductance (K_leaf) to cope with the higher water demand associated with increased light intensities. We evaluated K_leaf of cucumber (Cucumis sativus L.) seedlings that had been acclimatized to light with different proportions of FR. K_leaf tended to increase with decreasing FR light. K_leaf and leaf vein length density were positively correlated, indicating that increased K_leaf caused by low FR light may have been caused by changes in leaf vein structure. To clarify whether acclimatization to low-FR light can improve tolerance to high evaporative demand, we evaluated changes in stomatal conductance (g_s), quantum yield of photosystem II (Φ_PSII), and leaf water potential (Ψ_leaf) when seedlings that had been acclimatized to light with FR light in the same proportion as sunlight (FR+) or light without FR light (FR−) were transferred to a high vapor-pressure deficit (VPD) condition. After transfer to high VPD, g_s and Ψ_leaf of the seedlings decreased in all treatment groups, but the decrease was smaller in the FR− seedlings. After transfer to high VPD, Φ_PSII decreased significantly in the FR+ seedlings, but not in the FR− seedlings. These findings suggest that the changes in stress tolerance induced by FR light may be partly mediated by changes in K_leaf. Our results also indicate a potential new technique for mitigating drought stress in horticultural crops by controlling FR light.

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较低的远红外光照水平可通过提高叶片水力传导来改善黄瓜（Cucumis sativus L. ）幼苗对高蒸发需求的耐受性

在远红光（FR）比例较低的光照条件下，植物会认为自己生长在开阔的地方，这可能会导致它们增加叶片水导（Kleaf），以应对与光照强度增加相关的较高水分需求。我们对适应了不同比例 FR 光照的黄瓜（Cucumis sativus L.）幼苗的叶水导率进行了评估。叶片往往随着 FR 光照强度的降低而增加。叶面积和叶脉长度密度呈正相关，表明低 FR 光照导致的叶面积增加可能是由叶脉结构变化引起的。为了明确适应低FR光照是否能提高对高蒸发需求的耐受性，我们评估了将适应了与日光相同比例的FR光照（FR+）或无FR光照（FR-）的幼苗转移到高蒸汽压赤字（VPD）条件下时，气孔导度（gs）、光系统II量子产率（ΦPSII）和叶片水势（Ψleaf）的变化。转入高 VPD 条件后，所有处理组的幼苗的 gs 和 Ψleaf 都有所下降，但 FR- 幼苗的下降幅度较小。转入高 VPD 后，FR+ 组幼苗的 ΦPSII 显著下降，而 FR- 组幼苗的 ΦPSII 没有显著下降。这些发现表明，FR 光诱导的抗逆性变化可能部分是由 Kleaf 的变化介导的。我们的研究结果还表明，通过控制 FR 光，有可能成为缓解园艺作物干旱胁迫的一种新技术。

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来源期刊

Journal of Plant Growth Regulation 生物-植物科学

CiteScore

8.40

自引率

6.20%

发文量

312

审稿时长

1.8 months

期刊介绍： The Journal of Plant Growth Regulation is an international publication featuring original articles on all aspects of plant growth and development. We welcome manuscripts reporting question-based research on various aspects of plant growth and development using hormonal, physiological, environmental, genetic, biophysical, developmental and/or molecular approaches. The journal also publishes timely reviews on highly relevant areas and/or studies in plant growth and development, including interdisciplinary work with an emphasis on plant growth, plant hormones and plant pathology or abiotic stress. In addition, the journal features occasional thematic issues with special guest editors, as well as brief communications describing novel techniques and meeting reports. The journal is unlikely to accept manuscripts that are purely descriptive in nature or reports work with simple tissue culture without attempting to investigate the underlying mechanisms of plant growth regulation, those that focus exclusively on microbial communities, or deal with the (elicitation by plant hormones of) synthesis of secondary metabolites.