Enhanced recovery of doubled haploid lines from parthenogenetic plants of melon (<Emphasis Type="Italic">Cucumis melo</Emphasis> L.)

Recovery of doubled haploid (DH) progeny from haploid melon plants for use in breeding programs requires efficient chromosome doubling procedures. We describe improved procedures for recovery of fruits and viable seeds from parthenogenetic melon plants. Plant regeneration from nodal explants treated with 500 mg/L colchicine for 12 h was increased from 40 to 88% by transferring the treated explants to medium supplemented with a combination of growth regulators [5 μM IAA; 5 μM BA; 1 μM ABA; 30 μM AgNO₃). Prolonged exposure (2–7 days) to colchicine inhibited regeneration from nodal explants but had less effect on shoot tip explants. Many colchicine-treated plantlets flowered in vitro, allowing early assessment of their male fertility. Production of stained pollen in plants from nodal explants was highest after 0.5–2 days of colchicine treatment and on plants from shoot tips after 1–2 days. In vitro pollen counts correlated well with counts from greenhouse grown plants and with fruit set. The fruit set rate for colchicine-treated plants with a high pollen number was 47%. Appropriate colchicine treatment and culture of nodal explants as well as tip explants can substantially increase the number of fertile plants and DH lines recovered from parthenogenetic melons.     

Production of haploid and doubled haploid plants of melon (<Emphasis Type="Italic">Cucumis melo</Emphasis> L.) for use in breeding for multiple virus resistance

We have developed improved procedures for recovery of haploid and doubled haploid (DH) melon plants, using hybrids derived from crosses of lines with multiple virus resistance. Seeds formed after pollination with irradiated pollen were cultured in liquid medium for 10 days before excision of the embryos for further culture. This made it easier to identify the seeds containing parthenogenetic embryos, thereby reducing the effort required and increasing the percentage of plants recovered. The plants obtained (approximately 175) were transferred to a greenhouse for evaluation. Three fertile lines were identified, and selfed seeds were obtained for evaluating virus resistance. Flow cytometry of leaf tissues showed that two of these lines were spontaneous DH and the third was a mixoploid containing haploid and diploid cells. The other plants remained sterile through the flowering stage. Flow cytometry of 20 sterile plants showed that all were haploid. Attempts to induce chromosome doubling by applying colchicine to greenhouse-grown plants were unsuccessful. Shoot tips from the haploid plants were used to establish new in vitro cultures. In vitro treatment of 167 micropropagated haploid shoots with colchicine produced 10 diploid plants as well as 100 mixoploid plants. Pollen from male flowers that formed in vitro on the colchicine-treated plants was examined. High percentages of viable pollen that stained with acetocarmine were found not only in the diploids but also in >60% of the plants scored as mixoploid or haploid by flow cytometry. Efficient recovery of DH from hybrid melon lines carrying combinations of important horticultural traits will be a valuable tool for melon breeders.     

Efficient production of doubled haploid plants through colchicine treatment of anther-derived maize callus

Summary A chromosome doubling technique, involving colchicine treatment of an embryogenic, haploid callus line of maize (Zea mays L., derived through anther culture), was evaluated. Two colchicine levels (0.025% and 0.05%) and three treatment durations (24, 48, and 72 h) were used and compared to untreated controls. Chromosome counts and seed recovery from regenerated plants were determined. No doubled haploid plants were regenerated from calli without colchicine treatment. After treatment with colchicine for 24 h, the callus tissue regenerated about 50% doubled haploid plants. All of the plants regenerated from the calli treated with colchicine for 72 h were doubled haploids, except for a few tetraploid plants. No significant difference in chromosome doubling was observed between the two colchicine levels. Most of the doubled haploid plants produced viable pollen and a total of 107 of 136 doubled haploid plants produced from 1 to 256 seeds. Less extensive studies with two other genotypes gave similar results. These results demonstrate that colchicine treatment of haploid callus tissue can be a very effective and relatively easy method of obtaining a high frequency of doubled haploid plants through anther culture.     

Improved chromosome doubling of parthenogenetic haploid plants of cucumber (<Emphasis Type="Italic">Cucumis sativus</Emphasis> L.) using colchicine,trifluralin, and oryzalin

An effective chromosome doubling protocol was established in essential garden crop of cucumber (Cucumis sativus L.) Cv. Hi Power. The different concentrations of colchicine (0, 250, 500, 750, and 1500 mg/L), oryzalin (0, 5, 15, 25, 50, 75, and 150 mg/L) and trifluralin (0, 5, 15, 25, 50, 75, and 150 mg/L) were applied on parthenogenesis-induced haploid nodal and shoot tip explants of cucumber for 18 and 38 h in three independent factorial experiments. Increasing concentrations of applied antimitotic agents led to the significant reduction in the survival rate of both shoot tip and nodal explants, especially in longer exposure duration. Three ploidy levels including haploid, mixoploid, and doubled haploid were regenerated form both explant types treated with colchicine, oryzalin, and trifluralin. Flow cytometry analysis proved successful chromosome doubling of haploid plants. Based on the results obtained, the highest number of regenerated doubled haploid plants (92.31%) and fruit set (86.21%) were related to immersion of nodal explants in 50 mg/L oryzalin for 18 h. The highest doubled haploid regeneration for colchicine and trifluralin antimitotic agents were 58.33 and 83.33%, respectively. The leaf size of doubled haploid plants was larger than their correspond haploids. The optimized chromosome doubling protocol would be applicable for doubled haploid production in garden crops of Cucurbitaceae family, which is recalcitrant to the spontaneous doubling, and also for in vitro polyploidy induction studies.     

Improved production of doubled haploids of winter and spring triticale hybrids via combination of colchicine treatments on anthers and regenerated plants

Double haploids (DH), obtained during androgenesis in vitro or by genome diploidisation in regenerated haploids, are one type of basic materials used in triticale breeding programmes. The aim of this study was to improve DH production by a combination of colchicine treatment methods on a sample of five winter and five spring triticale hybrids. Colchicine was applied in vitro either in the C17 medium to induce embryo-like structures (ELS) or in the 190-2 medium for green plant (GP) development. Regenerants which remained haploid were immersed in a colchicine solution either when placed on the medium prior to transferring to soil or when growing in pots, followed by the application or absence of cooling. Colchicine treatment during anther culture affected neither ELS nor GP development, but significantly increased the number of DH plants in comparison to spontaneous chromosome doubling. The highest efficiency was recorded when colchicine was applied in the induction medium (55%) versus the regeneration medium (44.5%) or no colchicine treatment (30%). The effectiveness of chromosome duplication in haploid plants ranged from 32 to 64.5% and it was the highest for the treatment on the medium followed by cooling. Individual hybrids differed regarding their capability of regeneration and chromosome doubling, which were consistent only to a low or moderate extent. However, taken together, winter and spring hybrids did not differ significantly. Combined colchicine application resulted in a high yield of DH production, 82.6% for all triticale hybrids, and can provide a considerable number of fertile DH lines for triticale breeding programmes.     

Doubled haploid plants following colchicine treatment of microspore-derived embryos of oilseed rape (<Emphasis Type="Italic">Brassica napus L.</Emphasis>)

An efficient method for producing doubled haploid plants of oilseed rape (Brassica napus L.) was established using in vitro colchicine treatment of haploid embryos. Haploid embryos in the cotyledonary stage were treated with one of four colchicine concentrations (125, 250, 500 and 1,000 mg/L); for one of three treatment durations (12, 24 and 36 h) at one of the two temperatures (8 and 25°C) and were compared to control embryos (without colchicine treatment). The number of chromosomes, seed recovery, size and density of leaf stomata, and pollen grain size from regenerated plants were determined. No doubled haploid plants were regenerated from control embryos; however, the doubled haploid plants were regenerated from colchicine-treated embryos. A high doubling efficiency, 64.29 and 66.66% of regenerated plants, was obtained from 250 mg/L colchicine treatment for 24 h and 500 mg/L colchicine treatment for 36 h, respectively, at 8°C. Following 500 mg/L colchicine treatment for 36 h, a few plants regenerated (9 plants). At the higher colchicine concentration (1,000 mg/L), no plant regenerated. These results indicate that the colchicine treatment of embryos derived from microspores can induce efficient chromosome doubling for the production of doubled haploid lines of oilseed rape.     

Responses of alfalfa pollen and callus to filtrates from two isolates of Fusarium oxysporum

Summary For 25 Medicago sativa plants, measurements were made of in vitro pollen germination and growth and callus growth on mediums containing culture filtrate from two isolates of Fusarium oxysporum f. sp. medicaginis. In vivo resistance was determined by field inoculation with one isolate. There was no correlation between any in vitro measurement and in vivo resistance, and none of the in vitro measurements on control mediums were correlated. The only significant correlation for the same measurement between the two isolates was for pollen-tube length (r = 0.65). Percent of pollen germination was negatively correlated with callus growth for both isolates. Earlier work showed that callus growth in the presence of culture filtrate was linked to plant resistance, thus it appeared that percent pollen germination on culture filtrate had decreased for the more resistant plants. The haploid pollen may be used as a progeny test for identifying heterotic loci conferring resistance to Fusarium, but if the pollen of this plant species is used in direct selection by exposure to culture filtrate, the level of resistance to Fusarium may decrease.     

Production of normal,germinable and viable pollen from in vitro-cultured maize tassels

Summary Immature tassel meristems (1.0–1.5 cm long) of Zea mays L. inbred, Oh43, and single cross hybrid, Se60, cultured on a nutrient liquid medium underwent extensive development through to maturity and produced normal, mature, trinucleate pollen grains. The grains germinated on nutrient agar and on receptive silks and also produced viable kernels. No differences were observed between in vitro-produced pollen and in vivo pollen (pollen from greenhouse-grown plants) in characteristics such as pollen size, in vitro and in situ germination, and pollen tube growth in vitro. The kernels produced with in vitro pollen grew into mature plants (in vitro plants) which were similar to in vivo plants (plants produced with in vivo pollen), with no significant differences for all the morphological characteristics measured, and no phenotypic and cytological abnormalities. Gel electrophoresis of polypeptides revealed no major differences between in vitro and in vivo seedlings. This demonstration of fertilization and production of normal, uniform plants with pollen from cultured tassels has significant potential in basic and applied research studies.     

Effect of enhanced UV-B radiation on pollen quantity,quality, and seed yield in Brassica rapa (Brassicaceae)

We conducted three experiments to examine the influence of ultraviolet-B radiation (UV-B; 280–320 nm) exposure on reproduction in Brassica rapa (Brassicaceae). Plants were grown in a greenhouse under three biologically effective UV-B levels that simulated either an ambient stratospheric ozone level (control), 16% (“low enhanced”), or 32% (“high enhanced”) ozone depletion levels at Morgantown, WV, USA in mid-March. In the first experiment, we examined whether UV-B level during plant growth influenced in vivo pollen production and viability, and flower production. Pollen production and viability per flower were reduced by ≈50% under both enhanced UV-B levels relative to ambient controls. While plants under high-enhanced UV-B produced over 40% more flowers than plants under the two lower UV-B treatments, whole-plant production of viable pollen was reduced under high-enhanced UV-B to 17% of that of ambient controls. Whole-plant production of viable pollen was reduced under low-enhanced UV-B to 34% of ambient controls. In the second experiment, we collected pollen from plants under the three UV-B levels and examined whether source-plant UV-B exposure influenced in vitro pollen germination and viability. Pollen from plants under both enhanced-UV-B treatments had initially lower germination and viability than pollen from the ambient level. After in vitro exposure to the high-enhanced UV-B levels for 6 h, viability of the pollen from plants grown under ambient UV-B was reduced from 65 to 18%. In contrast, viability of the pollen from plants grown under both enhanced UV-B treatments was reduced to a much lesser extent: only from ≈43 to 22%. Thus, ambient source-plant pollen was more sensitive to enhanced UV-B exposure. In the third experiment, we used pollen collected from source plants under the three UV-B levels to fertilize plants growing under ambient-UV-B levels, and assessed subsequent seed production and germination. Seed abortion rates were higher in plants pollinated with pollen from the enhanced UV-B treatments, than from ambient UV-B. Despite this, seed yield (number and mass) per plant was similar, regardless of the UV-B exposure of their pollen source. Our findings demonstrate that enhanced UV-B levels associated with springtime ozone depletion events have the capacity to substantially reduce viable pollen production, and could ultimately reduce reproductive success of B. rapa.     

Colchicine-mediated chromosome doubling during anther culture of maize (Zea mays L.)

Efficient methods of chromosome doubling are critical for the production of microspore-derived, doubled-haploid (=DH) plants, especially if, as in maize anther culture, spontaneous chromosome doubling occurs infrequently. In the present study, colchicine (5–1000 mg/l) was added to the induction medium and maize anthers were incubated in the colchicine-containing medium for different durations (1–7 days). In order to improve overall anther culture response, the culture temperature was adjusted to 14°C during the first 7 days. Colchicine applied at low concentration, i.e. 5 mg/l (7 days), or for short duration, i.e. 1–3 days (250 mg/l), showed beneficial effects on the formation of embryolike structures (=ES) and thus led to increased plant production, but was comparatively ineffective regarding chromosome doubling. Optimal doubling effects were observed when anthers had been exposed to culture medium containing 250 and 1000 mg/l of colchicine (7 days); in these treatments the doubling index (=DI), defined as the quotient of the number of DH plants and the number of totally regenerated plants in a specific treatment, rose to 0.56 and 0.53, respectively, compared to 0.20 in the untreated control. However, colchicine administered at concentrations higher than 250 mg/l seemed to be detrimental to general plant production; thus, in spite of a high DI, the overall DH plant production was even lower than in the control treatment. Maximum DH plant production for three different genotypes was accomplished with culture medium containing 250 mg/l of colchicine (7 days). With the best-responding genotype (ETH-M 36) a DH plant production of 9.9 DH plants/100 anthers was accomplished, i.e. a 7-fold increase compared to the non-treated anthers. This is the first report on efficient chromosome doubling in anther culture by subjecting anthers to colchicinecontaining induction medium during a post-plating cold treatment. Chromosome doubling as described here becomes an integral part of the maize anther culture protocol and thus represents a rapid and economical way to produce DH plants.     

High frequency production of doubled haploid plants of Brassica napus cv. Topas derived from colchicine-induced microspore embryogenesis without heat shock

This report describes a very high genome doubling efficiency of Brassica napus cv. Topas plants, derived from microspores induced to undergo embryogenesis with a colchicine treatment, without the use of a heat treatment. The plants showed normal growth and development, and 90% were fertile. In contrast, only 6% of the plants derived from heat-induced embryos were fertile diploids. All cytological analysis of the progeny of fertile plants showed 2n=38 chromosomes. These results show that colchicine can simultaneously induce microspore embryogenesis and double the ploidy level to produce doubled haploid plants.     

Selection for tolerance to copper during pollen formation in Mimulus guttatus Fischer ex DC

In Mimulus guttatus, copper tolerance is determined largely by a single gene and is expressed in both the sporophyte and microgametophyte. This study explores the extent to which selection during pollen formation affects copper tolerance in the sporophytic generation. Two sets of plants heterozygous for copper tolerance, produced by reciprocal crosses between different copper-tolerant or sensitive families, and the plant on which the original observations were based, were cloned and grown in control or copper-supplemented solutions. Pollen viability and the number of tolerant progeny produced in backcrosses to sensitive plants were compared. In addition, the effect of copper treatment on pollen viability in vitro was compared for plants tolerant, sensitive and heterozygous for copper tolerance. The extent to which in vitro pollen viability decreased in response to copper treatment corresponded to the copper tolerance of the pollen source. When grown with added copper, four of the five plants showed significant reductions in pollen viability, ranging from 18% to 48% of control values. The reductions in pollen viability were correlated with an increase in tolerant progeny (r= 0.679, p=0.004). Increases in tolerant progeny could be large, ranging from 119% to 170% of that of controls, but were usually smaller than was predicted from the reductions in viable pollen. In addition, plants derived from reciprocal crosses differed significantly in the extent to which pollen viability was decreased and sporophytic tolerance increased. Thus, while selection during pollen formation could increase sporophytic tolerance, sporophytic factors, perhaps including cytoplasmic or epigenetic ones, moderated the effectiveness of pollen selection for copper tolerance.     

The auxins centrophenoxine and 2,4-D differ in their effects on non-directly induced chromosome doubling in anther culture of wheat (T. aestivum L.)

Doubled haploid technologies have become key tools for plant breeding. Using these techniques, the speed and efficiency of plant improvement processes can be significantly enhanced. Anther culture-based technologies have the potential to regenerate large numbers of doubled haploid plants without colchicine treatment. In an attempt to elucidate the influence of phytohormones on non-directly induced chromosome doubling, two synthetic auxins, 2,4-D and centrophenoxine, were tested in a wheat anther culture approach. Whereas the induction of androgenic embryo-like structures (ELSs) was efficient for both auxins, we observed a significantly higher frequency of chromosome doubling when using 2,4-D than when using centrophenoxine. When 2,4-D was added to the induction medium, a positive correlation between the size of ELSs and their ploidy level was detected by flow cytometry. The morphological selection of ELSs, a process that was included in routine operations of the method without significantly extending the input of time and effort, facilitates the production of fertile DH plants with a frequency of 60 %. Our findings may contribute to a more efficient production of doubled haploid wheat plants using a colchicine-free anther culture approach.     

Effects of colchicine on anther and microspore culture of bread wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis> L.)

The aim of this work was to study the effects of colchicine application on chromosome doubling and androgenic response in anther and microspore culture of different bread wheat genotypes. Colchicine was applied during a mannitol stress pretreatment or during the first 48 h of culture at concentrations of 0, 150 and 300 mg l⁻¹. When colchicine was applied during stress pretreatment, the percentage of doubling depended on genotype and concentration. A significant increase in doubling was observed with 300 mg l⁻¹ in the low androgenic responding cv. Caramba. Colchicine incorporation during the first hours of culture improved percentage of doubling in all genotypes, in both anther and microspore culture. Application of 300 mg l⁻¹ colchicine improved the percentage of doubling in the two low responding genotypes, to 118% of control in DH24033, and 75% in Caramba in microspore and anther culture, respectively. Concerning the androgenic response, the effect of colchicine on embryo formation and percentage of green plants depended on the genotype and on the culture method. In cv. Pavon, a 2- and a 3-fold increase in percentage of embryogenesis and green plants, respectively, were obtained with 300 mg l⁻¹ colchicine in microspore culture. However, no significant differences in these two variables were observed in anther culture. The number of green doubled haploid (DH) plants reflects the index of success of the procedure. Regardless of the culture method, when colchicine was incorporated during the first hours of culture, the number of green DH plants increased significantly in three of four genotypes. These results confirm the usefulness of colchicine application during the first hours of culture in wheat breeding programs.     

A group-1 grass pollen allergen influences the outcome of pollen competition in maize

Worldwide, 400 million people suffer from hay fever and seasonal asthma. The major causative agents of these allergies are pollen specific proteins called the group-1 grass pollen allergens. Although details of their antigenicity have been studied for 40 years with an eye towards immunotherapy, their function in the plant has drawn scant attention. Zea m 1 constitutes a class of abundant grass pollen allergens coded for by several genes that loosen the walls of grass cells, including the maize stigma and style. We have examined the impact of a transposon insertion into one of these genes (EXPB1, the most abundant isoform of Zea m 1) on the production of Zea m 1 protein, pollen viability, and pollen tube growth, both in vitro and in vivo. We also examined the effect of the insertional mutation on the competitive ability of the pollen by experimentally varying the sizes of the pollen load deposited onto stigmas using pollen from heterozygous plants and then screening the progeny for the presence of the transposon using PCR. We found that the insertional mutation reduced the levels of Zea m 1 in maize pollen, but had no effect on pollen viability, in vitro pollen tube growth or the proportion of progeny sired when small pollen loads are deposited onto stigmas. However, when large pollen loads are deposited onto the stigmas, the transposon mutation is vastly underrepresented in the progeny, indicating that this major pollen allergen has a large effect on pollen tube growth rates in vivo, and plays an important role in determining the outcome of the pollen-pollen competition for access to the ovules. We propose that the extraordinary abundance (4% of the extractable protein in maize pollen) of this major pollen allergen is the result of selection for a trait that functions primarily in providing differential access to ovules.     

Increased doubled haploid plant regeneration from rice (Oryza sativa L.) anthers cultured on colchicine-supplemented media

Plating rice anthers on a semisolid induction medium containing 250 or 500 mg/l colchicine for 24 or 48 h-incubations followed by transfer to colchicine-free medium and standard anther culture procedures resulted in overall 1.5- to 2.5- fold increases in doubled haploid green plant productions compared to control anther cultures. The addition of colchicine had no detrimental effects on the different anther culture efficiency parameters, but in some treatments led to significant enhancement of anther callusing frequency or callus green plant regenerating ability. The most efficient treatment raised doubled haploid plant recovery from 31% to 65.5%. These results suggest that post-plating colchicine treatment of anthers, since it was found to improve both anther culture efficiency and doubled haploid plant recovery frequency, could be integrated into rice doubled haploid plant production programmes.Abbreviations DH doubled haploid - NAA naphthalenacetic acid - PAS periodic acid Schiff     

The relationship between in vitro performance of haploid embryos and the agronomic performance of the derived doubled haploid lines in barley

Summary The relationship between in vitro performance of haploid embryos and the agronomic performance of the derived doubled haploid (DH) lines during the stages of field evaluation was investigated. The results showed a positive correlation between coleoptile height of haploid plantlets in culture and final plant height of their DH progeny lines in the field. These results illustrate that in vitro selection for plant height and other linked quantitative or pleiotropic characters can be carried out at the initial stages of a DH breeding programme.     

l-Ascorbic acid sodium salt promotes microspore embryogenesis and chromosome doubling by colchicine in ornamental kale (Brassica oleracea var. acephala)

Isolated microspore culture (IMC) represents a potential alternative technique in the plant breeding process, as it allows the effective production of doubled haploid (DH) homozygous lines. However, the implementation of this technique is limited by a low rate of embryogenesis, high level of embryo death, and low frequency of chromosome doubling. Thus, we investigated the effects of using different concentrations of L-ascorbic acid sodium salt (VcNa), which has never been applied for kale, to enhance the embryogenesis and regeneration by IMC. Specifically, 1 to 5 μM VcNa was added to the NLN-13 medium of four kale genotypes, while control was grown on VcNa-free medium. Overall, 1–4 μM VcNa at pH 5.84 increased embryogenesis, with 4 μM VcNa being the optimum concentration (12.92-fold increase). The proportion of embryo deaths declined when using appropriate VcNa concentrations. To increase the frequency of chromosome doubling, an artificial chromosome doubling protocol was developed for kale microspore-derived haploids. This protocol involved dipping roots of haploid plantlets in colchicine solution and adding colchicine treatment to solid Murashige and Skoog (MS) medium. Optimum chromosome doubling of haploids was achieved by dipping their roots in 750 mg/L colchicine solution for 4–6 h and 1000 mg/L colchicine solution for 2 h (doubling for nearly 50% of haploids). In conclusion, this study delineated an effective tissue culture process in promoting chromosomal ploidy of microspore-derived regenerated plants, allowing more microspores to be maintained that have excellent ornamental characteristics through crossbreeding.

     

Application of trifluralin to embryogenic microspore cultures to generate doubled haploid plants in Brassica napus

Microspore or anther culture has been used to produce desirable meiotic recombinants in numerous species. However, the utilization of these recombinants relies on inefficient genome doubling procedures to obtain fertile doubled haploid plants. This study presents a simple and rapid procedure to generate fertile doubled haploids in Brassica napus cv. Topas using trifluralin (α,α,α-trifluoro-2,6-dinitro-N,N-dipropyl- p -toluidine), a plant specific microtubule inhibitor. The effects of trifluralin on microtubule depolymerization and chromosome doubling in embryogenic microspore cultures of B. napus were examined and compared with those of colchicine. Indirect immunofluorescence labeling of isolated microspores indicated that microtubules were depolymerized within 30 min of trifluralin treatment and after 3–8 h of colchicine treatment. The direct application of these microtubule inhibitors to microspore cultures resulted in the recovery of fertile doubled haploid plants. Continuous culture in the presence of colchicine, was more effective than 18-h treatments for fertile plant production but resulted in abnormal embryo formation and recalcitrant plant regeneration. The application of 1 or 10 μ M trifluralin during the first 18 h of microspore culture was found to be the superior method for doubled haploid production. The embryos generated after trifluralin treatment developed normally, germinated readily and of the plants produced, close to 60% were fertile. The use of trifluralin to double chromosomes very early in microspore cultures is a simple process requiring minimal manipulation and should be very useful for genetic studies and breeding programs of B. napus and possibly other species.     

Plant transformation by particle bombardment of embryogenic pollen

Summary Direct delivery of DNA into embryogenic pollen was used to produce transgenic plants in tobacco. A plasmid bearing the ß-glucuronidase (GUS) marker gene in fusion with the 35S-promoter was introduced by microprojectile bombardment into mid-binucleate pollen of Nicotiana tabacum that had been induced to form embryos by a starvation treatment. In cytochemical expression assays, 5 out of 10⁴ pollen grains were GUS⁺. Visual selection by staining with a non-lethal substrate for GUS was used to manually isolate transformed embryos. From the initial population of embryogenic GUS⁺ pollen, 1–5% developed into multicellular structures and 0.02% formed regenerable embryos. Two haploid transformants were regenerated. GUS expression was detected in different parts of the plants, and Southern analysis confirmed stable integration of the foreign DNA. Diploidisation was induced by injection of colchicine into the stem near adventitious buds. Offspring from selfings and backcrosses of one transformant were tested for GUS expression and by Southern blots. All F1-plants were transgenic, in accordance with Mendelian inheritance.Abbreviations GUS ß-glucuronidase - CaMV Cauliflower Mosaic Virus - MCS multicellular structure - NPTII neomycin phosphotransferase - PEG polyethylene glycol - X-gluc 5-bromo-4-chloro-3-indolyl glucuronide - DAPI 4,6-diamidino-2-phenylindole - Tris Tris(hydroxymethyl)aminomethane hydrochloride - EDTA ethylenedinitrilo tetraacetic acid, disodium salt dihydrate