A large-scale study of rice plants transformed with different T-DNAs provides new insights into locus composition and T-DNA linkage configurations

Transgenic locus composition and T-DNA linkage configuration were assessed in a population of rice plants transformed using the dual-binary vector system pGreen (T-DNA containing the bar and gus genes)/pSoup (T-DNA containing the aphIV and gfp genes). Transgene structure, expression and inheritance were analysed in 62 independently transformed plant lines and in around 4,000 progeny plants. The plant lines exhibited a wide variety of transgenic locus number and composition. The most frequent form of integration was where both T-DNAs integrated at the same locus (56% of loci). When single-type T-DNA integration occurred (44% of loci), pGreen T-DNA was preferentially integrated. In around half of the plant lines (52%), the T-DNAs integrated at two independent loci or more. In these plants, both mixed and single-type T-DNA integration often occurred concurrently at different loci during the transformation process. Non-intact T-DNAs were present in 70–78% of the plant lines causing 14–21% of the loci to contain only the mid to right border part of a T-DNA. In 53–66% of the loci, T-DNA integrated with vector backbone sequences. Comparison of transgene presence and expression in progeny plants showed that segregation of the transgene phenotype was not a reliable indicator of either transgene inheritance or T-DNA linkage, as only 60–80% of the transgenic loci were detected by the expression study. Co-expression (28% of lines) and backbone transfer (53–66% of loci) were generally a greater limitation to the production of marker-free T₁ plants expressing the gene of interest than co-transformation (71% of lines) and unlinked integration (44% of loci).     

Integration of T-DNA binary vector 'backbone' sequences into the tobacco genome: evidence for multiple complex patterns of integration

During the process of crown gall tumorigenesis, Agrobacterium tumefaciens transfers part of the tumor-inducing (Ti) plasmid, the T-DNA, to a plant cell where it eventually becomes stably integrated into the plant genome. Directly repeated DNA sequences, called T-DNA borders, define the left and the right ends of the T-DNA. The T-DNA can be physically separated from the remainder of the Ti-plasmid, creating a 'binary vector' system; this system is frequently used to generate transgenic plants. Scientists initially thought that only those sequences located between T-DNA left and right borders transferred to the plant. More recently, however, several reports have appeared describing the integration of the non-T-DNA binary vector 'backbone' sequences into the genome of transgenic plants. In order to investigate this phenomenon, we constructed T-DNA binary vectors containing a nos-nptll gene within the T-DNA and a mas2'-gusA (β-glucuronidase) gene outside the T-DNA borders. We regenerated kanamycin-resistant transgenic tobacco plants and analyzed these plants for the expression of the vector-localized gusA gene and for the presence of binary vector backbone sequences. Approximately one-fifth of the plants expressed detectable GUS activity. PCR analysis indicated that approximately 75% of the plants contained the gusA gene. Southern blot analysis indicated that the vector backbone sequences could integrate into the tobacco genome linked either to the left or to the right T-DNA border. The vector backbone sequences could also integrate into the plant genome independently of (unlinked to) the T-DNA. Although we could readily detect T-strands containing the T-DNA within the bacterium, we could not detect T-strands containing only the vector backbone sequences or these vector sequences linked to the T-DNA.     

Marker-Free Transgenic Chrysanthemum Obtained by <Emphasis Type="Italic">Agrobacterium</Emphasis>-Mediated Transformation with Twin T-DNA Binary Vectors

In this study, a superbinary vector was constructed to evaluate the potential of a twin T-DNA system for generating selectable marker-free transgenic chrysanthemum plants. The first T-DNA of the pCAMBIA 1300 vector contained the hygromycin phosphotransferase (hpt) selectable marker gene, while the second T-DNA carried the β-glucuronidase gene (uidA) and featuring the gene of interest. The two T-DNA regions were placed adjacent to each other with no intervening region. This vector was then used to transform transversal thin cell layers (1–2 mm thick) of internodal stem segments of chrysanthemum via Agrobacterium-mediated transfer. Putative transgenic plants were obtained and analyzed for presence and integration of the transgene using polymerase chain reaction amplification and Southern blotting. The primary cotransformation frequency was calculated at 38.4%. A total of 17 hpt-resistant/gus-positive T0 plants were evaluated for segregation in the next generation (T1), and among those approximately 15.7% carried the transgene. Overall, the two T-DNA system appeared to be a useful approach to generate marker-free transgenic chrysanthemum plants, thereby eliminating public concerns regarding proliferation of antibiotic and herbicide resistance genes into the environment.     

Number and Accuracy of T-DNA Insertions in Transgenic Banana (Musa spp.) Plants Characterized by an Improved Anchored PCR Technique

Nineteen transgenic banana plants, produced via Agrobacterium-mediated transformation, were analyzed for the integration of T-DNA border regions using an improved anchored PCR technique. The method described is a relatively fast, three-step procedure (restriction digestion of genomic DNA, ligation of ‘vectorette’-type adaptors, and a single round of suppression PCR) for the amplification of specific T-DNA border-containing genomic fragments. Most transgenic plants carried a low number of inserts and the method was suitable for a detailed characterization of the integration events, including T-DNA border integrity as well as the insertion of non-T-DNA vector sequences, which occurred in 26% of the plants. Furthermore, the particular band pattern generated by four enzyme/primer combinations for each individual plant served as a fingerprint, allowing the identification of plants representing identical transformation events. Genomic Southern hybridization and nucleotide sequence analysis of amplification products confirmed the data obtained by anchored PCR. Sequencing of seven right or left border junction regions revealed different T-DNA processing events for each plant, indicating a relatively low frequency of precisely nicked T-DNA integration among the plants studied.     

Transgene behaviour in populations of rice plants transformed using a new dual binary vector system: pGreen/pSoup

Transgene integration, expression level and stability have been studied, across two generations, in a population of rice plants transformed using a new dual binary vector system: pGreen/pSoup. pGreen is a small Ti binary vector unable to replicate in Agrobacterium without the presence of another binary plasmid, pSoup, in the same strain. We engineered both pGreen and pSoup to contain each a different T-DNA. Transformation experiments were conducted using a pGreen vector containing the bar and gusA expression units (no transgene in pSoup) or with a pSoup vector containing an aphIV and gfp expression units (no transgene in pGreen). High plant transformation frequencies (up to 40%) were obtained using herbicide resistance ( bar) or antibiotic resistance ( aphIV) genes. Around 80% of the independently transformed plants expressed unselected reporter genes ( gusA or gfp) present in the vectors. Backbone sequences transfer was frequent (45% of lines) and occurred often in multicopy lines. Around 15-20% of the rice plant lines contained a single T-DNA integration without backbone. Integration of additional transgene copies did not improve expression levels in either T(0) plants or T(1) progenies. Nearly all multicopy lines contained transgenes integrated at several loci in the plant genome, showing that T-DNAs from either pGreen or pSoup frequently integrated at unlinked loci. Precise determination of loci number required the analysis of transgene presence in progeny. Segregation of transgene phenotype was generally misleading and tended to underestimate the real number of transgenic loci. The contribution of this new dual-binary vector system to the development of high-throughput rice transformation systems and to the production of marker-free transgenic rice plants is discussed.     

Optimized Agrobacterium-mediated sorghum transformation protocol and molecular data of transgenic sorghum plants

Agrobacterium-mediated sorghum transformation frequency has been enhanced significantly via medium optimization using immature embryos from sorghum variety TX430 as the target tissue. The new transformation protocol includes the addition of elevated copper sulfate and 6-benzylaminopurine in the resting and selection media. Using Agrobacterium strain LBA4404, the transformation frequency reached over 10% using either of two different selection marker genes, moPAT or PMI, and any of three different vectors in large-scale transformation experiments. With Agrobacterium strain AGL1, the transformation frequencies were as high as 33%. Using quantitative PCR analyses of 1,182 T₀ transgenic plants representing 675 independent transgenic events, data was collected for T-DNA copy number, intact or truncated T-DNA integration, and vector backbone integration into the sorghum genome. A comparison of the transformation frequencies and molecular data characterizing T-DNA integration patterns in the transgenic plants derived from LBA4404 versus AGL1 transformation revealed that twice as many transgenic high-quality events were generated when AGL1 was used compared to LBA4404. This is the first report providing molecular data for T-DNA integration patterns in a large number of independent transgenic plants in sorghum.     

Additional virulence genes in conjunction with efficient selection scheme, and compatible culture regime enhance recovery of stable transgenic plants in cowpea via Agrobacterium tumefaciens-mediated transformation

A critical step in the development of robust Agrobacterium tumefaciens-mediated transformation system in recalcitrant grain legume, cowpea is the establishment of optimal conditions for efficient T-DNA delivery into target tissue and recovery of transgenic plants. A dramatic increase in efficiency of T-DNA delivery was achieved by constitutive expression of additional vir genes in resident pSB1 vector in Agrobacterium strain LBA4404. A geneticin based selection system permitted rapid and efficient identification of transgenic shoots without interfering with their regeneration, and eliminated the bulk of escapes. Supplementation of 0.5 μM kinetin to medium containing 5.0 μM benzyl aminopurine after 1 week of culture followed by 3 weeks of culture were found critical for optimal multiplication and elongation of transformed shoots from cotyledonary node explants. Combining these three developments, we recovered fertile transgenic plants at a frequency of 1.64%, significantly higher than previous reports. The presence, integration, expression and inheritance of transgenes were confirmed by molecular analysis. The protocol developed for cultivar Pusa Komal will facilitate the transfer of desirable traits into cowpea.     

A transformation vector for the production of marker-free transgenic plants containing a single copy transgene at high frequency

We represent here the GST-MAT vector system. The R recombinase gene of the site-specific recombination system R/RS from Zygosaccharomyces rouxii was fused to the chemical inducible promoter of the glutathione-S-transferase (GST-II-27) gene from Zea mays. Upon excision, the isopentenyltransferase (ipt) gene that is used as a selectable marker gene is removed. When the cauliflower mosaic virus 35S promoter (CaMV 35S) was used to express R recombinase, 67% of the marker-free transgenic plants had more than three transgene copies. Because the CaMV 35S promoter transiently and efficiently excised the ipt gene before callus and adventitious bud formation, the frequency of emergence of the ipt-shooty explants with a single T-DNA copy might be reduced. In this study we show that the GST-MAT vector efficiently produced transgenic ipt-shooty explants from 37 (88%) out of 42 differentiated adventitious buds and marker-free transgenic plants containing the GUS gene from five (14%) out of 37 ipt-shooty lines. Furthermore, the GST-MAT vector also induced two marker-free transgenic plants without the production of ipt-shooty intermediates. Southern blot analysis showed that six (86%) out of seven marker-free transgenic plants had a single GUS gene. This result suggests that the GST-MAT vector is useful to generate high frequency, marker-free transgenic plants containing a single transgene.     

pBECKS2000: a novel plasmid series for the facile creation of complex binary vectors, which incorporates “clean-gene” facilities

A new plasmid series has been created for Agrobacterium-mediated plant transformation. The pBECKS2000 series of binary vectors exploits the Cre/loxP site-specific recombinase system to facilitate the construction of complex T-DNA vectors. The new plasmids enable the rapid generation of T-DNA vectors in which multiple genes are linked, without relying on the availability of purpose-built cassette systems or demanding complex, and therefore inefficient, ligation reactions. The vectors incorporate facilities for the removal of transformation markers from transgenic plants, while still permitting simple in vitro manipulations of the T-DNA vectors. A `shuttle' or intermediate plasmid approach has been employed. This permits independent ligation strategies to be used for two gene sets. The intermediate plasmid sequence is incorporated into the binary vector through a plasmid co-integration reaction which is mediated by the Cre/loxP site-specific recombinase system. This reaction is carried out within Agrobacterium cells. Recombinant clones, carrying the co-integrative binary plasmid form, are selected directly using the antibiotic resistance marker carried on the intermediate plasmid. This strategy facilitates production of co-integrative T-DNA binary vector forms which are appropriate for either (1) transfer to and integration within the plant genome of target and marker genes as a single T-DNA unit; (2) transfer and integration of target and marker genes as a single T-DNA unit but with a Cre/loxP facility for site-specific excision of marker genes from the plant genome; or (3) co-transfer of target and marker genes as two independent T-DNAs within a single-strain Agrobacterium system, providing the potential for segregational loss of marker genes.     

T-DNA vector backbone sequences are frequently integrated into the genome of transgenic plants obtained by Agrobacterium-mediated transformation

Transgenic Arabidopsis and tobacco plants (125) derived from seven Agrobacterium-mediated transformation experiments were screened by polymerase chain reaction and DNA gel blot analysis for the presence of vector `backbone' sequences. The percentage of plants with vector DNA not belonging to the T-DNA varied between 20% and 50%. Neither the plant species, the explant type used for transformation, the replicon type nor the selection seem to have a major influence on the frequency of vector transfer. Only the border repeat sequence context could have an effect because T-DNA vector junctions were found in more than 50% of the plants of three different transformation series in which T-DNAs with octopine borders without inner border regions were used. Strikingly, many transgenic plants contain vector backbone sequences linked to the left T-DNA border as well as vector junctions with the right T-DNA border. DNA gel blots indicate that in most of these plants the complete vector sequence is integrated. We assume that integration into the plant genome of complete vector backbone sequences could be the result of a conjugative transfer initiated at the right border and subsequent continued copying at the left and right borders, called read-through. This model would imply that the left border is not frequently recognized as an initiation site for DNA transfer and that the right border is not efficiently recognized as a termination site for DNA transfer.     

A simple method to enrich an Agrobacterium-transformed population for plants containing only T-DNA sequences

A simple modification to standard binary vector design has been utilized to enrich an Agrobacterium-transformed population for plants containing only T-DNA sequences. A lethal gene was incorporated into the non-T-DNA portion of a binary vector, along with a screenable marker. The resulting class of vectors is designated as NTL T-DNA vectors (non-T-DNA lethal gene-containing T-DNA vectors). The lethal gene used here is a CaMV 35S-barnase gene with an intron in the coding sequence (barnase-INT); the screenable marker is a pMAS-luciferase gene with an intron in the coding sequence (LUC-int). To evaluate the utility of this vector design, tobacco plants were transformed with either the NTL T-DNA vector or a control vector from which most of the barnase-INT gene was deleted. Populations of 50 transgenic plants were scored for LUC expression. The results indicated a dramatic reduction in the presence of non-T-DNA sequences in the transgenic population using the NTL T-DNA vector. Only one transgenic plant was found to be LUC+ using the NTL vector, compared with 42 of 50 plants using the control vector. Importantly, the efficiency with which transformed tobacco plants was obtained was reduced by no more than 30%. The reduction in LUC+ transgenics was partially reversed when a barstar-expressing tobacco line was transformed, indicating that barnase expression was responsible for the reduced frequency of incorporating non-T-DNA sequences. Similar transformation results were obtained with tomato and grape. The incorporation of a barnase-INT gene outside the left border appears to provide a generally applicable tool for enriching an Agrobacterium-transformed population for plants containing only T-DNA sequences.     

利用双T-DNA载体系统培育无选择标记转基因烟草

建立了一种利用双T-DNA载体培育无选择标记转基因植物的方法.通过体外重组构建了双T-DNA双元载体pDLBRBbarm.载体中,选择标记nptⅡ基因和另一代表外源基因的bar基因分别位于2个独立的T-DNA.利用农杆菌介导转化烟草(Nicotiana tabacum L.),在获得的转化植株中,同时整合有nptⅡ基因和bar基因的频率为59.2%.对4个同时整合有nptⅡ和bar基因植株自交获得的T1代株系进行检测分析,发现在3个T1代株系2个T-DNA可以发生分离,其中约19.5%的转基因T1代植株中只存在bar基因而不带选择标记nptⅡ.这一结果说明双T-DNA载体系统能有效地用于培育无选择标记的转基因植物.研究还利用位于2个不同载体上的nptⅡ基因与 bar基因通过农杆菌介导共转化烟草,获得共转化植株的频率为20.0%～47.4%,低于使用双T-DNA转化的共转化频率.     

Zinc finger nuclease and homing endonuclease-mediated assembly of multigene plant transformation vectors

Binary vectors are an indispensable component of modern Agrobacterium tumefaciens-mediated plant genetic transformation systems. A remarkable variety of binary plasmids have been developed to support the cloning and transfer of foreign genes into plant cells. The majority of these systems, however, are limited to the cloning and transfer of just a single gene of interest. Thus, plant biologists and biotechnologists face a major obstacle when planning the introduction of multigene traits into transgenic plants. Here, we describe the assembly of multitransgene binary vectors by using a combination of engineered zinc finger nucleases (ZFNs) and homing endonucleases. Our system is composed of a modified binary vector that has been engineered to carry an array of unique recognition sites for ZFNs and homing endonucleases and a family of modular satellite vectors. By combining the use of designed ZFNs and commercial restriction enzymes, multiple plant expression cassettes were sequentially cloned into the acceptor binary vector. Using this system, we produced binary vectors that carried up to nine genes. Arabidopsis (Arabidopsis thaliana) protoplasts and plants were transiently and stably transformed, respectively, by several multigene constructs, and the expression of the transformed genes was monitored across several generations. Because ZFNs can potentially be engineered to digest a wide variety of target sequences, our system allows overcoming the problem of the very limited number of commercial homing endonucleases. Thus, users of our system can enjoy a rich resource of plasmids that can be easily adapted to their various needs, and since our cloning system is based on ZFN and homing endonucleases, it may be possible to reconstruct other types of binary vectors and adapt our vectors for cloning on multigene vector systems in various binary plasmids.     

Genetic analysis of T-DNA insertions into the tobacco genome

A genetic test was performed on seeds from 283 transgenic tobacco plants obtained by T-DNA transformation. Seeds from self-fertilized transgenic plants were germinated on kanamycin-containing medium, and the percentage of seeds which germinated, as well as the ratio of kanamycin-resistant to kanamycin-sensitive seedlings were scored. Nine categories of transformants could be distinguished according to the number of loci into which T-DNA had inserted, and according to the effects of T-DNA integration on seed or seedling development. In most of the plants, T-DNA was inserted into a single site; others contained multiple independent copies of T-DNA. The number of T-DNA integration sites was found to be independent of whether a binary vector system or a cointegrate Ti plasmid had been used to obtain the transgenic plant. Loss of marker genes or marker gene expression from generation to generation appeared to be a quite frequent event. Plants which appeared to be insertional recessive embryo-lethal mutants did not exhibit this trait in the next generation.Abbreviations Kan^R kanamycin resistant - Kan^S kanamycin sensitive - NOP nopaline - NOS nopaline synthase - NPT II neomycin phosphotransferase II     

The 35S promoter used in a selectable marker gene of a plant transformation vector affects the expression of the transgene

Positive selection of transgenic plants is essential during plant transformation. Thus, strong promoters are often used in selectable marker genes to ensure successful selection. Many plant transformation vectors, including pPZP family vectors, use the 35S promoter as a regulatory sequence for their selectable marker genes. We found that the 35S promoter used in a selectable marker gene affected the expression pattern of a transgene, possibly leading to a misinterpretation of the result obtained from transgenic plants. It is likely that the 35S enhancer sequence in the 35S promoter is responsible for the interference, as in the activation tagging screen. This affected expression mostly disappeared in transgenic plants generated using vectors without the 35S sequences within their T-DNA region. Therefore, we suggest that caution should be used in selecting a plant transformation vector and in the interpretation of the results obtained from transgenic approaches using vectors carrying the 35S promoter sequences within their T-DNA regions.     

Reduced variation in transgene expression from a binary vector with selectable markers at the right and left T-DNA borders

A new binary vector for Agrobacterium-mediated plant transformation was constructed, in which two selectable markers, for kanamycin and hygromycin resistance, were placed next to the right and left T-DNA borders, respectively, and a CaMV 35S promoter-driven β-glucuronidase (GUS) gene was placed between these markers as a reporter gene (transgene). Using double antibiotic selection, all transgenic tobacco plants carrying at least one intact copy of the T-DNA expressed the transgene, and this population exhibited reduced variability in transgene expression as compared with that obtained from the parent vector pBI121. Absence of the intact transgene was the major reason for transgenic plants with little or no transgene expression. Integration of truncated T-DNAs was also observed among transgenic plants that expressed the transgene and carried multiple T-DNA inserts. The copy number of fully integrated T-DNAs was positively associated with transgene expression levels in R₀ plants and R₁ progeny populations. Variability due to position effect was determined among 17 plants carrying a single T-DNA insert. The coefficient of variability among these plants was only 35.5%, indicating a minor role for position effects in causing transgene variability. The new binary vector reported here can therefore be used to obtain transgenic populations with reduced variability in transgene expression.     

pBECKS2000: a novel plasmid series for the facile creation of complex binary vectors, which incorporates "clean-gene" facilities

A new plasmid series has been created for Agrobacterium-mediated plant transformation. The pBECKS2000 series of binary vectors exploits the Cre/loxP site-specific recombinase system to facilitate the construction of complex T-DNA vectors. The new plasmids enable the rapid generation of T-DNA vectors in which multiple genes are linked, without relying on the availability of purpose-built cassette systems or demanding complex, and therefore inefficient, ligation reactions. The vectors incorporate facilities for the removal of transformation markers from transgenic plants, while still permitting simple in vitro manipulations of the T-DNA vectors. A `shuttle' or intermediate plasmid approach has been employed. This permits independent ligation strategies to be used for two gene sets. The intermediate plasmid sequence is incorporated into the binary vector through a plasmid co-integration reaction which is mediated by the Cre/loxP site-specific recombinase system. This reaction is carried out within Agrobacterium cells. Recombinant clones, carrying the co-integrative binary plasmid form, are selected directly using the antibiotic resistance marker carried on the intermediate plasmid. This strategy facilitates production of co-integrative T-DNA binary vector forms which are appropriate for either (1) transfer to and integration within the plant genome of target and marker genes as a single T-DNA unit; (2) transfer and integration of target and marker genes as a single T-DNA unit but with a Cre/loxP facility for site-specific excision of marker genes from the plant genome; or (3) co-transfer of target and marker genes as two independent T-DNAs within a single-strain Agrobacterium system, providing the potential for segregational loss of marker genes. Received: 30 July 1998 / Accepted: 2 November 1998     

T-DNA tagging in the model legume Medicago truncatula allows efficient gene discovery

The annual legume Medicago truncatula has been proposed as a model plant to study various aspects of legume biology including rhizobial and mycorrhizal symbiosis because it is well suited for the genetic analysis of these processes . To facilitate the characterization of M. truncatula genes participating in various developmental processes we have initiated an insertion mutagenesis program in this plant using three different T-DNAs as tags. To investigate which type of vector is the most suitable for mutagenesis we compared the behavior of these T-DNAs. One T-DNA vector was a derivative of pBin19 and plant selection was based on kanamycin resistance. The two other vectors carried T-DNA conferring Basta resistance in the transgenic plants. For each T-DNA type, we determined the copy number in the transgenic lines, the structure of the T-DNA loci and the sequences of the integration sites. The T-DNA derived from pBin19 generated complex T-DNA insertion patterns. The two others generally gave single copy T-DNA inserts that could result in gene fusions for the pGKB5 T-DNA. Analysis of the T-DNA borders revealed that several M. truncatula genes were tagged in these transgenic lines and in vivo gus fusions were also obtained. These results demonstrate that T-DNA tagging can efficiently be used in M. truncatula for gene discovery.