Genetic and molecular analysis of Arabidopsis thaliana (ecotype ‘Estland’) transformed with Agrobacterium

Summary Agrobacterium-mediated transformation of Arabidopsis, ecotype ‘Estland’, was established from root explants using kanamycin selection. Continuous light during callus and shoot induction phases was promotive for shoot regeneration, as compared to light/dark cycles. Use of optimized conditions for transformation led to the formation of kanamycin-resistant calluses (up to 77%) and transformed plantlets at a frequency of up to 45%. Southern analysis showed the presence of 1.2. or more T-DNA inserts in 33%, 50%, and 17% of the primary transformants, respectively. Mendelian, as well as non-Mendelian, inheritance patterns were obtained upon screening the progeny (T1) of various transformants for the expression of gus and nptII genes; the analysis of some of these transformants at the molecular level also corroborated the Mendelian inheritance pattern. Moreover, genotypes of the T1 progeny could be predicted on the basis of T2 progeny analysis.     

Inheritance of two foreign genes co-introduced intoPetunia hybrida by direct gene transfer

In previous work, transformedPetunia hybrida plants were obtained by direct gene transfer, using two different genes on separate plasmids (NPT II gene and a cDNA of PEPC from green sorghum leaves). In this study, we have analysed the sexual transmission of the acquired genes by genetic crossing analysis of 2 of the transgenic petunias. The ploïdies of the two clones were determined by flow cytometric analysis showing that one was 2n and the other 4n. Self and back crosses show that the kanamycin character was inherited as a single dominant trait, and that the two clones were heterozygotes for this character. Therefore, the 4n clone probably arises from an endoploidization followed by a transformation event. Southern blot analyses show that all of the resistant progenies which were analysed harboured the kanamycin gene, and expressed the phosphorylation activity in vitro. The DNA of several progenies were also tested for the presence of co-transformed PEPC cDNA sequence. All of the kanamycin-resistant progenies tested contained the second coding sequence, indicating that the two foreign genes might be genetically co-inherited in the transgenic plants. The way in which the two genes are integrated into the genome is discussed.Abbreviations NPT neomycin phosphotransferase - PEG polyethyleneglycol - PEPC phosphoenolpyruvate carboxylase     

Agrobacterium-mediated transformation of Asparagus officinalis L. long-term embryogenic callus and regeneration of transgenic plants

Summary Twenty-three independent kanamycin resistant lines were obtained after cocultivation of longterm embryogenic cultures of three Asparagus officinalis L. genotypes with an Agrobacterium tumefaciens strain harboring ß-glucuronidase and neomycin phosphotransferase II genes. All the lines showed ß-glucuronidase activity by histological staining. DNA analysis by Southern blots of the kanamycin resistant embryogenic lines and of a plant regenerated from one of them confirmed the integration of the T-DNA.Abbreviations GUS ß-glucuronidase - X-Gluc 5-bromo-4-chloro-3indolyl ß-D-glucuronic acid - NPT II neomycin phosphotransferase II     

In planta transformation of Arabidopsis thaliana

Transformants of Arabidopsis thaliana can be generated without using tissue culture techniques by cutting primary and secondary inflorescence shoots at their bases and inoculating the wound sites with Agrobacterium tumefaciens suspensions. After three successive inoculations, treated plants are grown to maturity, harvested and the progeny screened for transformants on a selective medium. We have investigated the reproducibility and the overall efficiency of this simple in planta transformation procedure. In addition, we determined the T-DNA copy number and inheritance in the transformants and examined whether transformed progeny recovered from the same Agrobacterium-treated plant represent one or several independent transformation events. Our results indicate that in planta transformation is very reproducible and yields stably transformed seeds in 7–8 weeks. Since it does not employ tissue culture, the in planta procedure may be particularly valuable for transformation of A. thaliana ecotypes and mutants recalcitrant to in vitro regeneration. The transformation frequency was variable and was not affected by lower growth temperature, shorter photoperiod or transformation vector. The majority of treated plants gave rise to only one transformant, but up to nine siblings were obtained from a single parental plant. Molecular analysis suggested that some of the siblings originated from a single transformed cell, while others were descended from multiple, independently transformed germ-line cells. More than 90% of the transformed progeny exhibited Mendelian segregation patterns of NPTII and GUS reporter genes. Of those, 60% contained one functional insert, 16% had two T-DNA inserts and 15% segregated for T-DNA inserts at more than two unlinked loci. The remaining transformants displayed non-Mendelian segregation ratios with a very high proportion of sensitive plants among the progeny. The small numbers of transformants recovered from individual T₁ plants and the fact that none of the T₂ progeny were homozygous for a specific T-DNA insert suggest that transformation occurs late in floral development.National Research Council of Canada Publication No. 38003     

Transposition of the maize autonomous element Activator in transgenic Nicotiana plumbaginifolia plants

The maize autonomous transposable element Ac was introduced into haploid Nicotiana plumbaginifolia via Agrobacterium tumefaciens transformation of leaf disks. All the regenerated transformants (R0) were diploid and either homozygous or heterozygous for the hygromycin resistance gene used to select primary transformants. The Ac excision frequency was determined using the phenotypic assay of restoration of neomycin phosphotransferase activity and expression of kanamycin resistance among progeny seedlings. Some of the R0 plants segregated kanamycin-resistant seedlings in selfed progeny at a high frequency (34 to 100%) and contained one or more transposed Ac elements. In the primary transformants Ac transposition probably occurred during plant regeneration or early development. Other R0 transformants segregated kanamycin-resistant plants at a low frequency ( 4%). Two transformants of this latter class, containing a unique unexcised Ac element, were chosen for further study in the expectation that their kanamycin resistant progeny would result from independent germinal transposition events. Southern blot analysis of 32 kanamycin-resistant plants (R1 or R2), selected after respectively one or two selfings of these primary transformants, showed that 27 had a transposed Ac at a new location and 5 did not have any Ac element. Transposed Ac copy number varied from one to six and almost all transposition events were independent. Southern analysis of the R2 and R3 progeny of these kanamycin-resistant plants showed that Ac continued to transpose during four generations, and its activity increased with its copy number. The frequency of Ac transposition, from different loci, remained low ( 7%) from R0 to R3 generations when only one Ac copy was present. The strategy of choosing R0 plants that undergo a low frequency of germinal excision will provide a means to avoid screening non-independent transpositions and increase the efficiency of transposon tagging.     

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     

Genetic transformation of a hepatoprotective plant, <Emphasis Type="Italic">Phyllanthus amarus</Emphasis>

Phyllanthus amarus Schum & Thonn. is a source of various pharmacologically active compounds such as phyllanthin, hypophyllanthin, gallic acid, catechin, and nirurin, a flavone glycoside. A genetic transformation method using Agrobacterium tumefaciens was developed for this plant species for the first time. Shoot tips of full grown plants were used as explants for Agrobacterium-mediated transformation. Transgenic plants were obtained by co-cultivation of shoot tips explants and A. tumefaciens strain LBA4404 containing the pCAMBIA 2301 plasmid harboring neomycin phosphotransferase II (NPT II) and β-glucuronidase encoding (GUS) genes in the T-DNA region in the presence of 200 μM acetosyringone. Integration of the NPT II gene into the genome of transgenic plants was verified by PCR and Southern blot analyses. Expression of the NPT II gene was confirmed by RT-PCR analysis. An average of 25 explants was used, out of which an average of 19 explants produced kanamycin-resistant shoots, which rooted to produce 13 complete transgenic plants.     

Susceptibility of dry bean (Phaseolus vulgaris L.) to Agrobacterium infection: Transformation of cotyledonary and hypocotyl tissues

A germinating-seed assay was developed to determine the susceptibility of dry bean (Phaseolus vulgaris L.) to infection by Agrobacterium tumefaciens. Seedlings infected one to three days after germination were more susceptible to A. tumefaciens infection than seedlings germinated for five to seven days and the galls that formed on the one to three day seedlings were significantly larger. Nineteen genotypes of dry bean were screened with this assay and all were equally susceptible to nopaline, octopine and agropine biotypes of A. tumefaciens. In addition, cotyledonary nodes and hypocotyls of P. vulgaris were inoculated with disarmed strain A. tumefaciens strain C58Z707 and the avirulent A. rhizogenes strain A4RS (pRiB278b), respectively. Both strains contain the binary plasmid pGA482 which has the neomycin phosphotransferase II (NPT II) gene nested between T-DNA borders. From these infected tissues, callus and root tissues, respectively capable of growing in the presence of kanamycin were obtained. These tissues displayed NPT II activity and integrated copies of the NPT II gene were detected from putative transformed root cultures by genomic blot hybridization.     

Spontaneous extensive chromosome elimination in somatic hybrids between somatically congruent species Nicotiana tabacum L. and Atropa belladonna L.

Summary Mesophyll protoplasts of the kanamycin-resistant nightshade, Atropa belladonna, were fused with mesophyll protoplasts of the phosphinothricin resistant-tobacco, Nicotiana tabacum. A total of 447 colonies resistant to both inhibitors was selected. Most of them regenerated shoots with morphology similar to one of the earlier obtained and described symmetric somatic hybrids Nicotiana + Atropa. However, three colonies (0.2%) regenerated vigorously growing tobacco-like shoots; they readily rooted, and after transfer to soil, developed into normal, fertile plants. Unlike their tobacco parental line, BarD, the obtained plants are resistant to kanamycin [they root normally in the presence of kanamycin (200 mg/1)] and possess activity of neomycin phosphotransferase (NPT II) with the same electrophoretic mobility as the one of the nightshade line. According to Southern blot hybridization analysis carried out with the use of radioactively labeled cloned fragments of the Citrus lemon ribosomal DNA repeat, as well as with Nicotiana plumbaginifolia genus-specific, interspersed repeat Inp, the kanamycin-resistant plants under investigation have only species-specific hybridizing bands from tobacco. Cytological analysis of the chromosome sets shows that plants of all three lines possess 48 large chromosomes similar to Nicotiana tabacum ones (2n = 48), and one small extra chromosome (chromosome fragment) similar to Atropa belladonna ones (2n = 72). Available data allow the conclusion that highly asymmetric, normal fertile somatic hybrids with a whole diploid Nicotiana tabacum genome and only part (not more than 2.8%) of an Atropa belladonna genome have been obtained without any pretreatment of a donor genome, although both these species are somatically congruent.     

Agrobacterium rhizogenes mediated transformation of grapevine (Vitis vinifera L.)

Genetically transformed grapevine (Vitis vinifera L.) roots were obtained after inocultation of in vitro grown whole plants (cv. Grenache) with Agrobacterium rhizogenes. The strain used contains two plasmids: the wild-type Ri plasmid pRi 15834 and a Ti-derived plasmid which carries a chimaeric neomycin phosphotrans-ferase gene (NPT II) and the nopaline synthase gene. Expression of the NPT II gene can confer kanamycin resistance to transformed plant cells. Slowly growing axenic root cultures derived from single root tips were obtained. Opine analysis indicated the presence of agropine and/or nopaline in established root cultures. For one culture, the presence of T-DNA was confirmed by dot-blot hybridization with pRi 15834 TL-DNA. Callogenesis was induced by subculturing root fragments on medium supplemented with benzylaminopurine and indoleacetic acid.Transformation of in vitro cultured grapevine cells has recently been reported (baribault T.J. et al., Plant Cell Rep (1989) 8: 137–140). In contrast with the results presented here, expession of the NPT II gene Conferred kanamycin resistance to Vitis vinifera calli that was sufficient for selection of trasformed cells.Abbreviations BAP benzylaminopurine - IAA indoleacetic acid - NAA naphtaleneacetic acid - NPT II neomycin phosphostransferase II - EDTA ethylenediaminetetraacetic acid     

Transgenic plants of rutabaga (Brassica napobrassica) tolerant to pest insects

Cotyledons cut from axenic seedlings were immersed inAgrobacterium tumefaciens suspension which was treated with acetosyringone and nopaline at low pH overnight. The infected cotyledon explants were cultured on MSB medium (MS salts + B₅ Vitamins) containing 6-BA 3mg/1 for 2–3 days, and transferred onto selective medium (MSB with kanamycin 50–100 mg/l). Kanamycin-resistant shoots were selected. More than 60 regenerated plants were obtained. About 60% of the plants showed high NPT II activity. Southern blot hybridization showed that some of the plants gave a positive signal with the insecticidal crystal protein gene (cry IA gene) probe, and exhibited tolerant to insects such asPieris rapae (cabbage caterpillar) in leaf feeding experiments. Kanamycin-resistance and insect-resistance were maintained in the progeny.Abbreviations 6-BA 6-benzylaminopurine - IBA indole-3-butyric acid - CryIA gene bacillus thuringiensis insecticidal crystal protein genecryIA - NPT II neomycin phosphotransferase II     

Effects of 5-azacytidine on transformation and gene expression inNicotiana tabacum

Summary Protoplasts ofNicotiana tabacum var. Xanthi were incubated with liposomes containing the plasmid plGVneo23 encoding kanamycin resistance. Transformed protoplasts and calli and plants derived from transformed protoplasts were treated with the demethylating agent 5-azacytidine. Three lines of evidence indicate that 5-azacytidine can increase NPT II activity in transformed cell lines and plants: a) Addition of azacytidine to the protoplast medium increased the proportion of kanamycin-resistant transformants recovered. b) NPT II activity could not be detected in approximately 50% of calli derived from transformed protoplasts although such calli grew slowly on medium containing kanamycin. Treatment of NPT-negative calli with 5-azacytidine restored detectable gene activity and increased the growth rate of the callus in the presence of kanamycin. c) Shoot tips regenerated from transformed calli were either NPT-positive or NPT-negative. When shoots were NPT-negative, treatment with 5-azacytidine restored detectable gene activity and improved growth in the presence of kanamycin.     

Genetic characterization of a double-flowered tobacco plant obtained in a transformation experiment

Summary A leaf-disk transformation experiment was performed with tobacco (Nicotiana tabacum L.) using a binary vector and a strain of Agrobacterium tumefaciens that carried a wild-type Ti-plasmid, pTiBo542. Although the majority of kanamycin-resistant, transgenic plants was morphologically normal, one of the plants was double-flowered and had a slightly wavy stem and leaves whose edges were bent slightly upwards. The abnormal morphology was controlled by a single, dominant Mendelian gene. Young plants that carried this gene were distinguishable from normal plants at the stage of cotyledons. The homozygotes, with respect to this gene, were more seriously deformed than the heterozygotes. DNA segments derived from the binary vector and from the T_L-and T_R-DNA of pTiBo542 were detected in the double-flowered plant, but the T-DNA genes involved in biosynthesis of phytohormones were absent from the plant. The abnormal morphology, the resistance to kanamycin, and the segments of foreign DNA were genetically linked, and the linkage was very tight, at least between the abnormal morphology and the resistance to kanamycin; the meiotic recombination frequency was less than 0.02%, if recombination occurred at all.     

Chromosomal localization of foreign genes in Petunia hybrida

Summary A F1 hybrid of Petunia hybrida, heterozygous for at least one marker on each of the seven chromosomes, was transformed with a modified strain of Agrobacterium tumefaciens in which the phytohormone biosynthetic genes in the transferred DNA (T-DNA) were replaced with a NOS/NPTII/NOS chimeric gene and a wildtype nopaline synthase (NOS) gene. The chimeric gene, which confers kanamycin resistance, was used as selectable marker during the transformation process and the NOS gene was used as a scorable marker in the genetic studies. After plants had been regenerated from the transformed tissues, the transgenic plants that expressed both of these markers were backcrossed to the parental lines. The offspring were examined for the segregation of the NOS gene and the Petunia markers. Genetic mapping was thus accomplished in a single generation.By Southern hybridization analysis we confirmed the presence of the expected T-DNA fragments in the transformed plants. Four out of the six plants presented here, had just one monomeric T-DNA insertion. The sizes of the plant/T-DNA junction fragments suggest that the integration occurred in different sites of the Petunia genome. One transformant gave a more complicated hybridization pattern and possibly has two T-DNA inserts. Another transgenic plant was earlier reported (Fraley et al. 1985) to have two, possibly tandemly repeated T-DNAs.Data is presented on the genetic localization of the T-DNA inserts in six independently obtained transgenic plants. The T-DNA inserts in three plants were mapped to chromosome I. However, the distances between the NOS gene and the marker gene on this chromosome were significantly different. In another transgenic plant the NOS gene was coinherited with the marker on chromosome IV. Two other transgenic plants have the T-DNA insert on chromosome III. A three point cross enabled us to determine that both plants have the NOS gene distally located from the peroxidaseA (prxA) marker and both plants showed about 18% recombination. However, Southern hybridization analysis shows that the sizes of the plant/T-DNA junction fragments in these transgenic plants are different, thus suggesting that the integrations occurred in different sites.     

Locations and stability of Agrobacterium-mediated T-DNA insertions in the Lycopersicon genome

Summary The genomic distribution and genetic behavior of DNA sequences introduced into the tomato genome by Agrobacterium tumefaciens were investigated in the backcross progeny of 10 transformed Lycopersicon esculentum x L. pennellii hybrids. All transformants were found to represent single locus insertions based on the co-segregation of restriction fragments corresponding to the T-DNA left and right border sequences in the backcross progeny. Isozyme and restriction fragment length polymorphism (RFLP) markers were used to test linkage relationships of the insertion in each backcross family. The T-DNA inserts in 9 of the 10 transformants were mapped in relation to one or more of these markers, and each mapped to a different chromosomal location. Because only one insertion did not show linkage with the markers employed, it must be located somewhere other than the genomic regions covered by the markers assayed. We conclude that Agrobacterium-mediated insertion in the Lycopersicon genome appears to be random at the chromosomal level. No discrepancies were found between the T-DNA genotype and the nopaline phenotype in the 322 backcross progeny of the nopaline positive transformants. Backcross progeny of two nopaline negative transformants showed incomplete correspondence between the T-DNA genotype and the kanamycin resistance phenotype. No alteration of T-DNA was observed in progeny showing a discrepancy between T-DNA and kanamycin resistance. However, two kanamycin resistant progeny plants of one of these two transformants possessed altered T-DNA restriction patterns, indicating genetic instability of the T-DNA in this transformant.Journal article no. 1223 of the New Mexico Agricultural Experiment Station     

Transgenic broccoli expressing aBacillus thuringiensis insecticidal crystal protein: Implications for pest resistance management strategies

We usedAgrobacterium tumefaciens to transform flowering stalk explants of five genotypes of broccoli with a construct containing the neomycin phosphotransferase gene and aBacillus thuringiensis (Bt) gene [CryIA(c) type] optimized for plant expression. Overall transformation efficiency was 6.4%; 181 kanamycin-resistant plants were recovered. Of the 162 kanamycin-resistant plants tested, 112 (69%) caused 100% morality of 1st-instar larvae of aBt-susceptible diamondback moth strain. Southern blots of some resistant transformants confirmed presence of theBt gene. Selected plants that gave 100% mortality of susceptible larvae allowed survival of a strain of diamondback moth that had evolved resistance toBt in the field. F₁ hybrids between resistant and susceptible insects did not survive. Analysis of progeny from 26 resistant transgenic lines showed 16 that gave segregation ratios consistent with a single T-DNA integration. Southern analysis was used to verify those plants possessing a single T-DNA integration. Because these transgenic plants kill susceptible larvae and F₁ larvae, but serve as a suitable host for resistant ones, they provide an excellent model for tests ofBt resistance management strategies.     

Agrobacterium tumefaciens-mediated transformation of the aromatic shrub Lavandula latifolia

Transgenic plants of the aromatic shrub Lavandula latifolia (Lamiaceae) were produced using Agrobacterium tumefaciens-mediated gene transfer. Leaf and hypocotyl explants from 35–40-day old lavender seedlings were inoculated with the EHA105 strain carrying the nptII gene, as selectable marker, and the reporter gusA gene with an intron. Some of the factors influencing T-DNA transfer to L. latifolia explants were assessed. Optimal transformation rates (6.0 ± 1.6% in three different experiments) were obtained when leaf explants precultured for 1 day on regeneration medium were subcultured on selection medium after a 24 h co-cultivation with Agrobacterium. Evidence for stable integration was obtained by GUS assay, PCR and Southern hybridisation. More than 250 transgenic plants were obtained from 37 independent transformation events. Twenty-four transgenic plants from 7 of those events were successfully established in soil. -glucuronidase activity and kanamycin resistance assays in greenhouse-grown plants from two independent transgenic lines confirmed the stable expression of both gusA and nptII genes two years after the initial transformation. Evidence from PCR data, GUS assays and regeneration in the presence of kanamycin demonstrated a 1:15 Mendelian segregation of both transgenes among seedlings of the T1 progeny of two plants from one transgenic L. latifolia line.     

Transformation of cotton (Gossypium hirsutum L.) by Agrobacterium tumefaciens and regeneration of transgenic plants

Cotton (Gossypium hirsutum L.) cotyledon tissues have been efficiently transformed and plants have been regenerated. Cotyledon pieces from 12-day-old aseptically germinated seedlings were inoculated with Agrobacterium tumefaciens strains containing avirulent Ti (tumor-inducing) plasmids with a chimeric gene encoding kanamycin resistance. After three days cocultivation, the cotyledon pieces were placed on a callus initiation medium containing kanamycin for selection. High frequencies of transformed kanamycin-resistant calli were produced, more than 80% of which were induced to form somatic embryos. Somatic embryos were germinated, and plants were regenerated and transferred to soil. Transformation was confirmed by opine production, kanamycin resistance, immunoassay, and DNA blot hybridization. This process for producing transgenic cotton plants facilitates transfer of genes of economic importance to cotton.     

An assessment of gene transfer by pollen from field-grown transgenic potatoes to non-transgenic potatoes and related species

Information on the extent of transgene dispersal by pollen to adjacent potato plots and to related weed species is an important requisite for risk assessment; a procedure followed before novel transgenic plants are evaluated under field conditions. The purpose of the investigation was to determine the frequency of cross-pollination between potato (Solanum tuberosum) plants at different distances, using a kanamycin resistnace transgene (nptII) as a selectable marker. All potato plants were from the variety Désirée. Non-transgenic potato plants, used as potential recipients of transgene-containing pollen, were planted in 12 sub-plots, at distances of 0–20 m from the nearest transgenic potato plants. Seeds harvested from the non-transgenic plants were screened for resistance to kanamycin, and molecular methods were used to confirm that resistant progeny contained thenptII gene. Where transgenic and non-transgenic potato plants were in alternate rows (leaves touching), 24% of seedlings from the non-transgenic parent plants were kanamycin-resistant. Comparable seedlings from plants at up to 3 m distance had a resistance frequency of 2%, at 10 m the frequency was 0.017% and at 20 m no resistant progeny were observed. Plants of the weed speciesS. dulcamara andS. nigrum were also planted close to the transgenic potatoes to test for evidence of hybridization, and no kanamycin-resistant seedlings were observed among progeny fromS. dulcamara andS. nigrum. This investigation provided evidence that the extent of gene dispersal from transgenic potatoes to non-transgenic potatoes falls markedly with increasing distance, and is negligible at 10 m. There was, also, no evidence of transgene movement from potato toS. dulcamara andS. nigrum under field conditions. These data will be valuable in defining genetic isolation procedures for the early field evaluation and the use of novel transgenic potato genotypes.     

Factors influencing Agrobacterium tumefaciens mediated transformation and expression of kanamycin resistance in pickling cucumber

Cucumber (Cucumis sativus L.) petiole and leaf segments of two pickling genotypes were transformed with Agrobacterium tumefaciens strain LBA 4404, an octopine Ti-plasmid deletion mutant that is avirulent (disarmed plasmid), but to which were added T-DNA inserts on binary plasmids (pBIN 19, ca. 10 kb, and pCGN 783, ca. 25 kb). Expression of neomycin phosphotransferase (NPT II) encoding resistance to the aminoglycoside kanamycin was used as a selectable marker. Factors which influenced the frequency of callus development on medium containing kanamycin (75 mg l^-1) were explant size, bacterial concentration and length of exposure, cocultivation period, and presence of acetosyringone. The optimal procedure involved exposing segments of petiole (4–6 mm) or leaf (0.5 cm²) segments to a bacterial suspension (10⁸ cells ml^-1) containing 20 M acetosyringone for 5 min, followed by a 48 h cocultivation period on a tobacco feeder layer. Explants were placed on MS medium containing 500 mg l^-1 carbenicillin, 75 mg l^-1 kanamycin, and NAA/BA (5.0/2.5 M) or 2,4-d/BA (5.0/5.0 M) and subcultured twice, each after a 2–3 week period, onto fresh media. The overall frequency of transformed callus was 20–50%; the frequency of plantlet regeneration from transformed callus was 8–15%. Twenty-one out of 23 individual plants recovered from two genotypes of pickling cucumber were NPT II positive (transformation frequency of 9%). Copy number of the NPT II gene insert (35S-NPT II-3 fragment, ca. 2.2 kb) in three transformed plants was estimated at ten per haploid genome, indicative of multiple insertions within the cucumber genome. Multimers of the gene (visible as 4.4 and 6.6 kb fragments in Southern analysis) were detected in one plant, suggestive of tandem duplications or repeats. Progeny from a cross between this transformed plant and a nontransformed control showed segregation for the NPT II gene in dot-blot assays; at least 24 plants out of 32 were kanamycin positive. Copy number in the progeny was variable, and ranged from none to ten.Abbreviations 2,4-d 2,4-dichlorophenoxyacetic acid - NAA- napthaleneacetic acid - BA benzyladenine