Desiccation of plant tissues post-<Emphasis Type="Italic">Agrobacterium</Emphasis> infection enhances T-DNA delivery and increases stable transformation efficiency in wheat

Summary Factors influencing the Agrobacterium-mediated transformation of both monocotyledonous and dicotyledonous plant species have been widely investigated. These factors include manipulating Agrobacterium strains and plasmids, growth conditions for vir gene induction, plant genotype, inoculation and co-culture conditions, and the selection agents and their application regime. We report here a novel physical parameter during co-culture, desiccation of plant cells or tissues post-Agrobacterium infection, which greatly enhances transfer DNA (T-DNA) delivery and increases stable transformation efficiency in wheat. Desiccation during co-culture dramatically suppressed Agrobacterium growth, which is one of the factors known to favor plant cell recovery. Osmotic and abscisic acid treatments and desiccation prior to inoculation did not have the same enhancement effect as desiccation during co-culture on T-DNA delivery in wheat. An efficient transformation protocol has been developed based on desiccation and is suitable for both paromomycin and glyphosate selection. Southern analysis showed approximately 67% of transgenic wheat plants received a single copy of the transgene.     

T-DNA transfer and T-DNA integration efficiencies upon Arabidopsis thaliana root explant cocultivation and floral dip transformation

T-DNA transfer and integration frequencies during Agrobacterium-mediated root explant cocultivation and floral dip transformations of Arabidopsis thaliana were analyzed with and without selection for transformation-competent cells. Based on the presence or absence of CRE recombinase activity without or with the CRE T-DNA being integrated, transient expression versus stable transformation was differentiated. During root explant cocultivation, continuous light enhanced the number of plant cells competent for interaction with Agrobacterium and thus the number of transient gene expression events. However, in transformation competent plant cells, continuous light did not further enhance cotransfer or cointegration frequencies. Upon selection for root transformants expressing a first T-DNA, 43–69 % of these transformants showed cotransfer of another non-selected T-DNA in two different light regimes. However, integration of the non-selected cotransferred T-DNA occurred only in 19–46 % of these transformants, indicating that T-DNA integration in regenerating root cells limits the transformation frequencies. After floral dip transformation, transient T-DNA expression without integration could not be detected, while stable T-DNA transformation occurred in 0.5–1.3 % of the T1 seedlings. Upon selection for floral dip transformants with a first T-DNA, 8–34 % of the transformants showed cotransfer of the other non-selected T-DNA and in 93–100 % of them, the T-DNA was also integrated. Therefore, a productive interaction between the agrobacteria and the female gametophyte, rather than the T-DNA integration process, restricts the floral dip transformation frequencies.     

L-Cysteine increases Agrobacterium-mediated T-DNA delivery into soybean cotyledonary-node cells

A major limitation in producing transgenic soybeans [Glycine max (L.) Merrill] using the Agrobacterium-mediated cotyledonary-node method is low-frequency T-DNA transfer from Agrobacterium tumefaciens into cotyledonary-node cells. We increased Agrobacterium infection from 37% to 91% of explants in the cotyledonary-node region by amending the solid co-cultivation medium with L-cysteine, which resulted in a fivefold increase in stable T-DNA transfer in newly developed shoot primordia. Southern analysis detected greater than a twofold increase in transformation efficiency, as determined by the number of independent fertile, transgene plants per explants inoculated. Enzymatic browning on explant tissue was also reduced, which suggests cysteine may interact with wound- and pathogen-defense responses in the soybean explant, resulting in an increased T-DNA delivery into the cotyledonary-node cells.     

Caspase-resistant VirD2 protein provides enhanced gene delivery and expression in plants

Agrobacterium tumefaciens VirD2 protein is one of the key elements of Agrobacterium-mediated plant transformation, a process of transfer of T-DNA sequence from the Agrobacterium tumour inducing plasmid into the nucleus of infected plant cells and its integration into the host genome. The VirD2 protein has been shown to be a substrate for a plant caspase-like protease activity (PCLP) in tobacco. We demonstrate here that mutagenesis of the VirD2 protein to prevent cleavage by PCLP increases the efficiency of reporter gene transfer and expression. These results indicate that PCLP cleavage of the Agrobacterium VirD2 protein acts to limit the effectiveness of T-DNA transfer and is a novel resistance mechanism that plants utilise to combat Agrobacterium infection. Brian Reavy and Svetlana Bagirova contributed equally to this work.     

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.     

Agrobacterium-mediated sorghum transformation

Agrobacterium tumefaciens was used to genetically transform sorghum. Immature embryos of a public (P898012) and a commercial line (PHI391) of sorghum were used as the target explants. The Agrobacterium strain used was LBA4404 carrying a `Super-binary' vector with a bar gene as a selectable marker for herbicide resistance in the plant cells. A series of parameter tests was used to establish a baseline for conditions to be used in stable transformation experiments. A number of different transformation conditions were tested and a total of 131 stably transformed events were produced from 6175 embryos in these two sorghum lines. Statistical analysis showed that the source of the embryos had a very significant impact on transformation efficiency, with field-grown embryos producing a higher transformation frequency than greenhouse-grown embryos. Southern blot analysis of DNA from leaf tissues of T₀ plants confirmed the integration of the T-DNA into the sorghum genome. Mendelian segregation in the T₁ generation was confirmed by herbicide resistance screening. This is the first report of successful use of Agrobacterium for production of stably transformed sorghum plants. The Agrobacterium method we used yields a higher frequency of stable transformation that other methods reported previously.     

Factors influencing <Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation of monocotyledonous species

Summary Since the success of Agrobacterium-mediated transformation of rice in the early 1990s, significant advances in Agrobacterium-mediated transformation of monocotyledonous plant species have been achieved. Transgenic plants obtained via Agrobacterium-mediated transformation have been regenerated in more than a dozen monocotyledonous species, ranging from the most important cereal crops to ornamental plant species. Efficient transformation protocols for agronomically important cereal crops such as rice, wheat, maize, barley, and sorghum have been developed and transformation for some of these species has become routine. Many factors influencing Agrobacterium-mediated transformation of monocotyledonous plants have been investigated and elucidated. These factors include plant genotype, explant type, Agrobacterium strain, and binary vector. In addition, a wide variety of inoculation and co-culture conditions have been shown to be important for the transformation of monocots. For example, antinecrotic treatments using antioxidants and bactericides, osmotic treatments, desiccation of explants before or after Agrobacterium infection, and inoculation and co-culture medium compositions have influenced the ability to recover transgenic monocols. The plant selectable markers used and the promoters driving these marker genes have also been recognized as important factors influencing stable transformation frequency. Extension of transformation protocols to elite genotypes and to more readily available explants in agronomically important crop species will be the challenge of the future. Further evaluation of genes stimulating plant cell division or T-DNA integration, and genes increasing competency of plant cells to Agrobacterium, may increase transformation efficiency in various systems. Understanding mechanisms by which treatments such as desiccation and antioxidants impact T-DNA delivery and stable transformation will facilitate development of efficient transformation systems.     

Agrobacterium tumefaciens AKE10-mediated transformation of an Asian pea pear, Pyrus betulaefolia Bunge: host specificity of bacterial strains

The Asian pea pear, Pyrus betulaefolia Bunge, is tolerant to several disorders in the fruit bodies caused by high humidity and dryness and is hence widely used as a rootstock for many pear plants suitable for food sources. We have now successfully transformed P. betulaefolia Bunge by an Agrobacterium-mediated gene transfer system. Among several wild-type A. tumefaciens strains examined, only AKE10 induced shoot-forming tumors at a high frequency on excised cotyledons of P. betulaefolia Bunge cultured on phytohormone-free medium. Both the nptII (kanamycin resistance) and GUS (#-glucuronidase) genes were introduced into the cotyledons by infection with AKE10 harboring a binary vector, and regenerated plants were obtained. Southern hybridization and polymerase chain reaction analyses and histochemical GUS assay indicated that morphologically normal transformed plants faithfully contained genes from the vector but not from wild-type oncogenic T-DNA. However, morphologically abnormal plants additionally possessed the 6b gene (AK-6b) of AKE10. These results show that non-disarmed A. tumefaciens is adequate to transfer genes to the Asian pea pear, P. betulaefolia Bunge.     

Gene targeting in plants using theAgrobacterium vector system

In the past decade several methods have been developed for the introduction of foreign DNA into plant cells to obtain transgenic plants. In some of these methods, purified DNA is directly introduced into protoplasts that for some species can be regenerated into mature plants. The more commonly used protocols, however, employ the natural capacity ofAgrobacterium tumefaciens to transfer a defined peice of DNa, called T-DNA, to the nucleus of plant cells that are more easy to regenerate than protoplasts. In plant cells, like in animal cells, foreign DNA (including T-DNA) is readily inserted into the genome via illegitimates recombination. In contrast, targeted integration via homologous recombination, referred to as ‘gene targeting’, can only be obtained at relatively low frequencies. Nevertheless, gene targeting has become a standard strategy for reverse genetics studies in animals. In plants, the occurrence of gene targeting was only reported recently. This review focuses on the use of theAgrobacterium vector system to achieve gene targeting in plants. Recent experimental data concerning gene targeting in plants are presented and the overall suitability ofAgrobacterium T-DNA transfer for this purpose is assessed in light of contemporary views on the mechanism of T-DNA transfer.     

The promoter proximal region in the virD locus of Agrobacterium tumefaciens is necessary for the plant-inducible circularization of T-DNA

Summary The formation of crown gall tumours involves the transfer of the T-DNA region of the Ti plasmid from Agrobacterium to plant cells and its subsequent integration into plant chromosomes. When agrobacteria are incubated with plant protoplasts or exudates of plants, the T-DNA region is circularized by recombination or cleavage and rejoining between the 25 bp terminal repeats; the formation of circular T-DNAs is thought to be one step in T-DNA transfer (Koukolikova-Nicola et al. 1985; Machida et al. 1986). We previously showed that the virulence region of the Ti plasmid is required for T-DNA circularization. In the present paper, we examined the circularization event in agrobacteria harbouring octopine Ti plasmids with mutations in various loci of the virulence region. The results clearly demonstrate that the gene(s) encoded in the virD locus are necessary for T-DNA circularization. In particular, the gene(s) present in the region proximal to the virD promoter are essential. We propose that roduct(s) of this gene have recombinase or endonuclease activity which specifically recognizes the 25 bp terminal repeats of T-DNA.     

pBECKS

A series of binary T-DNA vectors (pBECKS) has been created for use in theAgrobacterium-mediated genetic transformation of plants. The pBECKS series has corrected the undesirable features of the popular pBIN19 vector; the deleterious mutation within the coding sequence ofnptII has been amended and the cloning sites are now adjacent to the right border repeat in order to reduce the possibility of producing truncated sequences of novel genes within transformants. One set of vectors incorporates various combiantions of the marker genesgusA,C1/Lc,nptII,hph, andbar, for pursuit of early and stable transformation events. A set of constructs which contain deleted T-DNA borders in various combinations and display predictably altered efficacies for gene transfer has also been created. A modular set of vectors has been designed to facilitate the insertion and transfer of novel gene sequences by providing anptII-linked plant expression cassette orlacZ-multiple cloning site. A range of antibiotic resistance genes has been incorporated into the non-T-DNA part of the vectors in order to facilitate their selection across the range ofAgrobacterium virulence strains.     

Optimization of <Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation conditions in mature embryos of elite wheat

Immature embryos have been used frequently as target tissues in the genetical transformation of wheat. However, obtaining a large number of high quality immature embryos throughout the year is a laborious and delicate process, because of the need to cultivate the plants under controlled conditions. To circumvent this, we have employed mature embryos rather than immature ones as starter explants for Agrobacterium-mediated transformation of an elite wheat (Triticum aestivum L.) cultivar EM12. The neomycin phosphotransferase ІІ (npt ІІ) and β-glucuronidase (gus) genes were used as selectable and screenable marker genes, respectively, to assess and optimize the performance of T-DNA delivery. With the aid of an orthogonal design, the effect of four factors in combination on transfer DNA (T-DNA) delivery was studied. These factors were preculture duration, different kinds of inoculation, length of inoculation and co-culture condition. Optimal conditions for T-DNA delivery were obtained for mature embryos precultured for 14 days, followed by immersing in inoculation suspension with full strength Murashige and Skoog (MS) salts in darkness at 23–25°C for 3 h, and then co-culturing with Agrobacterium under desiccating condition in the dark at 23–24°C for 2–3 days. Complete analysis of transgene insertion demonstrated that the optimized method for Agrobacterium-mediated transformation of mature embryos of wheat was efficient and practicable.     

An embryogenic suspension cell culture system for Agrobacterium-mediated transformation of citrus

A method for the genetic transformation of several citrus cultivars is described, including cultivars observed to be recalcitrant to conventional epicotyl-mediated transformation. Embryogenic cell suspension cultures, established from unfertilized ovules were used as target tissues for Agrobacterium-mediated transformation. Several modifications were made to the culture environment to investigate factors required for efficient transfer of the T-DNA and the subsequent regeneration of transgenic citrus plants. It was determined that co-cultivation of citrus cells and Agrobacterium in EME medium supplemented with maltose (EME-M) and 100 μM acetosyringone for 5 days at 25°C was optimum for transformation of each of the citrus cultivars. Efficient selection was obtained and escapes were prevented when the antibiotic hygromycin B was used as a selection antibiotic following transformation with an Agrobacterium strain containing hptII in the T-DNA region. Transgenic embryo regeneration and development was enhanced in medium that contained a liquid overlay consisting of a 1:2 mixture of 0.6 M BH3 and 0.15 M EME-M media. PCR and Southern blot analyses confirmed the presence of the T-DNA and the stable integration into the genome of regenerated plants, while RT-PCR demonstrated variable amounts of RNA being transcribed in different transgenic lines. This protocol can create an avenue for insertion of useful traits into any polyembryonic citrus cultivar that can be established as embryogenic cell suspension cultures, including popular specialty mandarins and seedless cultivars.     

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.     

Factors influencing <Emphasis Type="Italic">Agrobacterium tumefaciens</Emphasis>-mediated genetic transformation of <Emphasis Type="Italic">Eleusine coracana</Emphasis> (L.) Gaertn

Agrobacterium-mediated transformation protocol has been developed for Eleusine coracana (var. PR-202) by varying several factors which influence T-DNA delivery. Green nodular regenerative calli with meristematic nodules of seed origin were used as the target tissue for Agrobacterium tumefaciens-mediated gene transfer. The highest frequency of transformation (44.4%) was observed when callus was infected, co-cultivated and incubated at 22°C. Incorporation of higher level of CuSO₄ in the regeneration medium had significantly positive effect on the recovery of transformed plants. PCR analysis of T ₀ and T ₁ generation plants with nptII-specific primers revealed the amplification of nptII gene. Southern blot analysis of six regenerated plants confirmed selectable marker gene integration in three plants. This is a first report on Agrobacterium-mediated genetic transformation of finger millet and will pave the way for further studies in this and other millet crops.     

Transformation of Cucumis sativus tissue by Agrobacterium tumefaciens and the regeneration of transformed plants

Cotyledons of cucumber seedlings (Cucumis sativus L. cv. Poinsett 76) were co-cultivated with disarmed Agrobacterium strain C58Z707. The Agrobacterium strain contained the Agrobacterium-derived binary vector plasmid pGA482, its T-DNA region contains a plant expressible bacterial derived neomycin phosphotransferase II (NPT II) gene which upon transfer, genome integration, and expression in plant tissues confers resistance to the antibiotic kanamycin. After growth of inoculated cotyledon sections on selective medium containing 100 mg/l kanamycin, transformed embryogenic calli were obtained followed by the development of embryos and plant regeneration. Transformed R₀ and R₁ cucumber plants appeared normal and tested positive for NPT II enzyme activity. Genomic DNAs isolated from the NPT II positive plants all showed hybridization to the characteristic 2.0 kb (BamHI to HindIII) NPT II gene-containing fragment. These results show that the Agrobscterium-mediated gene transfer system and regeneration via somatic embryogenesis is an effective method for the transfer of genetic material into plant species belonging to the family Cucurbitaceae.Abbreviation Cb carbenicillin - 2,4-D 2,4-dichlorophenoxyacetic acid - Km kanamycin - KN kinetin - MS Murashige and Skoog - NAA naphthaleneacetic acid - NPT II neomycin phosphotransferase II     

An optimized Agrobacterium-mediated transformation procedure for Phaseolus acutifolius A. Gray

To improve Agrobacterium tumefaciens-mediated transformation of Phaseolus acutifolius, we examined the effect of different factors on T-DNA transfer by measuring transient expression levels of an intron-containing ß-glucuronidase gene. Improved transformation frequencies were obtained with an A. tumefaciens strain carrying nopaline-type virulence genes and when calli were infected with Agrobacterium cells in the early-log growth phase. Optimized co-cultivation was performed at 22°C under a 16/8-h (day/night) photoperiod in an acidic medium (pH 5.5) in the presence of 200 µ M acetosyringone. By combining the best treatments, an efficient and reproducible transformation procedure was established for the P. acutifolius genotype NI576. Southern and immunoblot analyses confirmed the stable integration and expression of the transgenes in the primary transgenic plants and their progeny.     

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     

Agrobacterium-mediated transformation of embryogenic calluses of Ponkan mandarin and the regeneration of plants containing the chimeric ribonuclease gene

Ponkan (Citrus reticulata Blanco), one of the most important commercial cultivars of mandarin, is very seedy. In this study, the chimeric ribonuclease gene (barnase) driven by an anther tapetum-specific promoter (pTA29) was introduced into embryogenic callus of Ponkan by Agrobacterium-mediated transformation using the bar gene as a selectable marker. In contrast to previous reports, embryogenic calluses were used as the explant for Agrobacterium infection and transgenic plant regeneration. Selection of transformed callus was accomplished using basta. After 3 days of co-culture, calluses were transferred to MT medium with 50 mg/l basta and 400 mg/l cefotaxime. Resistant calluses were recovered and proliferated after three to four subcultures and then regenerated plantlets. A total of 52 resistant plants were recovered, of which 43 were verified to be transformants by polymerase chain reaction amplification of a fragment of the transgene. Southern hybridization of seven randomly selected transformed plants further confirmed their transgenic nature. The potential of this strategy for breeding citrus seedless types is discussed.