豌豆复叶结构受基因单叶、卷叶、无叶和无卷须之间相互作用的调控。
Pea compound leaf architecture is regulated by interactions among the genes UNIFOLIATA, cochleata, afila, and tendril-lessn.
作者信息
Gourlay C W, Hofer J M, Ellis T H
机构信息
Department of Applied Genetics, John Innes Centre, Colney Lane, Norwich NR4 7UH, United Kingdom.
出版信息
Plant Cell. 2000 Aug;12(8):1279-94. doi: 10.1105/tpc.12.8.1279.
Abstract
The compound leaf primordium of pea represents a marginal blastozone that initiates organ primordia, in an acropetal manner, from its growing distal region. The UNIFOLIATA (UNI) gene is important in marginal blastozone maintenance because loss or reduction of its function results in uni mutant leaves of reduced complexity. In this study, we show that UNI is expressed in the leaf blastozone over the period in which organ primordia are initiated and is downregulated at the time of leaf primordium determination. Prolonged UNI expression was associated with increased blastozone activity in the complex leaves of afila (af), cochleata (coch), and afila tendril-less (af tl) mutant plants. Our analysis suggests that UNI expression is negatively regulated by COCH in stipule primordia, by AF in proximal leaflet primordia, and by AF and TL in distal and terminal tendril primordia. We propose that the control of UNI expression by AF, TL, and COCH is important in the regulation of blastozone activity and pattern formation in the compound leaf primordium of the pea.
摘要
豌豆的复叶原基代表一个边缘胚区,该区域从其生长的远端区域以向顶的方式起始器官原基。单叶(UNI)基因在边缘胚区维持中很重要,因为其功能丧失或减弱会导致单叶突变体叶片的复杂性降低。在本研究中,我们表明UNI在器官原基起始期间在叶胚区表达,并在叶原基确定时下调。在丝状叶(af)、卷须叶(coch)和无卷须丝状叶(af tl)突变体植株的复叶中,UNI的持续表达与胚区活性增加相关。我们的分析表明,在托叶原基中,UNI的表达受COCH负调控;在近端小叶原基中,受AF负调控;在远端和末端卷须原基中,受AF和TL负调控。我们提出,AF、TL和COCH对UNI表达的控制在豌豆复叶原基中胚区活性和模式形成的调控中很重要。
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