Site-specific mutagenesis of the nodule-infected cell expression (NICE) element and the AT-rich element ATRE-BS2* of the Sesbania rostrata leghemoglobin glb3 promoter.

Sesbania rostrata leghemoglobin glb3 (Srglb3) promoter sequences responsible for expression in infected cells of transgenic Lotus corniculatus nodules were delimited to a 78-bp Dral-Hinfl fragment. This region, which is located between coordinates -194 to -116 relative to the start codon of the Srglb3 gene, was named the nodule-infected cell expression (NICE) element. Insertion of the NICE element into the truncated nopaline synthase promoter was found to confer a nodule-specific expression pattern on this normally root-enhanced promoter. Within the NICE element, three distinct motifs ([A]AAAGAT, TTGTCTCTT, and CACCC[T]) were identified; they are highly conserved in the promoter regions of a variety of plant (leg)hemoglobin genes. The NICE element and the adjacent AT-rich element (ATRE-BS2*) were subjected to site-directed mutagenesis. The expression patterns of nine selected Srglb3 promoter fragments carrying mutations in ATRE-BS2* and 19 with mutations in the NICE element were examined. Mutations in ATRE-BS2* had varying effects on Srglb3 promoter activity, ranging from a two- to threefold reduction to a slight stimulation of activity. Mutations in the highly conserved (A)AAAGAT motif of the NICE element reduced Srglb3 promoter activity two- to fourfold, whereas mutations in the TCTT portion of the TTGTCTCTT motif virtually abolished promoter activity, demonstrating the essential nature of these motifs for Srglb3 gene expression. An A-to-T substitution in the CACCC(T) motif of the NICE element also abolished Srglb3 promoter activity, while a C-to-T mutation at position 4 resulted in a threefold reduction of promoter strength. The latter phenotypes resemble the effect of similar mutations in the conserved CACCC motif located in the promoter region of mammalian beta-globin genes. The possible analogies between these two systems will be discussed.     

Strong expression of the rice catalase gene CatB promoter in protoplasts and roots of both a monocot and dicots.

The rice (Oryza sativa L.) catalase (EC 1.11.1.6) gene CatB is expressed in roots and cultured cells. We examined the promoter activity of its 5'-flanking region in a monocot and in two dicots. Transient expression assays in rice Oc and tobacco BY-2 suspension cell protoplasts showed that CatB's 5'-flanking DNA fragments (nucleotides -1066 to +298) had about 20 and 3-4 times as much promoter activity, respectively, as the CaMV 35S promoter. Serial deletion analyses of the CatB promoter region revealed that the shortest fragment (-56 to +298) still had about 10 times as much promoter activity as the CaMV 35S promoter in rice protoplasts. In tobacco protoplasts, the activity of the fragment (-56 to +298) was about half of the CaMV 35S promoter. Transgenic rice and Arabidopsis plants carrying GUS genes driven by the 5'-truncated CatB promoters were generated and their GUS activity was examined. The region ranging from -329 to +298 showed preferential expression in the roots of rice and Arabidopsis, and in the shoot apical meristems of Arabidopsis. In situ hybridization revealed that CatB was highly expressed in branch root primordia and root apices of rice. Fusion of the GUS gene to the region (-329 to +298) conferred strong expression in these same areas, indicating that the presence of this region was sufficient to express CatB specifically in the roots. There may be new regulatory element(s) in this region, because it contained no previously known cis-regulatory elements specific for gene expression in roots.     

Promoter analysis of iron-deficiency-inducible barley IDS3 gene in Arabidopsis and tobacco plants.

Under conditions of iron deficiency, graminaceous plants induce the expression of genes involved in the biosynthesis of mugineic acid family phytosiderophores. We previously identified the novel cis-acting elements IDE1 and IDE2 (iron-deficiency-responsive element 1 and 2) through promoter analysis of the barley (Hordeum vulgare L.) iron-deficiency-inducible IDS2 gene in tobacco (Nicotiana tabacum L.). To gain further insight into plant gene regulation under iron deficiency, we analyzed the barley iron-deficiency-inducible IDS3 gene, which encodes mugineic acid synthase. IDS3 promoter fragments were fused to the beta-glucuronidase (GUS) gene, and this construct was introduced into Arabidopsis thaliana L. and tobacco plants. In both Arabidopsis and tobacco, GUS activity driven by the IDS3 promoter showed strongly iron-deficiency-inducible and root-specific expression. Expression occurred mainly in the epidermis of Arabidopsis roots, whereas expression was dominant in the pericycle, endodermis, and cortex of tobacco roots, resembling the expression pattern conferred by IDE1 and IDE2. Deletion analysis revealed that a sequence within -305 nucleotides from the translation start site was sufficient for specific expression in both Arabidopsis and tobacco roots. Gain-of-function analysis revealed functional regions at -305/-169 and -168/-93, whose coexistence was required for the induction activity in Arabidopsis roots. Multiple IDE-like sequences were distributed in the IDS3 promoter and were especially abundant within the functional region at -305/-169. A sequence moderately homologous to that of IDE1 was also present within the -168/-93 region. These IDE-like sequences would be the first candidates for the functional iron-deficiency-responsive elements in the IDS3 promoter.     

Nonlegume hemoglobin genes retain organ-specific expression in heterologous transgenic plants.

Hemoglobin genes from the nitrogen-fixing nonlegume Parasponia andersonii and the related non-nitrogen-fixing nonlegume Trema tomentosa have been isolated [Landsmann et al. (1986). Nature 324, 166-168; Bogusz et al. (1988). Nature 331, 178-180]. The promoters of these genes have been linked to a beta-glucuronidase reporter gene and introduced into both the nonlegume Nicotiana tabacum and the legume Lotus corniculatus. Both promoters directed root-specific expression in transgenic tobacco. When transgenic Lotus plants were nodulated by Rhizobium loti, both promoter constructs showed a high level of nodule-specific expression confined to the central bacteroid-containing portion of the nodule corresponding to the expression seen for the endogenous Lotus leghemoglobin gene. The T. tomentosa promoter was also expressed at a low level in the vascular tissue of the Lotus roots. The hemoglobin promoters from both nonlegumes, including the non-nodulating species, must contain conserved cis-acting DNA signals that are responsible for nodule-specific expression in legumes. We have identified sequence motifs postulated previously as the nodule-specific regulatory elements of the soybean leghemoglobin genes [Stougaard et al. (1987). EMBO J. 6, 3565-3569].     

Expression patterns of two genes for the delta-subunit of mitochondrial F1-ATP synthase from sweet potato in transgenic tobacco plants and cells.

Two nuclear genes, F1 delta-1 and F1 delta-2, coding for the delta-subunit of mitochondrial F1-ATP synthase, which corresponds to oligomycin-sensitivity conferring protein in animal and yeast mitochondria, were isolated from sweet potato. The gene for the delta-subunit was composed of 6 exons and these two genes shared high sequence similarities to each other not only in exons but also in introns and in the 5'-upstream regions. However, the 5'-upstream regions of F1 delta-1 and F1 delta-2 were distinguishable by the presence of novel sequences, designated Ins-1 and Ins-2, respectively. Ins-1 and Ins-2 contained a terminal direct repeat of 10 bp and 12 bp, respectively, and various forms of repeat sequences. The promoter fusion of both F1 delta-1 and F1 delta-2 with the GUS coding sequence gave expression of GUS activity in transformed tobacco BY-2 cells, although the levels of GUS activity and the patterns of expression during the growth of cells were different between the two. In transgenic tobacco plants, the two fusion genes showed similar levels of expression in leaves and stems, while F1 delta-2:GUS gave significantly higher levels of expression in roots than F1 delta-1:GUS. Deletion of Ins-1 from the 5'-upstream region of F1 delta-1:GUS did not affect the expression of the fusion gene in various organs of transgenic plants. However, it caused significant enhancement of expression in transformed tobacco BY-2 cells.     

Rice ubiquitin promoters: deletion analysis and potential usefulness in plant transformation systems

Strong constitutive promoters form a cornerstone for basic and applied research using transgenic plants. GUS (beta-glucuronidase) expression levels from constructs containing RUBQ1 or RUB2 rice ubiquitin promoters were 8- to 35-fold higher in transgenic rice [Oryza sativa (L.)] plants, respectively, when compared to the 35S promoter. Deletion analysis of the 5'-upstream region of RUBQ2 revealed a putative enhancer region that produced a 2.4-fold increase in transient GUS expression. Southern blot analysis showed that three to seven copies of the GUS gene were stably inserted into R0 and R1 plants and inherited in a monogenic fashion.     

番茄rbcS3A启动子控制的GUS融合基因在转基因水稻中的表达

为研究不同启动子用于转基因水稻,克隆了番茄Rubisco小亚基rbcS3A基因的5′上游调控区,构建了由rbcS3A启动子引导的GUS嵌合基因,并经农杆菌介导导入到水稻中。对转基因水稻植株中GUS活性的定性与定量测定结果表明,rbcS3A启动子可驱动GUS报告基因在转基因水稻植株茎和叶组织中高效表达,而在根和种子等器官中不表达或表达活性极弱,表现出一定的组织特异性。在转基因水稻中,番茄rbcS3A启动子驱动外源基因的表达不受光诱导。     

水稻OsGSTL1启动子的分离和表达分析

从水稻基因组文库中筛选得到一个水稻GST基因,命名为OsGSTL1.半定量RT-PCR分析表明OsGSTL1基因的表达不受绿磺隆、乙烯利、脱落酸、水杨酸和茉莉酸甲酯的诱导,因此该基因可能与植物抗逆性无关.为了研究OsGSTL1启动子在植物体内的表达特性,将OsGSTL1起始位点5＇端上游不同长度的调控序列与报告基因GUS融合,并在洋葱表皮瞬间表达和拟南芥中稳定表达.研究表明：在洋葱表皮细胞中,160bp及更长的上游调控序列均能启动GUS基因的表达;而在转基因拟南芥中,含有2155 bp的上游序列的PGZ2.1：：GUS具有时空表达的特性,在转基因的早期幼苗中GUS基因在子叶中特异性表达,但在根中没有表达;而在幼苗生长的后期,根、茎、叶中都有少量的表达.但包含1 224 bp的上游序列的PGZ1.2：：GUS却表现为组成型表达的特性.由此推测,OsGSTL1启动子启动的基因表达可能与幼苗的营养代谢相关;而OsGSTL1启动子的时空表达相关元件可能位于OsGSTL1翻译起始位点5＇端上游-2155 bp至-1224 bp范围内.     

Abscisic acid-responsive sequences from the em gene of wheat.

We demonstrate that a chimeric gene containing the beta-glucuronidase (GUS) reporter gene linked to a 646-base pair 5' fragment (-554 to +92) from the abscisic acid (ABA)-regulated Em gene from wheat is correctly expressed in transgenic tobacco. We observe high activity only in embryos of mature seeds, and immature seeds cultured on ABA show enhanced expression. Using a rice transient assay, we identify a 260-base pair fragment (-168 to +92) that accounts for the ABA-specific 15-fold to 20-fold increase in GUS expression. A 50-base pair sequence (-152 to -103) fused 5' in either orientation to a truncated cauliflower mosaic virus promoter (35S) increases GUS activity threefold in the presence of ABA. Insertion of the Em 5'-untranslated region (+6 to +86) between the 35S promoter and the ATG of GUS results in a 10-fold increase in GUS activity in the absence of ABA. These results suggest the following two functional fragments of the Em 5' region: an ABA response element from -152 to -103 and an element between +6 and +86 that quantitatively increases the ABA response.     

水稻OsWTF1基因启动子的克隆与表达分析

目的：分析水稻OsWTF1基因启动子的功能及核心序列。方法：利用PCR技术从水稻日本晴基因组中克隆了转录因子WTF1编码区5上游大小为2049bp的调控区域,命名为OsWTF1,将它和长度为1631、608、474、415bp的5端缺失体分别与GUS基因融合构建表达载体,并用农杆菌介导法转化水稻。结果：GUS组织化学分析表明,OsWTF1、Os1631能够驱动GUS基因在根、茎、叶、叶鞘、花药、颖壳上的表达,Os608,Os474,Os415能驱动GUS在根、茎、花药、颖壳中表达,在叶鞘中未表达,而且在叶中的表达也很微弱。结论：OsWTF1启动子核心序列可能位于-1bp--415bp之间,在-608bp--1631bp之间可能存在与基因叶肉特异表达相关的重要元件。