玉米19kD醇溶贮藏蛋白基因启动子种子特异性表达控制区段的分析

为研究玉米（Ｚｅａｍａｙｓ　Ｌ．）１９ｋＤ醇溶贮藏蛋白（ｚｅｉｎ）基因启动子种子特异性表达的控制区段,将全长６９４ｂｐ的启动子进行５’端缺失,共得到６个缺失突变体,长度分别为４８８ｂｐ、３７８ｂｐ、３０２ｂｐ、１５２ｂｐ、１２４ｂｐ和８５ｂｐ。将６个片段分别与报告基因ｇｕｓ连接构建成表达载体ｐＤＧＢ系列,经土壤农杆菌（Ａｇｒｏｂａｃｔｅｒｉｕｍ）介导转化,引入烟草。ＧＵＳ活性检测证明,４８８ｂｐ启动子片段能促使ｇｕｓ基因在种子中特异表达。３７８ｂｐ、３０２ｂｐ、１５２ｂｐ和１２４ｂｐ片段启动子引导的ｇｕｓ基因在烟草根、叶柄、种子中均可表达。     

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.     

Isolation and characterization of <Emphasis Type="Italic">Brittle2</Emphasis> promoter from <Emphasis Type="Italic">Zea Mays</Emphasis> and its comparison with <Emphasis Type="Italic">Ze19</Emphasis> promoter in transgenic tobacco plants

ADP-glucose pyrophosphorylase (AGPase) represents a key regulatory step in starch synthesis. A 0.9 kb of 5′ flanking region preceding Brittle2 gene, encoding the small subunit of maize endosperm AGPase, was cloned from maize genome and its expression pattern was studied via the expression of β-glucuronidase (GUS) gene in transgenic tobacco. Analysis of GUS activities showed that the 0.9 kb fragment flanking Brittle2 gene was sufficient for driving the seed-preferred expression of the reporter gene. The activity of the 0.9 kb 5′ flanking fragment was compared with that of the tandem promoter region from a zein gene (zE19, encoding a maize 19 kDa zein protein). The results indicated that both promoters were seed-preferred in a dicotyledonous system as tobacco and the activity of zE19 promoter was three to fourfold higher than that of the 0.9 kb fragment flanking Brittle2 gene in transgenic tobacco seeds. At the same time, zE19-driven GUS gene expressed earlier than Brittle2 promoter during seed development. Histochemical location of GUS activity indicated that both promoters showed high expression in embryos, which is different from similar promoters tested in maize.     

Characterization of a barley gene coding for an α-amylase inhibitor subunit (CMd protein) and analysis of its promoter in transgenic tobacco plants and in maize kernels by microprojectile bombardment

A gene coding for a barley CMd protein was isolated from a genomic library using a cDNA probe encoding the wheat CM3 protein. Promoter sequence analysis reveals motifs found in genes specifically expressed in endosperm and aleurone cells, as well as TATA and other putative functional boxes. 720 bp of the Hv85.1 CMd protein gene promoter, when fused to a gus coding region, were unable to direct GUS activity in the seeds of transgenic tobacco plants. In contrast, the same construction delivered into immature maize kernels by microprojectile bombardment was able to direct expression of GUS in the outermost cell layers of maize endosperm in both a tissue-specific and a developmentally determined manner.     

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.     

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.     

玉米醇溶贮藏蛋白基因启动子PCR扩增及其驱动GUS基因在转基因烟草种子中的表达

以玉米(Zea mays L.)黄化苗为材料,利用PCR技术扩增了玉米19kDa醇溶贮藏蛋白基因(zein)起始密码子上游启动子片段,序列分析结果表明,克隆的-1～-694片段具有19kDa zein启动子特点,与同一家族中其它基因的对应区段同源性达90％以上。将此启动子插入pPKGT的GUS基因及NOS终止子上游构成表达载体。经农杆菌转化烟草(Nicotiana tabaccum Var.samsum),得到了转化植株。转化的烟草的PCR扩增及Southern杂交证明目的片段已整合到烟草基因组中。转基因植株的GUS活性检测表明,在叶、根中无GUS活性,GUS活性只存在于种子中。转基因植株烟草种子经冷冻切片,GUS底物Xgluc活体组织染色证明GUS活性只存在一层介于种子胚乳与种皮之间的细胞中。     

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.     

Molecular and biochemical characterization of three aromatic polyketide synthase genes from Rubus idaeus

To play an essential role in C₄ photosynthesis, the maize C₄ phosphoenolpyruvate carboxylase gene (PPCZm1) acquired many new expression features, such as leaf specificity, mesophyll specificity, light inducibility and high activity, that distinguish the unique C₄ PPC from numerous non-C₄ PPC genes in maize. We present here the first investigation of the developmental, cell-specific, light and metabolic regulation of the homologous C₄ PPCZm1 promoter in stable transgenic maize plants. We demonstrate that the 1.7 kb of the 5-flanking region of the PPCZm1 gene is sufficient to direct the C₄-specific expression patterns of -glucuronidase (GUS) activity, as a reporter, in stable transformed maize plants. In light-grown shoots, GUS expression was strongest in all developing and mature mesophyll cells in the leaf, collar and sheath. GUS activity was also detected in mesophyll cells in the outer husks of ear shoots and in the outer glumes of staminate spikelets. We did not observe histological localization of GUS activity in light- or dark-grown callus, roots, silk, developing or mature kernels, the shoot apex, prop roots, or pollen. In addition, we used the stable expressing transformants to conduct and quantify physiological induction studies. Our results indicate that the expression of the C₄ PPCZm1-GUS fusion gene is mesophyll-specific and influenced by development, light, glucose, acetate and chloroplast biogenesis in transgenic maize plants. These studies suggest that the adoption of DNA regulatory elements for C₄-specific gene expression is a crucial step in C₄ gene evolution.