Analysis of an ABA-responsive rice gene promoter in transgenic tobacco

We have analyzed in transgenic tobacco the expression of a chimeric gene containing 5 sequences of the rice rab-16B gene fused to the -glucuronidase (GUS) reporter gene. This construct, a translational fusion (–482 to +184) including 14 amino acids of the RAB-16B protein, is expressed only in zygotic and pollen-derived embryos. In zygotic embryos, GUS activity begins to accumulate 10 days after flowering (daf), and increases until seed maturation at 25 daf. Immunological measurements of endogenous abscisic acid (ABA) accumulation in these seeds showed a close parallel between hormone levels and GUS activity. However, GUS activity could not be reproducibly induced by treatment of immature embryos with ABA (10 M). Neither GUS activity nor GUS mRNA could be detected in leaves of transgenic tobacco even after ABA treatment. In contrast, GUS activity could be induced to high levels in pollen-derived embryos by treatment with ABA. Our results show that 482 bp of 5 sequences of the rice rab-16B promoter can confer in transgenic tobacco developmentally regulated expression in embryos but not ABA-responsive expression in vegetative tissues.     

The Promoter of a Metallothionein-Like Gene from the Tropical Tree Casuarina Glauca is Active in Both Annual Dicotyledonous and Monocotyledonous Plants

A chimeric gene consisting of the -glucuronidase (gusA) reporter gene under the control of the metallothionein-like promoter cgMT1 from the tropical tree Casuarina glauca was introduced into Nicotiana tabacum via Agrobacterium tumefaciens and into Oryza sativa by particle bombardment. The strongest histochemical staining for GUS activity was observed in the root system of the transgenic plants, and especially in lateral roots. In contrast, a relatively low level of reporter gene expression was seen in the aerial tissues and GUS staining was located mainly in the plant vascular system. The average ratio of GUS activity between root and leaf was found to be 13:1 in tobacco and 1.5:1 in rice. The pattern of cgMT1 promoter activity in floral organs was found to be different in tobacco and rice. High levels of gusA gene expression were detected in the ovules, pollen grains and tapetum, whereas in rice PcgMT1 directs expression to the vascular system of the floral organs. These results suggest that PcgMT1 is potentially useful in molecular breeding to express genes of interest whose products are preferentially needed in roots.     

Characterization of a rice gene family encoding root-specific proteins

Two cDNA clones (RCc2 and RCc3) corresponding to mRNAs highly expressed only in root tissues of rice (Oryza sativa L.) seedlings were characterized. Respectively, they encode polypeptides of 146 (14.5 kDa) and 133 amino acids (13.4 kDa) that share high (<70%) sequence similarity with a polypeptide encoded by a cDNA (ZRP3) encoding an mRNA preferentially expressed in young maize roots. Genomic DNA blot analysis revealed that they are members of a small gene family and RCg2, the gene corresponding to RCc2, was isolated. A 1656 bp 5-upstream sequence of RCg2 was translationally fused to a -glucuronidase (GUS) reporter gene and stable introduction of the chimeric construct into rice was confirmed by PCR and genomic DNA blot analyses. Histochemical analysis of transgenic rice plants containing the full-length chimeric gene showed high levels of GUS activity in mature cells and the elongation and maturation zones of primary and secondary roots, and in the root caps, but no GUS activity was detected in root meristematic regions. Surprisingly, high GUS activity was also detected in leaves of the same plants. This raises the possibility that the RCg2 5-upstream element may not be sufficient for the proper spatial control of root specificity in transgenic rice.     

Expression of CaMV35S-GUS gene in transgenic rice plants

Summary To understand the properties of the cauliflower mosaic virus (CaMV) 35S promoter in a monocotyledonous plant, rice (Oryza sativa L.), a transgenic plant and its progeny expressing the CaMV35S-GUS gene were examined by histochemical and fluorometric assays. The histochemical study showed that -glucuronidase (GUS) activity was primarily localized at or around the vascular tissue in leaf, root and flower organs. The activity was also detected in the embryo and endosperm of dormant and germinating seeds. The fluorometric assay of various organs showed that GUS activity in transgenic rice plants was comparable to the reported GUS activity in transgenic tobacco plants expressing the CaMV35S-GUS gene. The results indicate that the level of expression of the CaMV 35S promoter in rice is similar to that in tobacco, a dicotyledonous plant, suggesting that it is useful for expression of a variety of foreign genes in rice plants.     

The first intron of rice EPSP synthase enhances expression of foreign gene

The first intron (EPI) of rice 5-enolpyruvylshikimate 3-phosphate synthase gene was isolated by PCR from one clone with genomic EPSP synthase gene. Sequence analysis showed that the first intron is 704 bp in length with 36.2% G+C content. To investigate its effect on expression of foreign gene, we inserted the first intron between CaMV35S promoter and β-glucuronidase (GUS) gene. The transient expression results showed that GUS could be expressed effectively with EPI. The GUS activity in transgenic tobacco shows that the EPI can greatly enhance the expression level of β-glucuronidase (P < 0.01) compared with transgenic tobacco without the first intron, and 3-to 6-fold increase in GUS activity in some transgenic tobaccos. Northern blot indicated the first intron was spliced from GUS pre-mRNA, and the steady-state mRNA levels of GUS with EPI in transgenic tobaccos were higher than that in transgenic tobacco without EPI, which suggested that the first intron of EPSP was a non-translated intron.     

Expression of the rice Osgrp1 promoter-Gus reporter gene is specifically associated with cell elongation/expansion and differentiation

To study the expression and regulation of a rice glycine-rich cell wall protein gene, Osgrpl, transgenic rice plants were regenerated that contain the Osgrpl promoter or its 5 deletions fused with the bacterial -glucuronidase (GUS) reporter gene. We report here a detailed histochemical analysis of the Osgrpl-Gus expression patterns in transgenic rice plants. In roots of transgenic rice plants, GUS expression was specifically located in cell elongation and differentiation regions, and no GUS expression was detectable in the apical meristem and the mature region. In shoots, GUS activity was expressed only in young leaves or in the growing basal parts of developing leaves, and little GUS activity was expressed in mature leaves or mature parts of developing leaves. In shoot apices, GUS activity was detected only in those leaf cells which were starting to expand and differentiate, and GUS expression was not detected in the apical meristem and the young meristematic leaf primordia. GUS activity was highly expressed in the young stem tissue, particularly in the developing vascular bundles and epidermis. Thus, the expression of the Osgrpl gene is closely associated with cell elongation/expansion during the post-mitotic cell differentiation process. The Osgrpl-Gus gene was also expressed in response to wounding and down-regulated by water-stress conditions in the elongation region of roots. Promoter deletion analysis indicates that both positive and negative mechanisms are involved in regulating the specific expression patterns. We propose a simple model for the developmental regulation of the Osgrpl gene expression.     

Developmental and environmental regulation of tissue- and cell-specific expression for a pea protein farnesyltransferase gene in transgenic plants

Farnesylation mediates membrane targeting and in vivo activities of several key regulatory proteins such as Ras and Ras-related GTPases and protein kinases in yeast and mammals, and is implicated in cell cycle control and abscisic acid (ABA) signaling in plants. In this study, the developmental expression of a pea protein farnesyl-transferase (FTase) gene was examined using transgenic expression of the β-glucuronidase (GUS) gene fused to a 3.2 kb 5′ upstream sequence of the gene encoding the pea FTase β subunit. Coordinate expression of the GUS transgene and endogenous tobacco FTase β subunit gene in tobacco cell lines suggests that the 3.2 kb region contains the key FTase promoter elements. In transgenic tobacco plants, GUS expression is most prominent in meristematic tissues such as root tips, lateral root primordia and the shoot apex, supporting a role for FTase in the control of the cell cycle in plants. GUS activity was also detected in mature embryos and imbibed embryos, in accordance with a role for FTase in ABA signaling that modulates seed dormancy and germination. In addition, GUS activity was detected in regions that border two organs, e.g. junctions between stems and leaf petioles, cotyledons and hypocotyls, roots and hypocotyls, and primary and secondary roots. GUS is expressed in phloem complexes that are adjacent to actively growing tissues such as young leaves, roots of light-grown seedlings, and hypocotyls of dark-grown seedlings. Both light and sugar (e.g. sucrose) treatments repressed GUS expression in dark-grown seedlings. These expression patterns suggest a potential involvement of FTase in the regulation of nutrient allocation into actively growing tissues.     

pib基因启动子及其诱导启动性初探

将pib基因上游5.7 kb区段取代pCAMBIA1301中gus基因上游的35S启动子构建了pib拟启动区-GUS+ 35S-hpt 基因表达载体pNAR604。经农杆菌介导转化水稻成熟胚愈伤,获得了转基因抗潮霉素愈伤和36株转基因水稻植株。 转基因抗性愈伤和转基因植株根的组织化学GUS活性检测表明,光照培养下的抗性愈伤和转基因植株根不能使X-gluc显色,而暗处理24 h后的抗性愈伤和定植后转基因植株的根能使X-gluc显色。转基因植株GUS荧光定量分析结果表明,GUS表达具有器官特异性,黑暗处理前根的GUS活性最高、茎次之,分别是是叶片的7倍和3倍,叶片中仅有痕量本底。24 h黑暗处理后根、茎、叶中GUS活性都有增加,且叶片中的增加比例最大,其活性仅次于根。5 mmol/L水杨酸和0.3 mol/L NaCl叶面喷施转基因植株24 h后叶片中GUS活性分别为处理前的2.7和3.6倍。初步确定pib拟启动区是一个诱导型启动子。黑暗、水杨酸和NaCl能诱导该启动子启动活性。     

DGP1, a drought-induced guard cell-specific promoter and its function analysis in tobacco plants

Stomatal pores on the surface of leaf are gate-ways of gas exchange between plants and environment. For example, plants can take in CO2 via photosynthe-sis and lose water by transpiration. It was estimated that plants account for around 65% fresh water use every year, which was mainly lost through stomata[1]. So they attracted much more attention to increase the ability of drought resistance by regulating stomatal movement. Then a tentative plan came to our brains, is it possible for us to as…     

DGP1, a drought-induced guard cell-specific promoter and its function analysis in tobacco plants

The genetic regulation of stomatal movement mainly depends on an efficient control system of gene expression, and guard cell-specific promoter is becoming the best choice. Here we combined the dehydration responsive element (DRE) with guard cell specific element (GCSE) to construct a novel promoter, DGP1. Histochemical assays in transgenic tobacco carryingβ-glucuronidase (gus) gene fused to DGP1 demonstrated that GUS activity was found to be highly inducible by drought treatment and specifically restricted to guard cells. No GUS activity was detected in roots, stems or flowers after treatment. Further quantitative analysis showed that GUS activity in the epidermal strips was apparently induced by dehydration and dramatically increased with the elongation of treatment. The GUS activity after 8 h treatment was 179 times that of those without treatment. Although GUS activity in roots, stems or mesophyll increased after treatment, no great changes were observed. These results suggested that DGP1 could drive target gene expressed in guard cells when plant is subjected to drought stress. And this gets us prepared to control opening and closing of stomata through plant gene engineering.     

Activity of a maize ubiquitin promoter in transgenic rice

We have used the maize ubiquitin 1 promoter, first exon and first intron (UBI) for rice (Oryza sativa L. cv. Taipei 309) transformation experiments and studied its expression in transgenic calli and plants. UBI directed significantly higher levels of transient gene expression than other promoter/intron combinations used for rice transformation. We exploited these high levels of expression to identify stable transformants obtained from callus-derived protoplasts co-transfected with two chimeric genes. The genes consisted of UBI fused to the coding regions of the uidA and bar marker genes (UBI:GUS and UBI:BAR). UBI:GUS expression increased in response to thermal stress in both transfected protoplasts and transgenic rice calli. Histochemical localization of GUS activity revealed that UBI was most active in rapidly dividing cells. This promoter is expressed in many, but not all, rice tissues and undergoes important changes in activity during the development of transgenic rice plants.