Insertion of cyanobacterial desA gene coding for Δ12-acyl-lipid desaturase increases potato plant resistance to oxidative stress induced by hypothermia

The role of Δ12-acyl-lipid desaturase in plant resistance to hypothermia-induced oxidative stress was investigated. This study focused on modulation of free-radical processes occurring at low temperature in leaf cells of potato plants (Solanum tuberosum L., cv. Desnitsa) transformed with the gene for Δ12-acyl-lipid desaturase from the cyanobacterium Synechocystis sp. PCC 6803. Nontransformed plants of the same cultivar were used as a control material. The plants were grown in vitro on Murashige and Skoog agarized medium containing 2% sucrose. During hypothermia the rate of superoxide anion generation and hydrogen peroxide concentration decreased significantly. In addition, the content of both primary products (conjugated dienes and trienes) and secondary products (malonic dialdehyde) of lipid peroxidation was lower in the transformed plant leaves than in leaves of wild-type plants. It is supposed that the insertion into the plant genome of Δ12-acyl-lipid desaturase stabilizes the composition and physical properties of biomembranes by promoting polyunsaturation of fatty acids, which averts the accelerated generation of O ₂ ^·? , — and suppresses lipid peroxidation during hypothermia. These changes improved cold resistance of potato plants, which was evident from the less severe injury of leaf blades in cold-treated transgenic plants, as compared to that in the wild-type line. The activity of superoxide dismutase, a key enzyme of the antioxidant defense system was lower in leaves of transformed plants than in leaves of wild-type plants. A comparatively low activity of superoxide dismutase in transgenic plants implies that these plants experience less severe thermal and oxidative stress upon cooling and can cope with the cold without considerable increase in the enzyme activity. It is concluded that the insertion of the desA gene encoding Δ12-acyl-lipid desaturase into cold-resistant potato plants improves plant resistance to cold-induced oxidative stress by decreasing the rate of intracellular free-radical processes.     

Engineering herbicide resistance in plants by expression of a detoxifying enzyme

Phosphinothricin (PPT) is a potent inhibitor of glutamine synthetase in plants and is used as a non-selective herbicide. The bar gene which confers resistance in Streptomyces hygroscopicus to bialaphos, a tripeptide containing PPT, encodes a phosphinothricin acetyltransferase (PAT) (see accompanying paper). The bar gene was placed under control of the 35S promoter of the cauliflower mosaic virus and transferred to plant cells using Agrobacterium-mediated transformation. PAT was used as a selectable marker in protoplast co-cultivation. The chimeric bar gene was expressed in tobacco, potato and tomato plants. Transgenic plants showed complete resistance towards high doses of the commercial formulations of phosphinothricin and bialaphos. These data present a successful approach to obtain herbicide-resistant plants by detoxification of the herbicide.     

cyp11A1 Canola plants under short time heat stress conditions

In order to investigate the high temperature tolerance of spring canola plants (Brassica napus L.) constitutively expressing cyp11A1 gene which encodes bovine cytochrome P450_SCC the growth features were analyzed under short time heat stress (42°C) in growth chamber. Earlier it was documented that results of the heat tolerance test positively correlated with improvement of high temperature resistance in field trial. Higher relative water content (by 13%) and superoxide dismutase (SOD) activity, lower electrolyte leakage (up 1.4-fold) and smaller increase in chlorophyll a and carotenoid contents in cyp11A1 canola leaves in comparison with wild-type plants under stress allowed to conclude cyp11A1 plants are more tolerant to high temperature than the control ones. We suppose that SOD activity increase which revealed in our transgenic canola in normal condition plays the defining role in the biochemical alterations in plant metabolism for the thermotolerance improvement. SOD activity increment could be caused by heterologous cytochrome P450_SCC activity which resulted in the superoxide radical formation. Cyp11A1 canola plants might be resistant to the other stress conditions of different origin.     

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.     

Characterization of the herbicide-resistance gene bar from Streptomyces hygroscopicus

A gene which confers resistance to the herbicide bialaphos (bar) has been characterized. The bar gene was originally cloned from Streptomyces hygroscopicus, an organism which produces the tripeptide bialaphos as a secondary metabolite. Bialaphos contains phosphinothricin, an analogue of glutamate which is an inhibitor of glutamine synthetase. The bar gene product was purified and shown to be a modifying enzyme which acetylates phosphinothricin or demethylphosphinothricin but not bialaphos or glutamate. The bar gene was subcloned and its nucleotide sequence was determined. Interspecific transfer of this Streptomyces gene into Escherichia coli showed that it could be used as a selectable marker in other bacteria. In the accompanying paper, bar has been used to engineer herbicide-resistant plants.     

<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.     

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.     

Transformation of bahiagrass (<Emphasis Type="Italic">Paspalum notatum</Emphasis> Flugge)

Bahiagrass (Paspalum notatum Flugge), a forage species widely used in the southeastern United States, and from Central Mexico to Argentina, was targeted for improvement through genetic engineering. Embryogenic callus, initiated from germinating seedlings, was bombarded with a vector containing the bar selectable marker/reporter gene that confers resistance to phosphinothricin (glufosinate) herbicide (trade names Liberty, Ignite and Finale). Thirty-two transgenic plants were recovered. These plants were identified by the polymerase chain reaction (PCR) and verified by Southern analysis. Transgenic plants with bar, as well as non-transgenic plants without bar, regenerated from bombarded callus and selected with glufosinate, developed strong and stable resistance to glufosinate during selection. This unusual resistance in non-transgenic plants has persisted for over a year and is passed on to new tillers. The development of resistance in non-transgenic cells reduced the herbicide selection efficiency and made it necessary to identify transgenic plants by PCR where the 32 transgenic plants were recovered from 674 glufosinate-resistant plants, giving a very low selection efficiency.     

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.     

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.     

Stable transformation of Phaseolus vulgaris via electric-discharge mediated particle acceleration

Summary Transgenic Phaseolus vulgaris or common bean has been produced using electric-discharge particle acceleration. The method uses particle acceleration to introduce DNA into bean seed meristems. Multiple shoots are then generated and screened to recover transgenic plants at a rate of 0.03% germline transformed plants/shoot. We have been able to recover transgenic plants using both GUS and herbicide screening to introduce the gus, bar, and bean golden mosaic virus coat protein genes into the navy bean cultivar, Seafarer. The transgenic plants have been characterized over 5 generations of self-fertilization with no loss of introduced genes or expression. In addition, several families have been crossed with non-transgenic parents and these plants also show expected inheritance patterns. The introduced bar gene has been shown to confer strong resistance in transgenic beans to basta herbicide application in the greenhouse.Abbreviations BGMV bean golden mosaic virus - PAT phosphinothricin acetyltransferase     

Heritable transformation of tobacco byAgrobacterium-mediated transfer of theStreptomyces-derived herbicide resistance genebar

Thebar gene ofStreptomyces hygroscopicus encodes an enzyme that detoxifies the herbicide Basta. We have transferred theStreptotnyces-derived bar gene to tobacco through theAgrobacterium tumefaciens gene delivery system. Expression ofbar was driven by two different promoters, TR2’ or CaMV 35S, in two DNA constructs. TR2’ is a weak promoter in tobacco. CaMV 35S is, on the other hand, a strong promoter in tobacco, and transformation using the CaMV 35S promoter construct yielded Basta-resistant transgenic plants. Out of the over one hundred transformants obtained, most could be grown to maturity. Four of these were characterized by genetic and molecular methods. Subsequently, one of the four plants was not resistant and did not show presence ofbar DNA. The remaining three plants contained one or more copies ofbar DNA at one or two loci. Segregation data were consistent with this observation: we obtained ratios of either 3:1 (single locus) or 15:1 (two loci) Basta-resistant:Basta-sensitive in the F₂ generation. Field-grown plants showed resistance to Basta up to a level of 4000 g of active ingredient per hectare.     

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     

Gabaculine selection using bacterial and plant marker genes (GSA-AT) in durum wheat transformation

Selectable marker genes are widely used for the efficient transformation of crop plants. In most cases, selection is based on antibiotic or herbicide resistance genes because they tend to be most efficient. The Synechococcus hemL gene has been successfully employed as a selectable marker for tobacco and alfalfa genetic transformation, by using gabaculine as the selective agent. The gene conferring gabaculine resistance is a mutant form of the hemL gene from Synechococcus PCC6301, strain GR6, encoding a gabaculine insensitive form of the glutamate1-semialdehyde aminotransferase (GSA) enzyme. In the present study we compared the transformation and selection efficiency of the common selection method based on the Streptomyces hygroscopicus bar gene conferring resistance to Bialaphos^®, with both the Synechococcus hemL gene and a Medicago sativa mutated GSA gene (MsGSAgr) conferring resistance to phytotoxin gabaculine. Callus derived from immature embryos of the durum wheat cultivar Varano were simultaneously co-bombarded with bar/hemL and bar/MsGSAgr genes. After gene delivery, the marker genes were individually evaluated through all the selection phases from callus regeneration to adult plant formation, and compared for their transformation and selection efficiency. The integration of the three genes in the T₀ generation was confirmed by PCR analysis with specific primers for each gene and southern blot analysis. Both Synechococcus hemL and MsGSA were more efficient than bar for biolistic transformation (2.8% vs. 1.8% and 1.1% vs. 0.5%) and selection (79% vs. 43% and 87% vs. 50%). Thus, an efficient selection method for durum wheat transformation was established that obviates the use of herbicide resistance genes.     

Increased stable inheritance of herbicide resistance in transgenic lettuce carrying a petE promoter-bar gene compared with a CaMV 35S-bar gene

Inheritance of resistance to herbicide (300 mg/l glufosinate ammonium) up to the third (T3) seed generation was compared in two populations of transgenic lettuce (Lactuca sativa L. cv ’Evola’) harbouring a T-DNA containing the bar gene, linked to either the Cauliflower Mosaic Virus (CaMV) 35S promoter, or a –784-bp plastocyanin promoter from pea (petE). Only 2.5% (4/163) of CaMV 35S-bar plants, selected by their kanamycin resistance(T0 generation), transmitted herbicide resistance at high frequency to their T3 seed generation compared with 97% (29/30) for kanamycin resistant petE-bar plants. In the case of 35S-bar transformants, only 16% (341/2,150) of the first seed generation (T1) plants, 22% (426/1,935) T2 plants and 11% (1,235/10,949) T3 plants were herbicide-resistant. In contrast, 63% (190/300) T1 plants, 83% (2,370/2,845) T2 plants and 99% (122/123) T3 petE-bar transformed plants were resistant to glufosinate ammonium. The T-DNAs carrying the petE-bar and CaMV 35S-bar genes also contained a CaMV 35S-neomycin phosphotransferase (nptII) gene. ELISA showed that NPTII protein was absent in 29% (45/156) of the herbicide-resistant T2 plants from 8/19 herbicide-resistant petE-bar lines. This indicated specific inactivation of the CaMV 35S promoter on the same T-DNA locus as an active petE promoter. The choice of promoter and T-DNA construct are crucial for long-term expression of transgenes in lettuce. Received: 13 November 1998 / Accepted: 20 February 1999     

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).     

Efficient Sugarcane Transformation via <Emphasis Type="Italic">bar</Emphasis> Gene Selection

Genetic engineering provides new opportunities for improving economically important traits in sugarcane cultivars. In this study, an efficient Agrobacterium-mediated transformation system that uses the bar gene (a herbicide resistance gene that is used in conjunction with the herbicide Basta) as a selection marker was developed. Using this transformation selection system, all of the resistant plants after selection were nearly 100% polymerase chain reaction (PCR) detection positive and showed herbicide resistance. Each gram of sugarcane calli used for transformation produced approximately 12 transgenic lines. It took approximately 4 months to generate transgenic plants that measured 10 cm in height for greenhouse transplantation.     

Transgenic <Emphasis Type="Italic">Eustoma grandiflorum</Emphasis> expressing the <Emphasis Type="Italic">bar</Emphasis> gene are resistant to the herbicide Basta<Superscript>®</Superscript>

Lisianthus (Eustoma grandiflorum) is a cut or ornamental flower that is popular all over the world. This ornamental crop, however, lacks an effective weed control method due to its susceptibility to herbicide. In this study, transgenic plants of a lisianthus cultivar were produced using Agrobacterium-mediated delivery of the plasmid pCAMBIA3300, which carried the bialaphos resistance (bar) gene under driven by the CaMV 35S promoter. The transgenic calli were derived from wounded edges of the leaves grown on a shoot regeneration medium containing 100 mg l^?1 cefotaxime and 2 mg l^?1 glufosinate ammonium for 4 weeks. The callus that was detached from the wounded edge of the leaf was transferred to the shoot regeneration medium with 100 mg l^?1 cefotaxime and 5 mg l^?1 glufosinate ammonium for 4 weeks for shoot regeneration. The bar gene integration and expression in the transgenic plants were confirmed by Southern and Northern blot analyses, respectively. Subsequently, the transgenic lines were assessed in vitro and under greenhouse conditions for their resistance to the commercial herbicide Basta^®, which contains glufosinate ammonium as the active component. Six transgenic lines showed high percentages (67–80%) of survival in vitro under the selection condition with glufosinate ammonium (up to 216 mg l^?1). Under greenhouse conditions, the plants from these six lines remained healthy and exhibited a normal phenotype after spraying with glufosinate ammonium (up to 1,350 mg l^?1). This is the first paper to provide a detailed survey of transgenic lisianthus expressing the bar gene and exhibiting herbicide-resistance under greenhouse conditions.     

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.