HD-ZIP IV Gene ROC1 Regulates Leaf Rolling and Drought Response Through Formation of Heterodimers with ROC5 and ROC8 in Rice.

IF 4.8 1区农林科学 Q1 AGRONOMY

Rice Pub Date : 2024-07-27 DOI:10.1186/s12284-024-00717-9

Zhihuan Tao, Xuexia Miao, Zhenying Shi

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Abstract

Leaf morphology is a crucial agronomic characteristic of rice that influences crop yield directly. One primary cause of rice leaf rolling can be attributed to alterations in bulliform cells. Several HD-ZIP IV genes have been identified to be epidemical characterized and function in leaf rolling in rice. Still others need to be studied to fully understand the overall function of HD-ZIP IV family. Among the nine ROC genes encoding HD-ZIP IV family transcription factors in rice, ROC1 exhibits the highest expression in the leaves. Overexpression of ROC1 decreased the size of bulliform cells, and thus resulted in adaxially rolled leaves. To the contrary, knockout of ROC1 (ROC1KO) through Crispr-cas9 system enlarged bulliform cells, and thus led to abaxially rolled leaves. Moreover, ROC1KO plants were sensitive to drought. ROC1 could form homodimers on its own, and heterodimers with ROC5 and ROC8 respectively. Compared to ROC1KO plants, leaves of the ROC1 and ROC8 double knocked out plants (ROC1/8DKO) were more severely rolled abaxially due to enlarged bulliform cells, and ROC1/8DKO plants were more drought sensitive. However, overexpression of ROC8 could not restore the abaxial leaf phenotype of ROC1KO plants. Therefore, we proved that ROC1, a member of the HD-ZIP IV family, regulated leaf rolling and drought stress response through tight association with ROC5 and ROC8.

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HD-ZIP IV 基因 ROC1 通过与 ROC5 和 ROC8 形成异源二聚体调控水稻的叶片卷曲和干旱响应

叶片形态是水稻的一个重要农艺特征，直接影响作物产量。水稻叶片卷曲的一个主要原因可归咎于牛皮状细胞的改变。目前已确定几个 HD-ZIP IV 基因具有流行特征，并在水稻卷叶中发挥作用。要全面了解 HD-ZIP IV 家族的整体功能，还需要对其他基因进行研究。在水稻中编码 HD-ZIP IV 家族转录因子的 9 个 ROC 基因中，ROC1 在叶片中的表达量最高。过量表达 ROC1 会减小牛皮状细胞的大小，从而导致叶片正面卷曲。相反，通过 Crispr-cas9 系统敲除 ROC1（ROC1KO）会增大鼓形细胞，从而导致叶片背面卷曲。此外，ROC1KO 植物对干旱很敏感。ROC1 可单独形成同源二聚体，也可分别与 ROC5 和 ROC8 形成异源二聚体。与 ROC1KO 植株相比，ROC1 和 ROC8 双基因敲除植株（ROC1/8DKO）的叶片由于牛皮状细胞增大而出现更严重的背面卷曲，并且 ROC1/8DKO 植株对干旱更敏感。然而，过表达 ROC8 并不能恢复 ROC1KO 植株的叶片背面表型。因此，我们证明了 HD-ZIP IV 家族成员 ROC1 通过与 ROC5 和 ROC8 的紧密联系调控叶片卷曲和干旱胁迫响应。

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来源期刊

Rice AGRONOMY-

CiteScore

10.10

自引率

3.60%

发文量

审稿时长

>12 weeks

期刊介绍： Rice aims to fill a glaring void in basic and applied plant science journal publishing. This journal is the world''s only high-quality serial publication for reporting current advances in rice genetics, structural and functional genomics, comparative genomics, molecular biology and physiology, molecular breeding and comparative biology. Rice welcomes review articles and original papers in all of the aforementioned areas and serves as the primary source of newly published information for researchers and students in rice and related research.