Co-integration, co-expression and inheritance of unlinked minimal transgene expression cassettes in an apomictic turf and forage grass (Paspalum notatum Flugge)

Bahiagrass (Paspalum notatum Flugge) is an important turf and forage grass in the southeastern United States and other subtropical regions. Biolistic co-transfer of two unlinked, minimal, linear transgene expression cassettes (MCs) into the apomictic bahiagrass cv. Argentine was carried out to evaluate co-integration, quantify co-expression and analyze inheritance to apomictic seed progeny. Gold projectiles were coated with minimal unlinked nptII and bar expression cassettes in a 1:2 molar ratio. Complexity of transgene loci correlated with the amount of DNA used during gene transfer. Transgenic plants displayed a simple nptII integration pattern with 1–4 hybridization signals compared to the non-selected bar gene with 2 to more than 5 hybridization signals per transgenic line. Co-expression of unlinked nptII and bar genes occurred in 19 of the 20 co-transformed lines (95% co-expression frequency). Protein quantification revealed that several lines with complex integration patterns displayed a higher transgene expression than lines with simple transgene integration patterns. Several transgenic lines displayed hybridization signals indicative of concatemerization. Concatemers were confirmed following PCR amplification and sequence analysis of transgene loci. The obligate apomictic bahiagrass cv. Argentine produced uniform seed progeny without segregation of simple or complex transgene loci. NPTII- and PAT-ELISA, as well as herbicide application, confirmed stable expression of the nptII and bar gene at levels similar to the primary transformants. These results demonstrate that biolistic transfer of MCs support stable and high level co-expression of transgenes in bahiagrass.     

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.     

Lox-dependent gene expression in transgenic plants obtained via Agrobacterium-mediated transformation

Lox sites of the Cre/lox recombination system from bacteriophage P1 were analyzed for their ability to affect on transgene expression when inserted upstream from a gene coding sequence adjacent to the right border (RB) of T-DNA. Wild and mutated types of lox sites were tested for their effect upon bar gene expression in plants obtained via Agrobacterium-mediated and biolistic transformation methods. Lox-mediated expression of bar gene, recognized by resistance of transgenic plants to PPT, occurred only in plants obtained via Agrobacterium-mediated transformation. RT-PCR analysis confirms that PPT-resistant phenotype of transgenic plants obtained via Agrobacterium-mediated transformation was caused by activation of bar gene. The plasmid with promoterless gus gene together with the lox site adjacent to the RB was constructed and transferred to Nicotiana tabacum as well. Transgenic plants exhibited GUS activity and expression of gus gene was detected in plant leaves. Expression of bar gene from the vectors containing lox site near RB allowed recovery of numerous PPT-resistant transformants of such important crops as Beta vulgaris, Brassica napus, Lactuca sativa and Solanum tuberosum. Our results demonstrate that the lox site sequence adjacent to the RB can be used to control bar gene expression in transgenic plants.     

Transgenic rice as a system to study the stability of transgene expression: multiple heterologous transgenes show similar behaviour in diverse genetic backgrounds

The success of contemporary breeding programmes involving genetic engineering depends on the stability of transgene expression over many generations. We studied the stability of transgene expression in 40 independent rice plant lines representing 11 diverse cultivated varieties. Each line contained three or four different transgenes delivered by particle bombardment, either by cotransformation or in the form of a cointegrate vector. Approximately 75% of the lines (29/40) demonstrated Mendelian inheritance of all transgenes, suggesting integration at a single locus. We found that levels of transgene expression varied among different lines, but primary transformants showing high-level expression of the gna, gusA, hpt and bar transgenes faithfully transmitted these traits to progeny. Furthermore, we found that cry1Ac and cry2A transgene expression was stably inherited when primary transformants showed moderate or low-level expression. Our results show that six transgenes (three markers and three insect-resistance genes) were stably expressed over four generations of transgenic rice plants. We showed that transgene expression was stable in lines of all the rice genotypes we analysed. Our data represent a step forward in the transfer of rice genetic engineering technology from model varieties to elite breeding lines grown in different parts of the world. Received: 22 March 1999 / Accepted: 6 December 1999     

Molecular characterization of the fate of transgenes in transformed wheat (Triticum aestivum L.)

Molecular analysis of the transgenes bar and gus was carried out over successive generations in six independent transgenic lines of wheat, until the plants attained homozygosity. Data on expression and integration of the transgenes is presented. Five of the lines were found to be stably transformed, duly transferring the transgenes to the next generation. The copy number of the transgenes varied from one to five in the different lines. One line was unstable, first losing expression of and then eliminating both the transgenes in R3 plants. Although the gus gene was detected in all the lines, GUS expression had been lost in R2 plants of all but one line. Rearrangement of transgene sequences was observed, but it had no effect on gene expression. All the stable lines were found to segregate for transgene activity in a Mendelian fashion.     

Genetic transformation of commercial cultivars of oat (Avena sativa L.) and barley (Hordeum vulgare L.) using in vitro shoot meristematic cultures derived from germinated seedlings

 Genetic transformation using shoot meristematic cultures (SMCs) derived from germinated seedlings is established in commercial varieties of oat cv 'Garry' and barley cv 'Harrington'. Six-month-old SMCs of oat were induced on MPM and bombarded with bar and uidA; 9-month-old SMCs of barley were induced on an improved medium (MPM-MC) containing maltose and high levels of copper and bombarded with bar/nptII and uidA. After 3–4 months on selection, seven independent transgenic lines of oat were obtained, two lines of barley. All transgenic lines produced T₀ plants; five lines of oat and one line of barley were self-fertile, and the other barley line produced T₁ seed when out-crossed. Both Mendelian and non-Mendelian segregation ratios of transgene expression were observed in T₁ and T₂ progeny of transgenic oat. Normal as well as low physical transmission of the transgenes was also seen in T₁ and T₂ progeny of oat. The bar-containing line of barley showed stable transgene expression in all of the T₁ and T₂ progeny tested. Received: 4 January 1999 / Accepted: 14 January 1999     

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.     

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.     

Structure and function of selectable and non-selectable transgenes in maize after introduction by particle bombardment

Zea mays transformants produced by particle bombardment of embryogenic suspension culture cells of the genotype A188 × B73 and selected on kanamycin or bialaphos were characterized with respect to transgene integration, expression, and inheritance. Selection on bialaphos, mediated by thebar orpat genes, was more efficient than selection on kanamycin, mediated by thenptII gene. Most transformants contained multicopy, single locus, transgene insertion events. A transgene expression cassette was more likely to be rearranged if expression of that gene was not selected for during callus growth. Not all plants regenerated from calli representing single transformation events expressed the transgenes, and a non-selectable gene (uidA) was expressed in fewer plants than was the selectable transgene. Mendelian inheritance of transgenes consistent with transgene insertion at a single locus was observed for approximately two thirds of the transformants assessed. Transgene expression was typically, but not always, predictable in progeny plants-transgene silencing, as well as poor transgene transmission to progeny, was observed in some plant lines in which the parent plants had expressed the transgene.     

Diploid potato (<Emphasis Type="Italic">Solanum tuberosum</Emphasis> L.) as a model crop to study transgene expression

This paper presents a method of Agrobacterium-mediated transformation for two diploid breeding lines of potato, and gives a detailed analysis of reporter gene expression. In our lab, these lines were also used to obtain tetraploid somatic hybrids. We tested four newly prepared constructs based on the pGreen vector system containing the selection gene nptII or bar under the 35S or nos promoter. All these vectors carried gus under 35S. We also tested the pDM805 vector, with the bar and gus genes respectively under the Ubi1 and Act1 promoters, which are strong for monocots. The selection efficiency (about 17%) was highest in the stem and leaf explants after transformation with pGreen where nptII was under 35S. About half of the selected plants were confirmed via PCR and Southern blot analysis to be transgenic and, depending on the combination, 0 to 100% showed GUS expression. GUS expression was strongest in multi-copy transgenic plants where gus was under Act1. The same potato lines carrying multi-copy bar under Ubi1 were also highly resistant to the herbicide Basta. The suggestion of using Agrobacterium-mediated transformation of diploid lines of potato as a model crop is discussed herein.     

Consistent and stable expression of the nptII, uidA and bar genes in transgenic Pinus radiata after Agrobacterium tumefaciens-mediated transformation using nurse cultures

An Agrobacterium tumefaciens-mediated transformation protocol has been developed for embryogenic cell cultures of Pinus radiata. Transgenic lines were only produced when embryogenic tissue was placed on nurse tissue during the Agrobacterium co-cultivation and recovery stages of the procedure. Plantlets were regenerated via somatic embryogenesis from ten of the 11 transgenic lines tested and at least 20 of each line were planted in a GMO glasshouse. Expression of the nptII, uidA and bar genes in up to ten plants of each individual transgenic line was evaluated by molecular, biochemical and functional analysis. As expected, expression of the nptII gene varied among the ten lines, while within ten replicates of the same line, nptII expression appeared to be consistent, with the exception of one line, K3. Likewise, the level of GUS activity varied among transgenic lines, but was relatively consistent in plants derived from the same tissue, except for two lines, G4 and G5. Moreover, similar absolute values and pattern of gene expression of uidA was observed in the transgenic plants, for two consecutive years. Plantlets from eight lines survived a spray treatment with the equivalent of 2 kg/ha and 4 kg/ha of the commercial formulation Buster, whereas non-transformed controls died. Southern hybridisation analysis of embryogenic tissue and green needle tissue from putative transgenic lines demonstrated a relatively low number of gene insertions (from one to nine) of both the bar and nptII genes in the nine transgenic lines tested.     

The development of herbicide-resistant maize: stable Agrobacterium-mediated transformation of maize using explants of type II embryogenic calli

One of the limitations to conducting maize Agrobacterium-mediated transformation using explants of immature zygotic embryos routinely is the availability of the explants. To produce immature embryos routinely and continuously requires a well-equipped greenhouse and laborious artificial pollination. To overcome this limitation, an Agrobacterium-mediated transformation system using explants of type II embryogenic calli was developed. Once the type II embryogenic calli are produced, they can be subcultured and/or proliferated conveniently. The objectives of this study were to demonstrate a stable Agrobacterium-mediated transformation of maize using explants of type II embryonic calli and to evaluate the efficiency of the protocol in order to develop herbicide-resistant maize. The type II embryogenic calli were inoculated with Agrobacterium tumefaciens strain C58C1 carrying binary vector pTF102, and then were subsequently cultured on the following media: co-cultivation medium for 1 day, delay medium for 7 days, selection medium for 4 × 14 days, regeneration medium, and finally on germination medium. The T-DNA of the vector carried two cassettes (Ubi promoter-EPSPs ORF-nos and 35S promoter–bar ORF-nos). The EPSPs conferred resistance to glyphosate and bar conferred resistance to phosphinothricin. The confirmation of stable transformation and the efficiency of transformation was based on the resistance to phosphinothricin indicated by the growth of putative transgenic calli on selection medium amended with 4 mg l^?1 phosphinothricin, northern blot analysis of bar gene, and leaf painting assay for detection of bar gene-based herbicide resistance. Northern blot analysis and leaf painting assay confirmed the expression of bar transgenes in the R₁ generation. The average transformation efficiency was 0.60%. Based on northern blot analysis and leaf painting assay, line 31 was selected as an elite line of maize resistant to herbicide.     

Transgenic rice plants expressing the snowdrop lectin gene (<Emphasis Type="Italic">gna</Emphasis>) exhibit high-level resistance to the whitebacked planthopper (<Emphasis Type="Italic">Sogatella furcifera</Emphasis>)

Transgenic rice plants, expressing snowdrop lectin [Galanthus nivalis agglutinin (GNA)], obtained by Agrobacterium-mediated genetic transformation, were evaluated for resistance against the insect, the whitebacked planthopper (WBPH). The transgene gna was driven by the phloem-specific, rice-sucrose synthase promoter RSs1, and the bar was driven by the CaMV 35S promoter. In our previous study, the transgenic status of these lines was confirmed by Southern, Northern and Western blot analyses. Both the transgenes, gna and bar, were stably inherited and co-segregated into progenies in T₁ to T₅ generations. Insect bioassays on transgenic plants revealed the potent entomotoxic effects of GNA on the WBPH. Also, significant decreases were observed in the survival, development and fecundity of the insects fed on transgenic plants. Furthermore, intact GNA was detected in the total proteins of WBPHs fed on these plants. Western blot analysis revealed stable and consistent expression of GNA throughout the growth and development of transgenic plants. Transgenic lines expressing GNA exhibited high-level resistance against the WBPH. As reported earlier, these transgenics also showed substantial resistance against the brown planthopper and green leafhopper .     

Inheritance of tissue-specific expression of barley hordein promoter-uidA fusions in transgenic barley plants

 Barley (Hordeum vulgare L.) hordeins are alcohol-soluble redundant storage proteins that accumulate in protein bodies of the starchy endosperm during seed development. Strong endosperm-specific β-glucuronidase gene-(uidA; gus) expression driven by B₁- and D-hordein promoters was observed in stably transformed barley plants co-transformed with the selectable herbicide resistance gene, bar. PCR analysis using DNA from calli of 22 different lines transformed with B₁- or D-hordein promoter-uidA fusions showed the expected 1.8-kb uidA fragment after PCR amplification. DNA-blot analysis of genomic DNA from T₀ leaf tissue of 13 lines showed that 12 (11 independent) lines produced uidA fragments and that one line was uidA-negative. T₁ progeny from 6 out of 12 independent regenerable transgenic lines tested for uidA expression showed a 3 : 1 segregation pattern. Of the remaining six transgenic lines, one showed a segregation ratio of 15 : 1 for GUS, one expressed bar alone, one lacked transmission of either gene to T₁ progeny, and three were sterile. Stable GUS expression driven by the hordein promoters was observed in T₅ progeny in one line, T₄ progeny in one line, T₃ progeny in three lines and T₂ or T₁ progeny in the remaining two fertile lines tested; homozygous transgenic plants were obtained from three lines. In the homozygous lines the expression of the GUS protein, driven by either the B₁- or D-hordein promoters, was highly expressed in endosperm at early to mid-maturation stages. Expression of bar driven by the maize ubiquitin promoter was also stably transmitted to T₁ progeny in seven out of eight lines tested. However, in most lines PAT expression driven by the maize ubiquitin promoter was gradually lost in T₂ or later generations; one homozygous line was obtained. In contrast, six out of seven lines stably expressed GUS driven by the hordein promoters in T₂ or later generations. We conclude that the B₁- and D-hordein promoters can be used to engineer, and subsequently study, stable endosperm-specific gene expression in barley and potentially to modify barley seeds through genetic engineering. Received: 28 May 1998 / Accepted: 19 December 1998