Generation of transgenic barley lines producing human lactoferrin using mutant alpha-tubulin gene as the selective marker

The biolistic transformation method was used for genetic improvement of three commercial cultivars of barley (Oksamytoviy, Vodogray, and Hetman). The plasmid pHLFTuBA containing target gene hLF encoding human lactoferrin under the control of the rice glutein B-1 promoter GluB-1 was used for transformation. The gene encoding mutant alfa-tubulin conferring resistance to trifluralin (dinitroaniline herbicide) was used as the selective marker. The screening of different trifluralin concentrations ranging from 0.1–30 μM was used for determination of selective concentration of the agent. Two transgenic barley lines of cultivars Oksamytoviy and Hetman’s callus line were selected after 2–3 months of cultivation on 10 μM of trifluralin. To confirm stable integration of the transformed gene, the PCR analysis of leafs from regenerated plant after their adaptation on the ground was carried out. The 734 bp fragment of the target gene was amplified from both regenerated plants.     

Development of transformation vectors based upon a modified plant alpha-tubulin gene as the selectable marker

A plant transformation and selection system has been developed utilizing a modified tubulin gene as a selectable marker. The vector constructs carrying a mutant alpha-tubulin gene from goosegrass conferring resistance to dinitroaniline herbicides were created for transformation of monocotyledonous and dicotyledonous plants. These constructs contained beta- and/or mutant alpha-tubulin genes driven either by ubiquitin or CaMV 35S promoter. The constructs were used for biolistic transformation of finger millet and soybean or for Agrobacterium-mediated transformation of flax and tobacco. Trifluralin, the main representative of dinitroaniline herbicides, was used as a selective agent in experiments to select transgenic cells, tissues and plantlets. Selective concentrations of trifluralin estimated for each species were as follows: 10 microM for Eleusine coracana, Glycine max, Nicotiana plumbaginifolia and Nicotiana sylvestris; 3 microM for Linum usitatissimum. PCR and Southern blotting analyses of transformed lines with a specific probe to nptII, alpha-tubulin or beta-tubulin genes were performed to confirm the transgenic nature of regenerated plants. Band specific for the mutant alpha-tubulin gene was identified in transformed plant lines. Results confirmed the stable integration of the mutant tubulin gene into the plant genomes. The present study clearly demonstrates the use of a plant mutant tubulin as a selective gene for plant transformation.     

Transformation and expression of a stilbene synthase gene of Vitis vinifera L. in barley and wheat for increased fungal resistance

 Transformation of barley and wheat via particle bombardment with a gene derived from Vitis vinifera L. (Vst1 gene) resulted in the expression of the foreign phytoalexin, resveratrol, in the transformed plants. Transgenic barley plants were regenerated from microspores and transgenic wheat plants from immature embryos were both selected on Basta. Stable integration of the gene in the genomes of transgenic barley and wheat plants, as well as their progeny, was analysed by Southern-blot analysis. The induction of the stilbene synthase promoter and the transient expression of stilbene synthase-specific mRNA after induction by wounding and infection were proofed in T₁ and T₂ progeny plants. An enhanced expression of the Vst1 gene under control of the stilbene synthase promoter was observed with enhancer sequences from the cauliflower mosaic virus 35s (CaMV 35s) promoter. The enzyme activity of the stilbene synthase was analysed in T₁ progeny plants. The first pathological results indicated an increased resistance of transgenic barley plants to Botrytis cinerea used as a model experimental system. Received: 5 November 1997 / Accepted: 11 November 1997     

Biolistic transformation of soybean using a new selectable marker gene conferring resistance to dinitroanilines

A biolistic transformation of soybean using the construct pAHTUAm, which contains a mutant α-tubulin gene, as a selectable marker gene that confers resistance to dinitroaniline herbicides, as well as the additional construct pAHTUB1, which carries a full-length barley β-tubulin gene that ensures correct co-expression of exogenous tubulin in cells of transgenic soybean lines, is carried out. It is established that 10 μM trifluralin is the most optimal selective concentration to pick up transformed soybean lines. The transgenic nature of the selected regenerants is confirmed by Southern blotting hybridization using a specific probe to the α-tubulin selectable gene     

Rapid production of fertile transgenic barley (Hordeum vulgare L.) by direct gene transfer to primary callus-derived protoplasts

Protoplasts were isolated from primary calli of barley (Hordeum vulgare L.), and an antibiotic (G418) resistance gene was introduced into these protoplasts using a polyethylene glycol (PEG) DNA uptake method. Sixty-four G418 resistant calli were obtained in nine experiments, and two plants were regenerated from these calli. NPTII ELISA and Southern analysis indicated that the G418 resistance gene was introduced and expressed in two T₀ plants. These plants set seed and the introduced gene was transmitted to T₁ plants. These results suggest that our transformation system using primary callus-derived protoplasts is a useful method for the generation of transgenic barley. Received: 14 November 1997 / Revision received: 12 March 1998 / Accepted: 24 April 1998     

Inducing homozygosity in transgenic barley (<Emphasis Type="Italic">Hordeum vulgare</Emphasis> L.) by microspore culture

Homozygosity was induced in transgenic barley by microspore culture. Spikes of transgenic barley plants carrying microspores in the late uni-nucleate stage were cold pretreated. Teflon rod maceration and a density of 100 000 viable micropores per plate were used. The developed calli were regenerated and plantlets were treated with colchicine. The microspore culture of 16 mother plants (three transgenic lines) resulted in 927 green regenerants. Of these plants, 476 were transferred to soil, 380 were transgenic, 358 reached maturity and 350 were fertile with a normal seed-set carrying a yield of 6.9 kg. A production efficiency of 0.8 fertile transgenic doubled haploid barley plants per spike used for microspore isolation was recorded. The produced transgenic seeds were used in malting experiments.     

Generation of Large Numbers of Independently Transformed Fertile Barley Plants

A rapid, efficient, and reproducible system to generate large numbers of independently transformed, self-fertile, transgenic barley (Hordeum vulgare L.) plants is described. Immature zygotic embryos, young callus, and microspore-derived embryos were bombarded with a plasmid containing bar and uidA either alone or in combination with another plasmid containing a barley yellow dwarf virus coat protein (BYDVcp) gene. A total of 91 independent bialaphos-resistant callus lines expressed functional phosphinothricin acetyltransferase, the product of bar. Integration of bar was confirmed by DNA hybridization in the 67 lines analyzed. Co-transformation frequencies of 84 and 85% were determined for the two linked genes (bar and uidA) and for two unlinked genes (bar and the BYDVcp gene), respectively. More than 500 green, fertile, transgenic plants were regenerated from 36 transformed callus lines on bialaphos-containing medium; albino plants only were regenerated from 41 lines. T0 plants in 25 lines (three plants per line) were analyzed by DNA hybridization, and all contained bar. Most contained the same integration patterns for the introduced genes (bar, uidA, and the BYDVcp gene) as their parental callus lines. Transmission of the genes to T1 progeny was confirmed in the five families analyzed by DNA hybridization. A germination test of immature T1 embryos on bialaphos-containing medium was useful for selecting individuals that were actively expressing bar, although this was not a good indicator of the presence or absence of bar. Expression of bar in some progeny plants was indicated by resistance to the herbicide Basta. The T1 plants were in soil approximately 7 months after bombardment of the immature embryo.     

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.     

Expression of a gene for Mn-peroxidase from Coriolus versicolor in transgenic tobacco generates potential tools for phytoremediation

In efforts aimed at the detoxification of contaminated areas, plants have many advantages over bacteria and fungi. We are attempting to enhance the environmental decontamination functions of plants by transferring relevant genes from microorganisms. When the gene for Mn-peroxidase (MnP) from Coriolus versicolor was expressed in transgenic tobacco plants, one line (designated fMnP21) expressed MnP activity at levels 54-fold higher than in control lines. When undamaged roots of transgenic plants were applied to liquid medium supplemented with 250 microM pentachlorophenol (PCP), the decrease in the level of PCP in fMnP21 (86% reduction) was about 2-fold higher than that in control lines (38% reduction). Expression of the gene for MnP in the transgenic plants had no obvious negative effects on their vegetative and sexual growth. Our system should contribute to the development of novel methods for the removal of hazardous chemicals from contaminated environments using transgenic plants.     

Agrobacterium-mediated RMCE approach for gene replacement

We describe the site-directed integration (SDI) system for Agrobacterium-mediated transformation to precisely integrate a single copy of a desired gene into a predefined target locus by recombinase-mediated cassette exchange (RMCE). The system requires the selection of a transformed line with an integrated copy of a target cassette, and subsequent introduction of an exchange vector. The target cassette contains the npt and cod genes between oppositely orientated recognition sites (RS). The exchange vector T-DNA possesses an exchange cassette containing the gene of interest and a selectable marker gene, such as hpt, between oppositely orientated (inner) RS. Adjacent to the exchange cassette are ipt and recombinase (R) genes and an additional (outer) RS. The recombinase catalyses double-crossover between target RS and exchange inner RS to replace the integrated target cassette with the introduced exchange cassette. Transgenic plants that contain randomly integrated copies of the exchange vector T-DNA show an abnormal phenotype as a result of the overproduction of cytokinin from ipt gene expression. The recombinase can also act on the directly orientated outer RS to remove such randomly integrated copies. The system resulted in single-copy exchange into the target site only in regenerated tobacco at a frequency of 1%-3% per treated explant, or 4%-9% per regenerated line of normal phenotype. Thus, transgenic plants with only an exchanged copy can be efficiently accumulated and selected. Here, we show that the SDI system can efficiently replace the target cassettes with the exchange cassettes in a heterozygous or homozygous condition. The SDI system may be useful for precise comparisons of different gene constructs, the characterization of different chromosomal regions and the cost-effective screening of reliable transgenic plants.     

农杆菌介导的雪花莲凝集素基因转入玉米骨干自交系

以农杆菌AGL0介导,将雪花莲凝集素基因转入玉米骨干自交系齐319和掖515胚性愈伤组织细胞,从筛选后的抗性愈伤组织获得再生植株。农杆菌浓度和共培养时间均能显著影响侵染后玉米愈伤组织的抗性频率。在农杆菌浓度OD600 0．2～0．3,共培养时间3d时,侵染后玉米愈伤组织的抗性频率最高,平均约4％。对再生植株及其子代基因组DNA的PCR及Southern杂交分析表明雪花莲凝集素基因已经整合到玉米基因组中,并遗传给后代。在蚜虫人工接种试验中,转基因植株上蚜虫的繁殖力为非转基因对照植株上的50％,这表明转基因植株抗蚜性显著增强。     

Use of the firefly luciferase gene in a barley (Hordeum vulgare) transformation system

Transgenic lines of the spring barley variety Golden Promise containing the firefly luciferase gene were produced by particle bombardment of immature embryos. Non-destructive analysis of luciferase gene expression was used to monitor the transformation process. This revealed that transformation efficiency, in terms of the percentage of bombarded immature embryos giving rise to transformed callus lines, was very high, up to 40%. Following the expression of the luciferase gene provided a method for the sensitive, non-destructive, real-time monitoring of gene expression throughout the transformation process. Luciferase expression could also be used to easily identify transgenic plants and to identify homozygous transgenic plants at an early stage. The production of transgenic barley by selecting for luciferase-positive material, without an additional selection system, was possible but technically difficult.     

Genetic transformation with untranslatable coat protein gene of <Emphasis Type="Italic">sugarcane yellow leaf virus</Emphasis> reduces virus titers in sugarcane

Sugarcane yellow leaf syndrome, characterized by a yellowing of the leaf midrib followed by leaf necrosis and growth suppression, is caused by sugarcane yellow leaf virus (SCYLV). We produced SCYLV-resistant transgenic sugarcane from a susceptible cultivar (H62-4671) and determined the amount of virus present following inoculation. The transgenic plants were produced through biolistic bombardment of cell cultures with an untranslatable coat protein gene. Presence of the transgene in regenerated plants was confirmed using PCR and Southern blot analysis. The transgenic lines were inoculated by viruliferous aphids and the level of SCYLV in the plants was determined. Six out of nine transgenic lines had at least 10³-fold lower virus titer than the non-transformed, susceptible parent line. This resistance level, as measured by virus titer and symptom development, was similar to that of a resistant cultivar (H78-4153). The selected SCYLV-resistant transgenic sugarcane lines will be available for integration of the resistance gene into other commercial cultivars and for quantification of viral effects on yield.     

Protoplast transformation and regeneration of transgenic Valencia sweet orange plants containing a juice quality-related pectin methylesterase gene

Valencia orange [Citrus sinensis (L.) Osbeck] is the leading commercial citrus species in the world for processed juice products; however, the presence of thermostable pectin methylesterase (TSPME) reduces its juice quality. A long-term strategy of this work is to eliminate or greatly reduce TSPME activity in Valencia orange. Previous work resulted in the isolation of a putative TSPME gene, CsPME4, associated with a thermostable protein fraction of Valencia orange juice. To begin research designed to overexpress CsPME4 to verify the thermostability of the protein product and/or to downregulate the gene, a sense gene cassette containing a gene-specific sequence from a putative TSPME cDNA and the enhanced green fluorescent protein (GFP) as a selectable marker was constructed (M2.1). In the work reported here, M2.1 plasmid DNA was transformed (polyethylene glycol-mediated) into protoplasts isolated from an embryogenic suspension culture of Valencia somaclone line B6-68, in an effort to obtain transgenic Valencia lines. A vigorous transformed line was identified via GFP expression, physically separated from non-transformed tissue, and cultured on somatic embryogenesis induction medium. One transgenic proembryo expressing GFP was recovered and multiple shoots were regenerated. The recovery of multiple transgenic plants was expedited by in vitro grafting. Polymerase chain reaction analysis revealed the presence of the PME gene in transgenic plants, and subsequent Southern blot analysis confirmed the presence of the eGFP gene. These transgenic plants show normal growth and minor morphological variation. The thermostability of PME in these plants will be assessed after flowering and fruit set. This is the first successful transfer of a target fruit-quality gene by protoplast transformation with recovery of transgenic plants in citrus. This method of transformation has the advantage over Agrobacterium-mediated transformation in that it requires no antibiotic-resistance genes.     

Production and analysis of plants that are somatic hybrids of barley (Hordeum vulgare L.) and carrot (Daucus carota L.)

In order to obtain plants that were somatic hybrids of barley (Hordeum vulgare L.) and carrot (Daucus carota L.), we fused protoplasts that had been isolated from 6-month-old suspension cultures of carrot cells with protoplasts isolated from barley mesophyll by electrofusion. After culture for 1 month at 25°C , the cells were cultured for 5 weeks at 4°C , and were then returned to 25°C for culture on a shoot-inducing medium. Three plants (nos. 1, 2 and 3) were regenerated from the cells. The morphology of the regenerated plants closely resembled that of the parental carrot plants. A cytological analysis of callus cultures induced from these plants indicated that most of the cells had about 24 chromosomes, fewer than the sum of the numbers of parent chromosomes which was 32. Southern hybridization analysis with fragments of the rgp1 gene used as probe showed that the regenerated plants contained both barley and carrot genomic DNA. Chloroplast (ct) and mitochondrial (mt) DNAs were also analyzed with several probes. The ctDNA of the regenerated plants yielded hybridization bands specific for both barley and carrot when one fragment of rice ctDNA was used as probe. Furthermore, the regenerated plants yielded a barley specific band and a novel band with another fragment of rice ct DNA as a probe. One of the regenerated plants (no. 1) yielded a novel pattern of hybridized bands of mt DNA (with an atp6 probe) that was not detected with either of the parents. These results indicated that the regenerated plants were somatic hybrids of barley and carrot and that recombination of both the chloroplast genomes and the mitochondrial genomes might have occurred. Received: 28 May 1996 / Accepted: 2 August 1996     

Immunological evidence for transfer of the barley nitrate reductase structural gene to Nicotiana tabacum by protoplast fusion

Summary A protoplast fusion experiment was designed in which the selectable marker, nitrate reductase (NR), also served as a biochemical marker to provide direct evidence for intergeneric specific gene transfer. NR-deficient tobacco (Nicotiana tabacum) mutant Nia30 protoplasts were the recipients for the attempted transfer of the NR structural gene from 50 krad -irradiated barley (Hordeum vulgare L.) protoplasts. Barley protoplasts did not form colonies and Nia30 protoplasts could not grow on nitrate medium; therefore, selection was for correction of NR deficiency allowing tobacco colonies to grow on nitrate medium. Colonies were selected from protoplast fusion treatments at an approximate frequency of 10^-5. This frequency was similar to the Nia30 reversion frequency, and thus provided little evidence for transfer of the barley NR gene to tobacco. Plants regenerated from colonies had NR activity and were analyzed by western blotting using barley NR antiserum to determine the characteristics of the NR conferring growth on nitrate. Ten plants exhibited tobacco NR indicating reversion of a Nia30 mutant NR locus. Twelve of 26 regenerated tobacco plants analyzed had NR subunits with the electrophoretic mobility and antigenic properties of barley NR. These included plants regenerated from colonies selected from 1) co-culturing a mixture of Nia30 protoplasts with irradiated barley protoplasts without a fusion treatment, 2) a protoplast fusion treatment of Nia30 and barley protoplasts, and 3) a fusion treatment of Nia30 protoplasts with irradiated barley protoplasts. No barley-like NR was detected in plants regenerated from a colony that grew on nitrate following selfed fusion of Nia30 protoplasts. Because tobacco plants expressing barley-like NR were recovered from mixture controls as well as fusion treatments, explanations for these results other than protoplast fusionmediated gene transfer are discussed.     

Differential mercury volatilization by tobacco organs expressing a modified bacterial merA gene

INTRODUCTIONEnvironmental pollution is an increasing prob-lem both fOr developing and developed countries.Mercury, both in organic and ionic fOrm, is one of themost hazardous pollutants among the heavy met-als[l]and its accumuIation in human body results ininactivation of metabolic enzymes and structuralproteins[2, 3] giving rise to serious health problems(Minamatasyndrome).Usually mercury pollution is caused by indus-trial and agricultural activities, releasing mercuryinto air, water an…     

Inheritance of a bacterial hygromycin phosphotransferase gene in the progeny of primary transgenic pea plants

Summary An analysis of the progeny of primary transgenic pea plants in terms of transmission of the transferred DNA, fertility and morphology is presented. A transformation system developed for pea that allows the regeneration of fertile transgenic pea plants from calli selected for antibiotic resistance was used. Expiants from axenic shoot cultures were co-cultivated with a nononcogenic Agrobacterium tumefaciens strain carrying a gene encoding hygromycin phosphotransferase as selectable marker, and transformed callus could be selected on callus-inducing media containing 15 mg/l hygromycin. After several passages on regeneration medium, shoot organogenesis could be reproducibly induced on the hygromycin resistant calli, and the regenerated shoots could subsequently be rooted and transferred to the greenhouse, where they proceeded to flower and set seed. The transmission of the introduced gene into the progeny of the regenerated transgenic plants was studied over two generations, and stable transmission was shown to take place. The transgenic nature of the calli and regenerated plants and their progeny was confirmed by DNA and RNA analysis. The DNA and ploidy levels of the progeny plants and primary regenerants were studied by chromosome analysis, and the offspring of the primary transformants were evaluated morphologically.Abbreviations 2,4-D 2,4-Dichlorophenoxyacetic acid - BA 6-ben-zyladenine - hpt hygromycin phosphotransferase gene - IAA indole acetic acid, kin, kinetin - NAA -naphtalene acetic acid - picloram 4-amino-3,5,6-trichloropicolinic acid     

Transformation of barley scutellum protoplasts: regeneration of fertile transgenic plants

 A system for barley transformation via polyethyleneglycol-mediated DNA uptake into protoplasts isolated directly from scutella and the regeneration of transgenic plants is reported. Scutellum protoplasts (cv. Clipper, an Australian malting cultivar) were co-transformed with plasmids Act 1-DGUS, containing the marker uidA gene, and pCaIneo, which contains the selectable marker neomycin phosphotransferase gene. Protoplast-derived calluses were selected on medium containing the antibiotic G418 (25 and 15 mg.l^–1) and macroscopic antibiotic resistant colonies were recovered. Fertile plants were regenerated from a callus line and molecular analysis confirmed transgene integration. Received: 11 October 1999 / Revision received: 11 February 2000 / Accepted: 11 February 2000