分子动力学模拟揭示了序列上下文在植物基于 ELF3-PrD 的温度感应机制中的作用

Richard J Lindsay, Rafael Giordano Viegas, VITOR B P LEITE, Philip Anthony Wigge, Sonya M Hanson
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摘要

黄昏复合体(EC)是一种三方 DNA 抑制因子,也是昼夜节律钟的核心组成部分,它为许多植物的温度响应性生长和发育提供了一种机制。ELF3是EC的一个组成部分,它是一种紊乱的支架蛋白,在低温下会阻碍生长基因的转录。温度升高时,EC 的 DNA 结合被破坏,ELF3 被封闭在可逆的核凝结物中,从而使转录和生长得以继续。凝结是由一个低复杂度的朊病毒样结构域(PrD)驱动的,温度反应的敏感性受可变多Q束长度的调节,较长的多Q束在温度升高时会增强凝结的形成和下胚轴的生长。在此,一系列计算研究提供了证据,证明polyQ束能促进侧翼残基中温度敏感螺旋的形成,从而对温度升高时EC的稳定性产生潜在影响。REST2 模拟发现了由热诱导的易凝结构象群,这是由于 "粘性 "芳香残基暴露于温度反应性长程接触断裂所致。粗粒度马蒂尼模拟显示,多Q束长度和序列上下文都会调节聚类形成的温度依赖性。了解植物中ELF3-PrD温度响应的分子机制对各种技术都有影响,包括用于热响应蛋白质设计的模块化温度响应元件和农业技术进步,从而优化作物产量并使植物在日益恶劣的环境中茁壮成长。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Molecular dynamics simulations illuminate the role of sequence context in the ELF3-PrD-based temperature sensing mechanism in plants
The evening complex (EC) is a tripartite DNA repressor and a core component of the circadian clock that provides a mechanism for temperature-responsive growth and development of many plants. ELF3, a component of the EC, is a disordered scaffolding protein that blocks transcription of growth genes at low temperature. At increased temperature EC DNA binding is disrupted and ELF3 is sequestered in a reversible nuclear condensate, allowing transcription and growth to proceed. The condensation is driven by a low complexity prion-like domain (PrD), and the sensitivity of the temperature response is modulated by the length of a variable polyQ tract, with a longer polyQ tract corresponding to enhanced condensate formation and hypocotyl growth at increased temperature. Here, a series of computational studies provides evidence that polyQ tracts promote formation of temperature-sensitive helices in flanking residues with potential impacts for EC stability under increasing temperature. REST2 simulations uncover a heat-induced population of condensation-prone conformations that results from the exposure of 'sticky' aromatic residues by temperature-responsive breaking of long-range contacts. Coarse-grained Martini simulations reveal both polyQ tract length and sequence context modulate the temperature dependence of cluster formation. Understanding the molecular mechanism underlying the ELF3-PrD temperature response in plants has implications for technologies including modular temperature-response elements for heat-responsive protein design and agricultural advances to enable optimization of crop yields and allow plants to thrive in increasingly inhospitable environments.
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