可点击的守卫细胞,第二版:守卫细胞信号传导机制和途径的互动模型。

The arabidopsis book Pub Date : 2008-01-01 Epub Date: 2008-11-26 DOI:10.1199/tab.0114
June M Kwak, Pascal Mäser, Julian I Schroeder
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引用次数: 0

摘要

保卫细胞位于叶片表皮,成对的保卫细胞环绕并形成气孔,可调节大气中的 CO(2) 流入叶片进行光合碳固定。气孔保卫细胞还能调节植物通过蒸腾作用向大气失水。保卫细胞的信号转导机制整合了多种不同的刺激来调节气孔孔径。气孔在光照下打开。气孔关闭是对干旱胁迫、高浓度 CO(2)、臭氧和低湿度的反应。为了应对干旱,植物会合成脱落酸(ABA)激素,引发气孔关闭。护卫细胞已成为一个高度发达的模型系统,用于剖析植物的信号转导机制,以及阐明单个信号机制如何在单个细胞的网络中相互作用。在过去几年中,人们已经有了许多新的发现。本章是对上一版《拟南芥全书》(Mäser 等人,2003 年)中电子互动章节的更新。在此,我们将重点介绍已确定基因和突变特征的机制,包括已有大量信号、生化和遗传证据的信号元件。离子通道已被证明是早期信号转导机制的目标,并提供了功能信号和定量分析点,以确定突变在何处以及如何影响保卫细胞信号网络中的分支。尽管近年来已经发现了大量在保卫细胞信号传导中起作用的基因和蛋白质,但还有更多的基因和蛋白质有待发现,而这一网络中蛋白质与蛋白质之间的相互作用将是未来研究的重要课题。本出版物的完全交互式可点击电子版可在以下网站访问:http://www-biology.ucsd.edu/labs/schroeder/clickablegc2/。交互式可点击版本包括以下功能:图 1.离子通道在 ABA 信号传导中的作用模型。保卫细胞中的蓝光信号途径......图 3.图 1 与鼠标移过时出现的解释相关联。图 2 和图 3 可点击并链接到信息框,而信息框又链接到 TAIR、PubMed 中的相关摘要以及 Schroeder 等人(2001 年)的最新背景说明。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Clickable Guard Cell, Version II: Interactive Model of Guard Cell Signal Transduction Mechanisms and Pathways.

Guard cells are located in the leaf epidermis and pairs of guard cells surround and form stomatal pores, which regulate CO(2) influx from the atmosphere into leaves for photosynthetic carbon fixation. Stomatal guard cells also regulate water loss of plants via transpiration to the atmosphere. Signal transduction mechanisms in guard cells integrate a multitude of different stimuli to modulate stomatal apertures. Stomata open in response to light. Stomata close in response to drought stress, elevated CO(2), ozone and low humidity. In response to drought, plants synthesize the hormone abscisic acid (ABA) that triggers closing of stomatal pores. Guard cells have become a highly developed model system for dissecting signal transduction mechanisms in plants and for elucidating how individual signaling mechanisms can interact within a network in a single cell. Many new findings have been made in the last few years. This chapter is an update of an electronic interactive chapter in the previous edition of The Arabidopsis Book (Mäser et al. 2003). Here we focus on mechanisms for which genes and mutations have been characterized, including signaling components for which there is substantial signaling, biochemical and genetic evidence. Ion channels have been shown to represent targets of early signal transduction mechanisms and provide functional signaling and quantitative analysis points to determine where and how mutations affect branches within the guard cell signaling network. Although a substantial number of genes and proteins that function in guard cell signaling have been identified in recent years, there are many more left to be identified and the protein-protein interactions within this network will be an important subject of future research. A fully interactive clickable electronic version of this publication can be accessed at the following web site: http://www-biology.ucsd.edu/labs/schroeder/clickablegc2/. The interactive clickable version includes the following features: Figure 1. Model for the roles of ion channels in ABA signaling.Figure 2. Blue light signaling pathways in guard cells.Figure 3. ABA signaling pathways in guard cells.Figure 1 is linked to explanations that appear upon mouse-over. Figure 2 and Figure 3 are clickable and linked to info boxes, which in turn are linked to TAIR, to relevant abstracts in PubMed, and to updated background explanations from Schroeder et al (2001), used with permission of Annual Reviews of Plant Biology.

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