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拟南芥的芜菁突变体表明,LEAFY COTYLEDON1的表达介导了生长素和糖类对促进胚胎细胞特性的影响。

The turnip mutant of Arabidopsis reveals that LEAFY COTYLEDON1 expression mediates the effects of auxin and sugars to promote embryonic cell identity.

作者信息

Casson Stuart A, Lindsey Keith

机构信息

Integrative Cell Biology Laboratory, School of Biological and Biomedical Sciences, University of Durham, Durham DH1 3LE, UK.

出版信息

Plant Physiol. 2006 Oct;142(2):526-41. doi: 10.1104/pp.106.080895. Epub 2006 Aug 25.

DOI:10.1104/pp.106.080895
PMID:16935993
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1586040/
Abstract

The transition from embryonic to vegetative growth marks an important developmental stage in the plant life cycle. The turnip (tnp) mutant was identified in a screen for modifiers of POLARIS expression, a gene required for normal root growth. Mapping and molecular characterization of tnp shows that it represents a gain-of-function mutant of LEAFY COTYLEDON1 (LEC1), due to a promoter mutation. This results in the ectopic expression of LEC1, but not of other LEC genes, in vegetative tissues. The LEC class of genes are known regulators of embryogenesis, involved in the control of embryonic cell identity by currently unknown mechanisms. Activation of the LEC-dependent pathway in tnp leads to the loss of hypocotyl epidermal cell marker expression and loss of SCARECROW expression in the endodermis, the ectopic accumulation of starch and lipids, and the up-regulation of early and late embryonic genes. tnp also shows partial deetiolation during dark growth. Penetrance of the mutant phenotype is strongly enhanced in the presence of exogenous auxin and sugars, but not by gibberellin or abscisic acid, and is antagonized by cytokinin. We propose that the role of LEC1 in embryonic cell fate control requires auxin and sucrose to promote cell division and embryonic differentiation.

摘要

从胚胎生长向营养生长的转变标志着植物生命周期中一个重要的发育阶段。芜菁(tnp)突变体是在筛选北极星(POLARIS)表达的修饰因子时鉴定出来的,北极星是正常根生长所需的一个基因。tnp的定位和分子特征表明,由于启动子突变,它代表了叶状子叶1(LEC1)的功能获得型突变体。这导致LEC1在营养组织中异位表达,但其他LEC基因没有。LEC类基因是已知的胚胎发生调节因子,通过目前未知的机制参与胚胎细胞身份的控制。tnp中LEC依赖性途径的激活导致下胚轴表皮细胞标记物表达丧失和内皮层中稻草人(SCARECROW)表达丧失,淀粉和脂质异位积累,以及早期和晚期胚胎基因上调。tnp在黑暗生长期间也表现出部分脱黄化现象。在外源生长素和糖存在的情况下,突变体表型的外显率显著增强,但赤霉素或脱落酸不会,细胞分裂素则会拮抗这种增强作用。我们提出,LEC1在胚胎细胞命运控制中的作用需要生长素和蔗糖来促进细胞分裂和胚胎分化。

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