Genetic transformation and full recovery of alfalfa plants via secondary somatic embryogenesis

A genetic transformation method via secondary somatic embryogenesis was developed for alfalfa (Medicago sativa L.). Mature somatic embryos of alfalfa were infected by Agrobacterium strain GV3101 containing the binary vector pCAMBIA2301. pCAMBIA2301 harbors the uidA Gus reporter gene and npt II acts as the selectable marker gene. Infected primary embryos were placed on SH2K medium containing plant growth regulators to induce cell dedifferentiation and embryogenesis under 75 mg/L kanamycin selection. The induced calli were transferred to plant medium free of plant growth regulators for embryo formation while maintaining selection. Somatic embryos germinated normally upon transfer to a germination medium. Plants were recovered and grown in a tissue culture room before transfer to a greenhouse. Histochemical analysis showed high levels of GUS activity in secondary somatic embryos and in different organs of plants recovered from secondary somatic embryos. The presence and stable integration of transgenes in recovered plants were confirmed by polymerase chain reaction using transgene-specific primers and Southern blot hybridization using the npt II gene probe. The average transformation efficiency achieved via secondary somatic embryogenesis was 15.2%. The selection for transformation throughout the cell dedifferentiation and embryogenic callus induction phases was very effective, and no regenerated plants escaped the selection procedure. Alfalfa transformation is usually achieved through somatic embryogenesis using different organs of developed plants. Use of somatic embryos as explants for transformation can avoid the plant development phase, providing a faster procedure for introduction of new traits and facilitates further engineering of previously transformed lines.     

Zein accumulation in forage species (<Emphasis Type="Italic">Lotus corniculatus</Emphasis> and <Emphasis Type="Italic">Medicago sativa</Emphasis>) and co-expression of the γ-zein:KDEL and β-zein:KDEL polypeptides in tobacco leaf

Plants of birdsfoot trefoil (Lotus corniculatus), alfalfa (Medicago sativa) and tobacco (Nicotiana tabacum) were transformed by Agrobacterium with binary vectors harbouring genes that code either for wild-type and %-zein:KDEL, or for #-zein:KDEL. The maize seed storage proteins %-zein and #-zein are rich in sulphur amino acids, and our long-term goal is to improve alfalfa and birdsfoot trefoil forage quality. Significant levels of zeins were detected in leaves of birdsfoot trefoil transformants, ranging up to 0.055% and 0.30% of total extractable protein for %-zein and #-zein:KDEL, respectively. In leaves of alfalfa, the %-zein:KDEL expression level was up to 0.026% of the total extractable protein. From a F₁ population of transgenic tobacco, a plant was selected in which the amount of zeins (%-zein:KDEL plus #-zein:KDEL) accounted for 1.1% of the total extractable protein.     

Transformation of potato (Solanum tuberosum) using particle bombardment

Internodes, leaves and tuber slices from potato (Solanum tuberosum), genotype 1024-2, were subjected to particle bombardment. Transient expression was optimized using the uidA and the luc reporter genes that encode #-glucuronidase (GUS) and luciferase, respectively. Stable transformation was achieved using the neomycin phosphotransferase (nptII) gene, which confers resistance to the antibiotic kanamycin. The influence of biological parameters (tissue type, growth period before bombardment, pre- and post-bombardment osmoticum treatment) and physical parameters (helium pressure, tissue distance) that are known to possibly affect stable transformation were investigated. Putative transgenic plants, which rooted in media containing kanamycin, were obtained from all of the tissues tested although there were large differences in the efficiency: internodes (0.77 plants per bombarded explant), microtuber slices (0.10 plants per bombarded explant) and leaves (0.02 plants per bombarded explant). Southern blot analysis of putative transgenic plants confirmed the integration of the transgenes into plant DNA. The results indicate that an efficient particle bombardment protocol is now available for both transient and stable transformation of potato internodal segments, thus contributing to an enhanced flexibility in the delivery of transgenes to this important food crop.     

Introduction and expression of an insect proteinase inhibitor in alfalfa Medicago sativa L.

As one approach to alleviating the need for insecticide spraying, our objective is to express protein insecticides in transgenic alfalfa. To initiate these studies, a cDNA encoding the protease inhibitor (PI) anti-elastase from Manduca sexta was placed under the control of the CaMV 35S promoter, inserted into pAN 70, and transferred into leaf and petiole sections of alfalfa (Medicago sativa L.) using Agrobacterium tumefaciens mediated gene transfer. Transformation rates were 10% of all explants exposed to Agrobacterium. More than 1000 transgenic plants containing the PI have been recovered. Transgenic plants were initially identified when leaf explants from the regenerated plants formed callus in the presence of 50 g/ml kanamycin, and subsequently the presence of the PI gene was confirmed by southern analysis. The 35S promoter-PI fusion produced up to 0.125% of total protein as PI protein in leaves, roots, and flowers. Progeny analysis demonstrated Mendelian segregation of the NPTII gene (observed as kanamycin resistance) and the PI (confirmed by southern analysis). Accumulation of the anti-elastase PI insecticide in transgenic alfalfa reduced the onset of thrip predation, suggesting that this methodology can establish insect resistance within this agronomically important legume.Abbreviations Km kanamycin - PI protease inhibitor - SDS Sodium dodecyl sulfate - NPTII neomycin phosphotransferase II - PCR polymerase chain reaction - SH Shenk and Hildebrandt (1972) medium     

Efficient Agrobacterium-mediated transformation of <Emphasis Type="Italic">Lotus japonicus</Emphasis> with reliable antibiotic selection

We have developed a new procedure for transforming a model legume, Lotus japonicus, that yields transformed plants from transverse cotyledon segments without contamination from the presence of non-transformants that survived the antibiotic selection. L. japonicus was transformed with the HPT gene as a selectable marker and the GUS reporter gene, both of which were driven by cauliflower mosaic virus 35S promoter. The efficacy of selection with hygromycin was tested using the assay of GUS activity in putative transformants. The integration of the GUS gene was also confirmed by polymerase chain reaction analysis of the genomic DNA. The integrated T-DNA was stable and inherited as a dominant trait. This procedure may have potential effectiveness and application in large-scale transformation for insertional mutagenesis or gene tagging.     

A novel dominant selectable system for the selection of transgenic plants under in vitro and greenhouse conditions based on phosphite metabolism

Antibiotic and herbicide resistance genes are currently the most frequently used selectable marker genes for plant research and crop development. However, the use of antibiotics and herbicides must be carefully controlled because the degree of susceptibility to these compounds varies widely among plant species and because they can also affect plant regeneration. Therefore, new selectable marker systems that are effective for a broad range of plant species are still needed. Here, we report a simple and inexpensive system based on providing transgenic plant cells the capacity to convert a nonmetabolizable compound (phosphite, Phi) into an essential nutrient for cell growth (phosphate) trough the expression of a bacterial gene encoding a phosphite oxidoreductase (PTXD). This system is effective for the selection of Arabidopsis transgenic plants by germinating T0 seeds directly on media supplemented with Phi and to select transgenic tobacco shoots from cocultivated leaf disc explants using nutrient media supplemented with Phi as both a source of phosphorus and selective agent. Because the ptxD/Phi system also allows the establishment of large‐scale screening systems under greenhouse conditions completely eliminating false transformation events, it should facilitate the development of novel plant transformation methods.     

A new GST-MAT vector containing both ipt and iaaM/H genes can produce marker-free transgenic tobacco plants with high frequency

. Agrobacterium-mediated transformation is highly dependent upon competency of the target plant tissues. It is important to develop the capacity of transformed cells to include cell proliferation and differentiation. A system which results in cell proliferation and differentiation only of transformed cells is highly desirable for plant transformation. We report here a new GST-MAT vector system (MATIMH), in which the ipt gene combined with iaaM/H genes was used as the selectable marker gene and the GST-II promoter was used as the promoter of the R gene in a site-specific recombination system. In tobacco transformation, the combination of the ipt gene and the iaaM/H genes can result in the production of both auxin and cytokinin in transformed tissues and induce regeneration of transgenic shoots exhibiting an ipt-shooty phenotype more efficiently than the ipt gene alone. When we transformed 20 tobacco leaf discs with the MATIMH vector, marker-free transgenic plants were produced from five (41.6%) out of 12 ipt-shooty lines. These results indicated that the combination of the iaaM/H genes and the ipt gene can more efficiently produce both transgenic plants and marker-free transgenic plants.     

Efficient biolistic transformation of maize (Zea mays L.) and wheat (Triticum aestivum L.) using the phosphomannose isomerase gene, pmi, as the selectable marker

A selectable marker system for plant transformation that does not require the use of antibiotics or herbicides was developed. The selectable marker consists of the manA gene from Escherichia coli under the control of a plant promoter that encodes for phosphomannose isomerase, pmi. Only transgenic plants were able to metabolize the selection agent, mannose, into a usable source of carbon, fructose. Transgenic plants were produced efficiently after delivery by Biolistics™ of the pmi gene into maize and wheat tissues, with mean transformation frequencies of 45% for maize and 20% for wheat. Adjustment of the sucrose and mannose levels in the selection medium essentially eliminated escapes. Transgenic events can be identified as early as 2 months for wheat and 4 months for maize. A simple test, a modified chlorophenol red assay, was used for early identification of transgenic events expressing the pmi gene. Transformation frequencies for both crops exceeded those obtained with the bar and pat genes with selection on either Basta^® or bialaphos.     

Plant selection principle based on xylose isomerase

Summary The xylose isomerase genes (xylA) from Thermoanaerobacterium thermosulfurogenes and Streptomyces rubiginosus were introduced and expressed in three plant species (potato, tobacco and tomato) and transgenic plants were selected on xylose-containing medium. The xylose isomerase genes were transferred to explants of the target plant by Agrobacterium-mediated transformation. The xylose isomerase genes were expressed under the control of the enhanced cauliflower mosaic virus 35S promoter and the Ω′ translation enhancer sequence from tobacco mosaic virus. In potato and tomato, xylose isomerase selection was more efficient than the established kanamycin selection. The level of enzyme activity in the regenerated transgenic plants selected on xylose was 5–25-fold higher than the enzyme activity in control plants selected on kanamycin. The xylose isomerase system enables transgenic cells to utilize xylose as a carbohydrate source. In contrast to antibiotic or herbicide resistance-based system where transgenic cells survive on a selective medium but nontransgenic cells are killed, the xylose system is an example of a positive selection system where transgenic cells proliferate while non-transgenic cells are starved but still survive. The results show that a new selection method, is established. The xylose system is devoid of the disadvantages of antibiotic or herbicide selection, and depends on an enzyme which is already being widely utilized in specific food processes and that is generally recognized as safe for use in the starch industry.     

Cyanobacterial GR6 glutamate-1-semialdehyde aminotransferase: a novel enzyme-based selectable marker for plant transformation

The mutant glutamate-1-semialdehyde aminotransferase (GSA-AT) enzyme encoded by the hemL gene of the gabaculine-resistant cyanobacterium Synechococcus PCC6301 strain GR6 was expressed in tobacco following Agrobacterium-mediated transformation of leaf discs. When targeted to plastids, the GR6 hemL gene product conveyed gabaculine resistance to transgenic plants. Selection using 50 and 100 µM gabaculine was shown to produce two distinct explant phenotypes: 'greens' and 'whites'. T₁ progeny displayed Mendelian segregation ratios, and PCR analysis demonstrated the 'green' phenotype corresponded with the presence of the GR6 hemL gene. Furthermore, 'whites' could be rescued after 9 days growth on solid media containing between 5 µM and 25 µM gabaculine, allowing the potential use of this system for the isolation of gabaculine-sensitive transformants in mutagenesis screening. The use of GR6 hemL as a selectable marker gene provides a novel enzyme-based method for the selection of transgenic regenerants without the need for antibiotic-resistance markers.     

Growth regulator pretreatment improves somatic embryogenesis from leaves of squash (Cucurbita pepo l.) and melon (Cucumis melo l.)

Leaf explants of squash (Cucurbita pepo L.) and melon (Cucumis melo L.) were pretreated initially with 113.1, 226.2 or 452.4 µM 2,4-dichlorophenoxyacetic acid (2,4-D), 46.5, 93 or 186 µM kinetin or a combination of both at the above concentrations, for 6, 24 or 48 h. After pretreatment, explants were transferred to an agar-solidified medium that was not supplemented with growth regulators or to a species-specific standard induction medium. Control explants from each species were incubated directly on the species-specific standard induction medium. Initial pretreatment of squash explants with 186 µM kinetin and of melon explants with 226.2 µM 2,4-D for 48 h significantly promoted the formation of somatic embryos which developed further to the torpedo-shape stage and germinated. Under these conditions at least four plants can be regenerated per square centimeter of explant surface, thus achieving an increase over non-pretreated cultures of 143% and 130% for squash and melon, respectively.     

Agrobacterium-mediated transformation of alfalfa (Medicago sativa) using a synthetic cry3a gene to enhance resistance against alfalfa weevil

To introduce genetic resistance against alfalfa weevil (Hypera postica), leaves and petiole explants of three commercial alfalfa genotypes, including Km-27, Kk-14 and Syn-18 were transformed with Agrobacterium tumefaciens strains GV101, LBA4404 and AGL01. All the Agrobacterium strains used harbored the recombinant binary vector pBI121 containing a synthetic cry3a gene under the control of CaMV35S promoter as well as the nptII gene as selectable marker. Transformed explants were cultured on callus-induction medium, and the germinated somatic embryos were then transferred to the regeneration medium. The primary transformants were evaluated by PCR and Southern blot analysis. The results indicated successful integration of the target gene into the genomes of primary transgenic lines. Moreover, the expression of Cry3a protein in the transgenic plants was confirmed by ELISA method. Three transgenic lines, including TL6, TL8 and TL11 showed significantly higher levels of insect resistance against H. postica larvae (mortality rate of 73–90 % after infestation), in comparison with the control plants during the two-year bioassays. All transgenic plants were fertile and no irregular behavior in terms of growth and the morphological traits were observed. Transgenic plants developed during the course of this study are currently being grown in greenhouse and will be crossed with each other for seed production.     

Agrobacterium tumefaciens-mediated transformation of bush monkey-flower (Mimulus aurantiacus Curtis) with a new reporter gene ZsGreen

A successful in vitro Agrobacterium-mediated transformation protocol was developed for Mimulus aurantiacus, a model species for ecological and evolutionary genetics and a promising ornamental plant. Three binary vectors were tested, each containing the hptII selectable marker gene and one of the reporter genes: gusA, EGFP or ZsGreen, all of them under CaMV 35S promoter. Genetic transformation was achieved through 4 days of co-cultivation of leaf, petiole and hypocotyl explants with Agrobacterium tumefaciens strain LBA 4404. Explants produced transformed callus tissue on solid modified Murashige and Skoog medium supplemented with 1 mg L^?1 6-benzylaminopurine, 0.5 mg L^?1 1-naphthaleneacetic acid, 30 g L^?1 sucrose and 20 or 50 mg L^?1 hygromycin B. All three reporter genes were expressed in callus tissue but the intensity of expression gradually decreased during further plant development. The new reporter gene ZsGreen proved suitable for plant transformation experiments since very intense and bright fluorescence was detected. Out of 1,760 co-cultured explants, 110 plants were regenerated and all of them were found to be PCR positive for the selection and/or reporter genes. Chemiluminescent Southern blot analysis revealed that 91 % of the regenerated plants (100 T₀ plants) contained T-DNA integrated in their genome. Transformation efficiency varied from 1.4 to 23.3 % for hypocotyl and petiole explants, respectively. Integration of some backbone sequences in plant genomes was confirmed in 75.3 % of T₀ plants. Using this protocol, stable transformants expressing selectable marker gene hptII and one of the reporter genes (gusA, ZsGreen or EGFP) were obtained in 4–5 months.     

Over-expression of StAPX in tobacco improves seed germination and increases early seedling tolerance to salinity and osmotic stresses

Ascorbate peroxidase plays a key role in scavenging reactive oxygen species under environmental stresses and in protecting plant cells against toxic effects. The Solanum lycopersicum thylakoid-bound ascorbate peroxidase gene (StAPX) was introduced into tobacco under the control of the cauliflower mosaic virus 35S promoter. Transformants were selected for their ability to grow on medium containing kanamycin. RNA gel blot analysis confirmed that StAPX was transferred into the tobacco genome and StAPX was induced by salt and osmotic stresses in tomato leaves. Over-expression of StAPX in tobacco improved seed germination rate and elevated stress tolerance during post-germination development. Two transgenic lines showed higher APX activity and accumulated less hydrogen peroxide than wild-type plants after stress treatments. The photosynthetic rates, the root lengths, the fresh and dry weights of the transgenic lines were distinctly higher than those of wild-type plants under stress conditions. Results indicated that the over-expression of StAPX had enhanced tolerance to salt stress and osmotic stress in transgenic tobacco plants.     

Flexible antipredator behaviour in herbivorous mites through vertical migration in a plant

When predation risk varies in space and time and with predator species, successful prey defence requires specific responses to each predator. In cassava fields in Africa, the herbivorous cassava green mite (Mononychellus tanajoa) is attacked by three predatory mite species that are segregated within the plant: the leaf-dwelling Typhlodromalus manihoti and Euseius fustis occur on the middle leaves, whereas the apex-inhabiting T. aripo migrates from the apex to the top leaves only during the night. We found that differential distributions of these predators allow prey to escape predation by vertical migration to other plant strata. We studied the role of odours in the underlying prey behaviour on predator-free plants placed downwind from plants with predators and prey or with prey only. Prey showed increased vertical migration in response to predator-related odours. Moreover, these responses were specific: when exposed to odours associated with T. manihoti, prey migrated upwards, irrespective of the plant stratum where they were placed. Odours associated with T. aripo triggered a flexible response: prey on the top leaves migrated downwards, whereas prey on the middle leaves migrated upwards. Odours associated with E. fustis, a low-risk predator, did not elicit vertical migration. Further experiments revealed that: (1) prey migrate up or down depending on the stratum where they are located, and (2) prey discrimination among predators is based upon the perception of predator species-specific body odours. Thus, at the scale of a single plant, odour-based enemy specification allows herbivorous mites to escape predation by vertical migration.     

Development of a plant transformation selection system based on expression of genes encoding gentamicin acetyltransferases

The development of selectable markers for transformation has been a major factor in the successful genetic manipulation of plants. A new selectable marker system has been developed based on bacterial gentamicin-3-N-acetyltransferases [AAC(3)]. These enzymes inactivate aminoglycoside antibiotics by acetylation. Two examples of AAC(3) enzymes have been manipulated to be expressed in plants. Chimeric AAC(3)-III and AAC(3)-IV genes were assembled using the constitutively expressed cauliflower mosaic virus 35S promoter and the nopaline synthase 3′ nontranslated region. These chimeric genes were engineered into vectors for Agrobacterium-mediated plant transformation. Petunia hybrida and Arabidopsis thaliana tissue transformed with these vectors grew in the presence of normally lethal levels of gentamicin. The transformed nature of regenerated Arabidopsis plants was confirmed by DNA hybridization analysis and inheritance of the selectable phenotype in progeny. The chimeric AAC(3)-IV gene has also been used to select transformants in several additional plant species. These results show that the bacterial AAC(3) genes will serve as useful selectable markers in plant tissue culture.     

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.     

Inducible Excision of Selectable Marker Gene from Transgenic Plants by the Cre/<Emphasis Type="Italic">lox</Emphasis> Site-specific Recombination System

In a plant transformation process, it is necessary to use marker genes that allow the selection of regenerated transgenic plants. However, selectable marker genes are generally superfluous once an intact transgenic plant has been established. Furthermore, they may cause regulatory difficulties for approving transgenic crop release and commercialization. We constructed a binary expression vector with the Cre/lox system with a view to eliminating a marker gene from transgenic plants conveniently. In the vector, recombinase gene cre under the control of heat shock promoter and selectable marker gene nptII under the control of CaMV35S promoter were placed between two lox P sites in direct orientation, while the gene of interest was inserted outside of the lox P sites. By using this vector, both cre and nptII genes were eliminated from most of the regenerated plants of primary transformed tobacco through heat shock treatment, while the gene of interest was retained and stably inherited. This autoexcision strategy, mediated by the Cre/lox system and subjected to heat shock treatment to eliminate a selectable marker gene, is easy to adopt and provides a promising approach to generate marker-free transgenic plants.