Nonlegume hemoglobin genes retain organ-specific expression in heterologous transgenic plants.

Hemoglobin genes from the nitrogen-fixing nonlegume Parasponia andersonii and the related non-nitrogen-fixing nonlegume Trema tomentosa have been isolated [Landsmann et al. (1986). Nature 324, 166-168; Bogusz et al. (1988). Nature 331, 178-180]. The promoters of these genes have been linked to a beta-glucuronidase reporter gene and introduced into both the nonlegume Nicotiana tabacum and the legume Lotus corniculatus. Both promoters directed root-specific expression in transgenic tobacco. When transgenic Lotus plants were nodulated by Rhizobium loti, both promoter constructs showed a high level of nodule-specific expression confined to the central bacteroid-containing portion of the nodule corresponding to the expression seen for the endogenous Lotus leghemoglobin gene. The T. tomentosa promoter was also expressed at a low level in the vascular tissue of the Lotus roots. The hemoglobin promoters from both nonlegumes, including the non-nodulating species, must contain conserved cis-acting DNA signals that are responsible for nodule-specific expression in legumes. We have identified sequence motifs postulated previously as the nodule-specific regulatory elements of the soybean leghemoglobin genes [Stougaard et al. (1987). EMBO J. 6, 3565-3569].     

Radiation as a tool to remove selective marker genes from transgenic soybean plants

The present study evaluated the use of γ-radiation to physically remove selective marker genes previously introduced into the soybean genome. Homozygous seeds from a transgenic soybean line carrying the gus and ahas transgenes were irradiated with γ-rays. Six plants presenting a deleted gus gene were analyzed by Southern blot to confirm removal of both ahas and gus genes. Line 1A presented an absence of the gus gene cassette and presence of the ahas gene cassette.     

Improvement of protein quality in transgenic soybean plants

Glycinin is one of the abundant storage proteins in soybean seeds. A modified Gy1 (A1aB1b) proglycinin gene with a synthetic DNA encoding four continuous methionines (V3-1) was connected between the hpt gene and the modified green fluorescent protein sGFP(S65T) gene, and a resultant plasmid was introduced into soybean by particle bombardment in order to improve nutritional value of its seeds. After the selection with hygromycin, the efficiency of gene introduction was evaluated. More than 60 % of the regenerated plants tolerant to hygromycin yielded the hpt and V3-1 fragment by polymerase chain reaction (PCR) analysis, and the expression of sGFP was detected in about 50 % of putative transgenic soybeans. Southern hybridization confirmed the presence of transgenes in T0 plants and the transgenic soybeans hybridized with the hpt and V3-1 genes were analyzed showed different banding patterns. Most of the transgenic plants were growing, flowering normally and produced seeds. Analysis of seed obtained from transgenic soybean plants expressing hpt and V3-1 genes showed higher accumulation of glycinin compared with non-transgenic plants. In addition, protein expression in transgenic soybean plants was observed by using 2D-electrophoresis.     

A simple procedure for the expression of genes in transgenic soybean callus tissue

Cotyledons from germinating seeds of the soybean cultivar Peking were inoculated with virulent Agrobacterium tumefaciens strain A281:pZA-7 which carries a wild type Ti plasmid pTiBo542 and a disarmed Ti plasmid (a binary vector)pZA-7 which contains the glucuronidase (uidA) and neomycin phosphotransferase (nptII) genes. Tumors were produced on all inoculated explants and 82% of these tumor lines were cotransformed by the nptII gene from the binary vector pZA-7 as shown by PCR analysis (18 of 22 lines tested). Eleven of these 18 lines were also resistant to kanamycin. Eleven lines expressed -glucuronidase activity (GUS), six of which were also kanamycin resistant. Since there is a high rate of coexpression of genes carried by the binary vector, this system provides a simple and rapid method for the expression of genes of interest in transformed soybean tissue which has been used successfully to test constructs designed for soybean transformation.     

Phenotypic manifestation of gene expression encoding xyloglucanase from Penicillium canescens in transgenic aspen plants

Plant xyloglucans play an important role in the processes of cell wall extension, determine their mechanical properties, thus affecting growth and morphology of individual cells and whole organs. Being one of the main components of hemicellulose, xyloglucans play a particular physiological role in woody plants. To study xyloglucan physiological role, transgenic aspen (Populus tremula L.) plants with a recombinant sp-Xeg gene from the fungus Penicillium canescens were produced. Constitutive expression of this gene in the heterologous surrounding was confirmed by RT-PCR method. The analysis of protein extracts from the leaves of greenhouse-grown plants and microshoots grown in vitro showed activation of xylogluconase in transgenic lines. The strongest activation (1.6-fold) was observed in the leaf extracts (clone PtXVXeg1b) and in vitro microshoots (clone PtXVXeg1c). In transgenic plants, the relative content of pentosans in the wood was declined. In control plants (Pt genotype), it was equal to 148 mg/g dry wt, whereas in tested clones (PtXVXeg1a, PtXVXeg1b, and PtXVXeg1c), it varied from 100 to 140 mg/g dry wt. The strongest decrease (by 31%) in the content of pentosans was observed for the line PtXVXeg1c; the content was equal to 102.1 ± 1.5 mg/g dry wt. A comparative analysis of leaf morphology revealed an increase in the length of petiole and a decrease in the length of the main vein in transgenic lines. In control plants, the ratio of the petiole length to the length of the main vein was equal to 0.49, whereas in transgenic plants, it varied from 0.51 to 0.66. A significant increase of this index was observed in 12 from 14 transgenic lines.     

Cell type specific expression of a CaMV 35S-GUS gene in transgenic soybean plants

A number of independently derived transgenic soybean plants expressing a chimeric β-glucuronidase (GUS) gene under the control of the 355 CaMV promoter and a nopaline synthase polyadenylation signal were recovered using direct DNA transfer via electric discharge particle acceleration. Expression of GUS in R, plants was localized using thin tissue sections. Many tissue types expressed GUS at various levels. Pericycle cells in root, parenchyma cells in xylem, and phloem tissues of stem and leaf had high levels of enzyme activity. Procambium, phloem, and cortex cells in root, vascular cambium cells in stem, and the majority of cortex cells in leaf midrib, expressed low or no GUS activity. Intermediate levels of GUS activity were detected in leaf mesophyll cells, certain ground tissue cells in stem and leaf midrib, and in trichome and epidermal guard cells. Thus, we conclude that the 35S CaMV promoter is cell-type specific and is developmentally regulated in soybean.     

转基因植物中标记基因的消除

随着转基因植物的商业化,植物遗传转化技术将为农业生产带来一场新的革命,新的基因转化程序要求转基因为单拷贝,不带有标记基因,并在不同的转化体中表达一致,稳定遗传,本文讨论了转基因植物中有关标记基因及其安全性和标记基因消除的方法等问题。     

Chromatin structure of transferred genes in transgenic plants

The chromatin structure of foreign genes in transgenic tobacco plants was investigated by digestion of nuclei with DNase I and micrococcal nuclease, respectively, followed by restriction and Southern analysis of the digestion products. The results were compared to the differential expression of the different transgenes. Two model systems were used: plants harbouring vector DNA derived from the disarmed vector pGV 3850 and plants harbouring the light-regulated and organ-specifically expressed potato ST-LS1 gene and the cotransferred ncpaline synthase (nos) reporter gene. Our results show that transferred genes are located in DNase l-sensitive domains in all transformants. Slight variations of DNase l-sensitivity of the transferred ST-LS1 constructs in different transformants neither reflected the between-transformant variability of expression nor the organ-specific activity of the transgenes. A deletion event was found responsible for silencing the ST-LS1 gene but not the nos gene in one of the transformants. Whereas no DNase l-hypersensitive sites were found within the 3850-T-DNA and the ST-LS1 gene, one prominent site was mapped to the nos promoter within the ST-LS1 construct in all transformants. Digestion of chromatin harbouring 3850-T-DNA with micrococcal nuclease resulted in a blurred nucleosomal pattern as compared to nucleolar and bulk chromatin, the extent of blurring being independent of the expression of transferred genes. The present results favour the “permissive domain” hypothesis which capitalizes on the chromatin surrounding the integration site as the determining factor for the chromatin structure of incoming alien genes. However, between-transformant variability of expression is not reflected by differential sensitivity to DNase I. Hence, other factors than chromatin structure must be involved in creating “position effects”.     

Expression of foreign genes in transgenic yellow-poplar plants

Cells of yellow-poplar (Liriodendron tulipifera L.) were transformed by direct gene transfer and regenerated into plants by somatic embryogenesis. Plasmid DNA bearing marker genes encoding β-glucuronidase (GUS) and neomycin phosphotransferase (NPT II) were introduced by microprojectile bombardment into single cells and small cell clusters isolated from embryogenic suspension cultures. The number of full-length copies of the GUS gene in independently transformed callus lines ranged from approximately 3 to 30. An enzyme-linked immunosorbent assay for NPT II and a fluorometric assay for GUS showed that the expression of both enzymes varied by less than fourfold among callus lines. A histochemical assay for GUS activity revealed a heterogeneous pattern of staining with the substrate 5-bromo-4-chloro-3-indoyl-β-d-glucuronic acid in some transformed cell cultures. However, cell clusters reacting positively (blue) or negatively (white) with 5-bromo-4-chloro-3-indoyl-β-d-glucuronic acid demonstrated both GUS activity and NPT II expression in quantitative assays. Somatic embryos induced from transformed cell cultures were found to be uniformly GUS positive by histochemical analysis. All transgenic plants sampled expressed the two marker genes in both root and shoot tissues. GUS activity was found to be higher in leaves than roots by fluorometric and histochemical assays. Conversely, roots expressed higher levels of NPT II than leaves.     

Manipulation of hormone biosynthetic genes in transgenic plants

Modification of plant hormone biosynthesis through the introduction of bacterial genes is a natural form of genetic engineering, which has been exploited in numerous studies on hormone function. Recently, biosynthetic pathways have been largely elucidated for most of the plant hormone classes, and genes encoding many of the enzymes have been cloned. These advances offer new opportunities to manipulate hormone content in order to study their mode of action and the regulation of their biosynthesis. Furthermore, this technology is providing the means to introduce agriculturally useful traits into crops.