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支撑茶叶(茶树(L.)O. 昆茨)中与热应激相关的耐热性的分子编程。

Underpinning the molecular programming attributing heat stress associated thermotolerance in tea (Camellia sinensis (L.) O. Kuntze).

作者信息

Seth Romit, Maritim Tony Kipkoech, Parmar Rajni, Sharma Ram Kumar

机构信息

Biotechnology Department, CSIR-Institute of Himalayan Bioresource Technology (CSIR-IHBT), Palampur, Himachal Pradesh, 176061, India.

Academy of Scientific and Innovative Research (AcSIR), CSIR-HRDC Campus, Ghaziabad, Uttar Pradesh, 201002, India.

出版信息

Hortic Res. 2021 May 1;8(1):99. doi: 10.1038/s41438-021-00532-z.

DOI:10.1038/s41438-021-00532-z
PMID:33931616
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8087774/
Abstract

The most daunting issue of global climate change is the deleterious impact of extreme temperatures on tea productivity and quality, which has resulted in a quest among researchers and growers. The current study aims to unravel molecular programming underpinning thermotolerance by characterizing heat tolerance and sensitivity response in 20 tea cultivars. The significantly higher negative influence of heat stress was recorded in a sensitive cultivar with reduced water retention (47%), chlorophyll content (33.79%), oxidation potential (32.48%), and increase in membrane damage (76.4%). Transcriptional profiling of most tolerant and sensitive cultivars identified 78 differentially expressed unigenes with chaperon domains, including low and high molecular weight heat shock protein (HSP) and heat shock transcription factors (HSFs) involved in heat shock response (HSR). Further, predicted transcriptional interactome network revealed their key role in thermotolerance via well-co-ordinated transcriptional regulation of aquaporins, starch metabolism, chlorophyll biosynthesis, calcium, and ethylene mediated plant signaling system. The study identified the key role of HSPs (CsHSP90) in regulating HSR in tea, wherein, structure-based molecular docking revealed the inhibitory role of geldanamycin (GDA) on CsHSP90 by blocking ATP binding site at N-terminal domain of predicted structure. Subsequently, GDA mediated leaf disc inhibitor assay further affirmed enhanced HSR with higher expression of CsHSP17.6, CsHSP70, HSP101, and CsHSFA2 genes in tea. Through the current study, efforts were made to extrapolate a deeper understanding of chaperons mediated regulation of HSR attributing thermotolerance in tea.

摘要

全球气候变化最严峻的问题是极端温度对茶叶产量和品质的有害影响,这引发了研究人员和种植者的探索。本研究旨在通过对20个茶树品种的耐热性和敏感性反应进行表征,揭示耐热性的分子调控机制。在一个敏感品种中,热胁迫的负面影响显著更高,表现为保水率降低(47%)、叶绿素含量降低(33.79%)、氧化电位降低(32.48%)以及膜损伤增加(76.4%)。对最耐热和最敏感品种的转录谱分析鉴定出78个具有伴侣结构域的差异表达单基因,包括参与热休克反应(HSR)的低分子量和高分子量热休克蛋白(HSP)以及热休克转录因子(HSF)。此外,预测的转录相互作用组网络揭示了它们通过对水通道蛋白、淀粉代谢、叶绿素生物合成、钙和乙烯介导的植物信号系统进行协调转录调控,在耐热性中发挥关键作用。该研究确定了HSPs(CsHSP90)在调节茶树HSR中的关键作用,其中基于结构的分子对接显示格尔德霉素(GDA)通过阻断预测结构N端结构域的ATP结合位点对CsHSP90具有抑制作用。随后,GDA介导的叶盘抑制试验进一步证实了茶树中CsHSP17.6、CsHSP70、HSP101和CsHSFA2基因的高表达增强了HSR。通过本研究,努力加深对伴侣蛋白介导的HSR调控赋予茶树耐热性的理解。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b417/8087774/eff2dbb887f2/41438_2021_532_Fig8_HTML.jpg
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