Variation in the inheritance of expression among subclones for unselected (uidA) and selected (bar) transgenes in maize (Zea mays L.)

Variation in the inheritance of expression among subclones for an unselected (uidA) and a selected (bar) transgene was analyzed in two individual transformation events in maize. The unselectable gene (uidA) and the selectable gene (bar), on two separate plasmids, were transferred to maize (Hi-II derivative) by particle bombardment of embryogenic calli or suspension cells. A total of 188 fertile T1 plants were obtained from one transformant (transformation event BG which integrated uidA and bar). A total of 98 fertile T1 plants were obtained from a second transformant (transformation event B which integrated bar). Through self-pollination and/or cross-pollination in the greenhouse, approximately 10 000 T2 progeny were obtained from event BG, and more than 1000 T2 progeny were obtained from event B. Segregation of transgene expression was analyzed statistically in a total of 2350 T2 progeny from 40 T1 subclones of event BG and in 217 T2 progeny from six T1 subclones from event B. Variation in the inheritance of expression among subclones for the two transgenes (uidA and bar) was observed in the two transformants. A significant difference was observed between the use of the female or male as the transgenic parent in the inheritance of expression for the two transgenes in event BG. No inheritance through the pollen was observed in two of four T1 subclones analyzed in event B. Co-expression analysis of event BG showed that both transgenes were co-expressed in 67.7% of the T2 plants which expressed at least one of the two transgenes. Of the T2 expressing plants, 30.4% expressed only bar, and 1.9% expressed only uidA. Inactivation of the unselected (uidA) and the selected (bar) transgenes was observed in individual T2 plants.     

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.     

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.     

Production of fertile transgenic maize by electroporation of suspension culture cells

Fertile, transgenic maize plants were generated by electroporation of suspension culture cells that were treated with a pectin-degrading enzyme. Electroporation of cells from two different suspension cultures, one derived from A188 X B73 and one derived from a B73-related inbred, with a plasmid containing the bar gene, resulted in high-frequency recovery of stably transformed callus lines. Plants were regenerated from thirteen transformed callus lines and transmission of bar to progeny was demonstrated.     

Natural glufosinate resistance of soil microorganisms and GMO safety

Bacteria and fungi from pristine soil, never exposed to glufosinate herbicide, were isolated and analyzed for glufosinate tolerance. Seven of the 15 tested isolates were sensitive to 1 mM glufosinate (an active ingredient of many nonselective contact herbicides), 5 were resistant to 4 mM glufosinate and 3 even to 8 mM glufosinate in liquid medium. None of the isolated microorganisms carried the gene for glufosinate resistance bar (bialaphos resistance) in its genome and at least in some of glufosinate-resistant isolates the increased glutamine synthetase level was detected as a possible resistance mechanism. The transfer of the bar glufosinate resistance gene from transgenic maize Bt 176 into glufosinate-sensitive soil bacterium Bacillus pumilus S1 was not detected under the laboratory conditions by a classical plate count method and PCR. The ecological risk of potential bar gene transfer from genetically modified plants into soil microcosms under natural circumstances is discussed.     

Generation of marker‐free transgenic hexaploid wheat via an Agrobacterium‐mediated co‐transformation strategy in commercial Chinese wheat varieties

Genotype specificity is a big problem lagging the development of efficient hexaploid wheat transformation system. Increasingly, the biosecurity of genetically modified organisms is garnering public attention, so the generation of marker‐free transgenic plants is very important to the eventual potential commercial release of transgenic wheat. In this study, 15 commercial Chinese hexaploid wheat varieties were successfully transformed via an Agrobacterium‐mediated method, with efficiency of up to 37.7%, as confirmed by the use of Quickstix strips, histochemical staining, PCR analysis and Southern blotting. Of particular interest, marker‐free transgenic wheat plants from various commercial Chinese varieties and their F₁ hybrids were successfully obtained for the first time, with a frequency of 4.3%, using a plasmid harbouring two independent T‐DNA regions. The average co‐integration frequency of the gus and the bar genes located on the two independent T‐DNA regions was 49.0% in T₀ plants. We further found that the efficiency of generating marker‐free plants was related to the number of bar gene copies integrated in the genome. Marker‐free transgenic wheat plants were identified in the progeny of three transgenic lines that had only one or two bar gene copies. Moreover, silencing of the bar gene was detected in 30.7% of T₁ positive plants, but the gus gene was never found to be silenced in T₁ plants. Bisulphite genomic sequencing suggested that DNA methylation in the 35S promoter of the bar gene regulatory region might be the main reason for bar gene silencing in the transgenic plants.     

Construction of a GFP-BAR plasmid and its use for switchgrass transformation

 A dual marker plasmid comprising the reporter gene sgfp (green fluorescent protein) and the selectable bar gene (Basta tolerance) was constructed by replacing the uidA (β-glucuronidase, GUS) gene in a uidA-bar construct with sgfp. A particle inflow gun was used to propel tungsten particles coated with this plasmid into immature inflorescence-derived embryogenic callus of switchgrass (Panicum virgatum L.). GFP was observed in leaf tissue and pollen of transgenic plants. Nearly 100 plants tolerant to Basta were obtained from the experiments, and Southern blot hybridization confirmed the presence of both the bar and sgfp genes. Plants regenerated from in vitro cultures of transgenic plants grew on medium with 10 mg l^–1 bialaphos. When the pH indicator chlorophenol red was in the medium, the transgenic plantlets changed the medium from red to yellow. Basta tolerance was observed in T₁ plants resulting from crosses between transgenic and nontransgenic control plants, indicating inheritance of the bar transgene. Received: 11 May 2000 / Revision received: 21 August 2000 / Accepted: 22 August 2000     

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).     

<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.     

High frequency production of rapeseed transgenic plants via combination of microprojectile bombardment and secondary embryogenesis of microspore-derived embryos

Transgenic doubled haploid rapeseed (Brassica napus L. cvs. Global and PF₇₀₄) plants were obtained from microspore-derived embryo (MDE) hypocotyls using the microprojectile bombardment. The binary vector pCAMBIA3301 containing the gus and bar genes under control of CaMV 35S promoter was used for bombardment experiments. Transformed plantlets were selected and continuously maintained on selective medium containing 10 mg l⁻¹ phosphinothricin (PPT) and transgenic plants were obtained by selecting transformed secondary embryos. The presence, copy numbers and expression of the transgenes were confirmed by PCR, Southern blot, RT-PCR and histochemical GUS analyses. In progeny test, three out of four primary transformants for bar gene produced homozygous lines. The ploidy level of transformed plants was confirmed by flow cytometery analysis before colchicine treatment. All of the regenerated plants were haploid except one that was spontaneous diploid. High frequency of transgenic doubled haploid rapeseeds (about 15.55% for bar gene and 11.11% for gus gene) were considerably produced after colchicines treatment of the haploid plantlets. This result show a remarkable increase in production of transgenic doubled haploid rapeseed plants compared to previous studies.     

Rapid transformation ofMedicago truncatula: regeneration via shoot organogenesis

Summary A rapid transformation and regeneration system has been developed forM. truncatula cv Jemalong (barrel medic) by which it is possible to obtain transgenic plants within 2.5 months. The procedure involvesAgrobacterium-mediated transformation of cotyledon explants coupled with the regeneration of transformed plants via direct organogenesis. To develop the procedure,M. truncatula explants were transformed with the binary plasmid pSLJ525 which carries thebar gene. Thebar gene encodes phosphinothricin acetyl transferase, and transformed plants were selected on media containing phosphinothricin (Ignite, AgrEvo). Transformed plants show phosphinothricin acetyl transferase activity and Southern blot analysis indicates that they carry thebar gene integrated into their genomes. The resistance to phosphinothricin is stable and is inherited by the R₁ progeny as a single dominant Mendelian trait. The transgenic plants are highly resistant to the broad spectrum herbicide, Ignite and therefore may also have commercial applications.     

Segregation of transgenes in maize

Progeny recovered from backcrossed transgenic maize tissue culture regenerants (R₀) were analyzed to determine the segregation, expression, and stability of the introduced genes. Transgenic A188×B73 R₀ plants (regenerated from embryogenic suspension culture cells transformed by microprojectile bombardment; see [9]) were pollinated with nontransformed B73 pollen. Inheritance of a selectable marker gene, bar, and a nonselectable marker gene, uidA, was analyzed in progeny (R₁) representing four independent transformation events. Activity of the bar gene product, phosphinothricin acetyltransferase (PAT), was assessed in plants comprising the four R₁ populations. The number of R₁ plants containing PAT activity per total number of R₁ plants recovered for each population was 2/7, 19/34, 3/14 and 73/73. Molecular analysis confirmed the segregation of bar in three R₁ populations and the lack of segregation in one R₁ population. Cosegregation analysis indicated genetic linkage of bar and uidA in all four R₁ populations. Analysis of numerous R₂ plants derived from crossing transformed R₁ plants with nontransformed inbreds revealed 1:1 segregation of PAT activity in three of four lines, including the line that failed to segregate in the R₁ generation. Integrated copies of bar in one line appeared to be unstable or poorly transmitted.     

Transformation of oat and inheritance of bar gene expression

Fertile transgenic plants of oat (Avena sativa L. var. Melys) were produced following microprojectile bombardment of primary embryogenic calli from immature embryos with two plasmids containing the bar gene or the β-glucuronidase (uidA) gene, after selection with glufosinate ammonium. Eleven plants were regenerated from phosphinothricin resistant callus, with three of the eleven plants containing either intact or rearranged copies. No plants co-transformed with the non-selected uidA gene were detected. Stable transmission and expression of the bar gene in the T₁ inbred progenies occurred in a Mendelian manner in one line, which contained an intact bar gene, and in all six T₂ lines tested from this transformant. This revised version was published online in June 2006 with corrections to the Cover Date.     

Novel synthetic Bacillus thuringiensiscry1B gene and the cry1B-cry1Ab translational fusion confer resistance to southwestern corn borer, sugarcane borer and fall armyworm in transgenic tropical maize

In order to develop a resistance management strategy to control tropical pests based on the co-expression of different toxins, a fully modified Bacillus thuringiensis cry1B gene and the translational fusion cry1B-cry1Ab gene have been developed. Both constructs were cloned under the control of a maize ubiquitin-1 or a rice actin-1 promoter and linked to the bar gene driven by the CaMV 35S promoter. Immature embryos from the tropical lines CML72, CML216, and their hybrids, were used as the target for transformation by microprojectile bombardment. Twenty five percent of the transformed maize plants with cry1B expressed a protein that is active against southwestern corn borer and sugarcane borer. Ten percent of the transgenic maize expressed single fusion proteins from the translational fusion gene cry1B-1Ab and showed resistance to these two pests as well as to the fall armyworm. Transgenic maize plants that carried the cry1B gene in T1 to T3 progenies transmitted trangenes with expected Mendelian segregation and conferred resistance to the two target insects. Molecular analyses confirmed the cry genes integration, the copy number, the size of protein(s) expressed in maize plants, the transmission, and the inheritance of the introduced cry gene. These new transgenic products will provide another recourse for reducing the build-up of resistance in pest populations. Received: 25 September 2000 / Accepted: 15 December 2000     

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.     

Agrobacterium-mediated transformation in Citrullus lanatus

Agrobacterium tumefaciens-mediated transformation was used to produce transgenic watermelon. Cotyledonary explants of Citrullus lanatus Thumb (cv. Daesan) were co-cultivated with Agrobacterium strains (LBA4404, GV3101, EHA101) containing pPTN289 carrying with bar gene and pPTN290 carrying with nptII gene, respectively. There was a significant difference in the transformation frequency between bacteria strains and selective markers. The EHA101/pPTN289 showed higher transformation frequency (1.16 %) than GV3101/pPTN289 (0.33 %) and LBA4404/pPTN289 or /pPTN290 (0 %). The shoots obtained (633 and 57 lines) showed some resistance to glufosinate and paromomycin, respectively. Of them, the β-glucuronidase positive response and PCR products amplified by bar and nptII specific primers showed at least 21 plants resistant to glufosinate and at least 6 plants to paromomycin. Southern blot analysis revealed that the bar gene integrated into genome of transgenic watermelon. Acclimated transgenic watermelons were successfully transplanted in the greenhouse and showed no phenotypic variation.     

Production of transgenic tropical maize with cryIAb and cryIAc genes via microprojectile bombardment of immature embryos

To enhance the level of resistance to insects in tropical maize germplasm we have developed techniques to successfully transform elite tropical maize inbred based on the activity of specific cryI proteins against four major maize pests – corn earworm, fall armyworm, southwestern corn borer and sugarcane borer. Constructs containing cryIAb or cryIAc synthetic genes were used. To generate transgenic plants we have established methods for biolistic bombardment and the selection and regeneration of immature embryos and calli from the elite tropical lines CML72, CML216, CML323, CML327 and hybrids. Transgenic plants resistant to the herbicide Basta^TM contained the bands for the cry, bar and gus genes as detected by Southern blot analyses. A simple leaf bioassay presented varying levels of resistance to Southwestern corn borer of transgenic tropical maize carrying the cryIAc gene. Analyses of the progenies confirmed the sexual transmission of the introduced genes and their stable expression. Received: 25 September 1998 / Accepted: 27 October 1998