The LpHsfA2-molecular module confers thermotolerance via fine tuning of its transcription in perennial ryegrass (Lolium perenne L.)

IF 9.3 1区 生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY
Guangjing Ma, Zhihao Liu, Shurui Song, Jing Gao, Shujie Liao, Shilong Cao, Yan Xie, Liwen Cao, Longxing Hu, Haichun Jing, Liang Chen
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Abstract

Temperature sensitivity and tolerance play a key role in plant survival and production. Perennial ryegrass (Lolium perenne L.), widely cultivated in cool-season for forage supply and turfgrass, is extremely susceptible to high temperatures, therefore serving as an excellent grass for dissecting the genomic and genetic basis of high-temperature adaptation. In this study, expression analysis revealed that LpHsfA2, an important gene associated with high-temperature tolerance in perennial ryegrass, is rapidly and substantially induced under heat stress. Additionally, heat-tolerant varieties consistently display elevated expression levels of LpHsfA2 compared with heat-sensitive ones. Comparative haplotype analysis of the LpHsfA2 promoter indicated an uneven distribution of two haplotypes (HsfA2Hap1 and HsfA2Hap2) across varieties with differing heat tolerance. Specifically, the HsfA2Hap1 allele is predominantly present in heat-tolerant varieties, while the HsfA2Hap2 allele exhibits the opposite pattern. Overexpression of LpHsfA2 confers enhanced thermotolerance, whereas silencing of LpHsfA2 compromises heat tolerance. Furthermore, LpHsfA2 orchestrates its protective effects by directly binding to the promoters of LpHSP18.2 and LpAPX1 to activate their expression, preventing the non-specific misfolding of intracellular protein and the accumulation of reactive oxygen species in cells. Additionally, LpHsfA4 and LpHsfA5 were shown to engage directly with the promoter of LpHsfA2, upregulating its expression as well as the expression of LpHSP18.2 and LpAPX1, thus contributing to enhanced heat tolerance. Markedly, LpHsfA2 possesses autoregulatory ability by directly binding to its own promoter to modulate the self-transcription. Based on these findings, we propose a model for modulating the thermotolerance of perennial ryegrass by precisely regulating the expression of LpHsfA2. Collectively, these findings provide a scientific basis for the development of thermotolerant perennial ryegrass cultivars.

Abstract Image

LpHsfA2分子模块通过微调其在多年生黑麦草(Lolium perenne L.)中的转录赋予耐热性。
温度敏感性和耐受性对植物的生存和生产起着关键作用。多年生黑麦草(Lolium perenne L.)被广泛栽培为冷季型牧草和草坪草,极易受高温影响,因此是研究高温适应性基因组和遗传基础的绝佳草种。在这项研究中,表达分析表明,与多年生黑麦草耐高温相关的重要基因 LpHsfA2 在热胁迫下被快速大量诱导。此外,与热敏感品种相比,耐热品种的 LpHsfA2 表达水平始终较高。LpHsfA2 启动子的单倍型比较分析表明,两种单倍型(HsfA2Hap1 和 HsfA2Hap2)在耐热性不同的品种中分布不均。具体来说,HsfA2Hap1 等位基因主要存在于耐热品种中,而 HsfA2Hap2 等位基因则表现出相反的模式。过量表达 LpHsfA2 会增强耐热性,而沉默 LpHsfA2 则会降低耐热性。此外,LpHsfA2 通过直接与 LpHSP18.2 和 LpAPX1 的启动子结合来激活它们的表达,防止细胞内蛋白质的非特异性错误折叠和细胞内活性氧的积累,从而协调其保护作用。此外,LpHsfA4 和 LpHsfA5 还能直接与 LpHsfA2 的启动子结合,上调其表达以及 LpHSP18.2 和 LpAPX1 的表达,从而增强耐热性。值得注意的是,LpHsfA2 通过直接与自身启动子结合来调节自我转录,从而具有自我调节能力。基于这些发现,我们提出了一个通过精确调控 LpHsfA2 的表达来调节多年生黑麦草耐热性的模型。总之,这些发现为开发耐高温的多年生黑麦草品种提供了科学依据。
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来源期刊
Journal of Integrative Plant Biology
Journal of Integrative Plant Biology 生物-生化与分子生物学
CiteScore
18.00
自引率
5.30%
发文量
220
审稿时长
3 months
期刊介绍: Journal of Integrative Plant Biology is a leading academic journal reporting on the latest discoveries in plant biology.Enjoy the latest news and developments in the field, understand new and improved methods and research tools, and explore basic biological questions through reproducible experimental design, using genetic, biochemical, cell and molecular biological methods, and statistical analyses.
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