Molecular characterization of the fate of transgenes in transformed wheat (Triticum aestivum L.)

Molecular analysis of the transgenes bar and gus was carried out over successive generations in six independent transgenic lines of wheat, until the plants attained homozygosity. Data on expression and integration of the transgenes is presented. Five of the lines were found to be stably transformed, duly transferring the transgenes to the next generation. The copy number of the transgenes varied from one to five in the different lines. One line was unstable, first losing expression of and then eliminating both the transgenes in R3 plants. Although the gus gene was detected in all the lines, GUS expression had been lost in R2 plants of all but one line. Rearrangement of transgene sequences was observed, but it had no effect on gene expression. All the stable lines were found to segregate for transgene activity in a Mendelian fashion.     

Variation in GUS activity in vegetatively propagated Hevea brasiliensis transgenic plants

Hevea brasiliensis transgenic plants are regenerated from transgenic callus lines by somatic embryogenesis. Somatic embryogenesis is not yet available for commercial propagation of Hevea clones, which requires conventional grafting of buds on rootstock seedlings (budding). The stability of transgene expression in budded plants is therefore necessary for further development of genetic engineering in rubber trees. Transgene expression was assessed by fluorimetric beta-glucuronidase (GUS) activity in fully developed leaves of in vitro plants from transgenic lines and their sub-lines obtained by budding. A large variation in GUS activity was found in self-rooted in vitro plants of five transgenic lines, and the absence of activity in one line suggested transgene silencing. Beyond confirming transmissibility of the reporter gene by budding and long-term expression, a quantification of GUS activity revealed that greater variability existed in budded plants compared to self-rooted mother in vitro plants for three transgenic lines. Although somatic embryogenesis provided more stable GUS activity, budding remained an efficient way of propagating transgenic plants but transgene expression in budded plants should be verified for functional analysis and further development.     

Lox-dependent gene expression in transgenic plants obtained via Agrobacterium-mediated transformation

Lox sites of the Cre/lox recombination system from bacteriophage P1 were analyzed for their ability to affect on transgene expression when inserted upstream from a gene coding sequence adjacent to the right border (RB) of T-DNA. Wild and mutated types of lox sites were tested for their effect upon bar gene expression in plants obtained via Agrobacterium-mediated and biolistic transformation methods. Lox-mediated expression of bar gene, recognized by resistance of transgenic plants to PPT, occurred only in plants obtained via Agrobacterium-mediated transformation. RT-PCR analysis confirms that PPT-resistant phenotype of transgenic plants obtained via Agrobacterium-mediated transformation was caused by activation of bar gene. The plasmid with promoterless gus gene together with the lox site adjacent to the RB was constructed and transferred to Nicotiana tabacum as well. Transgenic plants exhibited GUS activity and expression of gus gene was detected in plant leaves. Expression of bar gene from the vectors containing lox site near RB allowed recovery of numerous PPT-resistant transformants of such important crops as Beta vulgaris, Brassica napus, Lactuca sativa and Solanum tuberosum. Our results demonstrate that the lox site sequence adjacent to the RB can be used to control bar gene expression in transgenic plants.     

Morphological Description of Transgenic Soybean Chimeras Created by the Delivery, Integration and Expression of Foreign DNA Using Electric Discharge Particle Acceleration

Transgenic soybean (Glycine max L.) plants derived from electricdischarge particle acceleration experiments exhibited varyingdegrees of chimerism which was followed by the expression ofthe introduced ß-glucuronidase (gus) gene. Degreesof chimerism in transgenic plants were established by determiningexpression of the gus gene observed as blue spots, streaks orsectors in stem and leaf tissues in in vitro grown plantletsand greenhouse plants. Clonal plants were also obtained. Presenceof the gene was confirmed by Southern blot analysis. These studiespermitted the reconstruction of a partial picture for the developmentof the soybean plant. Glycine max L. cv. Williams 82, soybean, transformation, ß-glucuronidase, chimeric plant phenotypes, development     

The elimination of a selectable marker gene in the doubled haploid progeny of co-transformed barley plants

Following the production of transgenic plants, the selectable marker gene(s) used in the process are redundant, and their retention may be undesirable. They can be removed by exploiting segregation among the progeny of co-transformants carrying both the selectable marker gene and the effector transgene. Here we show that the doubled haploid technology widely used in conventional barley breeding programmes represents a useful means of fixing a transgene, while simultaneously removing the unwanted selectable marker gene. Primary barley co-transformants involving hpt::gfp (the selectable marker) and gus (a model transgene of interest) were produced via Agrobacterium-mediated gene transfer to immature embryos using two respective T-DNAs. These plants were then subjected to embryogenic pollen culture to separate independently integrated transgenes in doubled haploid progeny. A comparison between 14 combinations, involving two Agrobacterium strains carrying various plasmids, revealed that the highest rate of independent co-transformation was achieved when a single Agrobacterium clone carried two binary vectors. Using this principle along with Agrobacterium strain LBA4404, selectable marker-free, gus homozygous lines were eventually obtained from 1.5 per 100 immature embryos inoculated. Compared to the segregation of uncoupled T-DNAs in conventionally produced progeny, the incorporation of haploid technology improves the time and resource efficiency of producing true-breeding, selectable marker-free transgenic barley.     

Genomic stability and long-term transgene expression in poplar

Stable expression of foreign genes over the entire life span of a plant is important for long-lived organisms such as trees. For transgenic forest trees, very little information is available on long-term transgene expression and genomic stability. Independent transgenic lines obtained directly after transformation are initially screened in respect to T-DNA integration and transgene expression. However, very little consideration has been given to long-term transgene stability in long-lived forest trees. We have investigated possible genome wide changes following T-DNA integration as well as long-term stability of transgene expression in different transgenic lines of hybrid aspen (Populus tremula × Populus tremuloides) that are up to 19 years old. For studies on possible genome wide changes following T-DNA integration, four different independent rolC-transgenic lines were subjected to an extensive AFLP study and compared to the non-transgenic control line. Only minor genomic changes following T-DNA integration could be detected. To study long-term transgene expression, six different independent rolC-transgenic lines produced in 1993 and since that time have been kept continuously under in vitro conditions. In addition, 18 transgenic plants belonging to eight independent rolC-transgenic lines transferred to glasshouse between 1994 and 2004 were chosen to determine the presence and expression of the rolC gene. In all transgenic lines examined, the rolC gene could successfully be amplified by PCR tests. Both, the 19 years old tissue cultures and the up to 18 years old glasshouse-grown trees revealed expression of the rolC transgene, as demonstrated by the rolC-phenotype and/or northern blot experiments confirming long-term transgene expression.     

Visual screening of microspore-derived transgenic barley (Hordeum vulgare L.) with green-fluorescent protein

The green-fluorescent protein (GFP) gene from the Pacific Northwest jellyfish, Aequorea victoria, was used as a screenable marker in the production of transgenic barley plants. Isolated barley microspore culture was biolistically transformed with two synthetic forms of GFP, sgfp and pgfp. Thirty-seven fluorescing multicellular structures were isolated using epifluorescent microscopy. Sixteen structures developed shoots, but only five regenerated into green plants. Three events had been co-bombarded with #-glucuronidase (gus) and assayed positive for gus expression in the leaves, and all five events were positive for gfp expression. The expected transgene band size was PCR-amplified from all five plants, and Southern blots performed on three plants revealed unique patterns of gfp transgene integration. Fluorescent in situ hybridization also revealed the transgenic status and hemizygous nature of all the events. GFP-based visual screening provides a viable alternative method to chemical selection of transgenic plants from barley microspore culture.     

Stable germ line transformation of a leafy vegetable crop amaranth (Amaranthus tricolor L.) mediated by Agrobacterium tumefaciens

We have optimized a procedure for genetic transformation of a major leafy vegetable crop, Amaranthus tricolor L., using epicotyl explant co-cultivation with Agrobacterium tumefaciens. Two disarmed A. tumefaciens strains EHA 105 and LBA 4404, both carrying the binary plasmid p35SGUSINT harboring the neomycin phosphotransferase II gene (nptII) and the β-glucuronidase gene (gus), were evaluated as vector systems. The former displayed a higher transforming efficiency. Several key factors influencing the transformation events were optimized. The highest percentage of transformed shoots (24.24%) was achieved using hand-pricked epicotyl explants, a 10-min infection period, with 100 μM acetosyringone-pretreated Agrobacterium culture corresponding to OD₆₀₀???0.6 and diluted to 10⁹ cells ml^?1, followed by 4 d co-cultivation in the regeneration medium. Putative transformed explants capable of forming shoots were selected on medium supplemented with 75 μg?ml^?1 kanamycin, and transient as well as stable glucuronidase expression was determined by histochemical analysis. From a total of 48 selected shoot lines derived from independent transformation events with epicotyl explants co-cultivated with EHA 105, 32 showed positive PCR amplification for both the nptII and gus genes. Germ line transformation and transgene stability were evident in progeny of primary transformed plants (T₀). Among T₁ seedlings of 12 selected transgenic plant lines, kanamycin-resistant and kanamycin-sensitive seedlings segregated in a ratio typical of the Mendelian monohybrid pattern (3:1) as verified by the chi-square (χ ²) test. Southern hybridization of genomic DNA from kanamycin-resistant T₁ transgenic segregants to an nptII probe substantiated stable integration of the transgene. Neomycin phosphotransferase (NPTII) activity was detected in leaf protein extracts of selected T₁ transgenic plants, thereby confirming stable expression of the nptII gene.     

Stability of β-glucuronidase gene expression in transgenic Tricyrtis hirta plants after two years of cultivation

Transgenic plants of Tricyrtis hirta carrying the intron-containing β-glucuronidase (GUS) gene under the control of the CaMV35S promoter have been cultivated for two years. Four independent transgenic plants produced flowers 1–2 years after acclimatization, and all of them contained one copy of the transgene as indicated by inverse polymerase chain reaction (PCR) analysis. All the four transgenic plants showed stable expression of the gus gene in leaves, stems, roots, tepals, stamens and pistils as indicated by histochemical and fluorometric GUS assays, although differences in the GUS activity were observed among different organs of each transgenic plant. No apparent gus gene silencing was observed in transgenic T. hirta plants even after two years of cultivation.     

Transformation and Characterization of Transgenic Plants of Solanum dulcamara L.--Incidence of Transgene Silencing

A transformation system is described for Solanum dulcamara usingthe supervirulentAgrobacterium tumefaciens strain 1065, carryingboth the ß-glucuronidase (gus) and neomycin phosphotransferaseII (npt II) genes adjacent to the right and left T-DNA borders,respectively. Leaf explants were more efficient for the productionof transformed plants compared to stem explants on medium containing50 mg l^-1of kanamycin sulphate. A 1:10 (v:v) dilution of anovernight culture ofAgrobacterium gave optimal transformationin terms of transgenic plant regeneration. From a total of 174kanamycin-resistant plants selected by their antibiotic resistance,16 failed to exhibit GUS activity. Southern analysis revealedthat these GUS-negative transformants originated from threeindependently transformed cell lines. Restriction enzyme analysesshowed that the GUS-negative plants had both the gus and nptII genes integrated into their genome (one plant had a singlecopy of each gene; the other two plants had multiple copies),with major rearrangement of the gus gene occurring in plantswith several copies of the transgene. GUS-negative plants showedleaf malformations, delayed flowering and a reduction in flower,fruit and seed production compared to GUS-positive and non-transformed(control) plants. Although gene silencing of the gus gene occurred,albeit at a low frequency (9.2%), the transformation systemdescribed generates large numbers of phenotypically normal,stably transformed plants. Copyright 2000 Annals of Botany Company Agrobacterium -mediated transformation, gene silencing, Solanum dulcamara L. (Bittersweet, Woody Nightshade), T-DNA truncation, transgene expression     

Improved <Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation and direct plant regeneration in four cultivars of finger millet (<Emphasis Type="Italic">Eleusine coracana</Emphasis> (L.) Gaertn.)

We have developed an improved Agrobacterium-mediated transformation and rapid regeneration system for four cultivars (‘CO(Ra)-14’, ‘PR-202’, ‘Try-1’ and ‘Paiyur-2’) of finger millet using optimized transformation and direct plant regeneration conditions. The shoot apical meristems (SAMs) were used as explants in this study. Agrobacterium strain EHA105 carrying binary vector pCAMBIA1301 was used to optimize the transformation conditions. Concentration of hygromycin, the optical density of the culture, infection time, age of the explants, co-cultivation period, the concentrations of acetosyringone and antibiotics were optimized to improve the transformation frequency. The highest frequency of mean transient gus expression (85.1%) was achieved in cultivar ‘CO(Ra)-14’. The entire transformation procedure, from initiating SAMs to planting putative transgenic plantlets in the greenhouse, was completed within 45 days with the highest stable transformation frequency of 11.8% for ‘CO(Ra)-14’. PCR, gus staining and Southern blot analyses were performed in T₀ and T₁ generations to confirm the gene integration. Six events from T₀ had a single copy of the transgene and showed a normal Mendelian pattern of segregation. To our knowledge, this is the first report on the high frequency transformation of finger millet by Agrobacterium and subsequent recovery of transgenic plants via direct plant regeneration without a callus phase, in short duration (45 days). The proposed protocol could be supportive in breaking through the bottleneck in transformation and regeneration of finger millet cultivars.     

A large-scale study of rice plants transformed with different T-DNAs provides new insights into locus composition and T-DNA linkage configurations

Transgenic locus composition and T-DNA linkage configuration were assessed in a population of rice plants transformed using the dual-binary vector system pGreen (T-DNA containing the bar and gus genes)/pSoup (T-DNA containing the aphIV and gfp genes). Transgene structure, expression and inheritance were analysed in 62 independently transformed plant lines and in around 4,000 progeny plants. The plant lines exhibited a wide variety of transgenic locus number and composition. The most frequent form of integration was where both T-DNAs integrated at the same locus (56% of loci). When single-type T-DNA integration occurred (44% of loci), pGreen T-DNA was preferentially integrated. In around half of the plant lines (52%), the T-DNAs integrated at two independent loci or more. In these plants, both mixed and single-type T-DNA integration often occurred concurrently at different loci during the transformation process. Non-intact T-DNAs were present in 70–78% of the plant lines causing 14–21% of the loci to contain only the mid to right border part of a T-DNA. In 53–66% of the loci, T-DNA integrated with vector backbone sequences. Comparison of transgene presence and expression in progeny plants showed that segregation of the transgene phenotype was not a reliable indicator of either transgene inheritance or T-DNA linkage, as only 60–80% of the transgenic loci were detected by the expression study. Co-expression (28% of lines) and backbone transfer (53–66% of loci) were generally a greater limitation to the production of marker-free T₁ plants expressing the gene of interest than co-transformation (71% of lines) and unlinked integration (44% of loci).     

Increased resistance to fungal wilts in transgenic eggplant expressing alfalfa glucanase gene

The wilt diseases caused by Verticillium dahliae and Fusarium oxysporum are the major diseases of eggplant (Solanum melongena L.). In order to generate transgenic resistance against the wilt diseases, Agrobacterium-mediated gene transfer was performed to introduce alfalfa glucanase gene encoding an acidic glucanase into eggplant using neomycin phosphotransferase (npt-II) gene as a plant selection marker. The transgene integration into eggplant genome was confirmed by Polymerase chain reaction (PCR) and Southern blot analysis and transgene expression by the glucanase activity and western blot analysis. The selected transgenic lines were challenged with V. dahliae and F. oxysporum under in vitro and in vivo growth conditions, and transgenic lines showed enhanced resistance against the wilt-causing fungi with a delay of 5–7 days in the disease development as compared to wild-type plants.     

Overexpression of Arabidopsis cytokinin oxidase/dehydrogenase genes AtCKX1 and AtCKX2 in transgenic Centaurium erythraea Rafn.

Cytokinin oxidase/dehydrogenase (CKX) is the only known enzyme involved in cytokinin catabolism. Genes coding for two Arabidopsis CKX isoforms, AtCKX1 and AtCKX2, were introduced separately into a binary cloning vector, immobilized into Agrobacterium tumefaciens strain GV3101, and introduced into root explants of centaury (Centaurium erythraea Rafn.). The integration of each transgene was confirmed by genomic PCR. Of the total transformed explants, 30 and 28.2 % of the transformants carried AtCKX1 and AtCKX2 transgenes, respectively. Of these transformants, 50 % exhibited expression of the AtCKX1 transgene, while 64 % of transformants exhibited expression of the AtCKX2 transgene. For all analysed AtCKX transgenic centaury lines, as well as for untransformed control plants, CKX activity was higher in roots than in shoots. Expression of AtCKX in most transgenic lines contributed to enhanced levels of CKX activity in root tissues; whereas, only a few lines demonstrated increased CKX activity in shoot tissues compared to those of control plants. Moreover, overexpression of AtCKX resulted in reduced morphogenetic potential in transgenic plants, but did not significantly affect biomass production in comparison to untransformed control plants.     

A simple,rapid and systematic method for the developed GM rice analysis

We generated 383 independent transgenic lines that contained the PsGPD (Glyceraldehyde-3-Phosphate Dehydrogenase), ArCspA (Cold Shock Protein), BrTSR15 (Triple Stress Resistance 15) and BrTSR53 (Triple Stress Resistance 53) genes under the control of a constitutive (CaMV 35S) promoter to generate genetically modified (GM) rice. TaqMan copy number assay was performed to determine the copy numbers of inserted T-DNA. Flanking sequence tags (FSTs) were isolated from 203 single copy T-DNA lines of transgenic plants, and their sequences were mapped to the rice chromosomes. Of the 157 flanking sequence tags that were isolated from single copy lines, transgenes were found to be integrated into genic regions in 58 lines (36 %), whereas 97 lines (62 %) contained transgene insertions in intergenic regions. Approximately 27 putative homozygous lines were obtained through multi-generations of planting, resistance screening and TaqMan copy number assays. To investigate the transgene expression patterns, quantitative real-time PCR analysis was performed using total RNA from leaf tissue of homozygous T1 plants with a single copy and an intergenic insertion of T-DNA. The mRNA expression levels of the examined transgenic rice were significantly increased in all transgenic plants. In addition, myc-tagged 35S:BrTSR15 and 35S:BrTSR53 transgenic plants displayed higher levels of transgene protein. Using numerical data for the mass production of transgenic plants can reduce the time required to obtain a genetically modified plant. Moreover, the duration, cost, and efforts required for transformation can be deliberately predicted. These results may be useful for the large-scale production of transgenic plants or T-DNA inserted rice mutants.