Transgenic and herbicide resistant pearl millet (Pennisetum glaucum L.) R.Br. via microprojectile bombardment of scutellar tissue

Four different pearl millet breeding lines were transformed and led to the regeneration of fertile transgenic plants. Scutellar tissue was bombarded with two plasmids containing the bar selectable marker and the -glucuronidase reporter gene (gus or uidA) under control of the constitutive CaMV 35S promoter or the maize Ubiquitin1 promoter (the CaMV 35S is not a maize promoter). For the delivery of the DNA-coated microprojectiles, either the particle gun PDS 1000/He or the particle inflow gun was used. The calli and regenerants were selected for their resistance to the herbicide Basta (glufosinate ammonium) mediated by the bar gene. Putative transformants were screened for enzyme activity by painting selected leaves or spraying whole plants with an aqueous solution of the herbicide Basta and by the histochemical GUS assay using cut leaf segments. PCR and Southern blot analysis of genomic DNA indicated the presence of introduced foreign genes in the genomic DNA of the transformants. Five regenerated plants represent independent transformation events and have been grown to maturity and set seed. The integration of the bar selectable and the gus reporter gene was confirmed by genomic Southern blot analysis in all five plants. All five plants had multiple integrations of both marker genes. To date, the T₁ progeny of three out of four lines generated by the PDS particle gun shows co-segregating marker genes, indicating an integration of the bar and the gus gene at the same locus in the genome.     

Inheritance of foreign genes in transgenic bean (Phaseolus vulgaris L.) co-transformed via particle bombardment

Exploiting the biolistic process we have generated stable transgenic bean (Phaseolus vulgaris L.) plants with unlinked and linked foreign genes. Co-transformation was conducted using plasmid constructions containing a fusion of the gus and neo genes, which were co-introduced with the methionine-rich 2S albumin gene isolated from the Brazil nut and the antisense sequence of AC1, AC2, AC3 and BC1 genes from the bean golden mosaic geminivirus. The results revealed a co-transformation frequency ranging from 40% to 50% when using unlinked genes and 100% for linked genes. The introduced foreign genes were inherited in a Mendelian fashion in most of the transgenic bean lines. PCR and Southern blot hybridization confirmed the integration of the foreign genes in the plant genome.     

<Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation of <Emphasis Type="Italic">Cry1C,Cry2A</Emphasis> and <Emphasis Type="Italic">Cry9C</Emphasis> genes into <Emphasis Type="Italic">Gossypium hirsutum</Emphasis> and plant regeneration

Three constructs harbouring novel Bacillus thuringiensis genes (Cry1C, Cry2A, Cry9C) and bar gene were transformed into four upland cotton cultivars, Ekangmian10, Emian22, Coker201 and YZ1 via Agrobacterium-mediated transformation. With the bar gene as a selectable marker, about 84.8 % of resistant calli have been confirmed positive by polymerase chain reaction (PCR) tests, and totally 50 transgenic plants were regenerated. The insertions were verified by means of Southern blotting. Bioassay showed 80 % of the transgenic plantlets generated resistance to both herbicide and insect. We optimized conditions for improving the transformation efficiency. A modified in vitro shoot-tip grafting technique was introduced to help entire transplantation. This result showed that bar gene can replace antibiotic marker genes (ex. npt II gene) used in cotton transformation.     

<Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformed transgenic triploid bermudagrass (<Emphasis Type="Italic">Cynodon dactylon</Emphasis> × <Emphasis Type="Italic">C. transvaalensis</Emphasis>) plants are highly resistant to the glufosinate herbicide Liberty

Glufosinate resistance gene isolated from Streptomyces hygromicinroscopicus (bar) that confers the resistance of herbicide Liberty, a broad-spectrum grass and broadleaf contact herbicide widely used for weed control, was introduced into triploid bermudagrass by Agrobacterium-mediated transformation. Embryogenic calluses derived from stolonous nodal segment were co-cultured with the disarmed strain EHA105 harboring the binary vector pBG1300H containing the bar gene under the control of adh-1 promoter. A total of 18 independent transgenic lines were obtained. The integration of bar gene into plant genome was confirmed by the GUS histochemical staining assay, PCR amplification, and Southern blotting. Herbicide bioassay indicated that the bar-expressing transgenic plants exhibited greater herbicide resistance than the wild type and the non-transformed tissue culture-derived plants.     

Production of transgenic potato exhibiting enhanced resistance to fungal infections and herbicide applications

Potato (Solanum tuberosum L.), one of the most important food crops, is susceptible to a number of devastating fungal pathogens in addition to bacterial and other pathogens. Producing disease-resistant cultivars has been an effective and useful strategy to combat the attack of pathogens. Potato was transformed with Agrobacterium tumefaciens strain EHA101 harboring chitinase, (ChiC) isolated from Streptomyces griseus strain HUT 6037 and bialaphos resistance (bar) genes in a binary plasmid vector, pEKH1. Polymerase chain reaction (PCR) analysis revealed that the ChiC and bar genes are integrated into the genome of transgenic plants. Different insertion sites of the transgenes (one to six sites for ChiC and three to seven for bar) were indicated by Southern blot analysis of genomic DNA from the transgenic plants. Expression of the ChiC gene at the messenger RNA (mRNA) level was confirmed by Northern blot analysis and that of the bar gene by herbicide resistance assay. The results obviously confirmed that the ChiC and bar genes are successfully integrated and expressed into the genome, resulting in the production of bialaphos-resistant transgenic plants. Disease-resistance assay of the in vitro and greenhouse-grown transgenic plants demonstrated enhanced resistance against the fungal pathogen Alternaria solani (causal agent of early blight).     

Production of herbicide-resistant sweet potato plants transformed with the <Emphasis Type="Italic">bar</Emphasis> gene

Herbicide-resistant sweet potato plants were produced through biolistics of embryogenic calli derived from shoot apical meristems. Plant materials were bombarded with the vectors containing the β-glucuronidase gene (gusA) and the herbicide-resistant gene (bar). Selection was carried out using phosphinothricin (PPT). Transformants were screened by the histochemical GUS and Chlorophenol Red assays. PCR and Southern-blot analyses indicated the presence of introduced bar gene in the genomic DNA of the transgenic plants. When sprayed with Basta, the transgenic sweet potato plants was tolerant to the herbicide. Hence, we report successful transformation of the bar gene conferring herbicide resistance to sweet potato.     

Recovery of transgenic peanut (Arachis hypogaea L.) plants from elite cultivars utilizing ACCELL® technology

Transgenic plants of Florunner and Florigiant, two of the most widely cultivated peanut cultivars in the USA, have been developed using the ACCELL® gene delivery method. Shoot meristems of mature embryonic axes were bombarded with gold beads coated with DNA encoding β-glucuronidase (gus), phosphinothricin acetyl transferase (bar), and tomato spotted wilt virus-nucleocapsid protein (tswv-np) genes. Transgenic shoots were identified by screening for GUS activity, and independent transformants were recovered from both cultivars. Molecular analysis of two of these transformants in R₀ and R₁ generations demonstrated the stable integration of the foreign genes into the plant genome. One transgenic plant had one to two copies of the genes integrated into the genome of its progeny, whereas the other had multiple copies. Gus and bar genes exhibited predictable segregation ratios in the R₁ and R₂ generations and were genetically linked. Integration of the bar gene conferred resistance to BASTA^TM, a wide-spectrum herbicide, applied at 500 p.p.m. of active ingredient. Resistance of the transgenic plants to tomato spotted wilt virus is currently being tested under greenhouse conditions. The ACCELL® particle bombardment system is expected to be effective for transformation of a wide variety of commercial peanut cultivars.     

Type I callus as a bombardment target for generating fertile transgenic maize (Zea mays L.)

To develop a less genotype-dependent maize-transformation procedure, we used 10-month-old Type I callus as target tissue for microprojectile bombardment. Twelve transgenic callus lines were obtained from two of the three anther-culture-derived callus cultures representing different gentic backgrounds. Multiple fertile transgenic plants (T₀) were regenerated from each transgenic callus line. Transgenic leaves treated with the herbicide Basta showed no symptoms, indicating that one of the two introduced genes, bar, was functionally expressing. Data from DNA hybridization analysis confirmed that the introduced genes (bar and uidA) were integrated into the plant genome and that all lines derived from independent transformation events. Transmission of the introduced genes and the functional expression of bar in T₁ progeny was also confirmed. Germination of T₁ immature embryos in the presence of bialaphos was used as a screen for functional expression of bar; however, leaf painting of T₁ plants proved a more accurate predictor of bar expression in plants. This study suggests that maize Type I callus can be transformed efficiently through microprojectile bombardment and that fertile transgenic plants can be recovered. This system should facilitate the direct introduction of agronomically important genes in to commercial genotypes.     

Stable transformation ofArabidopsis with thebar gene using particle bombardment

A plasmid pARK 22 harbouring thebar gene encoding phosphinothricin acetyltransferase (PAT) under the control of the cauliflower mosaic virus (CaMV) 35S promoter and nopaline synthase (NOS) terminator was constructed and introduced into root sections ofArabidopsis thaliana using the pneumatic particle gun. The root sections that had been bombarded with this plasmid gave four to eight times higher yield of drug-resistant calluses than those sections bombarded with pCaMVNEO or pCH, which respectively contain the neomycin phosphotransferase and hygromycin phosphotransferase genes. Among a number of primary transformant (T₀) plants obtained from independent bialaphos-resistant calluses, three were studied by Southern blot hybridization and PAT enzyme activity analyses, confirming the stable integration of the foreign gene into theArabidopsis genome and its expression in plants. The progeny analysis showed transmission of the foreign gene and its expression in up to the T₂ generation. Some of the T₁ progeny showed morphological abnormalities. Thus, thebar gene can be used effectively to allow selection of transgenicA. thalianna plants.     

Production of herbicide-resistant transgenic sweet potato plants through <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis> method

Transgenic herbicide-resistant sweet potato plants [Ipomoea batatas (L.) Lam.] were produced through Agrobacterium-mediated transformation system. Embryogenic calli derived from shoot apical meristems were infected with Agrobacterium tumefaciens strain EHA105 harboring the pCAMBIA3301 vector containing the bar gene encoding phosphinothricin N-acetyltransferase (PAT) and the gusA gene encoding β-glucuronidase (GUS). The PPT-resistant calli and plants were selected with 5 and 2.5 mg l⁻¹ PPT, respectively. Soil-grown plants were obtained 28–36 weeks after Agrobacterium-mediated transformation. Genetic transformation of the regenerated plants growing under selection was demonstrated by PCR, and Southern blot analysis revealed that one to three copies of the transgene were integrated into the plant genome of each transgenic plant. Expression of the bar gene in transgenic plants was confirmed by RT-PCR and application of herbicide. Transgenic plants sprayed with Basta containing 900 mg l⁻¹ of glufosinate ammonium remained green and healthy. The transformation frequency was 2.8% determined by herbicide application which was high when compared to our previous biolistic method. In addition, possible problems with multiple copies of transgene were also discussed. We therefore report here a successful and reliable Agrobacterium-mediated transformation of the bar gene conferring herbicide-resistance and this method may be useful for routine transformation and has the potential to develop new varieties of sweet potato with several important genes for value-added traits such as enhanced tolerance to the herbicide Basta.     

Regeneration of herbicide resistant transgenic rice plants following microprojectile-mediated transformation of suspension culture cells

Summary Suspension cells of Oryza sativa L. (rice) were transformed, by microprojectile bombardment, with plasmids carrying the coding region of the Streptomyces hygroscopicus phosphinothricin acetyl transferase (PAT) gene (bar) under the control of either the 5 region of the rice actin 1 gene (Act1) or the cauliflower mosaic virus (CaMV) 35S promoter. Subsequently regenerated plants display detectable PAT activity and are resistant to BASTA^TM, a phosphinothricin (PPT)-based herbicide. DNA gel blot analyses showed that PPT resistant rice plants contain a bar-hybridizing restriction fragment of the expected size. This report shows that expression of the bar gene in transgenic rice plants confers resistance to PPT-based herbicide by suppressing an increase of ammonia in plants after spraying with the herbicide.     

Production of fertile transgenic maize plants by silicon carbide whisker-mediated transformation

A simple and inexpensive system for the generation of fertile, transgenic maize plants has been developed. Cells from embryogenic maize suspension cultures were transformed using silicon carbide whiskers to deliver plasmid DNA carrying the bacterial bar and uidA (gus) genes. Transformed cells were selected on medium containing the herbicide bialaphos. Integration of the bar gene and activity of the enzyme phosphinothricin acetyl transferase (PAT) were confirmed in all bialaphos-resistant callus lines analysed. Fertile transgenic maize plants were regenerated. Herbicide spraying of progeny plants revealed that the bar gene was transmitted in a Mendelian fashion.     

Co-transformation of gene expression cassettes via particle bombardment to generate safe transgenic plant without any unwanted DNA

The presence of resistant selectable marker genes and other added DNAs such as the vector backbone sequence in transgenic plant might be an unpredictable hazard to the ecosystem as well as to human health, which have affected the safe assessment of transgenic plants seriously. Using minimal gene expression cassette (containing the promoter, coding region, and terminator) without vector backbone sequence for particle bombardment is the new trend of plant genetic transformation. In the present paper, we co-transformed the selectable marker bar gene cassette and non-selected cecropinB gene cassette into rice (Oryza sativa L.) by particle bombardment, then eliminated the selectable marker bar gene in R₁ generation applying the hereditary segregation strategy and attained two safe transgenic plants only harboring cecropinB gene cassettes without any superfluous DNA. This is the fist report indicating that the combination of minimal gene cassettes transformation with the co-transformation and segregation strategy can generate selectable marker-free transgenic plants, which will promote the advancement in plant genetic engineering greatly.     

Transgenic fertile Scoparia dulcis L., a folk medicinal plant, conferred with a herbicide-resistant trait using an Ri binary vector

Summary Transgenic herbicide-resistant Scoparia dulcis plants were obtained by using an Ri binary vector system. The chimeric bar gene encoding phosphinothricin acetyltransferase flanked by the promoter for cauliflower mosaic virus 35S RNA and the terminal sequence for nopaline synthase was introduced in the plant genome by Agrobacterium-mediated transformation by means of scratching young plants. Hairy roots resistant to bialaphos were selected and plantlets (R0) were regenerated. Progenies (S1) were obtained by self-fertilization. The transgenic state was confirmed by DNA-blot hybridization and assaying of neomycin phosphotransferase II. Expression of the bar gene in the transgenic R0 and S1 progenies was indicated by the activity of phosphinothricin acetyltransferase. Transgenic plants accumulated scopadulcic acid B, a specific secondary metabolite of S. dulcis, in amounts of 15–60% compared with that in normal plants. The transgenic plants and progenies showed resistant trait towards bialaphos and phosphinothricin. These results suggest that an Ri binary system is one of the useful tools for the transformation of medicinal plants for which a regeneration protocol has not been established.Abbreviations CaMV cauliflower mosaic virus - NPT-II neomycin phosphotransferase - PAT phosphinothricin acetyltransferase - PPT phosphinothricin     

Use of bar as a selectable marker gene and for the production of herbicide-resistant rice plants from protoplasts

We have used the bar gene in combination with the herbicide Basta to select transformed rice (Oryza sativa L. cv. Radon) protoplasts for the production of herbicide-resistant rice plants. Protoplasts, obtained from regenerable suspension cultures established from immature embryo callus, were transformed using PEG-mediated DNA uptake. Transformed calli could be selected 2–4 weeks after placing the protoplast-derived calli on medium containing the selective agent, phosphinothricin (PPT), the active component of Basta. Calli resistant to PPT were capable of regenerating plants. Phosphinothricin acetyltransferase (PAT) assays confirmed the expression of the bar gene in plants obtained from PPT-resistant calli. The only exceptions were two plants obtained from the same callus that had multiple copies of the bar gene integrated into their genomes. The transgenic status of the plants was varified by Southern blot analysis. In our system, where the transformation was done via the protoplast method, there were very few escapes. The efficiency of co-transformation with a reporter gene gusA, was 30%. The T_o plants of Radon were self-fertile. Both the bar and gusA genes were transmitted to progeny as confirmed by Southern analysis. Both genes were expressed in T₁ and T₂ progenies. Enzyme analyses on T₁ progeny plants also showed a gene dose response reflecting their homozygous and heterozygous status. The leaves of T_o plants and that of the progeny having the bar gene were resistant to application of Basta. Thus, the bar gene has proven to be a useful selectable and screenable marker for the transformation of rice plants and for the production of herbicide-resistant plants.     

Insect- and herbicide-resistant transgenic eucalypts*

Transgenic Eucalyptus camaldulensis containing both the insecticidal cry3A gene and the bar gene (conferring tolerance to the herbicide glufosinate ammonium) have been produced by Agrobacterium tumefaciens-mediated transformation of seedling explants. Transgenic plants from two lines tested were resistant to first instars of chrysomelid beetles that are important pests of commercial Australian eucalypt plantations. Both lines also exhibit tolerance to the broad-spectrum herbicide Liberty® at 6 l/ha (1.2 kg active ingredient per hectare), twice the field application rate. Transgenic insect- and herbicide-resistant eucalypts like these are likely to provide better insect and weed control options in plantations, particularly during the vulnerable establishment phase, provided that any adverse ecological impacts of releasing transgenic trees into the environment can be assessed and minimized.     

Fertile,transgenicTriticale ( ×Triticosecale Wittmack)

Fertile transgenicTriticale ( ×Triticosecale Wittmack) plants expressing the-glucuronidase (uidA) and phosphinothricin acetyltransferase (bar) genes were obtained after microprojectile bombardment of scutellar tissue with the plasmid pDB1 containing theuidA gene under the control of the actin-1 promoter (Act1) from rice and the selectable marker genebar under the control of the CaMV 35S promoter. From 465 bombarded scutella about 4000 plantlets were regenerated; 300 plants survived the selection. These regenerants were screened for enzyme activity by the histological GUS assay and by spraying the plants with a herbicide (Basta). Twenty-five regenerants showed GUS activity and survived repeated Basta spraying. Southern blot analysis showed the presence of both marker genes introduced into the genome of analysed plants.All transgenic plants were fertile. They were grown to maturity and set seed. Pollen and progeny analyses provided evidence for inheritance of the introduced genes to the next generation.     

Transgenic radish (Raphanus sativus L. longipinnatus Bailey) by floral-dip method – plant development and surfactant are important in optimizing transformation efficiency

Transgenic radish (Raphanus sativus L. longipinnatus Bailey) plants were produced from the progeny of plants which were dipped into a suspension of Agrobacterium carrying both the -glucuronidase (gusA) gene and a gene for resistance to the herbicide Basta (bar) between T-DNA border sequences. The importance of development of the floral-dipped plant and presence of surfactant in the inoculation medium were evaluated in terms of transgenic plant production. Plants dipped at the primary bolt stage of growth, into a suspension of Agrobacterium containing 0.05% (v/v) Silwet L-77 resulted in optimum transformation efficiency, with 1.4% from 1110 seeds. The presence of Pluronic F-68 or Tween 20 in the inoculation medium was beneficial towards transgenic plant output compared to treatments without surfactant. Putative transformed T1 plants were efficiently selected by spraying with 0.03% (v/v) Basta and all herbicide-resistant plants tested positive for GUS activity when analysed both histochemically and fluorometrically. Southern analysis revealed that both the gusA and bar genes integrated into the genome of transformed plants and segregated as dominant Mendelian traits. These results demonstrate that radish can be genetically modified for the improvement of this important vegetable crop.