Expression interplay of genes coding for calcium-binding proteins and transcription factors during the osmotic phase provides insights on salt stress response mechanisms in bread wheat.

IF 3.9 2区 生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY Plant Molecular Biology Pub Date : 2024-11-01 DOI:10.1007/s11103-024-01523-z
Diana Duarte-Delgado, Inci Vogt, Said Dadshani, Jens Léon, Agim Ballvora
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Abstract

Bread wheat is an important crop for the human diet, but the increasing soil salinization is reducing the yield. The Ca2+ signaling events at the early stages of the osmotic phase of salt stress are crucial for the acclimation response of the plants through the performance of calcium-sensing proteins, which activate or repress transcription factors (TFs) that affect the expression of downstream genes. Physiological, genetic mapping, and transcriptomics studies performed with the contrasting genotypes Syn86 (synthetic, salt-susceptible) and Zentos (elite cultivar, salt-tolerant) were integrated to gain a comprehensive understanding of the salt stress response. The MACE (Massive Analysis of cDNA 3'-Ends) based transcriptome analysis until 4 h after stress exposure revealed among the salt-responsive genes, the over-representation of genes coding for calcium-binding proteins. The functional and structural diversity within this category was studied and linked with the expression levels during the osmotic phase in the contrasting genotypes. The non-EF-hand category from calcium-binding proteins was found to be enriched for the susceptibility response. On the other side, the tolerant genotype was characterized by a faster and higher up-regulation of genes coding for proteins with EF-hand domain, such as RBOHD orthologs, and TF members. This study suggests that the interplay of calcium-binding proteins, WRKY, and AP2/ERF TF families in signaling pathways at the start of the osmotic phase can affect the expression of downstream genes. The identification of SNPs in promoter sequences and 3' -UTR regions provides insights into the molecular mechanisms controlling the differential expression of these genes through differential transcription factor binding affinity or altered mRNA stability.

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钙结合蛋白和转录因子编码基因在渗透阶段的表达相互作用揭示了面包小麦的盐胁迫响应机制。
面包小麦是人类饮食中的重要作物,但土壤盐碱化的加剧正在降低其产量。盐胁迫渗透阶段早期的 Ca2+ 信号事件通过钙传感蛋白的作用对植物的适应反应至关重要,钙传感蛋白激活或抑制转录因子(TFs),从而影响下游基因的表达。为了全面了解盐胁迫反应,我们对 Syn86(合成、易感盐)和 Zentos(精英栽培品种、耐盐)这两种对比基因型进行了生理学、基因图谱和转录组学研究。基于 MACE(cDNA 3'-Ends 大规模分析)的转录组分析显示,在盐胁迫暴露 4 小时后的盐响应基因中,钙结合蛋白编码基因的比例过高。研究了这类基因的功能和结构多样性,并将其与不同基因型在渗透压阶段的表达水平联系起来。研究发现,钙结合蛋白中的非 EF-手类别富含易感反应。另一方面,耐受基因型的特点是编码具有 EF-手结构域的蛋白质(如 RBOHD 同源物和 TF 成员)的基因上调更快、更高。这项研究表明,钙结合蛋白、WRKY和AP2/ERF TF家族在渗透阶段开始时信号通路中的相互作用会影响下游基因的表达。启动子序列和 3' -UTR 区域 SNPs 的鉴定有助于深入了解通过转录因子结合亲和力的不同或 mRNA 稳定性的改变来控制这些基因不同表达的分子机制。
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来源期刊
Plant Molecular Biology
Plant Molecular Biology 生物-生化与分子生物学
自引率
2.00%
发文量
95
审稿时长
1.4 months
期刊介绍: Plant Molecular Biology is an international journal dedicated to rapid publication of original research articles in all areas of plant biology.The Editorial Board welcomes full-length manuscripts that address important biological problems of broad interest, including research in comparative genomics, functional genomics, proteomics, bioinformatics, computational biology, biochemical and regulatory networks, and biotechnology. Because space in the journal is limited, however, preference is given to publication of results that provide significant new insights into biological problems and that advance the understanding of structure, function, mechanisms, or regulation. Authors must ensure that results are of high quality and that manuscripts are written for a broad plant science audience.
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