The Promoter of the Gene for Plastidic Glutamine Synthetase (GS2) fromRice Is Developmentally Regulated and Exhibits Substrate-Induced Expression in Transgenic Tobacco Plants

A 1.3-kb fragment from the 5'-flanking region of the RGS-38gene, which encodes the plastidic glutamine synthetase in Oryzasativa L., was fused to a ß-glucuronidase (GUS) reportergene and introduced into Nicotiana tabacum by Agrobacterium-mediatedtransformation. The promoter directed GUS expression, both inleaves and in roots, and the expression of GUS was regulatedby light. The GUS activity was high in the mature leaves ofthe transgenic tobacco plants, in marked contrast to the activityof the GS1 promoter. The GS2 promoter also responded to externallyapplied ammonia, as is the case for the GS1 promoter. Theseresults suggest that the cis-acting regulatory elements thatcontrol the response to ammonia, a substrate for glutamine synthetase,are located within a 1.3-kb region of the promoter. (Received October 1, 1991; Accepted January 20, 1992)     

The Promoter of the Gene for Glutamine Synthetase from Rice Shows Organ-Specific and Substrate-Induced Expression in Transgenic Tobacco Plants

A 2-kb fragment from the 5'-flanking region of the RGS-28 gene,which encodes the cytosolic glutamine synthetase in Oryza sativaL., was fused to a ß-glucuronidase (GUS) reportergene and introduced into Nicotiana tabacum by Agrobacterium-mediatedtransformation. The promoter was predominantly active in theleaves of transgenic plants, as it is in authentic rice plants.The promoter also responded to externally applied ammonium ions.It is suggested that the cis-acting regulatory elements responsiblefor the recognition of the leaf as a site of synthesis and ofammonia, a substrate for glutamine synthetase, are located withina 2-kb region of the promoter. (Received October 15, 1990; Accepted January 11, 1991)     

Tissue-Dependent Expression of the Rice wx+ Gene Promoter in Transgenic Rice and Petunia

The waxy (wx) locus, which controls the amylose synthesis, isknown to be expressed specifically in the endosperm and pollen.To study the tissue-specific regulation of the wx⁺ gene, weintroduced a fusion gene that consisted of the upstream sequenceof the wx⁺ gene and the gene for rß-glucuronidase(GUS) into cells of rice (Oryza sativa L.) and petunia (Petuniahybrida L.). GUS activity was examined in the regenerated transgenicrice and petunia plants. In transgenic rice, the upstream sequenceof the wx⁺ gene was sufficient to direct the tissue-specificexpression of GUS in the endosperm and pollen, and the controlof expression was quantitative. By contrast, in transgenic petunia,the same fusion gene was expressed in pollen but not in theendosperm. These results suggest that the putative cis-actingelements that direct pollen-specific expression are common toor similar in both monocotyledonous and dicotyledonous plants,whereas ciy-elements responsible for the endosperm-specificexpression of the rice wx⁺ gene do not function in petunia,in which development of the endosperm differs from that in rice. ⁴Present address: Division of Biological Sciences, GraduateSchool of Science, Hokkaido University, Kita-ku, Sapporo, 060Japan     

Constitutive Expression of Stress-Inducible Genes, Including Pathogenesis-Related 1 Protein Gene in a Transgenic Interspecific Hybrid of Nicotiana glutinosa x Nicotiana debneyi

Constitutive expression of a type of stress-inducible proteinsincluding pathogenesisrelated (PR) 1 protein and ubiquitin-relatedprotein in an interspecific hybrid of Nicotiana glutinosa xNicotiana debneyi was noted. In the two parental species andin tobacco, these proteins are not expressed in healthy plantsbut they are induced by stresses such as the formation of locallesions after viral infection and treatment of salicylic acid.A second type of stress-inducible genes, such as the genes forbasic ß-1,3-glucanase and putative proteinase inhibitorwere regulated normally, and were not expressed constitutivelyin the hybrid. In the transgenic hybrid, into which a chimericgene consisting of 5' upstream of tobacco PRla gene and ß-glucuronidase(GUS) gene was introduced, very high GUS activity was expressedconstitutively even at healthy state. An abnormal response bythis hybrid to plant hormones was also noted. A possible mechanismfor the unregulated expression of the stress-inducible genesin the interspecific hybrid is discussed. (Received September 13, 1991; Accepted December 27, 1991)     

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。     

Transient Gene Expression in Plant Cells Mediated by Agrobacterium tumefaciens: Application for the Analysis of Virulence Loci

A simple system is described for detection of the transfer ofT-DNA from Agrobacterium cells to suspension-cultured tobaccoBY-2 cells. A modified reporter gene for rß-glucuronidase(GUS) that contained an intron sequence was introduced intothe T-DNA region such that the GUS protein could be synthesizedin plant cells only after transfer of the T-DNA to plant nuclei.When BY-2 cells were co-cultured with Agrobacterium cells thatcontained the modified reporter gene, transient synthesis ofGUS protein was observed between 36 and 48 h after the onsetof co-culture. The level of GUS activity reached a plateau withinas little as 48 h. This temporal profile of GUS activation suggeststhat the transient activity might have been due to expressionof the GUS gene in the T-DNA that had been transferred to theplant nuclei but had not yet been integrated into the plantchromosomes. Levels of transient GUS activity were also examinedwith various vir mutants of Agrobacterium and in a mutant withan altered chromosomal acvB gene, the gene for a protein thathas been postulated to function outside bacterial cells. Duringco-culture with virB, virD2, virD4 and acvB mutants, GUS activityremained at background levels, and the GUS activity in the caseof the virE2 mutant was thirty-fold lower than with the wildtype. On the basis of these results, we discuss the roles ofthese genes during infection by Agrobacterium of plant cells. ⁴Present address: Biochemistry Laboratory, Kanebo Ltd., 5-3-28Kotobuki-cho, Odawara, Kanagawa, 250 Japan     

Expression and Promoter Activity of Genes for Isozymes of Horseradish Peroxidase

The expression and promoter activity of genes for isozymes ofhorseradish peroxidase, namely, prxCla, prxClb, prxC2 and prxC3,were studied. Organ-specific expression of these genes in horseradishplants was examined by Northern blot analysis. The group ofprxCl genes was expressed mostly in stems, while prxC2 and prxC3were expressed to a greater extent in roots. Hardly any expressionof any of the genes was detected in leaves. In transient-expressionassays with tobacco protoplasts, about 500 bp of the 5'-noncodingregions of each of the genes, ligated to the gene for ß-glucuronidase(GUS), exhibited significant promoter activity. In particular,the fragments extending from the initiation codon of the prxC2gene to –529 bp and –1 kbp supported high levelsof GUS activity, which were 4.4 and 11.4 times respectively,the activity observed under control of the 35S promoter fromcauliflower mosaic virus (CaMV). Conserved enhancer sequencesof human genes were found in the 5'-flanking region of prxC2,and deletion of the regions that contained the enhancer sequencesreduced the GUS activity. High levels of GUS activity were observedin transgenic tobacco plants that contained 1 kbp of the 5'flanking region of prxC2 fused to the GUS gene. GUS activitywas diminished when deletion from the 5' end extended as faras the CAAT box. No significant organ-specific expression ofGUS was observed with any such deletion. (Received April 15, 1992; Accepted September 11, 1992)     

The Promoter of a Pine Photosynthetic Gene Allows Expression of a {beta}-Glucuronidase Reporter Gene in Transgenic Rice Plants in a Light-Independent but Tissue-Specific Manner

In angiosperms, the expression of the cab gene that encodesthe chlorophyll a/b-binding protein of PSII is light-regulated.However, the pine cab gene is expressed in a light-independentbut cell-type-specific manner. In the present study, the cab-6promoter (1.7 kbp) from pine was fused to a -glucuronidase (GUS)reporter gene and the chimeric gene was introduced into riceprotoplasts by electroporation. The GUS expression was studiedin the resultant transgenic rice plants. Expression of GUS ata substantial level was confirmed in primary leaves of dark-germinatedrice seedlings, and no obvious effect of light on the GUS activitywas observed. The expression of GUS was restricted to photosynthetictissues. The pine cab-6 promoter is, thus, sufficient for inductionof light-independent but cell-type-specific expression in cellsof a monocot, as is the case in the original pine cells. (Received December 17, 1993; Accepted April 22, 1994)     

The Mode of Expression and Promoter Analysis of the arcA Gene, an Auxin-Regulated Gene in Tobacco BY-2 Cells

The arcA, a member of the G protein rß-subunit family,was isolated from tobacco BY-2 cells as an auxin-responsivegene. Characterization of arcA, which should help to elucidatethe function of the gene product in the plant cells, was performedwith emphasis on the mode of expression and the analysis ofits promoter. Accumulation of the arcA message was detectedonly after treatments with auxins and not after treatments withother phytohormones or CdCl₂, implying that responsiveness ofarcA was exclusive to auxin. The putative arcA promoter regionwas fused to a reporter gene for rß-glucuronidase(GUS), and transient expression was analyzed in tobacco BY-2cells. Two series of arcA promoter/GUS chimeric genes were constructed.One consisted of a set of 5' nested deletions of the arcA promoterconnected to the gene for GUS and the other consisted of a varietyof the arcA promoter fragments fused to a minimal promoter-GUSconstruct. The results indicated that the promoter sequencecovering four sets of direct repeats (– 562 to –167)was necessary for the sufficient response of arcA promoter toauxin in BY-2 cells. Moreover, irrespective of auxin treatment,elevated activity of GUS driven by this promoter fragment wasdetected, a result that implies that this region behaves anenhancer in BY-2 cells. (Received September 30, 1995; Accepted March 1, 1996)     

水稻rbcS启动子控制的外源基因在转基因水稻中的特异性表达

为将不同启动子用于转基因水稻的研究,从武运粳8号水稻中克隆了Rubisco小亚基基因(rbcS)的5'上游调控区,构建了由rbcS启动子引导的GUS融合基因,并经农杆菌介导导入到水稻中.对转基因水稻植株中GUS活性的定性与定量测定结果表明,rbcS启动子可驱动GUS报告基因在转基因水稻植株叶片和叶鞘内的叶肉细胞中特异性高效表达,而在茎、根和种子等器官中不表达或表达活性极弱,表现出明显的组织与细胞特异性.结果还表明,光诱导处理可明显提高rbcS启动子启动的外源基因的表达量.     

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。     

Resistance to Active Oxygen Toxicity of Transgenic Nicotiana tabacum that Expresses the Gene for Glutathione Reductase from Escherichia coli

A chimeric gene consisting of a gene from Escherichia coli thatencodes glutathione reductase (GR), the 35S promoter of cauliflowermosaic virus and the terminator sequences of the gene for nopalinesynthase, was introduced into tobacco (Nicotiana tabacum SRI)cells via a Ti plasmid vector. Expression of the bacterial genein transformed plants and their descendants was confirmed byimmunochemical analysis. GR activity in leaf extracts variedamong transgenic plants, ranging from about 1.0 to 3.5 timesthe control level. These transgenic plants exhibited lower susceptibilityto paraquat than control plants in terms of the extent of visiblefoliar damage, a result that suggests that GR may play an importantrole in the detoxification of active oxygen in the cytoplasmicmatrix of plant cells. However, the transgenic plants were nomore resistant to ozone than were the controls, both in termsof the extent of visible foliar damage and with respect to photosyntheticactivity. (Received January 28, 1991; Accepted May 9, 1991)