快速且动态叶卷形态 OsRUS1 过表达水稻系的转录组分析。

Transcriptomic analysis of OsRUS1 overexpression rice lines with rapid and dynamic leaf rolling morphology.

机构信息

Center for Photosynthesis and Plant Stress Biology, College of Life Sciences, South-China Agricultural University, Guangzhou, 510642, China.

State Key Laboratory for Conservation and Utilization of Subtropical Agro-Bioresources, College of Life Sciences, South China Agricultural University, Guangzhou, 510642, China.

出版信息

Sci Rep. 2022 Apr 25;12(1):6736. doi: 10.1038/s41598-022-10784-x.

DOI:10.1038/s41598-022-10784-x

PMID:35468979

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9038715/

Abstract

Moderate leaf rolling helps to form the ideotype of rice. In this study, six independent OsRUS1-GFP overexpression (OsRUS1-OX) transgenic rice lines with rapid and dynamic leaf rolling phenotype in response to sunlight were constructed. However, the mechanism is unknown. Here, RNA-Seq approach was utilized to identify differentially expressed genes between flag leaves of OsRUS1-OX and wildtype under sunlight. 2920 genes were differentially expressed between OsRUS1-OX and WT, of which 1660 upregulated and 1260 downregulated. Six of the 16 genes in GO: 0009415 (response to water stimulus) were significantly upregulated in OsRUS1-OX. The differentially expressed genes between WT and OsRUS1-OX were assigned to 110 KEGG pathways. 42 of the 222 genes in KEGG pathway dosa04075 (Plant hormone signal transduction) were differentially expressed between WT and OsRUS1-OX. The identified genes in GO:0009415 and KEGG pathway dosa04075 were good candidates to explain the leaf rolling phenotype of OsRUS1-OX. The expression patterns of the 15 genes identified by RNA-Seq were verified by qRT-PCR. Based on transcriptomic and qRT-PCR analysis, a mechanism for the leaf rolling phenotype of OsRUS1-OX was proposed. The differential expression profiles between WT and OsRUS1-OX established by this study provide important insights into the molecular mechanism behind the leaf rolling phenotype of OsRUS1-OX.

摘要

适度的叶片卷曲有助于形成水稻的理想型。在这项研究中，构建了六个独立的 OsRUS1-GFP 过表达（OsRUS1-OX）转基因水稻品系，它们对阳光表现出快速和动态的叶片卷曲表型。然而，其机制尚不清楚。在这里，利用 RNA-Seq 方法来鉴定 OsRUS1-OX 和野生型在阳光照射下的旗叶之间差异表达的基因。在 OsRUS1-OX 和 WT 之间有 2920 个基因差异表达，其中 1660 个上调，1260 个下调。GO:0009415（对水刺激的反应）中 16 个基因中的 6 个在 OsRUS1-OX 中显著上调。WT 和 OsRUS1-OX 之间差异表达的基因被分配到 110 个 KEGG 途径。KEGG 途径 dosa04075（植物激素信号转导）中 222 个基因中的 42 个在 WT 和 OsRUS1-OX 之间差异表达。GO:0009415 和 KEGG 途径 dosa04075 中鉴定的基因是解释 OsRUS1-OX 叶片卷曲表型的良好候选基因。通过 RNA-Seq 鉴定的 15 个基因的表达模式通过 qRT-PCR 进行了验证。基于转录组和 qRT-PCR 分析，提出了 OsRUS1-OX 叶片卷曲表型的机制。本研究建立的 WT 和 OsRUS1-OX 之间的差异表达谱为 OsRUS1-OX 叶片卷曲表型的分子机制提供了重要的见解。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/f2a6/9038715/15269fb2a6bc/41598_2022_10784_Fig1_HTML.jpg

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快速且动态叶卷形态 OsRUS1 过表达水稻系的转录组分析。

Transcriptomic analysis of OsRUS1 overexpression rice lines with rapid and dynamic leaf rolling morphology.

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