Activated charcoal induced high frequency microspore embryogenesis and efficient doubled haploid production in Brassica juncea

Three Indian Brassica juncea cultivars were studied for embryogenic response of microspores, microspore embryo regeneration, ploidy assessment of microspore-derived plants and their diploidization. Genotype dependence for microspore totipotency was observed and a significant effect of genotype by bud size selection was established. The addition of activated charcoal in NLN medium containing 13% (w/v) sucrose and 10 μM silver nitrate resulted in a fourfold increase in microspore embryogenesis, ranging from 100 to 405 embryos per Petri dish corresponding to 2,700–10,935 embryos per 100 buds. Conversion/germination of embryos produced in presence or absence of activated charcoal was similar but air-drying of microspore embryos was essential. Incubation of microspore embryos at 4 ± 1°C for 10 days in dark resulted in 82.3% conversion. The majority of plants produced from these embryos was haploid. Treating microspore-derived plants at the 3–4 leaf growth stage with 0.34% colchicine for 2–3 h resulted in greatest survival (70%) and chromosome doubling (75%) frequencies. Doubled haploid plants were self-pollinated and grown to maturity under field conditions.     

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.     

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.     

A simple wheat haploid and doubled haploid production system using anther culture

Summary Wheat (Triticum aestivum L.) haploids and doubled haploids have been used in breeding programs and genetic studies. Wheat haploids and doubled haploids via anther culture are usually produced by a multiple step culture procedure. We improved a wheat haploid and doubled haploid production system via anther culture in which plants are produced from microspore-derived embryos using one medium and one culture environment. In the improved protocol, tillers of donor plants were pretreated at 4°C for 1–2 wk before anthers were plated on a modified 85D12 basal medium with phenylacetic acid (PAA) and zeatin and cultured at 30°C with a 12-h daylength (43 μEs⁻¹m⁻²) in an incubator. Microspore-derived embryos developed in 2–3 wk and the plants were produced 3–4 wk after anther plating. In the improved system, as much as 53% of the anthers of Pavon 76 were responsive with multiple embryos. For plant regeneration, as many as 22 green and 25 albino plants were produced from 100 anthers. Sixty-five green plants were grown to maturity and 32 (49%) plants were fertile and produced seeds (indicating spontaneous chromosome doubling) while 33 plants did not produce seed. Of five Nebraska breeding lines tested using the protocol, NE96675 was very responsive and the other lines less so, indicating that the protocol is genotype-dependent.     

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.     

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.     

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.     

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.     

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.     

The characterization of herbicide tolerant plants in Brassica napus L. after in vitro selection of microspores and protoplasts

Brassica napus L.(cv Topas) plants tolerant to chlorsulfuron (CS) were isolated after selection experiments utilizing microspores and haploid protoplasts. The first microspore-derived plant (M-37,) was CS tolerant, haploid and sterile. Normal plant morphology and fertility was restored after colchicine doubling. A CS tolerant plant was also selected from protoplasts (P-26) isolated from microspore-derived embryo tissue and grown on medium containing CS. P-26 was aneuploid, CS tolerant and had very low fertility. The two selected lines produced selfed progeny which were tolerant to from 10–100 times the CS levels of the corresponding Topas plants. Microspores and protoplasts derived from the selfed plants were also CS tolerant. The segregation pattern for CS tolerance from reciprocally crossed progeny of M-37 and Topas was consistent with a semi-dominant nuclear mode of inheritance. Biochemical analysis of the two mutants indicated that the microspore-derived mutant and F1 crosses contained an altered acetohydroxyacid synthase (AHAS) enzyme, while the AHAS activity of the protoplast mutant was similar to Topas. Selfed seed from the M-37 plants have provided tolerance to CS in both greenhouse and field tests. S1 plants from a second microspore selected mutant (M-42) have tolerated 30 g/ha of CS in greenhouse tests. The two single-celled selection systems are discussed and the microspore selection system highlighted as a new method for in vitro selection.     

Microspore embryogenesis in anther cultures of two Indian cultivars of Brassica juncea (L.) Czern.

Direct microspore-derived embryo formation in anther cultures of two cultivars of Brassica juncea was obtained. Preliminary culture of anthers at 35°C for 1–5 days prior to maintenance at 25°C stimulated embryogenesis. Embryogenesis was also stimulated by an initial culture at 5°C for 3 days. Analysis of squashed anthers revealed that approximately 10% of the microspores began dividing, but less than 1% developed into macroscopic embryos. All embryos transferred to embryo culture medium survived, but only 30% of these developed directly into normal plantlets. The androgenic plants were haploid (2n=18).     

Karyotype,genome size,and in vitro chromosome doubling of Pfaffia glomerata (Spreng.) Pedersen

Pfaffia glomerata (Spreng.) Pedersen, known worldwide as Brazilian ginseng, has an important commercial value due to its pharmaceutical properties. In addition to the newly described karyological traits and the first estimation of DNA content, this study reports a protocol for the successful induction of tetraploidy. Natural diploid individuals (2n = 34) showed a symmetric karyotype, centromeric DAPI⁺ bands, one chromosome pair with a CMA⁺ band and 45S rDNA site and another with one 5S rDNA site. To induce chromosome duplication, small nodal buds were cultured in semi-solid MS-based medium with 2.22 μM BA, 2.69 μM NAA, and colchicine or oryzalin at 10, 15, 20, 25, and 30 μM for 1 or 2 weeks before being transferred to MS basal medium. The results showed that colchicine induced tetraploid plants, mainly after 1 week of exposure, whereas oryzalin treatment induced only mixoploid plants. The tetraploid plants exhibited twice the chromosome number and DNA content and twice the number of chromosome markers observed for the diploids. Chromosome duplication reduced the dry mass of the stems and roots of the polyploid plants compared to the diploids, and the stomatal density was also reduced on the abaxial and adaxial leaf surfaces of the polyploids. Additionally, the production of β-ecdysone was 50 % higher in the tetraploids than in the diploids. Thus, chromosome doubling showed that is possible to increase the content of β-ecdysone, highlighting the considerable potential of this technique to produce new cultivars with high commercial value.     

Heterologous production of recombinant anti-HIV microbicide griffithsin in transgenic lettuce and tobacco lines

The present paper describes a detailed study of a highly efficient protocol to multiply the number of haploids in sugar beet production and subsequent chromosome doubling. The protocol involves an experiment investigating factorial interactions between cold pretreatment, seven genotypes of sugar beet, and kinetin to improve haploid embryo induction. In addition, the effects of color of ovules and flower bud position on haploid embryo induction were investigated. After subjecting the data to analysis of variance or Student’s t test (P?<?.05), the effect sizes of the independent variables were also estimated. Cold pretreatment was effective in stimulating the ovules. The haploid embryo induction rate for 1-week cold pretreated ovules (9.01%) was higher than that of freshly cultured ones (6.15%). In comparison with hormone-free medium (5.16%), the gynogenesis rate for the media supplemented with 0.05 or 0.5 mg L^?l kinetin increased to 7.58 and 10.05%, respectively. The genotype responses were significantly different. Interactions of kinetin?×?cold pretreatment, genotype?×?hormonal treatment, genotype?×?cold pretreatment, and the three-way interaction were statistically significant. Moreover, the main effects of flower bud position, ovule color, and comma-form ovule on gynogenic response were significant. After investigating the effect of 5 g L^?l colchicine for 3, 5, or 7 min on one genotype’s (SG2) specimens, all the haploid plantlets from the other genotypes were treated for 5 min as the best treatment. The paper discusses interactions of the factors, which may be interesting for others aiming to breed doubled haploid sugar beet or possibly other related plant species.     

Regeneration of fertile green plants from oat isolated microspore culture

Regeneration of fertile green plants from isolated oat microspores is reported for the first time. Factors critical for microspore growth and regeneration include cold pre-treatment, pH of culture medium and the use of conditioned culture medium. It was found that cold pre-treatment at 4°C in the dark for a minimum of 6 weeks was necessary to consistently achieve microspore growth into multicellular structures (MCS). Longer pre-treatments of up to 9 weeks were tested and found to be positively correlated with the number of MCS produced. Microspore culture medium with pH 8.0 produced significantly more MCS larger than eight cells in size than media with pH 5.8. The use of medium conditioned by actively growing barley microspores significantly increased the numbers of MCS larger than eight cells in size compared to non-conditioned media. Plants were regenerated only from cultures using conditioned medium. A total of 2 green plants and 15 albinos were regenerated. Of the green plants, one had the haploid chromosome complement (n = 3x = 21) and the other had the parental hexaploid chromosome complement (2n = 6x = 42) which may be due to spontaneous chromosome doubling. The hexaploid plant set seed naturally and the haploid plant set seed after its chromosome complement was doubled with colchicine.     

Blockage of mitosis in maize root tips using colchicine-alternatives

Mitosis in plants can be blocked by colchicine which has the capacity to bind microtubule subunits. In maize (Zea mays L.) breeding, it is frequently being used for doubling chromosome numbers of haploids for producing homozygous doubled haploids. However, colchicine is highly toxic for mammals and impacts negatively on the environment. Therefore, it was interesting to find substitutes like chemical compounds and/or physical methods which would be capable of doubling chromosome numbers in maize. For this purpose, a screening system was set up using root tips of maize. Herbicides like amiprophos methyl, oryzalin, and pronamide were identified to be effective in doubling chromosome sets of maize. Additionally, the toxicity of these compounds was lower than that of colchicine and treated seedlings recovered and grew. Therefore, they could be applied in reduced concentrations showing results comparable to colchicine.     

被子植物未受精胚珠与子房离体培养的研究进展

介绍被子植物未受精胚珠与子房离体培养诱导单倍体植株的研究进展。迄今已有9个科21种植物用这一方法诱导出单倍体植株,植物的基因型、外植体的发育程度、接种前的预处理、培养基和培养条件等均能影响诱导率的高低。胚胎学观察揭示大孢子与胚囊内的卵细胞、助细胞和反足细胞均有可能在培养中启动分裂,通过胚状体或愈伤组织形成单倍体植株。本项技术在植物单倍体育种中可发挥重要作用。     

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.     

In vitro induction of polyploidy in yacon (<Emphasis Type="Italic">Smallanthus sonchifolius</Emphasis>)

In vitro chromosome doubling was induced in octoploid (2n = 58) yacon using oryzalin and colchicine as mitotic spindle inhibitors. Nodal segments of in vitro cultured plants, 5–15 mm long, were exposed to 20, 25, or 30 μM oryzalin and 1, 3, or 5 mM colchicine for 24 or 48 h. The resulting ploidy level was determined by chromosome counting and flow cytometry. Out of 240 nodal segments, 3.33% hexadecaploid (2n = 116) plants were regenerated after the application of oryzalin. The greatest proportions of hexadecaploid plants (1.6%) were obtained after 48 h of 25 μM oryzalin treatment. With the colchicine treatment, only 0.42% hexadecaploid plants were detected and their survival rate was significantly lower in comparison with the oryzalin treatment. In hexadecaploid yacon, significantly higher levels of saccharides were detected (FOS 13.9 g/100 g FM, fructose 4.6 g/100 g FM and glucose 2.1 g/100 g FM) compared to the octoploid control (FOS 5.3 g/100 g FM, fructose 2.9 g/100 g FM and glucose 1.0 g/100 g FM). These results indicate that in vitro treatment of nodal segments with oryzalin solution could be an effective procedure for chromosome doubling and the polyploidy breeding can help to increase the FOS content in the tuberous roots.     

Isolated microspore culture and plant regeneration in rye (Secale cereale L.)

 An isolated microspore culture and green plant regeneration method for rye (Secale cereale L.) was established. Rye isolated microspore androgenesis was genotype-dependent. PG-96M medium supplemented with 6% maltose gave the highest microspore survival rate after 48 h of culture and the highest embryo/callus yield (930 embryos/calli per 100 anthers from cv. Florida 401). Osmotic pressure in the induction medium played an important role. Pretreatment of the anthers with mannitol was beneficial for the microspore culture. Embryos/calli of a relatively younger age and smaller size had a higher regeneration ability, with the best green plant regeneration rate being 6%. Over 150 microspore-derived green plants have been obtained so far. About 90% of the regenerated plants were spontaneous doubled haploids. This is the first report of isolated microspore culture in true rye resulting in androgenic embryogenesis and plant regeneration. Received: 26 April 1999 / Accepted: 23 November 1999     

Regeneration of soybean (<Emphasis Type="Italic">Glycine max</Emphasis> L. Merrill) through direct somatic embryogenesis from the immature embryonic shoot tip

We describe here a simple and efficient system of soybean (Glycine max L. Merrill) regeneration through direct somatic embryogenesis by using immature embryonic shoot tips (IEST) as explants. The cultivar Kaohsiung 10 (cv. K10) used in this study did not show embryogenic response either from mature seed-derived explants (cotyledon, embryonic tip, leaf, shoot and root) or immature cotyledons. However, it showed a high percentage (55.8%) of somatic embryo (SEm) formation from the IEST excised 2–3 wk after flowering, thus indicating the crucial roles of type and age of explants. The IEST put forth primary SEm after 2 mo of culturing on Murashige and Skoog (MS) medium supplemented with 6% sucrose, 164.8 μM 2,4-dichlorophenoxyacetic acid (2,4-D), 5 mM asparagine and 684 μM glutamine. Subsequently, secondary SEm were developed 1 mo after culturing on MS medium containing 123.6 μM 2,4-D and 3% sucrose. Cotyledonary embryos were induced on MS medium supplemented with 0.5% activated charcoal after 1 mo. The embryos were desiccated for 72–96 h on sterile Petri dishes and regenerated on hormone-free MS medium. Plantlets with well-developed shoots and roots were obtained within 5–6 mo of culturing of IEST. The SEm-derived plants were morphologically normal and fertile. Various parameters thought to be responsible for efficient regeneration of soybean through somatic embryogenesis are discussed. To our knowledge, this is the first report to employ IEST as explants for successful direct somatic embryogenesis in soybean.