Apomixis and ploidy barrier suppress pollen-mediated gene flow in field grown transgenic turf and forage grass (Paspalum notatum Flüggé)

Bahiagrass (Paspalum notatum Flüggé) is the predominant forage grass in the southeastern US. The commercially important bahiagrass cultivar ‘Argentine’ is preferred for genetic transformation over sexual diploid cytotypes, since it produces uniform seed progeny through apomixis. Pseudogamous apomictic seed production in Argentine bahiagrass may contribute to transgene confinement. It is characterized by embryo development which is independent of fertilization of the egg cell, but requires fertilization with compatible pollen to produce the endosperm. Pollen-mediated gene transfer from transgenic, glufosinate-resistant apomictic bahiagrass as pollen donor at close proximity (0.5–3.5 m) with non-transgenic sexual or apomictic bahiagrass cultivars as pollen receptors was evaluated under field conditions. Hybridization frequency was evaluated by glufosinate herbicide resistance in >23,300 seedlings derived from open-pollinated (OP) pollen receptor plants. Average gene transfer between transgenic apomictic, tetraploid and sexual diploid bahiagrass was 0.03%. Herbicide-resistant hybrids confirmed by immuno-chromatographic detection of the PAT protein displayed a single copy bar gene identical to the pollen parent. Hybrids resulting from diploid pollen receptors were confirmed as triploids or aneu-triploids with significantly reduced vigor and seed set as compared to the parents. Transmission of transgenes to sexual bahiagrass is severely restricted by the ploidy difference between tetraploid apomicts and diploid sexual bahiagrass. Average gene transfer between transgenic apomictic tetraploid and non-transgenic, apomictic tetraploid bahiagrass was 0.17%, confirming a very low frequency of amphimixis in apomictic bahiagrass cultivars. While not providing complete transgene containment, gene transfer between transgenic apomictic and non-transgenic bahiagrass occurs at a much lower frequency than reported for other cross-pollinating or facultative apomictic grasses.     

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

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

Controlling Transgene Escape in GM Creeping Bentgrass

Trait improvement of turfgrass through genetic engineering is important to the turfgrass industry and the environment. However, the possible transgene escape to wild and non-transformed species raises ecological and commercial concerns. Male sterility provides an effective way for interrupting gene flow. We have designed and synthesized two chimeric gene constructs consisting of a rice tapetum-specific promoter (TAP) fused to either a ribonuclease gene barnase, or the antisense of a rice tapetum-specific gene rts. Both constructs were linked to the bar gene for selection by resistance to the herbicide glufosinate. Agrobacterium-mediated transformation of creeping bentgrass (cv Penn A-4) with both constructs resulted in herbicide-resistant transgenic plants that were also 100% pollen sterile. Mendelian segregation of herbicide resistance and male sterility was observed in T1 progeny derived from crosses with wild-type plants. Controlled self- and cross-pollination studies showed no gene transfer to non-transgenic plants from male-sterile transgenic plants. Thus, male sterility can serve as an important tool to control transgene escape in bentgrass, facilitating the application of genetic engineering in producing environmentally responsible turfgrass with enhanced traits. It also provides a tool to control gene flow in other perennial species using transgenic technology.     

An efficient and rapid transgenic pollen screening and detection method using flow cytometry

Assaying for transgenic pollen, a major vector of transgene flow, provides valuable information and essential data for the study of gene flow and assessing the effectiveness of transgene containment. Most studies have employed microscopic screening methods or progeny analyses to estimate the frequency of transgenic pollen. However, these methods are time-consuming and laborious when large numbers of pollen grains must be analyzed to look for rare transgenic pollen grains. Thus, there is an urgent need for the development of a simple, rapid, and high throughput analysis method for transgenic pollen analysis. In this study, our objective was to determine the accuracy of using flow cytometry technology for transgenic pollen quantification in practical application where transgenic pollen is not frequent. A suspension of non-transgenic tobacco pollen was spiked with a known amount of verified transgenic tobacco pollen synthesizing low or high amounts of green fluorescent protein (GFP). The flow cytometric method detected approximately 75% and 100% of pollen grains synthesizing low and high amounts of GFP, respectively. The method is rapid, as it is able to count 5000 pollen grains per minute-long run. Our data indicate that this flow cytometric method is useful to study gene flow and assessment of transgene containment.     

Responses of MxPPO overexpressing transgenic tall fescue plants to two diphenyl-ether herbicides, oxyfluorfen and acifluorfen

We generated transgenic tall fescue (Festuca arundinacea Schreb. cv. Kentucky-31) plants harboring a synthetic Myxococcus xanthus protoporphyrinogen oxidase (MxPPO) gene through Agrobacterium-mediated gene transfer. Successful integration of the transgene into the genome of transgenic plants confirmed by polymerase chain reaction (PCR) and Southern blot analysis, and the functional expression of the MxPPO gene at the mRNA level in transgenic lines was validated by Northern blot analysis. Responses of transgenic and non-transgenic tall fescue plants to diphenyl-ether herbicides such as oxyfluorfen and acifluorfen have been evaluated in respect of various physiological and biochemical parameters. Differential responses were observed in chlorophyll content, in vivo H₂O₂ deposition and lipid peroxidation in both transgenic and non-transgenic plants exposed to oxyfluorfen or acifluorfen. Isozyme profiles of four antioxidant-enzymes, including peroxidase (POD), catalase (CAT), superoxide dismutase (SOD) and ascorbate peroxidase (APX), were also investigated in transgenic and non-transgenic plants using native PAGE analysis. Compared to the transgenic lines, higher staining activities of the examined antioxidant-enzymes observed in non-transgenic plants subjected to 100 μM of oxyfluorfen or acifluorfen suggests that non-transgenic plants are unable to prevent the photodynamic induced oxidative stress caused by herbicides. In addition, both transgenic and non-transgenic plants exposed to oxyfluorfen exhibited proportionally increased band-staining patterns in contrast to acifluorfen, which suggests that oxyfluorfen has relatively greater or more rapid effects on leaves than acifluorfen. Both Ki-Won Lee and Nagib Ahsan have contributed equally to this work.     

Production of tetraploid plants of non apomictic citrus genotypes

Ploidy manipulation in Citrus is a major issue of current breeding programs aiming to develop triploid seedless mandarins to address consumer demands for seedless fruits. The most effective method to obtain triploid hybrids is to pollinate tetraploid non apomictic cultivars with pollen of diploid varieties. Such non apomictic tetraploid lines are not found in the citrus germplasm and need to be created. In this work we describe a new methodology based on in vitro shoot-tip grafting combined with treatment of the micro-grafted shoot-tip with colchicine and oryzalin to achieve chromosome doubling and a dechimerization procedure assisted by flow cytometry. Stable tetraploid plants of Clemenules, Fina and Marisol clementines and Moncada mandarin have been obtained directly from shoot tip grafting combined with colchicine and oryzalin treatments or after dechimerization of mixoploids plants (2x–4x). These stable tetraploid plants have been used in 4x × 2x hybridizations, to recover over 3,250 triploid hybrids in 3 years.     

Spontaneous tetraploidy in apomictic seedlings ofCitrus

Populations of apomictic seedlings of clones ofCitrus species,Citrus hybrids, andPoncirus in the sub-family Aurantioideae were examined for spontaneous tetraploids as a source of materials for use in breeding experiments. Diagnostic features found useful in identifying nucellar tetraploids were leaf shape, petiole blade shape, leaf blade thickness, leaf color, comparative size differences in leaf venation, oil glands, and stomata, stem thickness, and relative size and developmental pattern of the root system. In older or bearing-age plants, nucellar tetraploids may be identified by differences in growth habit, vigor, size, time of growth initiation and bloom, and flower and fruit characteristics. Data are given for tetraploid frequency in glasshouse-grown, first-year nucellar seedlings of 42 populations of 32 clones of different genetic and seed origin and for tetraploid frequency in commercialnursery nucellar seedlings of the Carrizo rootstock clone in two consecutive years. Comparative data are given for quantitative development of roots, stems, and leaves of tetraploids and similar diploid nucellar seedlings. The data suggest that the ability to produce tetraploid apomictic seedlings is a variable genetic trait present in all or nearly all clones able to reproduce by adventitious embryony. Aspects of tetraploid nucellar seedlings that might warrant their testing as tree-size-controlling rootstocks in commercial citrus growing are discussed.     

A comparison of apomictic reproduction in eastern gamagrass (Tripsacum dactyloides (L.) L.) and maize-Tripsacum hybrids

The expression of gene(s) governing apomictic reproduction inTripsacum provides the best foundation for comparing the effectiveness of apomictic reproduction in a series of maize-Tripsacum hybrids. Several 38-chromosome, apomictic maize-Tripsacum hybrids are available which possess the gene(s) conferring apomictic reproduction fromTripsacum. Without a base line for comparison, studies directed towards discerning the successful transfer or effectiveness of gene expression in a maize background are hampered. The objectives of this study are to compare the reproductive features found in apomicticTripsacum with those in apomictic maize-Tripsacum hybrids. In addition, this study determined the feasibility of utilizing these maize-Tripsacum hybrid materials to continue an attempt to transfer the genes into a pure maize background. The frequency and occurrence of five unique reproductive features found in apomictic accessions ofTripsacum dactyloides were compared to the reproductive behaviours exhibited in the maize-Tripsacum hybrids. Results indicate the genes controlling apomixis in tetraploidTripsacum are fully functional in maize-Tripsacum hybrids with diploid and triploid maize constitutions. The ability of theTripsacum apomictic genes to retain full expression provides evidence to continue their transfer to a diploid or tetraploid maize background.The use of company names in this publication does not imply endorsement by the USDA-ARS, or the product names or criticism of similar ones not mentioned. All programs and services of the U.S. Department of Agriculture are offered on a nondiscriminatory basis without regard to race, color, national origin, religion, sex, age, marital status, or handicap.     

Transgene Containment Using Cytokinin-Reversible Male Sterility in Constitutive, Gibberellic Acid–Insensitive (Δgai) Transgenic Tobacco

Mechanisms are needed to prevent gene flow from transgenic crops, and the later establishment of these transgenes in populations of other varieties, weeds, or wild relatives. Such prevention can be achieved by containing the transgene within a crop, and then mitigating the effects of the inherent leakage and unidirectionality of containment systems. Mitigation lowers the fitness of recipients below that of the wild-type so that transgenes cannot spread. Transplastomic and male-sterility systems suppress transgene outflow, but not the influx of pollen from relatives, requiring mitigation. The Arabidopsis thaliana Δgai (gibberellic acid–insensitive) gene, driven by its own promoter, induced male sterility in transgenic tobacco (Nicotiana tabacum), which is chemically reversible by kinetin applications. Female reproduction was not affected. Kinetin-treated sterile hemizygous and homozygous dwarf tobacco produced viable pollen, becoming self-fertile with copious viable seed, restoring the small amount of seed production needed for such a crop. Thus, Δgai, under its endogenous promoter, can be used as a containment mechanism to prevent transgene outflow. This application is in addition to the previously described highly effective role of Δgai as a dwarfing mitigator gene, which renders the rare transgenic tobacco hybrids unfit and unable to compete with the wild-type in the mixed cultures. Δgai is unique in that it can be used both to prevent transgene outflow and to mitigate the flow should containment fail or should gene influx occur, a dual role for the gene, not previously reported.     

Attack of the clones: reproductive interference between sexuals and asexuals in the Crepis agamic complex

Negative reproductive interactions are likely to be strongest between close relatives and may be important in limiting local coexistence. In plants, interspecific pollen flow is common between co‐occurring close relatives and may serve as the key mechanism of reproductive interference. Agamic complexes, systems in which some populations reproduce through asexual seeds (apomixis), while others reproduce sexually, provide an opportunity to examine effects of reproductive interference in limiting coexistence. Apomictic populations experience little or no reproductive interference, because apomictic ovules cannot receive pollen from nearby sexuals. Oppositely, apomicts produce some viable pollen and can exert reproductive interference on sexuals by siring hybrids. In the Crepis agamic complex, sexuals co‐occur less often with other members of the complex, but apomicts appear to freely co‐occur with one another. We identified a mixed population and conducted a crossing experiment between sexual diploid C. atribarba and apomictic polyploid C. barbigera using pollen from sexual diploids and apomictic polyploids. Seed set was high for all treatments, and as predicted, diploid–diploid crosses produced all diploid offspring. Diploid–polyploid crosses, however, produced mainly polyploidy offspring, suggesting that non‐diploid hybrids can be formed when the two taxa meet. Furthermore, a small proportion of seeds produced in open‐pollinated flowers was also polyploid, indicating that polyploid hybrids are produced under natural conditions. Our results provide evidence for asymmetric reproductive interference, with pollen from polyploid apomicts contributing to reduce the recruitment of sexual diploids in subsequent generations. Existing models suggest that these mixed sexual–asexual populations are likely to be transient, eventually leading to eradication of sexual individuals from the population.     

Mitigation using a tandem construct containing a selectively unfit gene precludes establishment of Brassica napus transgenes in hybrids and backcrosses with weedy Brassica rapa

Transgenic oilseed rape ( Brassica napus ) plants can interbreed with nearby weedy Brassica rapa , potentially enhancing the weediness and/or invasiveness of subsequent hybrid offspring. We have previously demonstrated that transgenic mitigation effectively reduces the fitness of the transgenic dwarf and herbicide-resistant B. napus volunteers. We now report the efficacy of such a tandem construct, including a primary herbicide-resistant gene and a dwarfing mitigator gene, to preclude the risks of gene establishment in the related weed B. rapa and its backcross progeny. The transgenically mitigated and non-transgenic B. rapa  ×  B. napus interspecific hybrids and the backcrosses (BC₁) with B. rapa were grown alone and in competition with B. rapa weed. The reproductive fitness of hybrid offspring progressively decreased with increased B. rapa genes in the offspring, illustrating the efficacy of the concept. The fitness of F₂ interspecific non-transgenic hybrids was between 50% and 80% of the competing weedy B. rapa , whereas the fitness of the comparable T₂ interspecific transgenic hybrids was never more than 2%. The reproductive fitness of the transgenic T₂ BC₁ mixed with B. rapa was further severely suppressed to 0.9% of that of the competing weed due to dwarfism. Clearly, the mitigation technology works efficiently in a rapeseed crop–weed system under biocontainment-controlled environments, but field studies should further validate its utility for minimizing the risks of gene flow.     

Fertile transgenic pearl millet [<Emphasis Type="Italic">Pennisetum glaucum</Emphasis> (L.) R. Br.] plants recovered through microprojectile bombardment and phosphinothricin selection of apical meristem-, inflorescence-, and immature embryo-derived embryogenic tissues

Pearl millet [ Pennisetum glaucum (L.) R. Br.] is a drought-tolerant cereal crop used for grain and forage. Novel traits from outside of the gene pool could be introduced provided a reliable gene-transfer method were available. We have obtained herbicide-resistant transgenic pearl millet plants by microprojectile bombardment of embryogenic tissues with the bar gene. Embryogenic tissues derived from immature embryos, inflorescences and apical meristems from diploid and tetraploid pearl millet genotypes were used as target tissues. Transformed cells were selected in the dark on Murashige and Skoog medium supplemented with 2 mg/l 2,4-D and 15 mg/l phosphinothricin (PPT). After 3-10 weeks in the dark, herbicide-resistant somatic embryos were induced to germinate on MS medium containing 0.1 mg/l thidiazuron and 0.1 mg/l 6-benzylaminopurine. Plants were transferred to the greenhouse after they were rooted in the presence of PPT and had passed a chlorophenol red assay (the medium turned from red to yellow). Transgenic plants were recovered from bombardments using intact pAHC25 plasmid DNA, a gel-purified bar fragment, or a mixture of pAHC25 plasmid or bar fragment and a plasmid containing the enhanced green fluorescent protein ( gfp) gene (p524EGFP.1). Analyses by the polymerase chain reaction, Southern blot hybridization, GFP expression, resistance to herbicide application, and segregation of the bar and gfp genes confirmed the presence and stable integration of the foreign DNA. Transformed plants were recovered from all three explants, although transformation conditions were optimized using only the tetraploid inflorescence. Time from culture initiation to rooted transgenic plant using the tetraploid inflorescence ranged from 3-4 months. Seven independent DNA/gold precipitations were used to bombard 52 plates, 29 of which produced an average of 5.5 herbicide-resistant plants per plate. The number of herbicide-resistant plants recovered per successful bombardment ranged from one to 28 and the frequency of co-transformation with gfp ranged from 5% to 85%.     

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.     

Growth, fecundity and competitive ability of transgenic Trifolium subterraneum subsp. subterraneum cv. Leura expressing a sunflower seed albumin gene

Ecological risk assessment is an important step in the production and commercialisation of transgenic plants. To date, however, most risk assessment studies have been performed on crop plants, and few have considered the ecological consequences associated with genetic modification of pasture species. In this study we compared the growth, yield, population dynamics and competitive ability of transgenic Trifolium subterraneum subsp. subterraneum cv. Leura (subclover) expressing a nutritive sunflower seed albumin (ssa) gene with the equivalent non-transgenic commercial line in a glasshouse competition trial. Plants were grown in low-fertility soil typical of unimproved native southeastern Australian grasslands. We measured survivorship, seed production rate, seed germination rate, seed weight, dry weight yield and the intrinsic rate of population increase (lambda) of plants grown in mixtures and monocultures over a range of densities (250 to 2000 plants m(-2)), and also determined intragenotypic and intergenotypic competition coefficients for each line. There were no significant differences between transgenic and non-transgenic plants in any of the measured variables except survivorship; transgenic plants had a significantly lower survival rate than non-transgenic plants when grown at high densities (p<0.01). However, density-dependent effects were observed for all measured variables, and in all models plant density affected the response variables more than the presence of the transgene. Based on these results, we conclude that the ssa gene construct appears to confer no advantage to transgenic T. s. subterraneum cv. Leura growing in mixed or pure swards under the fertility and density regimes examined in the trial. Our data also suggest that transgenic subterranean clover expressing the ssa gene is unlikely to exhibit a competitive advantage over associated non-transgenic commercial cultivars when grown in dense swards in low-fertility pastures.     

Possible pathways of the gene flow inTaraxacum sect.Ruderalia

Reproductive behaviour and the pathways of gene flow among ploidy levels were studied experimentally inTaraxacum sect.Ruderalia. Diploid, triploid and tetraploid individuals were sampled from mixed diploid — polyploid natural populations. 136 experimental hybridizations between the plants of different ploidy levels were performed. Seeds resulting from these crosses, those obtained from isolated anthodia as well as from open pollinated anthodia (both from cultivated and wild plants) were subjected to the flow-cytometric seed screening (FCSS) to determine ploidy levels in the progeny and to infer breeding behaviour of maternal plants. Three possible pathways of the gene flow were studied: (A) fertilization of sexuals by pollen of apomicts, (B) B_III hybrid formation, (C) facultative apomixis. Diploid maternal plants when experimentally crossed with triploid pollen donors produced diploids and polyploid progeny, while when pollinated with a mixture of the pollen of diploids and triploids or insect pollinated, no polyploids were discovered. It seems that in the mixture with the pollen of diploids, the pollen of triploids is ineffective. Tetraploids produce hybrids much easier with diploid mothers and their role in wild populations requires further study. Triploid mothers, even those with subregular pollen did not show traces of facultative apomixis. B_III hybrids were present in the progeny of both triploids and tetraploids, in tetraploids in quite high percentages (up to 50% of the progeny in some crosses).     

Mitigation of establishment of Brassica napus transgenes in volunteers using a tandem construct containing a selectively unfit gene

Transgenic oilseed rape ( Brassica napus ) plants may remain as 'volunteer' weeds in following crops, complicating cultivation and contaminating crop yield. Volunteers can become feral as well as act as a genetic bridge for the transfer of transgenes to weedy relatives. Transgenic mitigation using genes that are positive or neutral to the crop, but deleterious to weeds, should prevent volunteer establishment, as previously intimated using a tobacco ( Nicotiana tabacum ) model. A transgenically mitigated (TM), dwarf, herbicide-resistant construct using a gibberellic acid-insensitive (Δ gai ) gene in the B. napus crop was effective in offsetting the risks of transgene establishment in volunteer populations of B. napus . This may be useful in the absence of herbicide, e.g. when wheat is rotated with oilseed rape. The TM dwarf B. napus plants grown alone had a much higher yield than the non-transgenics, but were exceedingly unfit in competition with non-transgenic tall cohorts. The reproductive fitness of TM B. napus was 0% at 2.5-cm and 4% at 5-cm spacing between glasshouse-grown plants relative to non-transgenic B. napus . Under screen-house conditions, the reproductive fitness of TM B. napus relative to non-transgenic B. napus was less than 12%, and the harvest index of the TM plants was less than 40% of that of the non-transgenic competitors. The data clearly indicate that the Δ gai gene greatly enhances the yield in a weed-free transgenic crop, but the dwarf plants can be eliminated when competing with non-transgenic cohorts (and presumably other species) when the selective herbicide is not used.     

Green, herbicide-resistant plants by particle inflow gun-mediated gene transfer to diploid bahiagrass (Paspalum notatum)

We have established an efficient particle-bombardment transformation protocol for the diploid non-apomictic genotype of the warm season forage crop Paspalum notatum (bahiagrass). A vector containing a herbicide resistance gene (bar) together with the GUS reporter gene was used in transformation experiments. The bar gene confers resistance to the herbicide bialaphos. An improved culture system, highly regenerative callus, dense in compact polyembryogenic clusters, was produced on medium with a high CuSO4 content at elevated temperature. Target tissue (360 calli) produced under these conditions yielded 52 rooted plants on herbicide-containing medium, and 22 of these plants were PCR-positive. DNA gel blot analysis revealed a copy number of 1-5 for the GUS gene in different independent transformants. There was no correlation between copy number and GUS activity. While conventional cultures yielded exclusively albino plants on herbicide-containing medium, improved culture conditions for the target tissue resulted in the recovery of 100% green transgenic plants. All green herbicide-resistant regenerants were morphological normal and fertile.