Activity of the 5′ regulatory regions of the rice polyubiquitin <Emphasis Type="Italic">rubi3</Emphasis> gene in transgenic rice plants as analyzed by both <Emphasis Type="Italic">GUS</Emphasis> and <Emphasis Type="Italic">GFP</Emphasis> reporter genes

Ubiquitin is an abundant protein involved in protein degradation and cell cycle control in plants and rubi3 is a polyubiquitin gene isolated from rice (Oryza sativa L.). Using both GFP and GUS as reporter genes, we analyzed the expression pattern of the rubi3 promoter as well as the effects of the rubi3 5'-UTR (5' untranslated region) intron and the 5' terminal 27 bp of the rubi3 coding sequence on the activity of the promoter in transgenic rice plants. The rubi3 promoter with the 5'-UTR intron was active in all the tissue and cell types examined and supported more constitutive expression of reporter genes than the maize Ubi-1 promoter. The rubi3 5'-UTR intron mediated enhancement on the activity of its promoter in a tissue-specific manner but did not alter its overall expression pattern. The enhancement was particularly intense in roots, pollen grains, inner tissue of ovaries, and embryos and aleurone layers in maturing seeds. The translational fusion of the first 27 bp of the rubi3 coding sequence to GUS gene further enhanced GUS expression directed by the rubi3 promoter in all the tissues examined. The rubi3 promoter should be an important addition to the arsenal of strong and constitutive promoters for monocot transformation and biotechnology.     

The Expression of a Cytosolic Cyclophilin Promoter from Periwinkle in Transgenic Tobacco Plants

The cloning of a 465 bp fragment from the 5-flanking region of the gene encoding a cytosolic cyclophilin from periwinkle was achieved through inverse polymerase chain reaction. The DNA fragment was fused to a gusA-intron marker then introduced into tobacco by Agrobacterium tumefaciens-mediated transformation. Histochemical analysis of the transgenic shoot cultures demonstrated that the construct was able to drive GUS expression in stomata guard cells, but not in mesophyll cells when shoots were still attached to the callus from which they were initiated. In separated transgenic shoots and in seedlings, GUS was expressed in external and internal phloem and root hairs, respectively. GUS activity in transgenic tobacco seedlings was also investigated by fluorimetric assays. Treatments with NaCl or ABA decreased promoter activity whereas treatment with yeast extracts increased it.     

拟南芥AtNHX6基因启动子的克隆及表达分析

为了探明拟南芥内膜反向转运体AtNHX6基因的组织表达模式,从基因组中克隆了AtNHX6基因开放阅读框(ORF)上游侧翼调控区1 922bp序列,并成功构建AtNHX6基因启动子与GUS融合表达载体pCAM-BIA1381-proNHX6-GUS,通过农杆菌花序浸染法转化野生型拟南芥获得T3代纯合转基因拟南芥株系,经PCR检测扩增得到2 187bp目的条带。利用组织染色法鉴定转基因拟南芥的GUS表达模式发现,在子叶、下胚轴和花中GUS活性显著。在这些广泛表达的部位中,微管系统中的表达最为显著,真叶中只有局部检测到GUS表达;在根中GUS在根毛和侧根生长部位表达;在未成熟果荚中只有在果荚顶端和基部存在GUS活性,成熟果荚中只在果柄检测到GUS表达;在花中,雄蕊的花丝和花粉粒及雌蕊的柱头中检测到GUS表达。GUS染色分析结果表明,AtNHX6基因启动子与GUS的融合表达载体成功构建并正常启动GUS基因表达,且AtNHX6基因主要在拟南芥的子叶、下胚轴、根、花、果荚中的微管系统、根毛和侧根生长部位以及花丝、花粉、柱头中表达。     

Analysis of a maize α-tubulin gene promoter by transient expression and in transgenic tobacco plants

The pattern of expression directed by the promoter of the maize Tub α 1 gene was investigated by analysis of chloramphenicol acetyl transferase (CAT) and β-glucuronidase (GUS) activities in transient expression experiments of maize and tobacco protoplasts. The same promoter was also investigated by histochemical GUS analysis in transgenic tobacco plants containing promoter gene fusions. As determined by histochemical tests, the Tub α 1 promoter gene preferentially directs GUS expression in regenerating root tip meristems and pollen. This pattern corresponds to the distinctive features of natural expression of the gene in maize as determined by Northern analysis. However, no expression is observed in other meristematic tissues of the transgenic tobacco plants, as in shoot apex or in coleoptiles, which is weakly detected in maize. Analysis of the regulatory properties of 5' promoter deletions showed that the proximal region of the promoter, from positions −1410 or −449 to 15 bp upstream of the ATG, is sufficient to establish the qualitative pattern of expression in transgenic tobacco plants. Deletions to positions −352 or −117 abolished the expression in roots, but not in pollen, suggesting that upstream of these positions there are elements responsible for the pattern in root. Further deletions abolished all the promoter activity, suggesting that this promoter region contains the elements essential for expression in pollen. The different patterns and levels of transient and stable expression are discussed.     

Different promoter regions control level and tissue specificity of expression of Agrobacterium rhizogenes rolB gene in plants

Expression of the rolB gene of A. rhizogenes T-DNA triggers root differentiation in transformed plant cells. In order to study the regulation of this morphogenetic gene, the GUS reporter gene was placed under the control of several deleted fragments of the rolB 5 non-coding region: carrot disc transformations and the analysis of transgenic tobacco plants containing these constructions identified the presence of distinct regulatory domains in the rolB promoter. Two regions (located from positions –623 to –471 and from –471 to –341, from the translation start codon) control the level but not the tissue specificity of rolB expression: progressive deletions of the rolB promoter starting from position –1185 to –341, although at different levels, maintained the same pattern of GUS expression — maximal in root meristems and less pronounced in the vascular tissue of aerial organs. Further deletion of 35 bp, from –341 to –306, drastically affected tissue specificity: GUS activity was still clearly detectable in the vascular tissue of the aerial organs while expression in the root meristem was totally suppressed. Analysis of transgenic embryos and seedlings confirmed that distinct promoter domains are responsible for meristematic (root) and differentiated (vascular) expression of rolB. Finally, we present data concerning the effects of plant hormones on the expression of rolB-GUS constructions.     

Expression of three <Emphasis Type="Italic">Arabidopsis</Emphasis> cytokinin oxidase/dehydrogenase promoter::GUS chimeric constructs in tobacco: response to developmental and biotic factors

Expression patterns of three Arabidopsis thaliana cytokinin oxidase/dehydrogenase promoter::GUS reporter fusions were investigated in tobacco plants. While cytokinin oxidase/dehydrogenase promoter 2 showed no expression in tobacco, the cytokinin oxidase/dehydrogenase promoters 3 and 4 were active in various tissues throughout development of the tobacco. Recently, the 1452 bp promoter region of AtCKX3 was reported as almost inactive in Arabidopsis. In contrast, the 1627 bp DNA fragment preceding the AtCKX3 coding region drove expression of the reporter GUS gene in various tobacco tissues. The promoter was mainly expressed in tobacco leaves and roots during early stages of development but also later in young flower buds as well as in pollen grains. The construct was particularly active before (hypocotyl region) and during (vascular system) lateral root initiation, supporting the idea of an inhibitory role of active cytokinins in the process of root initiation. The cytokinin oxidase/dehydrogenase promoter 4::GUS fusion in tobacco was shown to share some common (but weaker) expression patterns with promoter 3, namely in the leaves and pollen, but also conferred specific expression in tobacco root cap cells and trichomes. In addition, the response of cytokinin oxidase/dehydrogenase promoter::GUS reporter fusions to infection with the leafy gall-forming bacteria Rhodococcus fascians was examined. While an avirulent strain of R. fascians did not induce expression of any of the cytokinin oxidase/dehydrogenase promoters, the cytokinin oxidase/dehydrogenase promoter 3::GUS fusion was specifically induced at the site of infection when plants were challenged with a virulent strain of R. fascians, providing a possible explanation for the lack of significantly elevated cytokinin concentrations in tissues infected with virulent strains of R. fascians.This revised version was published online in August 2005 with some black and white figures replaced by coloured figures.