研究慢性蛋白质毒性内质网应激下拟南芥未折叠蛋白反应的转录组学数据集

Amelie Ducloy, Marianne Azzopardi, Caroline Ivsic, Gwendal Cueff, Delphine Sourdeval, Delphine Charif, Jean-Luc Cacas
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摘要

未折叠蛋白反应(UPR)是一种逆行的ER-to-nucleus信号通路,在多个王国中都是保守的。在植物中,它有助于发育、繁殖、免疫和对非生物胁迫的耐受性。该RNA测序数据集来自14日龄拟南芥幼苗,这些幼苗受到tunicamycin (Tm)的刺激,tunicamycin (Tm)是一种抑制内质网(ER)中Asn-linked糖基化的抗生素,导致内质网应激并最终激活UPR。在我们的实验设置中,使用野生型(WT)和双突变体缺乏UPR的两个主要参与者(INOSITOL-REQUIRING ENZYME 1A和INOSITOL-REQUIRING ENZYME 1B)作为遗传背景,以便区分依赖或独立于IRE1s的差异表达基因(deg)。此外,茎和根分别收获,以确定对Tm的器官特异性转录组反应。文库和测序采用北京基因组研究所DNBseq技术。对拟南芥基因组的Reads进行了定位和定量。差异表达基因经筛选和归一化后,采用Rflomics方法进行鉴定。虽然在模拟条件下基因型效应较弱(芽中有182个deg,根中有195个deg),但tunicamycin对每个基因型的影响在芽和根中都有数百个deg。其中,与WT相比,双突变体茎部组织中872个基因和563个基因分别有统计学上的上调和下调。在受tm胁迫的幼苗根系中,425和439个基因在突变体中与WT相关的显著上调和下调。我们相信我们的数据集可以重复用于研究与内质网稳态及其在植物生理学中的作用相关的任何生物学问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A transcriptomic dataset for investigating the Arabidopsis Unfolded Protein Response under chronic, proteotoxic endoplasmic reticulum stress
The Unfolded Protein Response (UPR) is a retrograde, ER-to-nucleus, signalling pathway which is conserved across kingdoms. In plants, it contributes to development, reproduction, immunity and tolerance to abiotic stress. This RNA sequencing dataset was produced from 14-day-old Arabidopsis thaliana seedlings challenged by tunicamycin (Tm), an antibiotic inhibiting Asn-linked glycosylation in the endoplasmic reticulum (ER), causing an ER stress and eventually activating the UPR. Wild-type (WT) and a double mutant deficient for two main actors of the UPR (INOSITOL-REQUIRING ENZYME 1A and INOSITOL-REQUIRING ENZYME 1B) were used as genetic backgrounds in our experimental setup, allowing to distinguish among differentially-expressed genes (DEGs) which ones are dependent on or independent on IRE1s. Also, shoots and roots were harvested separately to determine organ-specific transcriptomic responses to Tm. Library and sequencing were performed using DNBseq technology by the Beijing Genomics Institute. Reads were mapped and quantified against the Arabidopsis genome. Differentially-expressed genes were identified using Rflomics upon filtering and normalization by the Trimmed Mean of M-value (TMM) method. While the genotype effect was weak under mock conditions (with a total of 182 DEGs in shoots and 195 DEGs in roots), the tunicamycin effect on each genotype was characterized by several hundred of DEGs in both shoots and roots. Among these genes, 872 and 563 genes were statistically up- and down-regulated in the shoot tissues of the double mutant when compared to those of WT, respectively. In roots of Tm-challenged seedlings, 425 and 439 genes were significantly up- and down-regulated in mutants with respect to WT. We believe that our dataset could be reused for investigating any biological questions linked to ER homeostasis and its role in plant physiology.
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