<Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation of European chestnut embryogenic cultures

An innovative and efficient genetic transformation protocol for European chestnut is described in which embryogenic cultures are used as the target material. When somatic embryos at the globular or early-torpedo stages were cocultured for 4 days with Agrobacterium tumefaciens strain EHA105 harbouring the pUbiGUSINT plasmid containing marker genes, a transformation efficiency of 25% was recorded. Murashige and Skoog culture medium containing 150 mg/l of kanamycin was used as the selection medium. The addition of acetosyringone was detrimental to the transformation efficiency. Transformation was confirmed by a histochemical -glucuronidase (GUS ) assay, PCR and Southern blot analyses for the uidA (GUS) and nptII (neomycin phosphotransferase II) genes. At present, 93 GUS-positive chestnut embryogenic lines are being maintained in culture. Low germination rates (6.3%) were recorded for the transformed somatic embryos. The presence of the transferred genes in leaves and shoots derived from the germinated embryos was also verified by the GUS assay and PCR analysis.     

Agrobacterium-mediated transformation of American chestnut (Castanea dentata (Marsh.) Borkh.) somatic embryos

These studies were designed to test if a binary vector containing the gfp, bar and oxalate oxidase genes could transform American chestnut somatic embryos; to see if a desiccation treatment during co-cultivation would affect the transformation frequency of different American chestnut somatic embryo clones; to explore the effects of more rapid desiccation; and to see if the antibiotics used to kill the Agrobacterium were interfering with the regeneration of the somatic embryos. Two days of gradual desiccation was found to significantly enhance transient GFP expression frequency. When this treatment was tested on six American chestnut clones, five were transformed and four of these remained embryogenic. Transformation was confirmed by Southern hybridization. Phenotypically normal transgenic shoots were regenerated and rooted. Vascular tissue specific expression of the oxalate oxidase gene was detected in one transgenic line. Carbenicillin, cefotaxime, and tricarcillin were found to not interfere with the regeneration of transformed embryos.     

Sexually mature transgenic American chestnut trees via embryogenic suspension-based transformation

The availability of a system for direct transfer of anti-fungal candidate genes into American chestnut (Castanea dentata), devastated by a fungal blight in the last century, would offer an alternative or supplemental approach to conventional breeding for production of chestnut trees resistant to the blight fungus and other pathogens. By taking advantage of the strong ability of embryogenic American chestnut cultures to proliferate in suspension, a high-throughput Agrobacterium tumefaciens-mediated transformation protocol for stable integration of foreign genes into the tree was established. Proembryogenic masses (PEMs) were co-cultivated with A. tumefaciens strain AGL1 harboring the plasmid pCAMBIA 2301, followed by stringent selection with 50 or 100 mg/l Geneticin. A protocol employing size-fractionation to enrich for small PEMs to use as target material and selection in suspension culture was applied to rapidly produce transgenic events with an average efficiency of four independent transformation events per 50 mg of target tissue and minimal escapes. Mature somatic embryos, representing 18 transgenic events and derived from multiple American chestnut target genotypes, were germinated and over 100 transgenic somatic seedlings were produced and acclimatized to greenhouse conditions. Multiple vigorous transgenic somatic seedlings produced functional staminate flowers within 3 years following regeneration.     

Genetic improvement of the somatic embryogenesis and regeneration in soybean and transformation of the improved breeding lines

Somatic embryos of soybean [Glycine max (L.) Merrill] have been used to generate transgenic plants by particle bombardment. The induction and proliferation of somatic embryos from immature cotyledons are dependent on the genotype of the cultivar. Whereas somatic embryogenesis and plant regeneration are inefficient in most cultivars, they are efficient in the cultivar Jack. We previously established a breeding line, QF2, by the integration of null mutations of each subunit of the major seed storage proteins glycinin and β-conglycinin, but the embryogenic response of this line is insufficient to allow efficient transformation. We have now backcrossed QF2 to cultivar Jack in order to combine the null traits with competence for somatic embryogenesis. The backcrossed breeding lines selected on the basis of the absence of the major storage proteins exhibited an improved capacity for the induction and proliferation of somatic embryos compared with that of QF2. The induced somatic embryogenic tissue of these breeding lines was successfully used for the production of transgenic plants by particle bombardment. These results also indicate that somatic embryogenesis in soybean is genetically controlled and inherited in a manner independent of the null traits of the major seed storage proteins.     

Plate flooding as an alternative <Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation method for American chestnut somatic embryos

In an attempt to improve Agrobacterium-mediated transformation frequency of American chestnut somatic embryos, a novel method of inoculation/co-cultivation was developed. Plate flooding is a simple method where the Agrobacterium inoculum is poured onto the embryos while they remain on multiplication medium. This method tested the hypothesis that wounding tissues prior to co-cultivation was unnecessary or counterproductive. Two clones, WB296 and P1-1, were tested for differences in transformation efficiency as measured by the number of transformed embryogenic cell lines per Petri dish, the total number of transformed cell lines (embryos plus callus) and percentage of transformants that remained embryogenic. Plate flooding using clone WB296 produced significantly more transformed embryo cell lines and had a higher percentage of transformants remain embryogenic. The number of total transformed cell lines (embryos plus callus) was the same as obtained by other methods (desiccation, blot dry, sand abrasion, sonication and vacuum infiltration). With clone P1-1 there were no significant differences among the inoculation/co-cultivation treatments tested. Polymerase chain reaction and Southern hybridizations confirmed that the transgene of interest had been stably integrated into both American chestnut clones. Whole plants were regenerated from clone P1-1.     

Optimizing Agrobacterium-mediated transformation of grapevine

Summary A translational fusion between the enhanced green fluorescent protein (EGFP) and neomycin phosphotransferase (NPTH) genes was used to optimize parameters influencing Agrobacterium-mediated transformation of Vitis vinifera L. cv. Thompson Seedless. The corresponding bifunctional protein produced from this EGFP/NPTH fusion gene allowed for a single promoter to drive expression of both green fluorescence and kanamycin resistance, thus conserving promoter resources and climinating potential promoter-promoter interactions. The fusion gene, driven by either a double cauliflower mosaic virus 35S (CaMV 35S) promoter or a double cassava vein mosaic virus (CsVMV) promoter, was immobilized into Agrobacterium strain EHA 105. Somatic embryos capable of direct secondary embryogenesis were used as target tissues to recover transgenic plants. Simultaneous visualization of GFP fluorescence and kanamycin selection of transgenic cells, tissues, somatic embryos, and plants were achieved. GFP expression and recovery of embryogenic culture lines were used as indicators to optimize transformation parameters. Preculturing of somatic embryos for 7 d on fresh medium prior to transformation minimized Agrobacterium-induced tissue browning/necrosis. Alternatively, browning/necrosis was reduced by adding 1 gl⁻¹ of the antioxidant dithiothreitol (DTT) to post co-cultivation wash media. While combining preculture with antioxidant treatments did not result in a synergistic improvement in response, either treatment resulted in recovery of more stable embryogenic lines than did the control. A 48h co-cultivation period combined with 75 mgl⁻¹ kanamycin in selection medium was optimal. DNA analysis confirmed stable integration of transgenes into the grape genome: 63% had single gene insertions, 27% had two inserts, and 7 and 3% had three and four inserts, respectively. Utilizing optimized procedures, over 1400 stable independent transgenic embryogenic culture lines were obtained, of which 795 developed into whole plants. Transgenic grapevines have exhibited normal vegetative morphology and stable transgene expression for over 5 yr.     

Histological analysis of direct somatic embryogenesis in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> (L.) Heynh

In Arabidopsis the in vitro culture of immature zygotic embryos (IZEs) at a late stage of development, on the solid medium containing synthetic auxin, leads to formation of somatic embryos via direct somatic embryogenesis (DSE). The presented results provide evidence that in IZE cells competent for DSE are located in the protodermis and subprotodermis of the adaxial side of cotyledons and somatic embryos displayed a single- or multicellular origin. Transgenic Arabidopsis lines expressing the GUS reporter gene, driven by the DR5 and LEC2 promoters, were used to analyse the distribution of auxin to mark embryogenic cells in cultured explants and develop somatic embryos. The analysis showed that at the start of the culture auxin was accumulated in all explant tissues, but from the fourth day onwards its location shifted to the protodermis and subprotodermis of the explant cotyledons. In globular somatic embryos auxin was detected in all cells, with a higher concentration in the protodermis, and in the heart stage its activity was mainly displayed in the shoot, root pole and cotyledon primordia. The embryogenic nature of dividing protodermal and subprotodermal cells accumulating auxin was confirmed by high expression of promoter activity of LEC2 in these cells. Analysis of symplasmic tracer (CFDA) distribution indicated symplasmic isolation between tissues engaged in DSE and other parts of an explant. Symplasmic isolation of somatic embryos from the explant was also detected.     

Plant regeneration in cotton: A short-term inositol starvation promotes developmental synchrony in somatic embryogenesis

Summary Despite high commercial interest, the success of biotechnological applications in cotton (Gossypium hirsutum) has been limited due to difficulties in genetic transformation. Major problems have been genotype dependence and low frequency of somatic embryogenesis, making it difficult to regenerate plants from transgenic tissue. This study reports an increase in somatic embryogenesis efficiency and the induction of developmental synchrony in embryogenic callus cultures of cotton by a single cycle of myo-inositol depletion in liquid culture. Calluses were initiated on hypocotyl or cotyledon explants of cultivar Coker 312 by culturing these explants on callus-inducing solid medium [Murashige and Skoog salts plus vitamins of Gamborg's B₅ medium, 30 g l⁻¹ glucose, 100 mg l⁻¹ myo-inositol, 2.2 μM 2,4-dichlorophenoxyacetic acid, and 0.88 μM 6-benzyladenine]. The calluses were transferred to an identical liquid basal medium devoid of plant growth regulators. This induced the development of embryogenic cells. Friable clumps of cells formed after 20 d in the medium were selectively collected over filter mesh 40 subjected to one cycle of myo-inositol starvation. This induced a highly synchronized embryogenesis in the culture. The optimized protocol gave 100% embryos at the globular stage, out of which more than 80% developed into bipolar torpedo-stage embryos. About 68% of these were converted to plantlets by subculturing onto a simplified solid medium, and finally grown into healthy, fertile plants.     

Agrobacterium tumefaciens-mediated transformation of embryogenic tissue and transgenic plant regeneration in Chamaecyparis obtusa Sieb. et Zucc.

A genetic transformation procedure for Chamaecyparis obtusa was developed after co-cultivation of embryogenic tissues with disarmed Agrobacterium tumefaciens strain C58/pMP90, which harbours the sgfp (synthetic green fluorescent protein) visual reporter and nptII (neomycin phoshotransferase II) selectable marker genes. The highest transformation frequency was 22.5 independent transformed lines per dish (250 mg embryogenic tissue) following selection on kanamycin medium. Transgenic plantlets were regenerated through the maturation and germination of somatic embryos. The intensity of GFP fluorescence, observed under a fluorescence microscope, varied from very faint to relatively strong, depending on the transgenic line or part of the transgenic plant. The integration of the genes into the genome of regenerated plantlets was confirmed by Southern blot analysis.     

Proliferation and maintenance of embryogenic capacity in elm embryogenic cultures

Summary This paper investigates maintenance and proliferation of somatic embryogenesis systems for Ulmus minor and U. glabra. Proliferation occurred with subculture of embryogenic calluses. The calluses were mainly formed by friable nodules composed of meristematic cells organized into proembryogenic cell masses (PEMs) and thin-walled vacuolated parenchymatic cells. Cotyledonary embryos, with procambial strands and differentiation of their vascular tissues as well as visible root meristems, were identifiable after 18d of culture on a proliferation medium with 0.44 μM benzyladenine (BA). The shoot meristem was only occasionally well developed. Somatic embryo multiplication from elm embryogenic calluses is a clearly asynchronic system, and PEMs as well as embryos at all stages of development are observed simultaneously at the end of subculture period. Factors affecting the proliferation of elm embryogenic callus, such as culture medium, carbon source and genotype, were studied. Basal medium (MS) or medium supplemented with 0.44 μM BA produced the highest number of somatic embryos. Somatic embryo production was higher with sucrose or glucose than with maltose, and significant differences were also found among the four embryogenic lines tested. The use of liquid medium with filter paper support is an essential step for the survival of isolated somatic embryos during the germination stage. The addition of 0.22 μM BA′ to liquid MS medium was the best treatment for germination and plantlet conversion of elm somatic embryos.     

Long-term cryopreservation of Greek fir embryogenic cell lines: recovery, maturation and genetic fidelity

In coniferous species, including Greek fir (Abies cephalonica Loud), the involvement of somatic embryo plants in breeding and reforestation programs is dependent on the success of long-term cryostorage of embryogenic cultures during clonal field testing. In the present study on Greek fir, we assayed the recovery, morphological characteristics and genetic fidelity of embryogenic cell lines 6 and 8 during proliferation and maturation after long-term cryostorage. Our results indicate successful recovery of both cell lines after 6 years in cryostorage. In the maturation phase, both cell lines were capable of producing somatic embryos although some differences were detected among experiments. However, these changes were more dependent on the differences in the components of the maturation media or in the experimental set-up than on the long-term cryostorage. During both proliferation and maturation phases, the morphological fidelity of the embryogenic cultures as well as of the somatic embryos were alike before and after cryopreservation. The genetic fidelity of the cryopreserved cell line 6 that was assayed by random amplified polymorphic DNA (i.e. RAPD) markers demonstrated some changes in the RAPD profiles. The results indicate possible genetic aberrations caused by long-term cryopreservation or somaclonal variation during the proliferation stage. However, in spite of these changes the embryogenic cultures did not lose their proliferation or maturation abilities.     

Genotype effects on proliferative embryogenesis and plant regeneration of soybean

Summary Proliferative somatic embryogenesis is a regeneration system suitable for mass propagation and genetic transformation of soybean [Glycine max (L.) Merr.]. The objective of this study was to examine genotypic effects on induction and maintenance of proliferative embryogenic cultures, and on yield, germination, and conversion of mature somatic embryos. Somatic embryos were induced from eight genotypes by explanting 100 immature cotyledons per genotype on induction medium. Differences in frequency of induction were observed among genotypes. However, this step was not limiting for plant regeneration because induction frequency in the least responding genotype was sufficient to initiate and maintain proliferative embryogenic cultures. Six genotypes selected for further study were used to initiate embryogenic cultures in liquid medium. Cultures were evaluated for propagation of globular-stage tissue in liquid medium, yield of cotyledon-stage somatic embryos on differentiation medium, and plant recovery of cotyledon-stage embryos. Genotypes also differed for weight and volume increase of embryogenic tissue in liquid cultures, for yield of cotyledon-stage embryos on differentiation medium, and for plant recovery from cotyledon-stage embryos. Rigorous selection for a proliferative culture phenotype consisting of nodular, compact, green spheres increased embryo yield over that of unselected cultures, but did not affect the relative ranking of genotypes. In summary, the genotypes used in this study differed at each stage of plant regeneration from proliferative embryogenic cultures, but genotypic effects were partially overcome by protocol modifications.     

In vitro propagation and cryopreservation of Thuja koraiensis Nakai via somatic embryogenesis

Korean arbor vitae (KAV; Thuja koraiensis Nakai) is a critically endangered coniferous tree in Korea. Here, we report the somatic embryogenesis (SE) and cryopreservation system that can be used for micropropagation of KAV and long-term storage of KAV cultures. To induce SE in KAV, the influence of the developmental stage of zygotic embryos and the effect of basal medium on embryogenesis induction were examined. The developmental stage of zygotic embryos had a significant effect on the embryogenesis induction (P < 0.0001). The highest frequency of embryogenesis induction occurred in megagametophytes with zygotic embryos at precotyledonary (P) and late embryogeny (L1) stage (36%). The highest frequency of embryogenesis induction was obtained on initiation medium containing IM basal salts with 2.2 μM 6-benzylaminopurine and 4.5 μM 2,4-dichlorophenoxyacetic acid (35%). The effect of abscisic acid (ABA) on production of somatic embryos was tested. The highest number of somatic embryos per 50 mg of embryogenic tissue was achieved on maturation medium with levels of 100 μM ABA (24.0 ± 2.4). The effect of cryopreservation treatment to embryogenic tissues on the maturation capacity of somatic embryos was also tested. No significant differences between noncryopreservation and cryopreservation treatment were observed (P = 0.1896), and the highest mean number of somatic embryo per 50 mg of embryogenic tissues was obtained in noncryopreserved cell line (28.17 ± 5.66). Finally, the genetic identities of the plantlets regenerated from non- and cryopreserved embryogenic cell lines were verified and there was no genetic variation in the regenerated plantlets from cryostored embryogenic cell lines. This study is the first report on SE and the successful cryopreservation of embryogenic culture of the genus Thuja.

     

Cryopreservation and plant regeneration via somatic embryogenesis using shoot apical domes of mature Pinus roxburghii sarg, trees

Summary The present investigation reports optimized parameters for somatic embryogenesis and cryopreservation of embryogenic cultures using shoot apical domes from mature trees of Pinus roxburghii Sarg. Embryogenic tissue of P. roxburghii Sarg. was cryopreserved for 24 h, 10 d, and 8 wk using sorbitol and dimethylsulfoxide (DMSO) as cryoprotectants. Results indicate that 0.2M sorbitol and 5% DMSO had the best cryoprotecting effect. The recovered tissue showed luxuriant growth on maintenance medium (II). Partial desiccation of thawed embryogenic tissue for 24 h prior to transfer to maturation medium enhanced the maturation of somatic embryos. Maturation frequency increased from 1.3 to 18.3% after 12 h desiccation treatment, and from 18.3 to 61.8% after 24 h of desiccation. However, non-desiccated embryogenic tissue produced the least number of somatic embryos (1.3%) on the maturation medium with the same abscisic acid and Gellan gum concentration. All the three embryogenic lines produced plantlets and had the same appearance and normal growth as compared to unfrozen controls.     

Enhancement of somatic embryogenesis in Norway spruce (Picea abies L.)

Summary Embryogenic callus developed in 55% of the mature embryo explants of Norway spruce (Picea abies L.) growing on a LP medium minus the amino acids and sugars (except sucrose). This is the highest reported yield of embryogenic callus from mature embryos of P. abies that has ever been reported. Callus induction from either the middle or the end of the hypocotyl of the embryos began after 2–3 weeks. Three types of calli were recovered: (a) globular, (b) light green-compact, (c) white mucilaginous. Only the white mucilaginous calli were embryogenic. The globular and light green-compact calli never become embryogenic, even after several subcultures. The development of somatic embryos was accomplished on half-strength macro-elements of NSIII medium containing 1 M -naphthaleneacetic acid, 1 M abscisic acid, and 3% sucrose. The addition of 10^–7 M buthionine sulfoximine to the medium increased the development of somatic embryos by three fold. These results suggest that there is a great potential for increasing the frequency and development of somatic embryos in P. abies. Careful selection of the genotype and modification of the culture medium is required.     

Efficient transformation of papaya by coat protein gene of papaya ringspot virus mediated byAgrobacterium following liquid-phase wounding of embryogenic tissues with caborundum

Summary Generation of transgenic papaya (Carica papaya L.) has been hampered by the low rates of transformation achieved by conventionalAgrobacterium infection or microprojectile bombardment. We describe an efficientAgrobacterium-mediated transformation method based on wounding of cultured embryogenic tissues with carborundum in liquid phase. Embryogenic tissues were obtained from cultured immature zygotic embryos collected 75–90 days after pollination. The expressible coat protein (CP) gene of a Taiwan strain of papaya ringspot virus (PRSV) was constructed in a Ti binary vector pBGCP, which contained the NPT-II gene as a selection marker. The embryogenic tissues were vortexed with 600 mesh carborundum in sterile distilled water for 1 min before treating with the disarmedA. tumefaciens containing the pBGCP. Transformed cells were cultured on kanamycin-free medium containing 2,4-D and carbenicillin for 2–3 weeks and then on the kanamycin medium for 3–4 months. The developed somatic embryos were transferred to the medium containing NAA, BA and kanamycin and subsequently regenerated into normal-appearing plants. Presence of the PRSV CP gene in the putative transgenic lines was detected by PCR and the expression of the CP was verified by Western blotting. The transgene was nuclearly inherited as revealed by segregation analysis in the backcrossed R₁ progeny. From five independent experiments, the average successful rate of transformation was 15.9% of the zygotic embryos treated (52 transgenic somatic embryo clusters out of 327 zygotic embryos treated), about 10–100 times higher than the available methods previously reported. Thus, wounding highly regenerable differentiating tissues by carborundum vortexing provides a simple and efficient way for papaya transformation mediated byAgrobacterium.     

Embryogenic cell lines of <Emphasis Type="Italic">Juniperus communis</Emphasis>; easy establishment and embryo maturation,limited germination

Several coniferous species belonging to the Pinaceae family can be propagated via somatic embryogenesis, while species belonging to the Cupressaceae family cannot. The aim of this study was to identify possibilities and limitations with somatic embryogenesis in Cupressaceae. Juniperus communis was chosen as model species. We show that a high initiation frequency of embryogenic cell lines can be established from intact megagametophytes at the time when intensive cleavage polyembryogeny takes place. The embryogenic cell lines proliferate fast on medium lacking plant growth regulators. Early somatic embryos develop after transfer to medium with decreased content of nitrogen and calcium. The early embryos mature after exposure to abscisic acid. Mature cotyledonary embryos germinate after partial desiccation. A high proportion, over 40%, of the germinating embryos retain the embryogenic potential in the basal part, resulting in development of new embryogenic tissue.     

Enhancement of American chestnut somatic seedling production

Somatic embryogenesis holds promise for mass propagation of American chestnut trees bred or genetically engineered for resistance to chestnut blight. However, low germination frequency of chestnut somatic embryos has limited somatic seedling production for this forest tree. We tested the effects of culture regime (semi-solid versus liquid), cold treatment, AC and somatic embryo morphology (i.e., cotyledon number) on germination and conversion of the somatic embryos. Cold treatment for 12 weeks was critical for conversion of chestnut somatic embryos to somatic seedlings, raising conversion frequencies for one line to 47%, compared to 7% with no cold treatment. AC improved germination and conversion frequency for one line to 77% and 59%, respectively, and kept roots from darkening. For two lines that produced embryos with one, two or three-plus cotyledons, cotyledon number did not affect germination or conversion frequency. We also established embryogenic American chestnut suspension cultures and adapted a fractionation/plating system that allowed us to produce populations of relatively synchronous somatic embryos for multiple lines. Embryos derived from suspension cultures of two lines tested had higher conversion frequencies (46% and 48%) than those from cultures maintained on semi-solid medium (7% and 30%). The improvements in manipulation of American chestnut embryogenic cultures described in this study have allowed over a 100-fold increase in somatic seedling production efficiency over what we reported previously and thus constitute a substantial advance toward the application of somatic embryogenesis for mass clonal propagation of the tree.     

Regeneration of transgenic plants by Agrobacterium-mediated transformation of somatic embryos of juvenile and mature Quercus robur

A protocol was developed for genetic transformation of somatic embryos derived from juvenile and mature Quercus robur trees. Optimal transformation conditions were evaluated on the basis of the results of transient GUS expression assays with five oak embryogenic lines and a strain of Agrobacterium tumefaciens (EHA105) harbouring a p35SGUSINT plasmid containing a nptII and a uidA (GUS) genes. For stable transformation, embryo clumps at globular/torpedo stages (4–10 mg) were inoculated with EHA105:p35SGUSINT bacterial cultures, cocultivated for 4 days and selected in proliferation medium with 75 mg/l of kanamycin. Putatively transformed masses appeared after 20–30 weeks of serial transfers to selective medium. Histochemical and molecular analysis (PCR and Southern blot) confirmed the presence of nptII and uidA genes in the plant genomes. Transformation efficiencies ranged from up to 2% in an embryogenic line derived from a 300-year-old tree, to 6% in a juvenile genotype. Twelve independent transgenic lines were obtained from these oak genotypes, and transgenic plantlets were recovered and acclimatized into the soil. This is the first demonstration of the production of transformed somatic embryos and regenerated plants from juvenile and mature trees of Q. robur and suggests the possibility of introducing other genetic constructions to develop trees that are tolerant/resistant to pathogens and/or biotic stresses.     

Production ofAgrobacterium-mediated transgenic fertile plants by direct somatic embryogenesis from immature zygotic embryos ofDatura innoxia

This work describes a new method to obtain transgenic somatic embryos fromAgrobacterium-infected immature zygotic embryos ofDatura innoxia. It has several advantages over previous transformation methods such as the absence of a callus phase, an average transformation rate of 76% and a high regeneration frequency. Critical steps for optimal transformation were the embryo stage and a short preculture treatment. The marker gene -glucuronidase and light microscopy were used to identify the competent embryogenic cells which, after transformation, passed through the classical stages of embryo development. The transgenes were transmitted to the progeny in a Mendelian fashion. The plants regenerated via direct somatic embryogenesis were cytologically and morphologically uniform. We also observed that: (1) wounding or wound-induced divisions were not required for zygotic embryo transformation; (2) epidermal cells were competent for both transformation and regeneration; and (3) competency forAgrobacterium infection was developmental stage-specific. This new method should facilitate the development of new strategies to routinely transform recalcitrant plant species.