Light-regulated expression of the pea plastocyanin gene is mediated by elements within the transcribed region of the gene

Expression of the pea plastocyanin gene ( PetE ) is regulated by light in both pea and transgenic tobacco plants. However, the PetE promoter with the 5' untranslated leader region does not direct light-regulated expression of the GUS reporter gene in transgenic tobacco. This suggested that sequences downstream of the translation start of the PetE gene are required for light-regulated expression. To investigate this possibility the expression of a series of chimeric gene constructs in transgenic tobacco plants was examined to assess the contributions of the promoter, the 5' untranslated leader region, the coding region and the 3' region of the PetE gene to light-regulated expression. Both the coding region and the 5' untranslated leader region of the PetE gene were found to be required for full light regulation. Full light regulation of chimeric gene constructs containing the cauliflower mosaic virus (CaMV) 35S promoter required the deletion of CaMV 5' leader and polylinker sequences from the constructs. The presence of CaMV and polylinker sequences at the 5' end of the PetE leader masked the light regulation directed by the transcribed region of the pea PetE gene.     

Both internal and external regulatory elements control expression of the pea Fed-1 gene in transgenic tobacco seedlings.

In previous studies using leaves of light-grown transgenic tobacco plants, we have shown that sequences located within the transcribed region of the pea Fed-1 gene (encoding ferredoxin I) are major cis-acting determinants of light-regulated mRNA accumulation. However, we show here that these internal sequences are less important for the Fed-1 light response in etiolated tobacco seedlings than they are in green leaves and that upstream elements confer organ specificity and contribute significantly to Fed-1 light responses in etiolated material. Light effects mediated by upstream response elements are thus most pronounced during the initial induction of gene activity, whereas internal elements play a more prominent role in modulating Fed-1 expression once the gene is already active.     

Effect of an enhanced CaMV 35S promoter and a fruit-specific promoter on uida gene expression in transgenic tomato plants

Summary Two different promoters, a cauliflower mosaic virus (CaMV) 35S promoter with a 5′-untranslated leader sequence from alfalfa mosaic virus RNA4 (designated as CaMV 35S/AMV) and an E-8 fruit-ripening-specific promoter, were compared to evaluate their effects on expression of the uidA reporter gene in transgenic tomato plants. In order to generate sufficient numbers of transgenic tomato plants, both a reliable regeneration system and an efficient Agrobacterium transformation protocol were developed using 8-d-old cotyledons of tomato (Lycopersicon ecsulentum Mill. cv. Swifty Belle). Two sets of constructs, both derivatives of the binary vector pBI121, were used in transformation of tomato whereby the uidA gene was driven either by the CaMV 35S/AMV or the E-8 fruit-ripening-specific promoter. Southern blot hybridization confirmed the stable integration of the chimeric uidA gene into the tomato genome. Fruit and leaf tissues were collected from T₀ and T₁ plants, and assayed for β-glucuronidase (GUS) enzyme activity. As expected, both vegetative and fruit tissues of transgenic plants carrying the uidA gene under the control of CaMV 35S/AMV showed varying levels of GUS activity, while no expression was observed in vegetative tissues of transgenic plants carrying the uidA gene driven by the E-8 promoter. All fruits from transgenic plants produced with both sets of constructs displayed expression of the uidA gene. However, when this reporter gene was driven by the CaMV 35S/AMV, GUS activity levels were significantly higher than when it was driven by the E-8 fruit-specific promoter. The presence/absence of the uidA gene in T₁ plants segregated in a 3∶1 Mendelian ratio.     

Light regulatory sequences are located within the 5'' portion of the Fed-1 message sequence.

We have previously shown that element(s) mediating a light-induced increase in the abundance of Fed-1 mRNA in the leaves of transgenic tobacco plants are located within the transcribed portion of the gene. As part of an effort to define the mechanism of this effect, we report here that cis-acting elements capable of mediating a 5-fold light-induced increase in the abundance of this mRNA are located within a region comprising the 5' leader and first third of the Fed-1 coding sequence. No activity was detected in the 3' untranslated region of the gene. In a gain-of-function assay, the 5' region was found to be capable of conferring light responsiveness on three different reporter sequences, although experiments with the gusA reporter were complicated by an apparent negative light effect on the stability of this mRNA. Deletion experiments show that at least one essential light regulatory element is located in the 5' untranslated region of Fed-1 between nucleotides +19 and +57. Additional Fed-1 sequences, including a portion of the protein coding region, are required to confer positive responsiveness on the gusA reporter. These additional sequences may include specific light regulatory elements or simply provide an environment in which the leader element can function normally.     

番茄多胁迫诱导型LeMTshsp 启动子的分子克隆及其功能分析

根据Southern 杂交结果, 选取KpnⅠ与EcoRⅠ双酶切番茄中蔬4 号基因组DNA, 3 kb 左右的酶切片段连入pBSⅡKS ( + ) 载体, 构建成含有线粒体小分子热激蛋白基因( LeMTshsp) 上游2 kb 左右调控区的质粒文库。通过巢式PCR 方法从构建的质粒文库中克隆出LeMTshsp 基因上游1915 bp 的调控区( GenBank登录号为AB239774) 。该序列含有TATA box 及CAAT box 等启动子基本元件, 还具有6 组典型的HSE 元件及多个AT-rich 区, 另外还有许多逆境反应元件如ABRE , C-repeat— DRE , AP-1。凝胶阻滞结果表明, 纯化的HsfA2 蛋白与LeMTshsp 启动子的HSE 元件在体外具有结合活性, 且与近端5 组HSE 的结合活性比与远端HSE 的结合活性强。构建该启动子与GUS 基因的融合载体, 利用农杆菌介导的叶圆盘法转化番茄, GUS 组织化学染色结果表明LeMTshsp 启动子对热激、低温、外源ABA 及重金属胁迫都有应答     

Construction of phosphomannose isomerase (PMI) transformation vectors and evaluation of the effectiveness of vectors in tobacco (Nicotiana tabacum L)

Phosphomannose isomerase (pmi) gene isolated from Escherichia coli allows transgenic plants carrying it to convert mannose-6- phosphate (from mannose), a carbon source that could not be naturally utilized by plants into fructose-6-phosphate which can be utilized by plants as a carbon source. This conversion ability provides energy source to allow the transformed cells to survive on the medium containing mannose. In this study, four transformation vectors carrying the pmi gene alone or in combination with the β-glucuronidase (gusA) gene were constructed and driven by either the maize ubiquitin (Ubi1) or the cauliflower mosaic virus (CaMV35S) promoter. Restriction digestion, PCR amplification and sequencing were carried out to ensure sequence integrity and orientation. Tobacco was used as a model system to study the effectiveness of the constructs and selection system. PMI11G and pMI3G, which carry gusA gene, were used to study the gene transient expression in tobacco. PMI3 construct, which only carries the pmi gene driven by CaMV35S promoter, was stably transformed into tobacco using biolistics after selection on 30 g 1(-1) mannose without sucrose. Transgenic plants were verified using PCR analysis. ABBREVIATIONS: PMI/pmi - Phosphomannose isomerase, Ubi1 - Maize ubiquitin promoter, CaMV35S - Cauliflower mosaic virus 35S promoter, gusA - β-glucuronidase GUS reporter gene.     

Inheritance of gusA and neo genes in transgenic rice

Inheritance of foreign genes neo and gusA in rice (Oryza sativa L. cv. IR54 and Radon) has been investigated in three different primary (T₀) transformants and their progeny plants. T₀ plants were obtained by co-transforming protoplasts from two different rice suspension cultures with the neomycin phosphotransferase II gene [neo or aph (3) II] and the -glucuronidase gene (uidA or gusA) residing on separate chimeric plasmid constructs. The suspension cultures were derived from callus of immature embryos of indica variety IR54 and japonica variety Radon. One transgenic line of Radon (AR2) contained neo driven by the CaMV 35S promoter and gusA driven by the rice actin promoter. A second Radon line (R3) contained neo driven by the CaMV 35S promoter and gusA driven by a promoter of the rice tungro bacilliform virus. The third transgenic line, IR54-1, contained neo driven by the CaMV 35S promoter and gusA driven by the CaMV 35S.Inheritance of the transgenes in progeny of the transgenic rice was investigated by Southern blot analysis and enzyme assays. Southern blot analysis of genomic DNA showed that, regardless of copy numbers of the transgenes in the plant genome and the fact that the two transgenes resided on two different plasmids before transformation, the introduced gusA and neo genes were stably transmitted from one generation to another and co-inherited together in transgenic rice progeny plants derived from self-pollination. Analysis of GUS and NPT II activities in T₁ to T₂ plants provided evidence that inheritance of the gusA and neo genes was in a Mendelian fashion in one plant line (AR2), and in an irregular fashion in the two other plant lines (R3 and IR54-1). Homozygous progeny plants expressing the gusA and neo genes were obtained in the T₂ generation of AR2, but the homozygous state was not found in the other two lines of transgenic rice.     

Overproduction of Arabidopsis thaliana FeSOD confers oxidative stress tolerance to transgenic maize.

Transgenic maize (Zea mays L.) plants have been generated by particle gun bombardment that overproduce an Arabidopsis thaliana iron superoxide dismutase (FeSOD). To target this enzyme into chloroplasts, the mature Fesod coding sequence was fused to a chloroplast transit peptide from a pea ribulose-1,5-bisphosphate carboxylase gene. Expression of the chimeric gene was driven by the CaMV 35S promoter. Growth characteristics and in vitro oxidative stress tolerance of transgenic lines grown in control and chilling temperatures were evaluated. The transgenic line with the highest transgenic FeSOD activities had enhanced tolerance toward methyl viologen and had increased growth rates.     

Comparison of hCMV immediate early and CaMV 35S promoters in both plant and human cells

Cauliflower mosaic virus 35S promoter, widely used in transgenic crop plants, is known to be recognized in widely differing kinds of cells. Its activity in human cells may have impact on the risk assessment for the environmental release of genetically modified plants. In this study, transient expression of several constructs containing beta-glucuronidase (GUS) gene driven by cauliflower mosaic virus 35S promoter or by immediate early promoter of human cytomegalovirus (pCMV) was tested in both potato leaf protoplasts and cultured human cells. The results showed very low but measurable activity of 35S promoter in human 293T-cells (0.01% of that revealed when using pCMV) and in 293 cells that do not produce SV40 T antigen this activity was even lower. On the other hand, in potato protoplasts, pCMV displayed nearly 1% activity seen with p35S.     

Transient gene expression in cassava using high-velocity microprojectiles

The bacterial gene encoding -glucuronidase (GUS) was transiently expressed in cassava leaves following the introduction of the gene by microparticle bombardment. The DNA expression vector used to introduce the reporter gene is a pUC 19 derivative and consisted of a CaMV 35S promoter (P35S), the GUS coding region and 7S polyadenylation region. Several other promoters and regulating sequences were tested for efficiency in cassava leaves. Two derivatives of the P35S, one including a partial duplication of the upstream region of the P35S and the other containing a tetramer of the octopine synthase enhancer, were found to be expressed at three times the level of the P35S in cassava leaves. The ubiquitin 1 promoter fromArabidopsis thaliana was expressed at the same level as the P35S. No influence on the level of expression was observed when different 3 ends were used. The biolistic transient gene expression system in cassava leaves allows rapid analysis of gene constructs and can serve as a preliminary screen for chimeric gene function in the construction of transgenic cassava plants.     

The first exon coding region of cystathionine gamma-synthase gene is necessary and sufficient for downregulation of its own mRNA accumulation in transgenic Arabidopsis thaliana.

Expression of the gene for cystathionine gamma-synthase (CGS), which catalyzes the key step of methionine biosynthesis, is feedback regulated at the level of mRNA stability. The first exon polypeptide of CGS is suggested to be involved in this regulation and amino acid sequence alterations caused by mto1 mutations in that region lead to an overaccumulation of CGS mRNA [Chiba et al. (1999) Science 286: 1371-1374]. Transgenic Arabidopsis thaliana harboring chimeric constructs in which wild-type or mto1 mutant CGS exon 1 are fused in-frame to reporter genes and driven by the cauliflower mosaic virus 35S RNA promoter were constructed. Studies with these transgenic lines demonstrated that the coding region of CGS exon 1 is necessary and sufficient for downregulation of its own mRNA accumulation in response to methionine application and that this region acts in cis in this process.