Cell Specific,Cross-Species Expression of Myrosinases in Brassica Napus,Arabidopsis Thaliana and Nicotiana Tabacum

A prototypical characteristic of the Brassicaceae is the presence of the myrosinase-glucosinolate system. Myrosinase, the only known S-glycosidase in plants, degrades glucosinolates, thereby initiating the formation of isothiocyanates, nitriles and other reactive products with biological activities. We have used myrosinase gene promoters from Brassica napus and Arabidopsis thaliana fused to the beta -glucuronidase (GUS) reporter gene and introduced into Arabidopsis thaliana, Brassica napus and/or Nicotiana tabacum plants to compare and determine the cell types expressing the myrosinase genes and the GUS expression regulated by these promoters. The A. thaliana TGG1 promoter directs expression to guard cells and phloem myrosin cell idioblasts of transgenic A. thaliana plants. Expression from the same promoter construct in transgenic tobacco plants lacking the myrosinase enzyme system also directs expression to guard cells. The B. napus Myr1.Bn1 promoter directs a cell specific expression to idioblast myrosin cells of immature and mature seeds and myrosin cells of phloem of B. napus. In A. thaliana the B. napus promoter directs expression to guard cells similar to the expression pattern of TGG1. The Myr1.Bn1 signal peptide targets the gene product to the reticular myrosin grains of myrosin cells. Our results indicate that myrosinase gene promoters from Brassicaceae direct cell, organ and developmental specific expression in B. napus, A. thaliana and N. tabacum.     

Timing of Transposition of Ac Mobile Element in Potato

The timing of excision of maize transposable element Ac was studied using visual histochemical assay based on Ac excision restoring activity of -glucuronidase (GUS). The Solanum tuberosum L. cv. Bintje was used for Agrobacterium-mediated transformation with pTT230 plasmid harbouring Ac-interrupted gus A gene and npt II gene as a selectable marker gene. Twenty-eight out of 72 kanamycin resistant calli did not express any GUS activity, 31 calli showed partial GUS expression and 13 out of assayed calli revealed strong expression of gus A gene. Plants were regenerated from calli without and/or with partial expression of gus A gene. The regenerated transformants which did not express GUS during the callus phase often contained many small GUS expressing spots on leaves. A phenotypic selection assay for excision of Ac has been also used. This non-detectable excision of Ac in callus tissue could be followed by a "late" timing excision during leaf development. After transformation with pTT224 plasmid harbouring Ac-interrupted hpt II gene and npt II gene transgenic calli containing Ac within the hygromycin resistance gene were derived and hygromycin sensitive plants were regenerated from them. Protoplasts isolated from leaves of transgenic regenerated plants were selected on hygromycin. Hygromycin resistant minicalli showed to harbour multiple copies of Ac and mark out low uniqueness of integration sites.     

Arabidopsis thaliana vegetative storage protein (VSP) genes: gene organization and tissue-specific expression

We have previously identified two cDNAs encoding vegetative storage proteins (VSPs) in Arabidopsis thaliana. Unlike soybean in which VSPs accumulate at high levels in leaves, A. thaliana VSP mRNAs are abundant in flowers. To understand tissue-specific expression and possible roles of VSPs on reproductive organ development, genes corresponding to VSPs (Vsp1 and Vsp2) and their putative promoters were characterized in this study. Genomic sequence analysis revealed that Vsp1 and Vsp2 resemble each other except in their introns, and that these two genes were organized in a tandem array with an interval of 6 kb in a region. The expression patterns of Vsp1 and Vsp2 were examined using transgenic A. thaliana plants carrying a promoter from Vsp1 or Vsp2 fused to a bacterial -glucuronidase (GUS) reporter gene. The promoter from Vsp1 expressed its effect in gynoecia, especially in styles, the basal and distal ends of ovaries and in siliques, whereas the promoter from Vsp2 showed its activity in vegetative shoots, petioles, peduncles and receptacles of floral organs. These results suggest that expression of Vsp1 and Vsp2 may be developmentally regulated in A. thaliana. In the transgenic plants, the GUS activity was induced by wounding in an area around the mid-rib of leaves. Therefore, Vsp1 and Vsp2 promoters appear to have elements required for both tissue specificity and wounding.     

Activity of a chimeric promoter with the doubled CaMV 35S enhancer element in protoplast-derived cells and transgenic plants in maize

A reproducible and efficient transformation system has been developed for maize that is based on direct DNA uptake into embryogenic protoplasts and regeneration of fertile plants from protoplast-derived transgenic callus tissues. Plasmid DNA, containing the -glucuronidase (GUS) gene, under the control of the doubled enhancer element (the –208 to –46 bp upstream fragment) from CaMV 35S promoter, linked to the truncated (up to –389 bp from ATG) promoter of wheat, -amylase gene was introduced into protoplasts from suspension culture of HE/89 genotype. The constructed transformation vectors carried either the neomycin phosphotransferase (NPTII) or phosphinothricin acetyltransferase (PAT) gene as selective marker. The applied DNA uptake protocol has resulted at least in 10–20 resistant calli, or GUS-expressing colonies after treatment of 10⁶ protoplasts. Vital GUS staining of microcalli has made possible the shoot regeneration from the GUS-stained tissues. 80–90% of kanamycin or PPT resistant calli showed GUS activity, and transgenic plants were regenerated from more than 140 clones. Both Southern hybridization and PCR analysis showed the presence of introduced foreign genes in the genomic DNA of the transformants. The chimeric promoter, composed of a tissue specific monocot promoter, and the viral enhancer element specified similar expression pattern in maize plants, as it was determined by the full CaMV 35S promoter in dicot and other monocot plants. The highest GUS specific activity was found in older leaves with progressively less activity in young leaves, stem and root. Histochemical localization of GUS revealed promoter function in leaf epidermis, mesophyll and vascular bundles, in the cortex and vascular cylinder of the root. In roots, the meristematic tip region and vascular tissues stained intensively. Selected transformants were grown up to maturity, and second-generation seedlings with segregation for GUS activity were obtained after outcrossing. The GUS-expressing segregants carried also the NPTII gene as shown by Southern hybridization.     

Repeated sequences from theArabidopsis thaliana genome function as enhancers in transgenic tobacco

Sixteen segments ofArabidopsis thaliana DNA that function as enhancers in transgenic tobacco plants were isolated using the pROA97 enhancer cloning vehicle and library transformation ofNicotiana tabacum. The sequences were compared for AT content, homology, repeated motifs, and expression pattern in transgenicN. tabacum. The sequences were average with respect to the AT content ofA. thaliana DNA. They could be placed into seven homology groups. Five of the sequences are single-copy sequences. The remaining eleven sequences represent two homology groups. Homology Group I contains seven sequences with minor differences. Homology Group II contains four sequences with minor differences. Two repeated motifs were identified (5′-CCTCT-3′ and 5′-AAGGAT-3′). Both repeated motifs are found in other plant enhancers, and in the promoter region of the cauliflower mosaic virus 35S gene. In the 35S gene TATA region, the motifs can form two alternative stem-loop structures. The TATATAA sequence is located in the loop region of both stem-loop structures.     

Specialized binary vector for plant transformation: expression of the Arabidopsis thaliana AHAS gene in Nicotiana tabacum.

We constructed a cosmid vector, pOCA18, designed for transferring plant genomic libraries from Agrobacterium tumefaciens to plants. Clones from a genomic library of Arabidopsis thaliana DNA in pOCA 18 were propagated stably in both Escherichia coli and A. tumefaciens. Clones from the pOCA18 A. thaliana library were used to construct transgenic Nicotiana tabacum plants; the DNA inserts were transferred intact in 10 out of 16 transgenic N. tabacum plants examined but were partially deleted in six others. Transgenic N. tabacum plants constructed with a mutant A. thaliana acetohydroxy acid synthase gene (from the pOCA18 library) that encodes an enzyme resistant to the herbicide chlorsulfuron were resistant to chlorsulfuron. A statistical analysis indicated that if the A. thaliana library contains 10(7) members and if 10(7) A. tumefaciens transconjugants containing the library were used to transform plant cells, then 2 x 10(4) transformed plant cells must be generated to have a 95% probability of constructing a transgenic plant carrying a specific DNA sequence from the A. thaliana library.     

A xylanase,AtXyn1, is predominantly expressed in vascular bundles,and four putative xylanase genes were identified in the Arabidopsis thaliana genome

The cDNA clone RXF12, which encodes a xylanase (EC 3.2.1.8), was isolated from Arabidopsis thaliana. The C-terminal half of the amino acid sequence of the deduced protein, named AtXyn1, showed similarity with the catalytic domain of barley xylanase X-1. The N-terminal half of AtXyn1 also contained three regions with sequences similar to cellulose-binding domains (CBDs). A xylanase assay revealed that transgenic A. thaliana plants expressing exogenous AtXyn1 fused with enhanced green fluorescent protein (EGFP) possessed approximately twice as much xylanase activity as wild-type plants. Observation by fluorescence microscopy of transgenic A. thaliana plants expressing a fusion protein of AtXyn1 and EGFP suggested that AtXyn1 is a cell wall protein. Analysis of the localization of beta-glucuronidase (GUS) activity in transgenic A. thaliana plants containing a chimeric gene with the upstream sequence of the AtXyn1 gene and the GUS gene demonstrated that the AtXyn1 gene is predominantly expressed in vascular bundles, but not in vessel cells. These data suggest that AtXyn1 is involved in the secondary cell wall metabolism of vascular bundle cells. A database search revealed that four putative xylanase genes exist in the A. thaliana genome, besides the AtXyn1 gene. Of these, two also contain several regions with sequences similar to CBDs in their N-terminal regions. Comparison of the amino acid sequences of the five xylanases suggests a possible process for their molecular evolution.     

Combination of the ALCR/alcA ethanol switch and GAL4/VP16-UAS enhancer trap system enables spatial and temporal control of transgene expression in Arabidopsis

The experimental control of gene expression in specific tissues or cells at defined time points is a useful tool for the analysis of gene function. GAL4/VP16-UAS enhancer trap lines can be used to selectively express genes in specific tissues or cells, and an ethanol-inducible system can help to control the time of expression. In this study, the combination of the two methods allowed the successful regulation of gene expression in both time and space. For this purpose, a binary vector, 962-UAS::GUS, was constructed in which the ALCR activator and β-glucuronidase (GUS) reporter gene were placed under the control of upstream activator sequence (UAS) elements and the alcA response element, respectively. Three different GAL4/VP16-UAS enhancer trap lines of Arabidopsis were transformed, resulting in transgenic plants in which GUS activity was detected only on ethanol induction and exclusively in the predicted tissues of the enhancer trap lines. As a library of different enhancer trap lines with distinct green fluorescent protein (GFP) patterns exist, transformation with a similar vector, in which GUS is replaced by another gene, would enable the control of the time and place of transgene expression. We have constructed two vectors for easy cloning of the gene of interest, one with a polylinker site and one that is compatible with the GATEWAY™ vector conversion system. The method can be extended to other species when enhancer trap lines become available.     

Review: Biosafety of E. coli β-glucuronidase (GUS) in plants

The -glucuronidase (GUS) gene is to date the most frequently used reporter gene in plants. Marketing of crops containing this gene requires prior evaluation of their biosafety. To aid such evaluations of the GUS gene, irrespective of the plant into which the gene has been introduced, the ecological and toxicological aspects of the gene and gene product have been examined. GUS activity is found in many bacterial species, is common in all tissues of vertebrates and is also present in organisms of various invertebrate taxa. The transgenic GUS originates from the enterobacterial species Escherichia coli that is widespread in the vertebrate intestine, and in soil and water ecosystems. Any GUS activity added to the ecosystem through genetically modified plants will be of no or minor influence. Selective advantages to genetically modified plants that posses and express the E. coli GUS transgene are unlikely. No increase of weediness of E. coli GUS expressing crop plants, or wild relatives that might have received the transgene through outcrossing, is expected. Since E. coli GUS naturally occurs ubiquitously in the digestive tract of consumers, its presence in food and feed from genetically modified plants is unlikely to cause any harm. E. coli GUS in genetically modified plants and their products can be regarded as safe for the environment and consumers     

海州香薷(Elsholtzia haichowensis Sun)细胞壁转化酶基因启动子(EhcwINVP)的克隆及活性分析

以海州香薷基因组DNA为模板,通过hiTAIL-PCR和walking技术扩增得到其细胞壁转化酶基因启动子(Ehcw INVP)片段,长度为1727 bp。生物信息学分析结果表明,该启动子片段中含有多个对脱落酸、赤霉素、细胞分裂素等激素以及对干旱、低温、重金属铜等逆境胁迫响应相关的顺式作用元件。将通过克隆得到的Ehcw INVP序列替换p CAMBIA1301载体上驱动GUS报告基因表达的Ca MV35S启动子序列,构建Ehcw INVP融合GUS的植物表达载体Ehcw INVP::GUS。转基因拟南芥植株的组织化学分析结果表明,海州香薷细胞壁转化酶基因启动子序列具有驱动GUS基因表达的功能,且在10μmol/L铜胁迫下,转基因拟南芥植株叶和根中的GUS活性分别约是对照组的1.7倍和1.5倍。     

Expression of a gene encoding a ribosomal p40 protein and identification of an active promoter site

The promoter of a gene encoding a ribosome-associated protein of 40 kDa from Arabidopsis thaliana (A-p40) was sequenced and the expression of the gene studied. A-p40 was expressed in the same organs and with the same variations as the eukaryotic elongation factor 1 (eEF1A), another gene coding for a protein involved in translation Arabidopsis plants transformed with a -glucuronidase (GUS) gene driven by the A-p40 promoter confirm that A-p40 is expressed in actively dividing and growing cells. eEF1A promoter-GUS fusions have the same pattern of expression. Comparison of cis-acting elements from A-p40 and eEF1A revealed some common elements. A-p40 promoter deletions and transient gene expression in transfected Arabidopsis protopasts allowed the identification of trap40, a cis-acting element regulating gene expression. Gel retardation experiments indicate that eEF1A and A-p40 are regulated by different cis-acting elements. The role of such elements is discussed.     

Structure and expression analyses of the S-adenosylmethionine synthetase gene family in Arabidopsis thaliana

The plant, Arabidopsis thaliana, contains two S-adenosylmethionine synthetase-encoding genes (sam). Here, we analyze the structure and expression of the sam-2 gene and compare it with the previously described sam-1 gene. Northern-blot analysis using gene-specific probes shows that both sam-1 and sam-2 are highly expressed in stem, root, and callus tissue. This similar expression pattern might be mediated by the presence of three highly conserved sequences in the 5' region of both sam genes. Using a chimeric beta-glucuronidase (GUS)-encoding gene, we show that in transgenic tobacco plants, 748 bp of 5' sam-1 sequences generate high GUS activity in the same type of tissues as previously observed in transgenic A. thaliana plants. A deletion analysis of these 5' sam-1 sequences indicates that 224 bp of 5' sam-1 sequences can still induce higher expression of the gene in stem and root relative to leaf. However, the level of expression is reduced when compared to the expression level obtained with the full-length promoter.     

Isolation and characterization of root-specific phosphate transporter promoters from Medicago trunatula

Promoters of phosphate transporter genes MtPT1 and MtPT2 of Medicago truncatula were isolated by utilizing the gene-space sequence information and by screening of a genomic library, respectively. Two reporter genes, beta-glucuronidase (GUS) and green fluorescent protein (GFP) were placed under the control of the MtPT1 and MtPT2 promoters. These chimeric transgenes were introduced into Arabidopsis thaliana and transgenic roots of M. truncatula, and expression patterns of the reporter genes were assayed in plants grown under different phosphate (Pi) concentrations. The expression of GUS and GFP was only observed in root tissues, and the levels of expression decreased with increasing concentrations of Pi. GUS activities in roots of transgenic plants decreased 10-fold when the plants were transferred from 10 microM to 2 mM Pi conditions, however, when the plants were transferred back to 10 microM Pi conditions, GUS expression reversed back to the original level. The two promoters lead to different expression patterns inside root tissues. The MtPT1 promoter leads to preferential expression in root epidermal and cortex cells, while MtPT2 promoter results in strong expression in the vascular cylinder in the center of roots. Promoter deletion analyses revealed possible sequences involved in root specificity and Pi responsiveness. The promoters are valuable tools for defined engineering of plants, particularly for root-specific expression of transgenes.     

Enhancer trapping identifies TRI, an Arabidopsis gene up-regulated by pathogen infection

Enhancer trap Arabidopsis thaliana plants were screened for genes up-regulated by virus infection. The plants carried T-DNA insertions comprising a minimal -60-bp Cauliflower mosaic virus 35S promoter fused to the beta-glucuronidase (GUS) reporter gene. Approximately 12,000 plants were assayed for GUS activity before and after rub-inoculation with Tobacco rattle virus (TRV) tagged with the green fluorescent protein (GFP). One plant and its progeny consistently showed upregulation of GUS activity in response to TRV-GFP infection, indicating that a virus-responsive enhancer element was "tagged" by the T-DNA in this line. Other viruses, bacteria, and oomycetes, but not wounding, up-regulated GUS activity in the enhancer trap line, indicating that the response was not specific to TRV-GFP infection. A pathogen-inducible, alternatively spliced gene was identified, which we have termed TRI for TRV-induced gene. A pathogen-responsive element was localized to a 1.1-kb region upstream of the T-DNA insertion, and two different cis-acting elements, both implicated in defense responses, were found in the sequence upstream of TRI. Sequence analyses revealed that TRI is similar to ACRE169, a gene that is up-regulated in Cf-9-expressing tobacco when treated with Avr-9, the Cladosporium fulvum elicitor of the Cf-9 resistance response.     

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.     

病程相关基因启动子片段与GUS的融合基因在拟南芥中的表达

PR1是拟南芥(Arabidopsisis thaliana L.)系统获得抗性的一个标志基因.利用PCR技术,从拟南芥中扩增并克隆了PR1基因的启动子片段.将该启动子片段与GUS报告基因拼接,构建成含有PR1-GUS融合基因的重组表达质粒.经根癌农杆菌介导转化,得到了转基因的拟南芥植株.用已知的系统获得抗性激活剂处理转基因植物,检测到GUS活性.因此,这一转基因体系可以作为一种简便、灵敏的实验体系以筛选激活植物系统获得抗性的化合物.