Transactivated and chemically inducible gene expression in plants

Several vector systems are available for tissue-specific transactivation or chemical induction of transgene expression in plants. The choice facing researchers is which promoter system to commit to as this determines the range and characteristics of the expression resources available. The decision will not be the same for all species or applications. We present some general discussion on the use of these technologies and review in detail the properties in various (mainly angiosperm) species of the most promising: mGal4:VP16/UAS and pOp/LhG4 for transactivation, and the alc-switch, GVE/VGE, GVG, pOp6/LhGR, and XVE systems for chemical induction.     

Improved ecdysone receptor-based inducible gene regulation system.

To develop an ecdysone receptor (EcR)-based inducible gene regulation system, several constructs were prepared by fusing DEF domains of Choristoneura fumiferana EcR (CfEcR), C. fumiferana ultraspiracle (CfUSP), Mus musculus retinoid X receptor (MmRXR) to either GAL4 DNA binding domain (DBD) or VP16 activation domain. These constructs were tested in mammalian cells to evaluate their ability to transactivate luciferase gene placed under the control of GAL4 response elements and synthetic TATAA promoter. A two-hybrid format switch, where GAL4 DBD was fused to CfEcR (DEF) and VP16 AD was fused to MmRXR (EF) was found to be the best combination. It had the lowest background levels of reporter gene activity in the absence of a ligand and the highest level of reporter gene activity in the presence of a ligand. Both induction and turn-off responses were fast. A 16-fold induction was observed within 3 h of ligand addition and increased to 8942-fold by 48 h after the addition of ligand. Withdrawal of the ligand resulted in 50% and 80% reduction in reporter gene activity by 12 h and 24 h, respectively.     

Construction of Stress Responsive Synthetic Promoters and Analysis of Their Activity in Transgenic Arabidopsis thaliana

To obtain strong inducible promoters to drive abiotic stress-inducible transgene expression with minimal negative effects, we constructed three artificial synthetic promoters (EKCM, EKCRM, and ECCRM) comprising multiple cis-acting stress-response elements. Each promoter was fused independently to the β-glucuronidase (GUS) reporter gene, and GUS expression was analyzed in stable expression systems in Arabidopsis thaliana. T2 transgenic progenies showed integration of the promoter-GUS construct in their genome. RT-PCR assays and histochemical staining analysis showed that GUS expression driven by each promoter increased under desiccation, cold, and high salt conditions. The activity of synthetic promoters, assessed by fluorometric quantitative analysis of GUS enzyme activity, was significantly higher than that of the rd29A promoter under various stress treatments. The most powerful promoter, EKCM, allowed about 1.29-fold in GUS activity relative to the rd29A promoter, on average, under dehydration conditions. All three synthetic promoters could drive stress-inducible GUS expression in different organs of transgenic Arabidopsis. These synthetic promoters represent valuable tools for improving the stress tolerance of crops.     

AtSTP3启动子控制的外源基因在转基因水稻中的特异表达研究

利用PCR技术从哥伦比亚型拟南芥基因组DNA中分离了AtSTP3绿色组织特异表达的启动子,序列分析表明,扩增片段(1774bp)与已报道序列的相应区域同源性达99.9%。将其与GUS报告基因融合在一起,构建了植物表达载体,并由农杆菌介导法导入水稻品种‘中花11’中。对转基因水稻植株中的GUS活性进行定性与定量测定结果表明,AtSTP3启动子可驱动GUS报告基因在转基因水稻植株叶片中特异性表达,而在根和种子等器官中不表达或表达活性极弱,AtSTP3启动子表现出明显的组织特异性。