拟南芥单体g蛋白,细胞分化早期和晚期事件的标记。

Mariette Bedhomme, C. Mathieu, A. Pulido, Y. Henry, C. Bergounioux
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引用次数: 10

摘要

在裂糖酵母pombe中,隔膜形成是由构成SIN(隔膜起始网络)信号级联的蛋白质复杂地控制的。SIN确保有丝分裂退出和细胞分裂之间的协调。酵母spg1p是SIN通路的核心组成部分,我们之前已经在拟南芥中鉴定了该g蛋白的两个同源物(命名为AtSGP1和2)。在这项工作中,利用稳定转化的拟南芥系中AtSGP启动子::GUS融合分析了植物发育过程中AtSGP基因的细胞和组织表达。AtSGP1启动子活性仅限于静止中心、柱状细胞、气孔保护细胞和柱状细胞,而AtSGP2启动子活性在成纤维细胞、毛状体和花粉中检测到。所观察到的启动子活性与公开的花粉、气孔保护细胞和根转录组数据一致。先前的双杂交实验证明了AtMAP3Kepsilon1和AtSGP1之间的相互作用。在根尖、毛状体和胚珠被毛中检测到AtMAP3Kepsilon1启动子活性。一种涉及这些特化细胞和突变背景的标记的遗传方法被用来加强我们的假设。尽管spg1p g蛋白在植物和真菌之间高度保守,但它似乎已经在植物中进化到执行与SIN途径不同的功能。有趣的是,细胞表达AtSGPs拥有有限的或空有丝分裂活动。我们的数据表明,AtSGP是参与早期细胞命运规范或细胞分化最后步骤的关键信号成分。这是一个有趣的起点,一个更广泛的研究致力于功能实验,旨在测试这些假设。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Arabidopsis monomeric G-proteins, markers of early and late events in cell differentiation.
In Schizosaccharomyces pombe, septum formation is intricately controlled by proteins which constitute the SIN (Septum Initiation Network) signalling cascade. The SIN ensures the coordination between mitotic exit and cytokinesis. Yeast spg1p is a core component of the SIN pathway and we have previously characterized the two orthologs of this G-protein in Arabidopsis thaliana (named AtSGP1 and 2). In this work, the cell and tissue expression of AtSGP genes during plant development has been analysed using AtSGP promoter::GUS fusions in stably transformed A. thaliana lines. AtSGP1 promoter activity was restricted to the quiescent centre, collumella cells, stomata guard cells and the stele while AtSGP2 promoter activity was detected in atrichoblasts, trichomes and pollen. The observed promoter activities are in accordance with publicly available pollen, stomata guard cell and root transcriptome data. Two-hybrid experiments previously evidenced an interaction between AtMAP3Kepsilon1 and AtSGP1. The AtMAP3Kepsilon1 promoter activity was detected in root apices, trichomes and ovule integuments. A genetic approach involving both markers of these specialized cells and mutant backgrounds was used to reinforce our hypothesis. It appears that, although highly conserved between plants and fungi, the spg1p G-protein has evolved in plants to perform a function different from the SIN pathway. Interestingly, cells expressing AtSGPs possessed limited or null mitotic activity. Our data suggests that AtSGP are crucial signalling components involved either in early cell fate specification, or in the final steps of cell differentiation. This is an interesting starting point for a wider study devoted to functional experiments designed to test these hypotheses.
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