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水稻腋芽分生组织形成过程中LAX PANICLE1蛋白积累的两步调控

Two-Step Regulation of LAX PANICLE1 Protein Accumulation in Axillary Meristem Formation in Rice.

作者信息

Oikawa Tetsuo, Kyozuka Junko

机构信息

Graduate School of Agriculture and Life Sciences, University of Tokyo, Yayoi, Bunkyo, Tokyo 113-8657, Japan.

出版信息

Plant Cell. 2009 Apr;21(4):1095-108. doi: 10.1105/tpc.108.065425. Epub 2009 Apr 3.

DOI:10.1105/tpc.108.065425
PMID:19346465
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2685638/
Abstract

Axillary meristem (AM) formation is an important determinant of plant architecture. In rice (Oryza sativa), LAX PANICLE1 (LAX1) function is required for the generation of AM throughout the plant's lifespan. Here, we show a close relationship between AM initiation and leaf development; specifically, the plastochron 4 (P4) stage of leaf development is crucial for the proliferation of meristematic cells. Coincident with this, LAX1 expression starts in the axils of leaves at P4 stage. LAX1 mRNA accumulates in two to three layers of cells in the boundary region between the initiating AM and the shoot apical meristem. In lax1 mutants, the proliferation of meristematic cells is initiated but fails to progress into the formation of AM. The difference in sites of LAX1 mRNA expression and its action suggests non-cell-autonomous characteristics of LAX1 function. We found that LAX1 protein is trafficked to AM in a stage- and direction-specific manner. Furthermore, we present evidence that LAX1 protein movement is required for the full function of LAX1. Thus, we propose that LAX1 protein accumulates transiently in the initiating AM at P4 stage by a strict regulation of mRNA expression and a subsequent control of protein trafficking. This two-step regulation is crucial to the establishment of the new AM.

摘要

腋生分生组织(AM)的形成是植物株型的一个重要决定因素。在水稻(Oryza sativa)中,整个植株生命周期中AM的产生都需要LAX PANICLE1(LAX1)发挥功能。在此,我们展示了AM起始与叶片发育之间的密切关系;具体而言,叶片发育的第4个叶龄期(P4)对于分生细胞的增殖至关重要。与此一致的是,LAX1在P4阶段开始在叶腋处表达。LAX1 mRNA在起始的AM与茎尖分生组织之间的边界区域的两到三层细胞中积累。在lax1突变体中,分生细胞的增殖开始启动,但未能发展为AM的形成。LAX1 mRNA表达位点与其作用的差异表明LAX1功能具有非细胞自主性特征。我们发现LAX1蛋白以阶段和方向特异性的方式运输到AM。此外,我们提供证据表明LAX1蛋白的移动对于LAX1的完整功能是必需的。因此,我们提出LAX1蛋白通过严格调控mRNA表达以及随后控制蛋白运输,在P4阶段在起始的AM中短暂积累。这两步调控对于新AM的建立至关重要。

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