Polyethylene glycol and maltose enhance somatic embryo maturation in loblolly pine (Pinus taeda L.)

Summary A culture medium that can efficiently produce mature somatic embryos was developed for loblolly pine (Pinus taeda L.). The medium contained maltose as a carbohydrate source and polyethylene glycol as an osmoticum. This medium formulation significantly enhanced embryo maturation efficiency compared to a medium with only maltose, or with sucrose combined with polyethylene glycol. Maltose at 4% and polyethylene glycol at 6% resulted in the highest embryo maturation efficiency; an average of around 100 cotyledonary embryos were produced from 1 g of embryogenic tissue. These results suggested that previous ineffective embryo maturation in loblolly pine may be due to the lack of the proper combination of osmoticum and carbohydrate source. This embryo maturation method also improved morphology of cotyledonary embryos of loblolly pine.     

Patterns of storage protein and triacylglycerol accumulation during loblolly pine somatic embryo maturation

Conifer somatic embryo germination and early seedling growth are fundamentally different than in their zygotic counterparts in that the living maternal megagametophyte tissue surrounding the embryo is absent. The megagametophyte contains the majority of the seed storage reserves in loblolly pine and the lack of the megagametophyte tissue poses a significant challenge to somatic embryo germination and growth. We investigated the differences in seed storage reserves between loblolly pine mature zygotic embryos and somatic embryos that were capable of germination and early seedling growth. Somatic embryos utilized in this study contained significantly lower levels of triacylglycerol and higher levels of storage proteins relative to zygotic embryos. A shift in the ratio of soluble to insoluble protein present was also observed. Mature zygotic embryos had roughly a 3:2 ratio of soluble to insoluble protein whereas the somatic embryos contained over 5-fold more soluble protein compared to insoluble protein. This indicates that the somatic embryos are not only producing more protein overall, but that this protein is biased more heavily towards soluble protein, indicating possible differences in metabolic activity at the time of desiccation.     

Improved somatic embryo maturation in loblolly pine by monitoring ABA-responsive gene expression

During loblolly pine zygotic embryo development, increases in mRNAs for three ABA-responsive LEA-like genes coincided with the two developmental stage-specific peaks of endogenous ABA accumulation (Kapik et al. 1995). These ABA concentration profiles from zygotic embryo development were used to develop several tissue culture approaches that altered the exposure of somatic embryos to exogenous ABA. Elevating exogenous ABA at a time corresponding to mid-maturation improved the germination and resulted in more zygotic-like expression of selected genes in somatic embryos. Extending the time on maturation medium for a fourth month increased embryo yield, dry weight, and germination in high-and low-yield genotypes. Optimizing the amounts of embryogenic suspension, plated and exogenous ABA concentration increased from 22 to 66% in the early-stage bipolar embryos that developed to the cotyledonary stage.     

Improved somatic embryo production from embryogenic tissue of Pinus patula

Summary Embryogenic tissue from six genotypes of Pinus patula (Schiede et Deppe) was subjected to a number of treatments to improve both somatic embryo maturation and germination protocols. The use of a slightly modified 240 medium supplemented with polyethylene glycol (PEC) significantly improved both the number and quality of embryos produced, especially at the 7.5 and 10% level. Various pre-germination treatments were tested to enhance embryo germination. A partial drying treatment (PDT) at high relative humidity, lasting approximately 4 wk, gave the best germination results. Despite the beneficial effects of the PDT, embryos that had been harvested from the 240 maturation treatment containing no PEG gave the best germination responses when compared to the PEG-treated cultures. Plantlets were acclimatized ex vitrum, but success rates were low. Latent PEG effects were observed in acclimatized somatic seedlings.     

In vitro propagation of loblolly pine via direct somatic organogenesis from mature cotyledons and hypocotyls

A high-efficiency two-step culture procedure for direct somaticorganogenesis in loblolly pine (Pinus taeda L.) resulting inthe formation of multiple shoot structures induced on cotyledons andhypocotyls of mature zygotic embryos is described. Mature zygoticembryos of eight genotypes of loblolly pine were used as explants toinduce direct somatic organogenesis with this two-step culture method,involving the induction and the differentiation of direct adventitiousshoots. After mature zygotic embryos of eight genotypes of loblolly pinewere cultured on induction medium containing 2,4-dichlorophenoxyaceticacid (2,4-D) or -naphthaleneacetic acid (NAA), 6-benzyladenine(BA), and kinetin for 2–3 weeks, embryos were transferred todifferentiation medium. Adventitious shoot regeneration via directsomatic organogenesis with the frequency of 8.7–27.8% wasobtained from mature zygotic embryo cultures of the genotypes tested.The highest mean number of 32.6 adventitious shoots per mature zygoticembryo was produced from genotype La. The tissue culture protocol of invitro shoot regeneration via direct somatic embryogenesis was optimizedafter examining the periods of the induction culture, chillingtreatment, glutamine concentration, and basic medium levels. Rooting wasachieved on TE medium supplemented with 0.5 mg/l indole-3-butyric acid(IBA), 0.5 mg/l gibberellic acid (GA₃), and 1 mg/l6-benzyladenine (BA), and regenerated plantlets were established insoil. These results suggested that adventitious shoot regeneration viadirect somatic organogenesis could be useful for clonal micropropagationof some genotypes of loblolly pine and for establishing a transformationsystem of this coniferous species.     

Water relations parameters and tissue development in somatic and zygotic embryos of three pinaceous conifers

There is increasing interest in using somatic embryogenesis to meet the demand for high quality seedlings. However, in vitro production of propagules on a large scale depends on the optimization of the maturation and germination steps promoted by desiccation and subsequent imbibition of the embryo, respectively. It is therefore important to characterize zygotic and somatic embryos in terms of their water relations. Bound water, elastic modulus, osmotic potential at full turgor, and relative water content at turgor loss point were determined for somatic and zygotic embryos of western larch and loblolly pine and somatic embryos of white spruce at two developmental stages. These water relations parameters were derived from water-release curves obtained by suspending tissue samples in sealed vials over unsaturated NaCl solutions of known water potential. There was little difference in water relations parameters among species but marked stage dependency for bound water and elastic modulus. The amount of bound water was lowest in western larch somatic embryos (0.02-0.07) and highest in zygotic loblolly pine embryos (0.10-0.18). Elastic modulus ranged from 2.5 to 6.2 MPa in somatic embryos but varied between 1.4 and 1.8 MPa in zygotic embryos. The osmotic potential was lower in somatic embryos than in their zygotic counterparts. Our results show that water relations parameters are remarkably conservative across species but that, within a given species, these parameters are stage specific. It would seem, therefore, that desiccation protocols might be developed for a given developmental stage and applied across a range of species without the confounding effects of differences in water relations parameters.     

Factors influencing somatic embryo maturation, high frequency germination and plantlet formation in Terminalia chebula Retz.

The factors influencing somatic embryo maturation, high frequency somatic embryo germination, and plantlet formation were studied in Terminalia chebula Retz. Maturation of somatic embryo were influenced by a number of factors such as in vitro culture passage, concentrations of sucrose, levels of abscisic acid (ABA), basal media and media additive combinations. Maximum frequency of somatic embryo maturation (57.22 ± 2.02), was obtained on MS medium supplemented with 50 g/l sucrose. Different factors such as strengths of MS nutrients, plant growth regulators, media additives and their combinations controlling somatic embryo germination and plantlet formation were studied. High frequency of germination and plantlet formation (58.80 ± 1.47) were achieved by subsequent subculture of mature somatic embryos on MS medium containing 30 g/l sucrose and 0.5 mg/l benzyladenine (BA). However, although duration of in vitro passage of the callus tissue was critical, contribution of the combinations of plant growth regulators and media additives showed nugatory effect on somatic embryo maturation and germination as evident from variable responses.     

High-frequency somatic embryo production and maturation into normal plants in cotton (<Emphasis Type="Italic">Gossypium hirsutum</Emphasis>) through metabolic stress

A highly efficient somatic embryo production and maturation procedure has been developed to regenerate plantlets from cotton ( Gossypium hirsutum). This procedure involves the acceleration of differentiation through manipulations of nutrient and microenvironment conditions. Embryogenic calli, initiated from hypocotyls or cotyledonary leaf sections on MS medium containing 0.1 mg/l 2,4 dichlorophenoxyacetic acid, 0.5 mg/l kinetin, and 3% maltose produced globular-stage somatic embryos when transferred to hormone-free MS medium supplemented with high concentrations of nitrate. Subculture of globular embryos on hormone-free MS medium led to the development of torpedo- and cotyledonary-stage at a low frequency (two to four per plate) with the majority of embryos lacking further growth or entering into the dedifferentiation stage. Significant improvement in embryogenesis (two- to threefold) was achieved when calli were cultured on 1/5-strength MS medium irrespective of stress treatment. However, the frequency of globular embryos developing into normal plantlets improved considerably (20-24 per plate) when cultured on filter paper placed on MS medium. In this procedure, about 33% of globular embryos not only developed into the cotyledonary stage but rooted simultaneously, eliminating a separate rooting step. More than 70% of cotyledonary embryos developed into normal plantlets when cultured on full- strength MS medium containing 0.05 mg/l gibberellic acid.     

Regeneration of Acacia mangium through somatic embryogenesis

 Somatic embryogenesis and whole plant regeneration were achieved in callus cultures derived from immature zygotic embryos of Acacia mangium. Embryogenic callus was induced on MS medium containing combinations of TDZ (1–2 mg/l), IAA (0.25–2 mg/l) and a mixture of amino acids. Globular embryos developed on embryogenic callus cultured on the induction medium. Nearly 42% of embryogenic cultures with globular embryos produced torpedo- and cotyledonary-stage embryos by a two-step maturation phase. The first stage occurred on 1/2-strength MS basal medium containing 30 g/l sucrose and 5 mg/l GA₃ followed by the second stage on 1/2-strength MS basal medium containing 50 g/l sucrose. Of the cotyledonary-stage somatic embryos, 11% germinated into seedlings that could be successfully transferred to pots. Light- and scanning electron microscopy showed that the somatic embryos originated from single cells of the embryogenic callus. Further, a single cell layer could be detected beneath the developing somatic embryos that appeared to be a demarcation layer isolating the somatic proembryonic structure from the rest of the maternal callus. A suspensor-like structure connected the globular embryos to the demarcation layer. This is the first successful report of plant regeneration through somatic embryogenesis for this economically important tropical forest species. Received: 20 January 2000 / Revision received: 28 September 2000 / Accepted: 29 September     

Regulation of starch and protein accumulation in alfalfa (Medicago sativa L.) somatic embryos

Compared to seeds, somatic embryos accumulated relatively low levels and different types of storage carbohydrates. The regulation of starch accumulation was studied to determine its effects on desiccation tolerance and vigor of dry somatic embryos. Somatic embryos of Medicago sativa are routinely matured through three phases: 7 days of development; 10 days of phase I maturation, a rapid growth phase; and 10 days of phase II maturation, a phase leading to the acquisition of desiccation tolerance. The control of starch deposition was investigated in alfalfa somatic embryos by manipulating the composition of the phase I maturation medium with different levels of sucrose, abscisic acid, glutamine and different types of carbohydrates and amino acids. After phase II maturation, mature somatic embryos were collected for desiccation and subsequent conversion, or for biochemical analyses. Starch deposition occurred primarily during phase I maturation, and variations in the composition of this medium influenced embryo quality, storage protein and starch accumulation. A factorial experiment with two levels of glutamine × three levels of sucrose showed that increasing the sucrose concentration from 30 to 80 g/l increased embryo size and starch content, but had minimal effect on accumulation of storage proteins; glutamine also increased embryo size, but decreased starch content and increased accumulation of the high salt soluble S-2 (medicagin) storage proteins. ABA did not influence any of the parameters tested when included in phase I maturation at concentration up to 10 μM. Replicating sucrose with maltose, glucose, or glucose and fructose did not alter embryo size or starch accumulation (mg/g fresh weight), but replacement with fructose alone reduced embryo size, and replacement with glucose alone reduced germination. Suplementation with the amino acids, asparagine, aspartic acid and glutamine increased seedling vigor, but decreased the starch content of embryos. The data indicate that starch accumulation in somatic embryos is regulated by the relative availability of carbon versus nitrogen nutrients in the maturation medium. The quality of mature somatic embryos, determined by the rate of seedling development (conversion and vigor), correlated with embryo size, storage protein and free amino acid but not with starch. Therefore, further improvements in the quality of somatic embryo may be achieved through manipulation of the maturation medium in order to increase storage protein, but not starch deposition.     

Analysis of the effects of maturation treatments on the probabilities of somatic embryo germination and plantlet regeneration in pistachio using a linear logistic method

Embryogenic masses (EMSes) of pistachio (Pistacia vera L.) were proliferated in liquid Murashige and Skoog (MS) medium without growth regulators. To determine the effects of benzylaminopurine (BAP), racemic (±) abscisic acid (ABA) and sucrose treatments during maturation on the subsequent germination and plantlet regeneration, clusters of mature somatic embryos were transferred from maturation medium onto the surface of 0.7% agar-solidified Murashige and Skoog medium. Neither germination nor plantlet development medium contained BAP or ABA. Germination studies were carried out using 80 somatic embryos at every combination of four sucrose concentrations, three maturation periods and either five concentrations of BAP or four of ABA, and the numbers germinating were recorded after four durations of culture. A similar experimental plan was used to study plantlet regeneration. The number of germinated somatic embryos increased markedly with duration of the culture on germination medium, and was influenced by the concentrations of BAP or ABA in the maturation medium; the concentration of sucrose in this medium had little influence. Plantlet regeneration also increased with culture duration and was reduced at the highest levels of BAP or ABA; with ABA, the probability of plantlet regeneration was lower for longer maturation periods. ABA and BAP have similar effects on somatic embryo germination (except at the highest levels used), but BAP is superior to ABA for promoting subsequent plantlet regeneration. Linear logistic models were used to investigate the significance of the treatments, and to estimate the optimum conditions for germination and plantlet regeneration. This revised version was published online in June 2006 with corrections to the Cover Date.     

Recent advances in conifer somatic embryogenesis: improving somatic embryo quality

Somatic embryogenesis of coniferous species was first reported more than 20 years ago. Since then, there has been an explosion of research aimed at developing and optimizing protocols for efficient regeneration of plantlets. Although routinely used both as a means of propagation, as well as a valuable model system for investigating the structural, physiological, and molecular events occurring during embryo development, in vitro embryogenesis is still problematic for some coniferous species. Major problems include: low number of embryos generated; and low frequency of mature embryos able to convert into viable plantlets. Until recent years, despite the fact that embryogenesis is comprised of a sequence of defined steps which include proliferation of embryogenic tissue, embryo maturation, and germination, attempts at improving the whole procedure have been made almost exclusively during the maturation stage. This strategy was based on the assumption that successful regeneration is related to treatments provided during the development of the embryos. Major optimizations of the maturation medium have involved judicious selections of type and concentration of growth regulators, namely abscisic acid, and adjustments of the osmoticum of the culture medium. Extensive work has been conducted in defining the effects of plasmolysing and non-plasmolysing osmoticum agents during maturation, as well as in improving desiccation techniques required for the completion of the maturation program. In the last 2 years, however, work on spruce has clearly demonstrated that the early events in embryogenesis are crucial for the successful completion of the overall embryogenic program. The use of cell tracking techniques, implemented by physiological and molecular studies, has revealed that manipulations of the culture conditions early in the process can increase both number and quality of embryos produced in culture. Additional manipulations of the germination medium can also enhance germination and conversion frequency of somatic embryos matured in a sub-optimal environment. These new findings, together with the unraveling of molecular mechanisms involved in the control/regulation of embryo development hold considerable promise for clonal propagation in conifers.     

High-frequency plant regeneration through cyclic secondary somatic embryogenesis in black pepper (Piper nigrum L.)

A high-frequency plantlet regeneration protocol was developed for black pepper (Piper nigrum L.) through cyclic secondary somatic embryogenesis. Secondary embryos formed from the radicular end of the primary somatic embryos which were originally derived from micropylar tissues of germinating seeds on growth regulator-free SH medium in the absence of light. The process of secondary embryogenesis continued in a cyclic manner from the root pole of newly formed embryos resulting in clumps of somatic embryos. Strength of the medium and sucrose concentration influenced the process of secondary embryogenesis and fresh weight of somatic embryo clumps. Full-strength SH medium supplemented with 1.5% sucrose produced significantly higher fresh weight and numbers of secondary somatic embryos while 3.0 and 4.5% sucrose in the medium favored further development of proliferated embryos into plantlets. Ontogeny of secondary embryos was established by histological analysis. Secondary embryogenic potential was influenced by the developmental stage of the explanted somatic embryo and stages up to “torpedo” were more suitable. A single-flask system was standardized for proliferation, maturation, germination and conversion of secondary somatic embryos in suspension cultures. The system of cyclic secondary somatic embryogenesis in black pepper described here represents a permanent source of embryogenic material that can be used for genetic manipulations of this crop species.     

Maturation and germination of oak somatic embryos originated from leaf and stem explants: RAPD markers for genetic analysis of regenerants

Experiments were performed to determine the influence of maturation medium carbohydrate content on the rates of germination and plantlet conversion (root and shoot growth) of somatic embryos from four embryogenic lines derived from leaf or internode explants of Quercus robur L. seedlings. The conversion rate was favoured by high carbohydrate content as long as the maturation medium contained at least 2% sucrose, which was necessary for healthy embryo development. Given this, sorbitol and mannitol favoured the conversion rate more efficiently than sucrose, the highest rate, 32%, being achieved by medium with 6% sorbitol and 3% sucrose. Maturation treatment did not affect the root or shoot lengths of converted embryos. In supplementary experiments, 2 weeks of gibberellic acid treatment between maturation and germination treatments did not improve germination rates, but did reduce root length and the number of leaves per regenerated plantlet. In the four embryogenic lines tested, plant recovery rate was enhanced by inclusion of benzyladenine into the germination medium following culture of the embryos on maturation medium with 6% sorbitol and 2-3% sucrose. In embryogenic systems it is important to assess the uniformity of the regenerants. Random amplified polymorphic DNA (RAPD) analysis using 32 arbitrary oligonucleotide primers was performed to study variability in DNA sequences within and between four embryogenic lines. No intraclonal nor interclonal polymorphism was detected between embryogenic lines originating from different types of explant from the same seedling, but every one of the primers detected enough polymorphism among clones originating from different plants to allow these three origins to be distinguished. No differences in DNA sequences between regenerated plantlets and their somatic embryos of origin were detected, but a nodular callus line that had lost its embryogenic capacity was found to be mutant with respect to three other clones originating from the same plantlet. This study shows that high carbohydrate levels in the maturation medium significantly increase plant conversion of oak somatic embryos, which exhibit no variation in DNA sequences when proliferated by secondary embryogenesis.     

The sensitivity of transgenic spruce (Picea glauca (Moench) Voss) cotyledonary somatic embryos and somatic seedlings to kanamycin selection

Transformed white spruce cultures containing immature Stage I somatic embryos, were developed after particle bombardment of somatic embryos with pBI 426, carrying an expression cassette with a gus::nptII fusion gene. These Stage I cultures did not show tolerance to kanamycin concentrations above 3 to 5 mg l–1, although assays for GUS and NPTII showed that functional enzymes were present in the transgenic tissue. Embryonic liquid suspension cultures were initiated from this transformed tissue. After treatment on agar-solidified maturation medium with 48 m (±)-ABA high numbers of Stage III (cotyledonary) somatic embryos were produced. When subjected to an embryogenesis re-induction process with 2,4-D and BA, these Stage III embryos produced a new generation of Stage I embryogenic tissues which could tolerate 5--10 mg l–1 kanamycin. Stage III somatic embryos could alternatively be placed onto germination medium for the development of somatic seedlings. When germinated in the presence of 20 mg l–1 kanamycin, 77% of inoculants were resistant. The stability of integration of the gus::nptII fusion gene in the genome of white spruce Stage III somatic embryos and somatic seedlings was confirmed through Southern blot analysis     

Enhancing frequency of regeneration of somatic embryos of avocado (Persea americana Mill.) using semi-permeable cellulose acetate membranes

Regeneration of avocado via somatic embryogenesis is difficult due to poor embryo maturation, resulting in low frequencies of germination. In this study, the influence of semi-permeable cellulose acetate membranes and culture media, containing high levels of sucrose along with coconut water, on maturation and germination of somatic embryos of avocado have been evaluated. The culture of embryogenic calli on top of cellulose acetate membranes significantly increased the number of mature, white-opaque embryos that were recovered after 5 weeks of culture. These embryos showed a much more normal appearance and better quality compared with the control embryos, although the embryo size was significantly reduced. To increase the embryo size and to complete maturation, several two-step maturation treatments were tested. The culture of white-opaque somatic embryos in a modified MS medium with B5 macronutrients gelled with 10 g L^?1 agar (B5m10A medium) over a 5-week period, followed by 5 additional weeks in B5m10A with 45 g L^?1 sucrose and 20 % coconut water, yielded the best results, reducing the percentage of necrotic embryos and the number of calli formed. The beneficial effects of this maturation treatment were enhanced when using embryos that were pre-matured on cellulose acetate membranes. Following this two-step maturation treatment, the germination rate of the control somatic embryos, which were not cultured on cellulose membranes, was lower than 10 %, but it significantly improved when the embryos had been pre-matured on cellulose acetate membranes for 5 weeks, reaching a germination rate close to 40 %. The water availability was significantly reduced when somatic embryos were cultured on cellulose membranes, and after this pre-maturation treatment, the white-opaque embryos showed lower water potential and ABA content compared with the control embryos. These results suggest that culturing over cellulose membranes causes a controlled embryo desiccation that enhances the recovery of plants.     

Effect of partial drying and desiccation on somatic seedling quality in Norway and Serbian spruce

Somatic embryo quality is still a problem for many researchers. To improve the efficiency of germination, special procedures are used, such as partial drying of somatic embryos at high relative humidity or desiccation in the presence of supersaturated solutions of salt. In this work, cotyledonary somatic embryos of Norway spruce (Picea abies) and Serbian spruce (P. omorika) were placed on culture media (ME or BM-5) to germinate. We found that after 4 weeks of incubation on these media, hypocotyl and radicle growth of control (non-dried) somatic embryos of both species was not adequate to yield seedlings able to acclimatize to greenhouse conditions. Therefore, somatic embryos were partly dried at relative humidity of 97 % or desiccated at relative humidity of 79 %, for 2 or 3 weeks, and then placed on the Margara (ME) medium. Partial drying of somatic embryos at the higher relative humidity (97 %) enabled an improvement of radicle growth of germinating somatic embryos in both species. The highest conversion rate (45 %) was obtained for embryos of Norway spruce maintained for 2 weeks at relative humidity of 97 %. This treatment contributed to the improvement of germination and conversion efficiency of somatic embryos of Norway spruce, regardless of the drying period. Improved radicle growth facilitated development of better quality seedlings of this spruce species. In Serbian spruce, we did not obtain seedlings of sufficient quality, due to poor hypocotyl growth. Desiccation at humidity of 79 % for 3 weeks proved to be lethal to somatic embryos of both species.     

Improvement of Citrus somatic embryo development by temporary immersion

Liquid medium improves and facilitates somatic embryo development from Citrus deliciosa Ten. suspension cultures. Three different culture conditions were compared to determine a means of overcoming poor somatic embryo development. Somatic embryos derived from suspension cultures were plated on solid medium, maintained in suspension culture or temporarily immersed. About 60% of somatic embryos plated on solid medium developed to the cotyledonary stage, but were hyperhydric. Continuous growth in suspension culture at 100 rpm hindered cotyledon and protoderm formation, and somatic embryos were unable to develop beyond the globular stage. Temporary immersion promoted somatic embryo development, i.e. 66% of the somatic embryos produced were cotyledonary, and were morphologically similar to nucellar embryos. This latter culture system also improved regeneration synchronization by hampering secondary embryogenesis at the onset of germination. Irrespective of the culture system used, most cotyledonary somatic embryos studied had no caulinary meristem or starch and protein reserves, thus explaining the low germination rates obtained. This revised version was published online in June 2006 with corrections to the Cover Date.     

Application of bioreactor system for large-scale production of Eleutherococcus sessiliflorus somatic embryos in an air-lift bioreactor and production of eleutherosides

Embryogenic callus was induced from leaf explants of Eleutherococcus sessiliflorus cultured on Murashige and Skoog (MS) basal medium supplemented with 1 mg l(-1) 2,4-dichlorophenoxyacetic acid (2,4-D), while no plant growth regulators were needed for embryo maturation. The addition of 1 mg l(-1) 2,4-D was needed to maintain the embryogenic culture by preventing embryo maturation. Optimal embryo germination and plantlet development was achieved on MS medium with 4 mg l(-1) gibberellic acid (GA(3)). Low-strength MS medium (1/2 and 1/3 strength) was more effective than full-strength MS for the production of normal plantlets with well-developed shoots and roots. The plants were successfully transferred to soil. Embryogenic callus was used to establish a suspension culture for subsequent production of somatic embryos in bioreactor. By inoculating 10 g of embryogenic cells (fresh weight) into a 3l balloon type bubble bioreactor (BTBB) containing 2l MS medium without plant growth regulators, 121.8 g mature somatic embryos at different developmental stages were harvested and could be separated by filtration. Cotyledonary somatic embryos were germinated, and these converted into plantlets following transfer to a 3l BTBB containing 2l MS medium with 4 mg l(-1) GA3. HPLC analysis revealed that the total eleutherosides were significantly higher in leaves of field grown plants as compared to different stages of somatic embryo. However, the content of eleutheroside B was highest in germinated embryos. Germinated embryos also had higher contents of eleutheroside E and eleutheroside E1 as compared to other developmental stages. This result indicates that an efficient protocol for the mass production of E. sessiliflorus biomass can be achieved by bioreactor culture of somatic embryos and can be used as a source of medicinal raw materials.     

Towards normalization of soybean somatic embryo maturation

Soybean (Glycine max L. Merrill) somatic embryos have been useful for assaying seed-specific traits prior to plant recovery. Such traits could be assessed more accurately if somatic embryos more closely mimicked seed development. Amino acid supplements, carbon source, and abscisic acid and basal salt formulations were tested in an effort to modify existing soybean embryogenesis histodifferentiation/maturation media to further normalize the development of soybean somatic embryos. The resultant liquid medium, referred to as soybean histodifferentiation and maturation medium (SHaM), consists of FNL basal salts, 3% sucrose, 3% sorbitol, filter-sterilized 30 mM glutamine and 1 mM methionine. SHaM-derived somatic embryos are more similar to seed in terms of protein and fatty acid/lipid composition, and conversion ability, than somatic embryos obtained from traditional soybean histodifferentiation and maturation media.