拟南芥AGL8 MADS盒基因在花序分生组织中表达,并受APETALA1负调控。
The Arabidopsis AGL8 MADS box gene is expressed in inflorescence meristems and is negatively regulated by APETALA1.
作者信息
Mandel M A, Yanofsky M F
机构信息
Department of Biology, University of California at San Diego, La Jolla 92093-0116, USA.
出版信息
Plant Cell. 1995 Nov;7(11):1763-71. doi: 10.1105/tpc.7.11.1763.
Abstract
MADS box genes encode putative transcription factors that play important roles in plant and animal development. In plants, MADS box genes are involved in the early step of specifying floral meristem identity as well as the later step of determining the fate of floral organ primordia. Here, we describe the isolation and characterization of a new MADS box gene from Arabidopsis, designated AGL8. Although AGL8 RNA does not accumulate during vegetative growth, it accumulates to high levels in the inflorescence apical meristem as well as in the inflorescence stem and cauline leaves. AGL8 RNA is excluded from the young flower primordia that arise on the flanks of the inflorescence meristem but later accumulates in the walls of the developing carpels. The lack of AGL8 RNA in floral meristems is due in part to the action of another MADS box gene, APETALA1, because AGL8 RNA does accumulate in apetala1 mutant flower primordia.
摘要
MADS盒基因编码假定的转录因子,这些转录因子在植物和动物发育中发挥重要作用。在植物中,MADS盒基因参与确定花分生组织特性的早期步骤以及决定花器官原基命运的后期步骤。在此,我们描述了从拟南芥中分离和鉴定一个新的MADS盒基因,命名为AGL8。虽然AGL8 RNA在营养生长期间不积累,但它在花序顶端分生组织以及花序茎和茎生叶中积累到高水平。AGL8 RNA被排除在花序分生组织侧面产生的幼小花原基之外,但后来在发育中的心皮壁中积累。花分生组织中缺乏AGL8 RNA部分归因于另一个MADS盒基因APETALA1的作用,因为AGL8 RNA确实在apetala1突变体花原基中积累。
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