UV-B increases active phytochrome B to suppress thermomorphogenesis and enhance UV-B stress tolerance at high temperatures.

IF 9.4 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Plant Communications Pub Date : 2024-10-09 DOI:10.1016/j.xplc.2024.101142

Geonhee Hwang, Taedong Lee, Jeonghyang Park, Inyup Paik, Nayoung Lee, Yun Ju Kim, Young Hun Song, Woe-Yeon Kim, Eunkyoo Oh

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引用次数: 0

Abstract

Plants respond to small increases in ambient temperature by changing their architecture, a response collectively termed thermomorphogenesis. Thermomorphogenesis is considered to attenuate the damage caused by potentially harmful high-temperature conditions, and multiple environmental factors can modulate this process. Among these factors, ultraviolet-B (UV-B) light has been shown to strongly suppress this response. However, the molecular mechanisms through which it regulates thermomorphogenesis and the physiological roles of the UV-B-mediated suppression of thermomorphogenesis remain poorly understood. Here, we show that UV-B inhibits thermomorphogenesis through the UVR8-COP1-phyB/HFR1 signaling module. We found that cop1 mutants maintain high levels of active phyB at high temperatures. Extensive genetic analyses revealed that the increased phyB, HFR1, and CRY1 in cop1 mutants redundantly reduce both the level and activity of a key positive regulator in thermomorphogenesis, PIF4, thereby repressing this growth response. Additionally, we found that UV-B light increases phyB stability and its photobody number through the inactivation of COP1. The UV-B-stabilized active phyB, together with HFR1, inhibits thermomorphogenesis by interfering with PIF4. We further show that the increased active phyB enhances UV-B tolerance by activating flavonoid biosynthesis and inhibiting thermomorphogenic growth. Taken together, our study demonstrates that UV-B increases the levels of active phyB and HFR1 by inhibiting COP1 to suppress PIF4-mediated growth responses, which is essential for plant tolerance to UV-B stress at high temperatures.

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紫外线-B能提高植物色素B的活性，从而抑制高温下的热形态发生，增强对紫外线-B胁迫的耐受性。

植物通过改变其结构来应对环境温度的小幅升高，这种反应统称为热形态发生。热蜕变被认为可以减轻潜在有害高温条件造成的损害，而多种环境因素可以调节这一过程。在这些因素中，紫外线-B（UV-B）光已被证明能强烈抑制这种反应。然而，人们对紫外线-B调控温态发生的分子机制以及紫外线-B介导的温态发生抑制作用的生理作用仍然知之甚少。在这里，我们发现紫外线-B通过UVR8-COP1-phyB/HFR1信号模块抑制热态性发生。我们发现，cop1 突变体在高温下能保持高水平的活性 phyB。广泛的遗传分析表明，cop1突变体中增加的phyB、HFR1和CRY1冗余地降低了热形态发生中一个关键正调控因子PIF4的水平和活性，从而抑制了这种生长反应。此外，我们还发现紫外线-B 光通过使 COP1 失活，增加了 phyB 的稳定性及其光抗体的数量。紫外线-B稳定的活性phyB与HFR1一起通过干扰PIF4抑制热形态发生。我们进一步发现，活性phyB的增加通过激活类黄酮的生物合成和抑制热变性生长，增强了对紫外线-B的耐受性。综上所述，我们的研究表明，紫外线-B通过抑制COP1来增加活性phyB和HFR1的水平，从而抑制PIF4介导的生长反应，这对于植物在高温下耐受紫外线-B胁迫至关重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Plant Communications Agricultural and Biological Sciences-Plant Science

CiteScore

15.70

自引率

5.70%

发文量

105

审稿时长

6 weeks

期刊介绍： Plant Communications is an open access publishing platform that supports the global plant science community. It publishes original research, review articles, technical advances, and research resources in various areas of plant sciences. The scope of topics includes evolution, ecology, physiology, biochemistry, development, reproduction, metabolism, molecular and cellular biology, genetics, genomics, environmental interactions, biotechnology, breeding of higher and lower plants, and their interactions with other organisms. The goal of Plant Communications is to provide a high-quality platform for the dissemination of plant science research.