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Dof 转录因子 SCAP1 对于拟南芥功能性气孔的发育至关重要。

A Dof transcription factor, SCAP1, is essential for the development of functional stomata in Arabidopsis.

机构信息

Department of Biology, Faculty of Sciences, Kyushu University, Fukuoka 812-8581, Japan.

出版信息

Curr Biol. 2013 Mar 18;23(6):479-84. doi: 10.1016/j.cub.2013.02.001. Epub 2013 Feb 28.

DOI:10.1016/j.cub.2013.02.001
PMID:23453954
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4039172/
Abstract

Stomata are highly specialized organs that consist of pairs of guard cells and regulate gas and water vapor exchange in plants [1-3]. Although early stages of guard cell differentiation have been described [4-10] and were interpreted in analogy to processes of cell type differentiation in animals [11], the downstream development of functional stomatal guard cells remains poorly understood. We have isolated an Arabidopsis mutant, stomatal carpenter 1 (scap1), that develops irregularly shaped guard cells and lacks the ability to control stomatal aperture, including CO2-induced stomatal closing and light-induced stomatal opening. SCAP1 was identified as a plant-specific Dof-type transcription factor expressed in maturing guard cells, but not in guard mother cells. SCAP1 regulates the expression of genes encoding key elements of stomatal functioning and morphogenesis, such as K(+) channel protein, MYB60 transcription factor, and pectin methylesterase. Consequently, ion homeostasis was disturbed in scap1 guard cells, and esterification of extracellular pectins was impaired so that the cell walls lining the pores did not mature normally. We conclude that SCAP1 regulates essential processes of stomatal guard cell maturation and functions as a key transcription factor regulating the final stages of guard cell differentiation.

摘要

气孔是高度特化的器官,由一对保卫细胞组成,调节植物的气体和水蒸气交换[1-3]。尽管已经描述了保卫细胞分化的早期阶段[4-10],并且这些阶段被解释为类似于动物细胞类型分化的过程[11],但功能型气孔保卫细胞的下游发育仍知之甚少。我们分离到一个拟南芥突变体,气孔木匠 1(scap1),其保卫细胞形状不规则,并且丧失控制气孔开度的能力,包括 CO2 诱导的气孔关闭和光诱导的气孔开放。SCAP1 被鉴定为一种植物特异性的 Dof 型转录因子,在成熟的保卫细胞中表达,但不在保卫母细胞中表达。SCAP1 调节编码气孔功能和形态发生关键元件的基因的表达,如 K+通道蛋白、MYB60 转录因子和果胶甲酯酶。因此,scap1 保卫细胞中的离子稳态受到干扰,细胞外果胶的酯化受到损害,因此排列在孔周围的细胞壁不能正常成熟。我们得出结论,SCAP1 调节气孔保卫细胞成熟的基本过程,并作为调节保卫细胞分化最后阶段的关键转录因子发挥作用。

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