Interspecies compatibility of NAS1 gene promoters.

Nicotianamine and nicotianamine synthase (NAS) play key roles in iron nutrition in all higher plants. However, the mechanism underlying the regulation of NAS expression differs among plant species. Sequences homologous to iron deficiency-responsive elements (IDEs), i.e., cis-acting elements, are found on the promoters of these genes. We aimed to verify the interspecies compatibility of the Fe-deficiency response of NAS1 genes and understand the universal mechanisms that regulate their expression patterns in higher plants. Therefore, we introduced the graminaceous (Hordeum vulgare L. and Oryza sativa L.) NAS1 promoter::GUS into dicots (Nicotiana tabacum L. and Arabidopsis thaliana L.). Fe deficiency induced HvNAS1 expression in the shoots and roots when introduced into rice. HvNAS1 promoter::GUS and OsNAS1 promoter::GUS induced strong expression of GUS under Fe-deficient conditions in transformed tobacco. In contrast, these promoters only definitely functioned in Arabidopsis transformants. These results suggest that some Fe nutrition-related trans-factors are not compatible between graminaceous plants and Arabidopsis. HvNAS1 promoter::GUS induced GUS activity only in the roots of transformed tobacco under Fe-deficient conditions. On the other hand, OsNAS1 promoter::GUS induced GUS activity in both the roots and shoots of transformed tobacco under conditions of Fe deficiency. In tobacco transformants, the induction of GUS activity was induced earlier in the shoots than roots. These results suggest that the HvNAS1 and OsNAS1 promoters are compatible with Fe-acquisition-related trans-factors in the roots of tobacco and that the OsNAS1 promoter is also compatible with some shoot-specific Fe deficiency-related trans-factors in tobacco.     

Strong expression of the rice catalase gene CatB promoter in protoplasts and roots of both a monocot and dicots.

The rice (Oryza sativa L.) catalase (EC 1.11.1.6) gene CatB is expressed in roots and cultured cells. We examined the promoter activity of its 5'-flanking region in a monocot and in two dicots. Transient expression assays in rice Oc and tobacco BY-2 suspension cell protoplasts showed that CatB's 5'-flanking DNA fragments (nucleotides -1066 to +298) had about 20 and 3-4 times as much promoter activity, respectively, as the CaMV 35S promoter. Serial deletion analyses of the CatB promoter region revealed that the shortest fragment (-56 to +298) still had about 10 times as much promoter activity as the CaMV 35S promoter in rice protoplasts. In tobacco protoplasts, the activity of the fragment (-56 to +298) was about half of the CaMV 35S promoter. Transgenic rice and Arabidopsis plants carrying GUS genes driven by the 5'-truncated CatB promoters were generated and their GUS activity was examined. The region ranging from -329 to +298 showed preferential expression in the roots of rice and Arabidopsis, and in the shoot apical meristems of Arabidopsis. In situ hybridization revealed that CatB was highly expressed in branch root primordia and root apices of rice. Fusion of the GUS gene to the region (-329 to +298) conferred strong expression in these same areas, indicating that the presence of this region was sufficient to express CatB specifically in the roots. There may be new regulatory element(s) in this region, because it contained no previously known cis-regulatory elements specific for gene expression in roots.     

Expression of iron-acquisition-related genes in iron-deficient rice is co-ordinately induced by partially conserved iron-deficiency-responsive elements

Rice plants (Oryza sativa L.) utilize the iron chelators known as mugineic acid family phytosiderophores (MAs) to acquire iron from the rhizosphere. Synthesis of MAs and uptake of MA-chelated iron are strongly induced under conditions of iron deficiency. Microarray analysis was used to characterize the expression profile of rice in response to iron deficiency at the genomic level. mRNA extracted from iron-deficient or iron-sufficient rice roots or leaves was hybridized to a rice array containing 8987 cDNA clones. An induction ratio of greater than 2.0 in roots was observed for 57 genes, many of which are involved in iron-uptake mechanisms, including every identified or predicted step in the methionine cycle and the biosynthesis of MAs from methionine. Northern analysis confirmed that the expression of genes encoding every step in the methionine cycle is thoroughly induced by iron deficiency in roots, and almost thoroughly induced in leaves. A promoter search revealed that the iron-deficiency-induced genes related to iron uptake possessed sequences homologous to the iron-deficiency-responsive cis-acting elements IDE1 and IDE2 in their promoter regions, at a higher rate than that showing no induction under Fe deficiency. These results suggest that rice genes involved in iron acquisition are co-ordinately regulated by conserved mechanisms in response to iron deficiency, in which IDE-mediated regulation plays a significant role.     

Pollen-specific gene expression in transgenic plants: coordinate regulation of two different tomato gene promoters during microsporogenesis

To investigate the regulation of gene expression during male gametophyte development, we analyzed the promoter activity of two different genes (LAT52 and LAT59) from tomato, isolated on the basis of their anther-specific expression. In transgenic tomato, tobacco and Arabidopsis plants containing the LAT52 promoter region fused to the beta-glucuronidase (GUS) gene, GUS activity was restricted to pollen. Transgenic tomato, tobacco and Arabidopsis plants containing the LAT59 promoter region fused to GUS also showed very high levels of GUS activity in pollen. However, low levels of expression of the LAT59 promoter construct were also detected in seeds and roots. With both constructs, the appearance of GUS activity in developing anthers was correlated with the onset of microspore mitosis and increased progressively until anthesis (pollen shed). Our results demonstrate co-ordinate regulation of the LAT52 and LAT59 promoters in developing microspores and suggest that the mechanisms that regulate pollen-specific gene expression are evolutionarily conserved.     

拟南芥冷诱导型启动子CBF 3的克隆及活性检测

目的：构建冷诱导型启动子CBF3基因的植物表达载体,并将其转入烟草。方法：以拟南芥基因组DNA为模板,通过特异PCR扩增,克隆冷诱导表达启动子CBF3（C-repeat binding factor）。用CBF3启动子替换pBI121载体上的35S启动子构建新的载体pBC-GUS,通过农杆菌介导的叶盘法转化烟草。结果：获得了转基因烟草,转基因烟草的GUS组织化学染色及PCR分析结果表明,在低温诱导下,CBF3启动子可增强GUS基因表达。结论：CBF3启动子可应用于植物抗冷基因工程研究。     

Rice Triosephosphate Isomerase Gene 5[prime] Sequence Directs [beta]-Glucuronidase Activity in Transgenic Tobacco but Requires an Intron for Expression in Rice

In rice (Oryza sativa L.), cytosolic triosephosphate isomerase (TPI) is encoded by a single gene. TPI catalyzes a vital step in glycolysis, and RNA blots showed that the tpi gene is expressed in all vegetative tissues (root, culm, and leaves) and in rice suspension cells. No effect of light on expression was detected, but submergence of rice seedlings resulted in elevated levels of TPI mRNA in roots and culms. The 2767-bp 5[prime] upstream sequence of the tpi gene was fused translationally with the [beta]-glucuronidase (gusA) gene, and the resulting construct, TPI-GUS, was found to express constitutive, high levels of GUS activity in transgenic tobacco (Nicotiana tabacum) plants. However, the same construct yielded no GUS activity in stably transformed rice plants, and RNA blots showed that no GUS mRNA could be detected even though stable integration of functional copies of the construct was confirmed by Southern blot and genomic polymerase chain reaction analyses. Transient assays using particle bombardment yielded high levels of GUS expression from the TPI-GUS construct in tobacco leaves, but essentially no expression in rice, barley, or maize leaves. When the first intron of the tpi gene was included in the construct (TPI-int1-GUS), transient GUS activity was routinely obtained in rice leaves, revealing that the first intron of the rice tpi gene is crucial for its expression in rice. TPI-int1-GUS also directed transient GUS expression in maize and barley leaves, but little or no activity was obtained from this construct in tobacco, tomato, or soybean leaves. These results with the rice tpi promoter are in accordance with mounting evidence that differences in gene expression exist between monocots and dicots.     

The expression of a barley HvNAS1 nicotianamine synthase gene promoter-gus fusion gene in transgenic tobacco is induced by Fe-deficiency in roots

Nicotianamine (NA) is a precursor for mugineic acid-family phytosiderophores, which are a critical component of the Fe aquisition process in graminaceous plants. In addition, nicotianamine synthase (NAS) is strongly induced in these plants by Fe deficiency. NA is essential for Fe metabolism also in dicots, but NAS is not induced by Fe deficiency. We introduced a barley HvNAS1 promoter-gus fusion gene into tobacco. GUS activity was induced in the roots of these plants by Fe deficiency, and was constitutively expressed at a low level in their leaves.     

The Expression of a Barley HνNAS1 Nicotianamine Synthase Gene Promoter-gus Fusion Gene in Transgenic Tobacco is Induced by Fe-deficiency in Roots

Nicotianamine (NA) is a precursor for mugineic acid-family phytosiderophores, which are a critical component of the Fe aquisition process in graminaceous plants. In addition, nicotianamine synthase (NAS) is strongly induced in these plants by Fe deficiency. NA is essential for Fe metabolism also in dicots, but NAS is not induced by Fe deficiency. We introduced a barley HνNAS1 promoter-gus fusion gene into tobacco. GUS activity was induced in the roots of these plants by Fe deficiency, and was constitutively expressed at a low level in their leaves.     

The tobacco Cel7 gene promoter is auxin-responsive and locally induced in nematode feeding sites of heterologous plants

Emerging evidence suggests that plant cell-wall-modifying enzymes induced by root-parasitic nematodes play important roles in feeding cell formation. We previously identified a tobacco endo-β-1,4-glucanase (cellulase) gene, NtCel7 , that was strongly induced in both root-knot and cyst nematode feeding cells. To characterize further the developmental and nematode-responsive regulation of NtCel7 , we isolated the NtCel7 promoter and analysed its expression over a time course of nematode infection and in response to auxin, gibberellin, ethylene and sucrose in soybean and tomato hairy roots and in Arabidopsis containing the NtCel7 promoter fused to the β-glucuronidase (GUS) reporter gene. Histochemical analyses of transgenic plant materials revealed that the NtCel7 promoter exhibited a unique organ-specific expression pattern during plant development suggestive of important roles for NtCel7 in both vegetative and reproductive growth. In all plant species tested, strong GUS expression was observed in root tips and lateral root primordia of uninfected roots with weaker expression in the root vasculature. Further analyses of transgenic Arabidopsis plants revealed expression in shoot and root meristems and the vasculature of most organs during plant development. We also determined that the NtCel7 promoter was induced by auxin, but not gibberellin, ethylene or sucrose. Moreover, strong GUS activity was observed in both cyst and root-knot nematode-induced feeding sites in transgenic roots of soybean, tomato and Arabidopsis. The conserved developmental and nematode-responsive expression of the NtCel7 promoter in heterologous plants indicates that motifs of this regulatory element play a fundamental role in regulating NtCel7 gene expression within nematode feeding sites and that this regulation may be mediated by auxin.     

Analysis of the Maize 19 kD Zein Gene Promoter Fragment Driving Seed specific Expression

A deletion works of a maize 19 kD zein gene promoter in the 5'end was performed and six promoter fragments of different length were obtained. A series of expression vectors was constructed and then transferred into tobacco ( Nicotiarta tabacum L. ) plants. GUS activity assays indicated that the expression of 488 bp promoter was tissue-specific, for which GUS was active only in transgenic tobacco seeds. The other four fragments containing 378 bp,302 bp,152 bp and 124 bp also have the activity of promoter. They could drive gus gene expressed not only in seeds but also in roots and petioles.     

Tissue-specific,light-regulated and plastid-regulated expression of the single-copy nuclear gene encoding the chloroplast Rieske FeS protein of Arabidopsis thaliana

The single-copy PetC gene encoding the chloroplast Rieske FeS protein of Arabidopsis thaliana consists of five exons interrupted by four introns and encodes a protein of 229 amino acid residues with extensive sequence similarity to the chloroplast Rieske proteins of other higher plants. The N-terminal 50 amino acid residues constitute a presequence for targeting to the chloroplast and the remaining 179 amino acid residues make up the mature protein. Three of the introns are in identical positions in the PetC gene of Chlamydomonas reinhardtii, suggesting that they are of ancient origin. RNA-blot hybridisation showed that the gene was expressed in shoots, but not roots, and was light regulated and repressed by sucrose. The expression of chimeric genes consisting of PetC promoter fragments fused to the beta-glucuronidase (GUS) reporter gene was examined in A. thaliana and tobacco. In A. thaliana, GUS activity was detected in leaves, stems, flowers and siliques, but not in roots, and showed a strong correlation with the presence of chloroplasts. In transgenic tobacco, low levels of GUS activity were also detected in light-exposed roots. GUS activity in transgenic tobacco seedlings was light regulated and was decreased by norflurazon in the light suggesting regulation of PetC expression by plastid signals.