Baerson S R, Vander Heiden M G, Lamppa G K
Department of Molecular Genetics and Cell Biology, University of Chicago, IL 60637.
Plant Mol Biol. 1994 Dec;26(6):1947-59. doi: 10.1007/BF00019505.
Deletions were made in the promoter of the acyl carrier protein (ACP) Acll.2 gene from Arabidopsis to investigate the nature of the cis-acting elements that direct its expression. These constructs, which included the untranslated leader region, were fused to a reporter gene coding for beta-glucuronidase (GUS) and transformed into tobacco. Quantitative fluorometric analysis of GUS activity in transgenic plants showed that expression in young leaves drops to a basal level when a 85 bp domain, from -320 to -236 relative to transcription initiation, is deleted. Maximum promoter activity in roots also depends on this domain, but two other regions are also important. In total, deletion of the sequences from -466 to -55 caused an ca. 80-fold reduction in Acl1.2 promoter activity in roots. The -320 to -236 domain forms a complex with a protein factor found in leaves and roots, which was not detectable in seeds. The formation of this protein-DNA complex was abolished by mutation of a bZIP core motif, ACGT, found within the context AAGACGTAG, which is dissimilar to the other bZIP-binding sites thus far characterized in plants. Previously we showed that Acl1.2 promoter activity is highest in seeds [2]. Here we find, in contrast to leaves and roots, that deletion to position -236 has no effect on GUS levels in seeds. However, nearly a 100-fold drop was observed when the -235 to -55 region was removed. Hence, this 180 bp domain contains all the cis-acting information necessary for Acl1.2 promoter activity in seeds. The same region is necessary for Acl1.2 activity in the receptacle, stigma, tapetum and pollen of the flower, as demonstrated by histochemical staining.
对拟南芥酰基载体蛋白(ACP)Acl1.2基因的启动子进行缺失操作,以研究指导其表达的顺式作用元件的性质。这些构建体包括非翻译前导区,与编码β-葡萄糖醛酸酶(GUS)的报告基因融合,并转化到烟草中。对转基因植物中GUS活性的定量荧光分析表明,当相对于转录起始点从-320至-236的85 bp结构域被缺失时,幼叶中的表达降至基础水平。根中的最大启动子活性也取决于该结构域,但另外两个区域也很重要。总体而言,从-466至-55的序列缺失导致根中Acl1.2启动子活性降低约80倍。-320至-236结构域与在叶和根中发现的一种蛋白质因子形成复合物,在种子中未检测到该复合物。AAGACGTAG背景下发现的bZIP核心基序ACGT发生突变后,这种蛋白质-DNA复合物的形成被消除,该基序与迄今为止在植物中鉴定的其他bZIP结合位点不同。此前我们表明Acl1.2启动子活性在种子中最高[2]。在这里我们发现,与叶和根不同,缺失至-236位置对种子中的GUS水平没有影响。然而,当去除-235至-55区域时,观察到近100倍的下降。因此,这个180 bp的结构域包含Acl1.2启动子在种子中活性所需的所有顺式作用信息。组织化学染色表明,同一区域对花的花托、柱头、绒毡层和花粉中的Acl1.2活性也是必需的。
