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det1、cop1和cop9突变导致多个基因集的异常表达。

det1, cop1, and cop9 mutations cause inappropriate expression of several gene sets.

作者信息

Mayer R, Raventos D, Chua N H

机构信息

Laboratory of Plant Molecular Biology, Rockefeller University, New York, New York 10021-6399, USA.

出版信息

Plant Cell. 1996 Nov;8(11):1951-9. doi: 10.1105/tpc.8.11.1951.

DOI:10.1105/tpc.8.11.1951
PMID:8953766
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC161326/
Abstract

Genetic studies using Arabidopsis offer a promising approach to investigate the mechanisms of light signal transduction during seedling development. Several mutants, called det/cop, have been isolated based on their deetiolated/constitutive photomorphogenic phenotypes in the dark. This study examines the specificity of the det/cop mutations with respect to their effects on genes regulated by other signal transduction pathways. Steady state mRNA levels of a number of differently regulated gene sets were compared between mutants and the wild type. We found that det2, cop2, cop3, and cop4 mutants displayed a gene expression pattern similar to that of the wild type. By contrast, det1, cop1, and cop9 mutations exhibited pleiotropic effects. In addition to light-responsive genes, genes normally inducible by plant pathogens, hypoxia, and developmental programs were inappropriately expressed in these mutants. Our data provide evidence that DET1, COP1, and COP9 most likely act as negative regulators of several sets of genes, not just those involved in light-regulated seedling development.

摘要

利用拟南芥进行的遗传学研究为探究幼苗发育过程中光信号转导机制提供了一种很有前景的方法。基于它们在黑暗中去黄化/组成型光形态建成的表型,已经分离出了几个名为det/cop的突变体。本研究考察了det/cop突变对受其他信号转导途径调控基因的影响的特异性。比较了突变体和野生型之间一些不同调控基因集的稳态mRNA水平。我们发现det2、cop2、cop3和cop4突变体表现出与野生型相似的基因表达模式。相比之下,det1、cop1和cop9突变表现出多效性。除了光响应基因外,通常由植物病原体、缺氧和发育程序诱导的基因在这些突变体中也异常表达。我们的数据提供了证据,表明DET1、COP1和COP9很可能作为几组基因的负调控因子,而不仅仅是那些参与光调控幼苗发育的基因。

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