一个冗余bHLH蛋白网络在拟南芥所有依赖TTG1的途径中发挥作用。

A network of redundant bHLH proteins functions in all TTG1-dependent pathways of Arabidopsis.

作者信息

Zhang Fan, Gonzalez Antonio, Zhao Mingzhe, Payne C Thomas, Lloyd Alan

机构信息

Molecular Cell and Developmental Biology, and The Institute for Cellular and Molecular Biology, The University of Texas at Austin, Austin, TX 78712, USA.

出版信息

Development. 2003 Oct;130(20):4859-69. doi: 10.1242/dev.00681. Epub 2003 Aug 13.

DOI:10.1242/dev.00681

PMID:12917293

Abstract

GLABRA3 (GL3) encodes a bHLH protein that interacts with the WD repeat protein, TTG1. GL3 overexpression suppresses the trichome defect of the pleiotropic ttg1 mutations. However, single gl3 mutations only affect the trichome pathway with a modest trichome number reduction. A novel unlinked bHLH-encoding locus is described here, ENHANCER OF GLABRA3 (EGL3). When mutated, egl3 gives totally glabrous plants only in the gl3 mutant background. The double bHLH mutant, gl3 egl3, has a pleiotropic phenotype like ttg1 having defective anthocyanin production, seed coat mucilage production, and position-dependent root hair spacing. Furthermore, the triple bHLH mutant, gl3 egl3 tt8, phenocopies the ttg1 mutation. Yeast two-hybrid and plant overexpression studies show that EGL3, like GL3, interacts with TTG1, the myb proteins GL1, PAP1 and 2, CPC and TRY, and it will form heterodimers with GL3. These results suggest a combinatorial model for TTG1-dependent pathway regulation by this trio of partially functionally redundant bHLH proteins.

摘要

GLABRA3（GL3）编码一种与WD重复蛋白TTG1相互作用的bHLH蛋白。GL3的过表达抑制了多效性ttg1突变体的毛状体缺陷。然而，单个gl3突变仅影响毛状体途径，导致毛状体数量适度减少。本文描述了一个新的不连锁的bHLH编码基因座，即GLABRA3增强子（EGL3）。当发生突变时，egl3仅在gl3突变体背景下产生完全无毛的植株。双bHLH突变体gl3 egl3具有多效性表型，类似于ttg1，存在花青素生成缺陷、种皮黏液生成缺陷以及位置依赖性根毛间距缺陷。此外，三bHLH突变体gl3 egl3 tt8表现出与ttg1突变相似的表型。酵母双杂交和植物过表达研究表明，EGL3与GL3一样，与TTG1、myb蛋白GL1、PAP1和2、CPC以及TRY相互作用，并将与GL3形成异源二聚体。这些结果表明，这三种部分功能冗余的bHLH蛋白对TTG1依赖性途径调控存在一种组合模型。

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一个冗余bHLH蛋白网络在拟南芥所有依赖TTG1的途径中发挥作用。

A network of redundant bHLH proteins functions in all TTG1-dependent pathways of Arabidopsis.

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