开花在时间和空间上的控制。

The control of flowering in time and space.

作者信息

Jaeger Katja E, Graf Alexander, Wigge Philip A

机构信息

Department of Cell and Developmental Biology, John Innes Centre, Colney Lane, Norwich NR4 7UH, UK.

出版信息

J Exp Bot. 2006;57(13):3415-8. doi: 10.1093/jxb/erl159. Epub 2006 Sep 27.

DOI:10.1093/jxb/erl159

PMID:17005922

Abstract

The transition to flowering is one of the most important developmental decisions made by plants. Classical studies have highlighted the importance of photoperiod in controlling flowering time. More recently, the identification of mutants specifically affected in the photoperiod pathway in the model system Arabidopsis thaliana has enabled the flowering time pathways to be placed in a molecular context. This review highlights recent advances in understanding how photoperiod signals (perceived in the leaves) act at the apex of the plant where the floral stimulus is perceived. The photoperiod pathway acts predominantly through the gene CONSTANS to activate the small signalling molecule FT. While FT transcription is induced in the leaves, it is essential that FT protein is present at the apex of the plant. FT at the apex interacts with the transcription factor FD to induce flowering.

摘要

向开花的转变是植物做出的最重要的发育决定之一。经典研究强调了光周期在控制开花时间方面的重要性。最近，在模式植物拟南芥中对光周期途径中受到特异性影响的突变体的鉴定，使得开花时间途径能够置于分子背景下进行研究。本综述着重介绍了在理解光周期信号（在叶片中被感知）如何在植物顶端（此处感知到成花刺激）发挥作用方面的最新进展。光周期途径主要通过CONSTANS基因来激活小信号分子FT。虽然FT转录在叶片中被诱导，但FT蛋白必须存在于植物顶端才至关重要。顶端的FT与转录因子FD相互作用以诱导开花。

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开花在时间和空间上的控制。

The control of flowering in time and space.

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