Gómez-Mena C, Piñeiro M, Franco-Zorrilla J M, Salinas J, Coupland G, Martínez-Zapater J M
Departamento de Mejora Genética y Biotecnología, Subdirección General de Investigación y Tecnología, Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria, Carretera de la Coruña Kilómetro 7, 28040 Madrid, Spain.
Plant Cell. 2001 May;13(5):1011-24.
The time of flowering in Arabidopsis is controlled by multiple endogenous and environmental signals. Some of these signals promote the onset of flowering, whereas others repress it. We describe here the isolation and characterization of two allelic mutations that cause early flowering and define a new locus, EARLY BOLTING IN SHORT DAYS (EBS). Acceleration of flowering time in the ebs mutants is especially conspicuous under short-day photoperiods and results from a reduction of the adult vegetative phase of the plants. In addition to the early flowering phenotype, ebs mutants show a reduction in seed dormancy, plant size, and fertility. Double mutant analysis with gibberellin-deficient mutants indicates that both the early-flowering and the precocious-germination phenotypes require gibberellin biosynthesis. Analysis of the genetic interactions among ebs and several mutations causing late flowering shows that the ft mutant phenotype is epistatic over the early flowering of ebs mutants, suggesting that the precocious flowering of ebs requires the FT gene product. Finally, the ebs mutation causes an increase in the level of expression of the floral homeotic genes APETALA3 (AP3), PISTILLATA (PI), and AGAMOUS (AG) and partially rescues the mutant floral phenotype of leafy-6 (lfy-6) mutants. These results suggest that EBS participates as a negative regulator in developmental processes such as germination, flowering induction, and flower organ specification.
拟南芥的开花时间受多种内源性和环境信号控制。其中一些信号促进开花的起始,而其他信号则抑制开花。我们在此描述了两个导致早花的等位基因突变的分离和特征,并定义了一个新位点,即短日照下早抽薹(EBS)。在短日照光周期下,ebs突变体开花时间的加速尤为明显,这是由于植物成年营养期缩短所致。除了早花表型外,ebs突变体的种子休眠、植株大小和育性也有所降低。与赤霉素缺陷型突变体的双突变分析表明,早花和早熟萌发表型都需要赤霉素生物合成。对ebs与几个导致晚花的突变之间的遗传相互作用分析表明,ft突变体表型在ebs突变体的早花之上呈上位性,这表明ebs的早熟开花需要FT基因产物。最后,ebs突变导致花同源异型基因APETALA3(AP3)、PISTILLATA(PI)和AGAMOUS(AG)的表达水平增加,并部分挽救了叶状-6(lfy-6)突变体的突变花表型。这些结果表明,EBS作为负调控因子参与了萌发、开花诱导和花器官特化等发育过程。