Studies on genetic transformation of Theobroma cacao L.: evaluation of different polyamines and antibiotics on somatic embryogenesis and the efficiency of uidA gene transfer by Agrobacterium tumefaciens

In order to develop a more efficient genetic transformation system for cacao somatic embryos, the effects of polyamines and β-lactam antibiotics on somatic embryogenesis, hygromycin as selective agent, and different factors affecting uidA gene transfer have been evaluated. The polyamines putrescine, spermidine, and spermine significantly improved secondary somatic embryogenesis in cacao. Spermine at 1,000 μM provided the best responses, increasing 6.7× the percentage of embryogenic callus and 2.5× the average number of embryos per embryogenic callus. The β-lactam antibiotics timentin and meropenem, used for Agrobacterium tumefaciens counter-selection, had a non-detrimental effect on secondary somatic embryogenesis, depending on their concentration, whereas the commonly used β-lactam cefotaxime inhibited it, irrespective of the tested concentration. Hygromycin showed a strong inhibitory effect on secondary somatic embryogenesis of cacao, impairing completely the embryo production at 20 mg l⁻¹. Following the criterion of GUS activity, the best conditions for T-DNA transfer into cotyledon explants from primary somatic embryos of cacao were a sonication of the explants for 100 s, a 20-min incubation period in Agrobacterium solution, an Agrobacterium concentration of 1.0 (OD₆₀₀), and cocultivation of the explants on tobacco feeder layers. These findings will have important implications for studies on functional genomics of cacao.     

Effect of MgSO4 and K2SO4 on somatic embryo differentiation in Theobroma cacao L.

Somatic embryogenesis in cacao is difficult and this species is considered as recalcitrant. Therefore, reformulation of culture media might be a breakthrough to improve its somatic embryogenesis. In cacao, acquisition of somatic embryogenesis competence involves three main stages: induction of primary callus, induction of secondary callus and embryo development. Screening for MgSO₄ and K₂SO₄ concentrations for somatic embryo differentiation was conducted on three genotypes (Sca6, IMC67 and C151-61) at the three stages. The effect of these two salts in culture media appears to be most efficient at the embryo development stage. At this stage, high MgSO₄ (24 mM) and K₂SO₄ (71.568 mM) in the culture media induced direct somatic embryos on staminodes and petals of the Sca6 and IMC67 genotypes. Media supplemented with 6.0 mM and 12.0 mM MgSO₄ enabled high responsive of explants and produced high proportion of embryos. The positive effect of MgSO₄ and K₂SO₄ on the acquisition of embryogenesis competence was further tested on seven cacao genotypes reputed as non embryogenic: SNK12, ICS40, POR, IMC67, PA121, SNK64 and SNK10. All these genotypes were able to produce somatic embryos depending on the MgSO₄ concentration. Thus, our results showed that the recalcitrance of cacao to somatic embryo differentiation can be overcome by screening for the suitable MgSO₄ or K₂SO₄ concentration. Studies of the influence of different K⁺/Mg²⁺ ratios (at normal sulphate concentration) on somatic embryo differentiation revealed that sulphate supply was the main factor promoting responsive explants and the proportion of embryos. Cysteine synthase isoforms showed patterns related to morphogenetic structures sustaining that sulphur supply and its assimilation improve somatic embryogenesis in cacao.     

Induction of somatic embryogenesis from different explants of shoot cultures derived from young <Emphasis Type="Italic">Quercus alba</Emphasis> trees

The induction of somatic embryogenesis from shoot apices and leaf explants of shoot cultures derived from 6- to 7-year-old white oak (Quercus alba L.) trees is reported in this study. Embryogenic response was obtained in two out of the three genotypes evaluated with embryo induction frequencies up to 50.7% for WOQ-1 and 3.4% for WOQ-5 genotypes. The embryogenic explants formed translucent nodular structures and cotyledonary-stage somatic embryos, which developed from callus tissue, indicating an indirect embryogenesis process. An efficient procedure was developed for WOQ-1 material on the basis of the most appropriate leaf developmental stage. Growing leaves excised from two nodes below the shoot apex showed the highest embryogenic induction index. These leaves contain cells in an undifferentiated state, as shown by the presence of precursor cells of stomata, absence of intercellular spaces and low starch content in the mesophyll cells. Nodular structures and/or somatic embryos began to arise 7–8 weeks after culture initiation, although most emerged after 9–12 weeks in culture. The sequence of application of media for somatic embryo induction was optimized with a two-step procedure consisting of culturing the explants in medium supplemented with 21.48 μM NAA and 2.22 μM BA for 8 weeks and transfer of explants into plant growth regulator-free medium for another 12 weeks. Clonal embryogenic lines were established and maintained by secondary embryogenesis. Embryo germination (30%) and plantlet conversion (16.6%) were achieved after cold storage for 2 months.     

Somatic embryogenesis and plant regeneration from floral explants of cacao (Theobroma cacao L.) using thidiazuron

Summary A procedure for the regeneration of cacao (Theobroma cacao) plants from staminode explants via somatic embryogenesis was developed. Rapidly growing calli were induced by culturing staminode explants on a DKW salts-based primary callus growth (PCG) medium supplemented with 20 g glucose per L, 9 μM 2,4-D, and thidiazuron (TDZ) at various concentrations. Calli were subcultured onto a WPM salts-based secondary callus growth medium supplemented with 20 g glucose per L, 9 μM 2,4-D, and 1.4 nM kinetin. Somatic embryos were formed from embryogenic calli following transfer to a hormone-free DKW salts-based embryo development medium containing sucrose. The concentration of TDZ used in PCG medium significantly affected the rate of callus growth, the frequency of embryogenesis, and the number of somatic embryos produced from each responsive explant. A TDZ concentration of 22.7 nM was found to be the optimal concentration for effective induction of somatic embryos from various cacao genotypes. Using this procedure, we recovered somatic embryos from all 19 tested cacao genotypes, representing three major genetic group types. However, among these genotypes, a wide range of variation was observed in both the frequency of embryogenesis, which ranged from 1 to 100%, and the average number of somatic embryos produced from each responsive explant, which ranged from 2 to 46. Two types of somatic embryos were identified on the basis of their visual appearance and growth behavior. A large number of cacao plants have been regenerated from somatic embryos and established in soil in a greenhouse. Plants showed morphological and growth characteristics similar to those of seed-derived plants. The described procedure may allow for the practical use of somatic embryogenesis for clonal propagation of elite cacao clones and other applications that require the production of a large number of plants from limited source materials.     

The use of somatic embryogenesis for plant propagation in cassava

In cassava, somatic embryogenesis starts with the culture of leaf explants on solid Murashige and Skoog-based medium supplemented with auxins. Mature somatic embryos are formed within 6 wk. The cotyledons of the primary somatic embryos are used as explants for a new cycle of somatic embryogenesis. The cotyledons undergo secondary somatic embryogenesis on both liquid and solid Murashige and Skoog-based medium supplemented with auxins. Depending on the auxin, new somatic embryos are formed after 14–30 d after which they can be used for a new cycle of somatic embryogenesis. In liquid medium, more than 20 secondary somatic embryos are formed per initial cultured embryo. In both primary and secondary somatic embryogenesis, the somatic embryos originate directly from the explants. Transfer of clumps of somatic embryos to a Greshoff and Doy-based medium supplemented with auxins results in indirect somatic embryogenesis. The direct form of somatic embryogenesis has a high potential for use in plant propagation, whereas the indirect has a high potential for use in genetic modification of cassava. Mature somatic embryos germinate into plants after desiccation and culture on a Murashige and Skoog-based medium supplemented with benzylaminopurine (BA). Depending on the used BA concentration, plants can either be transferred either directly to the greenhouse or after using standard multiplication protocols.     

Improved somatic embryogenesis from Cocos nucifera (L.) plumule explants

Summary Coconut is one of the most recalcitrant species to regenerate in vitro. Although previous research efforts using plumule explants have resulted in reproducible somatic embryogenesis, efficiency is only 4 or 10 somatic embryos per plumule without or with a brassinolide treatment, respectively. In order to increase the efficiency of somatic embryogenesis in coconut, two different approaches were evaluated and reported here: secondary somatic embryogenesis and multiplication of embryogenic callus. Primary somatic embryos obtained from plumule explants were used as explants and formed both embryogenic callus and secondary somatic embryos. The embrogenic calluses obtained after three multiplication cycles were capable of producing somatic embryos. The efficiency of the system was evaluated in a stepwise process beginning with an initial step for inducing primary somatic embryogenesis followed by three steps for inducing secondary somatic embryogenesis followed by three steps for embryogenenis callus multiplication, and finally production of somatic embryos from callus. The total calculated yield from one plumule was 98 000 somatic embryos. Comparing this to the yield obtained from primary somatic embryogenesis results in about a 50 000-fold increase. When compared to the yield previously reported in the literature with the use of a brassinolide treatment, it is about a 10 000-fold increase in yield. The present protocol represents important progress in improvement in the efficiency of coconut somatic embryo production.     

Secondary somatic embryogenesis of carnation (<Emphasis Type="Italic">Dianthus caryophyllus</Emphasis> L.)

This is the first report describing culture conditions necessary to induce secondary embryogenesis in two carnation cultivars, Nelson and Spirit. In the first step, embryogenic calli were induced on petal explants followed by development of primary somatic embryos from the calli. In the second stage, secondary somatic embryos were obtained when precotyledonary and cotyledonary primary embryos were isolated and transferred onto a series of culture media all containing MS basal salt mixture, and supplemented with different concentrations of 2,4-D, BA, sucrose and mannitol. The highest rate of secondary embryogenesis occurred on mannitol containing media. Secondary somatic embryos were converted into plantlets when they were transferred onto growth regulator-free half-strength MS medium and successfully acclimated in the greenhouse.     

A temporary immersion system improves in vitro regeneration of peach palm through secondary somatic embryogenesis

Background and Aims

Secondary somatic embryogenesis has been postulated to occur during induction of peach palm somatic embryogenesis. In the present study this morphogenetic pathway is described and a protocol for the establishment of cycling cultures using a temporary immersion system (TIS) is presented.

Methods

Zygotic embryos were used as explants, and induction of somatic embryogenesis and plantlet growth were compared in TIS and solid culture medium. Light microscopy, scanning electron microscopy (SEM) and transmission electron microscopy (TEM) were used to describe in vitro morphogenesis and accompany morpho-histological alterations during culture.

Key Results

The development of secondary somatic embryos occurs early during the induction of primary somatic embryos. Secondary somatic embryos were observed to develop continually in culture, resulting in non-synchronized development of these somatic embryos. Using these somatic embryos as explants allowed development of cycling cultures. Somatic embryos had high embryogenic potential (65·8 ± 3·0 to 86·2 ± 5·0 %) over the period tested. The use of a TIS greatly improved the number of somatic embryos obtained, as well as subsequent plantlet growth. Histological analyses showed that starch accumulation precedes the development of somatic embryos, and that these cells presented high nucleus/cytoplasm ratios and high mitotic indices, as evidenced by DAPI staining. Morphological and SEM observations revealed clusters of somatic embryos on one part of the explants, while other parts grew further, resulting in callus tissue. A multicellular origin of the secondary somatic embryos is hypothesized. Cells in the vicinity of callus accumulated large amounts of phenolic substances in their vacuoles. TEM revealed that these cells are metabolically very active, with the presence of numerous mitochondria and Golgi apparatuses. Light microscopy and TEM of the embryogenic sector revealed cells with numerous amyloplasts, large nuclei and nucleoli, and numerous plasmodesmata. Plantlets were obtained and after 3 months in culture their growth was significantly better in TIS than on solid culture medium. However, during acclimatization the survival rate of TIS-grown plantlets was lower.

Conclusions

The present study confirms the occurrence of secondary somatic embryos in peach palm and describes a feasible protocol for regeneration of peach palm in vitro. Further optimizations include the use of explants obtained from adult palms and improvement of somatic embryo conversion rates.     

Primary and repetitive secondary somatic embryogenesis of <Emphasis Type="Italic">Lepidosperma drummondii</Emphasis> (Cyperaceae) and <Emphasis Type="Italic">Baloskion tetraphyllum</Emphasis> (Restionaceae) for land restoration and horticulture

Somatic embryogenesis was developed as a method of mass propagation for Lepidosperma drummondii (Cyperaceae), a difficult to propagate but important species for post-mining restoration in a region of high plant biodiversity, in the southwest of Western Australia. Cultures were initiated from excised zygotic embryos, shoot cultures to rhizomes. Only zygotic embryos of L. drummondii developed somatic embryos, with half strength Murashige and Skoog basal medium (BM) and 1 μM 2,4-dichlorophenoxyacetic acid (2,4-D) being the most effective combination. The first culture cycle yielded a mean of 30 somatic embryos per excised zygotic embryo forming an embryo cluster. After a further 6 wk in culture (on fresh BM with 1 μM 2,4-D), approximately 350 somatic embryos per starting embryo cluster were recorded. Following regular sub-culturing of primary somatic embryo clusters onto fresh media (every 4 wk), more than 74,000 secondary somatic embryos were estimated to have been produced after eight subculture periods. This translates to between 1,000 and 2,000 somatic embryos produced from an estimated 45 mg of starting tissue per culture plate or potentially 22,0000–44,000 somatic embryos per gram of tissue. This is a significant improvement over all previous methods used to propagate L. drummondii, in which typical in vitro shoot multiplication rates are as low as 1.43 per 8 wk. This also compared favourably with published data and concurrent experiments undertaken in this study (as an extra control measure) on somatic embryo production for a related species Baloskion tetraphyllum (using the same BM with 1 μM 2,4-D and coleoptile segments as explants). Various media combinations were investigated for efficacy in converting somatic embryos into plants with best results ranging from 86% to 100% conversion for B. tetraphyllum on BM without plant growth regulators. Development of L. drummondii somatic embryos into plants was not observed on BM without plant growth regulators. However, a best result of 39% conversion to plants was observed on BM with 1 μM thidiazuron. This is the first report of successful development of somatic embryogenesis and conversion of somatic embryos into plants using thidiazuron for the Australian cyperale L. drummondii.     

Growth regulators affect primary and secondary somatic embryogenesis in Madagaskar periwinkle (<Emphasis Type="Italic">Catharanthus roseus</Emphasis> (L.) G. Don) at morphological and biochemical levels

An efficient somatic embryogenesis system has been established in Catharanthus roseus (L.) G. Don in which primary and secondary embryogenic calluses were developed from hypocotyls and primary cotyledonary somatic embryos (PCSEs), respectively. Two types of calluses were different in morphology and growth behaviour. Hypocotyl-derived embryogenic callus (HEC) was friable and fast-growing, while secondary callus derived from PCSE was compact and slow-growing. HEC differentiated into somatic embryos which proliferated quickly on medium supplemented with NAA (1.0 mg l⁻¹) and BA (1.5 mg l⁻¹). Although differentiation and proliferation of somatic embryos were faster in primary HEC, maturation and germination efficiency were better in somatic embryos developed from primary cotyledonary somatic embryo-derived secondary embryogenic callus (PCSEC). At the biochemical level, two somatic embryogenesis systems were different. Both primary and secondary/adventive somatic embryogenesis and the role of plant growth regulators in two modes of somatic embryo formation have been discussed.     

Protocols for efficient repetitive and secondary somatic embryogenesis in Helianthus maximiliani (Schrader)

 Indirect somatic embryogenesis was induced on leaf explants of greenhouse-grown Helianthus maximiliani plants. Leaves of the regenerated plants were used as starting explants for the induction of direct somatic embryogenesis. Another cycle of somatic embryogenesis was induced on the leaves of regenerated plants. In both cases, leaf explants were cultured on media containing different auxin/cytokinin ratios. The auxin/cytokinin ratio had an influence on the intensity of embryo formation, germination and the capability to regenerate plants. Somatic embryogenesis was generally more intensive on the medium with lower concentrations of 6-benzylamino-purine. Further, the percentage of regenerated plants was higher when embryos were induced on high-cytokinin, low-auxin medium. Secondary somatic embryogenesis was induced on embryos by culture in liquid hormone-free medium. Similar to direct embryogenesis the efficiency of secondary embryogenesis depended on the medium used for the induction of the primary embryos. In contrast to the mostly low frequencies of conversion of secondary embryos into plants that has been observed in other species, the percentage of regenerated plants from secondary embryos of H. maximiliani was quite high, although slightly lower than that obtained in primary embryos. Received: 28 March 2000 / Revision received: 1 September 2000 / Accepted: 2 October 2000     

Somatic embryogenesis,acclimatization and genetic homogeneity assessment of regenerated plantlets of <Emphasis Type="Italic">Anoectochilus elatus</Emphasis> Lindl., an endangered terrestrial jewel orchid

An efficient in vitro plant regeneration system was established through somatic embryogenesis for Anoectochilus elatus Lindley, an endangered jewel orchid. Direct somatic embryogenesis was achieved from nodal explants (17.4 embryos per explant with 63.4% response) on Mitra medium supplemented with Morel vitamins, thidiazuron (4.54 µM) and ∞-naphthaleneacetic acid (2.69 µM). Simultaneously, a protocol was developed for indirect somatic embryogenesis from internodal explant, produced embryogenic calli and embryos (31.3 embryos with 76.4% response) on same medium amended with 50 mg/L peptone and 5% coconut water. Both types of embryogenic pathways, produced morphologically similar globular embryos in the form of protocorm like bodies and successfully germinated on hormone free Mitra medium supplemented with Morel vitamins. Morpho-histological investigation of the embryo revealed the initiation and developmental features of somatic embryos. In vitro regenerated plantlets were successfully established from heterotrophic to a photoautotrophic stage by reducing the nutrient content in culture media, adjusting temperature and humidity through three step method. During the process, no morphological and physiological abnormalities were observed. Hardened plantlets were successfully acclimatized at poly tunnel chamber with 95% of survival rate. Further, inter simple sequence repeats (ISSRs) molecular markers were used to analyse the genetic homogeneity of regenerated plants. Analysis with this method showed that the homogeneity is comparatively higher in direct somatic embryo regenerated plants (94.22%) as compared to plants elevated from an indirect somatic embryo (93.05%). The present study provides morpho-histological and genetically stable plants for germplasm conservation and further utility of this endangered jewel orchid.     

Regeneration of somatic embryos in Theobroma cacao L. in temporary immersion bioreactor and analyses of free amino acids in different tissues

The present study aimed at developing temporary immersion bioreactor techniques for multiplication of cacao somatic embryos. Temporary Immersion System (TIS), i.e. flooding of plant tissue at regular time intervals provides an efficient way to propagate plants. Somatic embryos were regenerated in twin flask bioreactors. The TIS proved to be suitable for mass regeneration of somatic embryos and for their subsequent direct sowing. The number of embryos after 3 months of culture was significantly higher in TIS cultures than in the solid medium variant. TIS also improved embryo development regarding the conversion to torpedo shaped forms. Matured embryos derived from TIS and pre-treated with 6% sucrose were converted into plants after direct sowing. Additionally to the influence of culture conditions on the development of somatic embryogenesis the content and composition of free amino acids were analysed. The content of free amino acids in somatic embryos rose as immersion frequency increased. The endogenous free GABA content in embryogenic callus was significantly higher than in non-embryogenic callus.     

Proliferation,maturation and germination of Castanea sativa Mill. Somatic embryos originated from leaf explants

Experiments were performed to determine the influence of proliferation medium on the maintenance of embryogenic competence and on repetitive embryogenesis in Castanea sativa Mill. somatic embryos derived from leaf explants. Somatic embryo proliferation was carried out by both direct secondary embryogenesis and by the culture of nodular callus tissue originated from cotyledons of somatic embryos. Both systems led to the production of cotyledonary somatic embryos on Murashige and Skoog proliferation medium supplemented with 0.1 mg l-1 benzyladenine and 0.1 mg l-1 naphthaleneacetic acid. Carbon source and concentration had a marked influence on maturation and subsequent germination ability of chestnut somatic embryos. Plantlet conversion was achieved in embryos matured on media with 6 % sucrose, and on 3 or 6 % maltose, whereas mean shoot length, root length and leaf number of produced plants were not significantly affected by these maturation media. Overall, the best results were obtained with 3 % maltose-matured somatic embryos, giving rise to 6 % plant recovery in addition to 33 % of embryos exhibiting only shoot development. The application of a 2-month cold treatment at 4 degrees C to somatic embryos matured on medium with 3 % maltose was necessary for achieving plant conversion, while partial desiccation did not appear to influence this response. A total of 39 % of embryos eventually produced plants either through conversion to plantlets or indirectly through rooting of shoots. Shoots formed by somatic embryos could be excised, multiplied and rooted following the micropropagation procedures previously developed for chestnut.     

Somatic embryo cycling: Evaluation of a novel transformation and assay system for seed-specific gene expression in soybean

Somatic embryo cycling, a modification of soybean somatic embryogenic suspension culture, was developed as an efficient and rapid method of producing tissue suitable for stable transformation of soybean germplasm by biolistic particle bombardment. Instead of using immature seed explants, cotyledon-staged somatic embryo hypocotyls were placed on auxin-containing medium, where they initiated new somatic embryos primarily from single epidermal cells. By bombarding hypocotyls prior to initiation of subsequent embryo formation, we have effectively transformed soybean somatic embryos with the reporter genes neomycin phosphotransferase,gb-glucuronidase, and a mammalian stearyl CoA delta-9 desaturase, controlled by a seed-specific promoter. These embryos contain significantly reduced levels of saturated palmitic and stearic fatty acids, and significant amounts of monounsaturated palmitoleic acid, which is not normally abundant in soybean seeds. This study demonstrates the effectiveness of somatic embryo cycling for soybean transformation, and for testing expression of genes for seed-specific proteins. Abnormal flower development in recovered plants is a limitation for application of the technique to produce transgenic seed at present.     

Somatic embryo cycling: Evaluation of a novel transformation and assay system for seed-specific gene expression in soybean

Somatic embryo cycling, a modification of soybean somatic embryogenic suspension culture, was developed as an efficient and rapid method of producing tissue suitable for stable transformation of soybean germplasm by biolistic particle bombardment. Instead of using immature seed explants, cotyledon-staged somatic embryo hypocotyls were placed on auxin-containing medium, where they initiated new somatic embryos primarily from single epidermal cells. By bombarding hypocotyls prior to initiation of subsequent embryo formation, we have effectively transformed soybean somatic embryos with the reporter genes neomycin phosphotransferase,gb-glucuronidase, and a mammalian stearyl CoA delta-9 desaturase, controlled by a seed-specific promoter. These embryos contain significantly reduced levels of saturated palmitic and stearic fatty acids, and significant amounts of monounsaturated palmitoleic acid, which is not normally abundant in soybean seeds. This study demonstrates the effectiveness of somatic embryo cycling for soybean transformation, and for testing expression of genes for seed-specific proteins. Abnormal flower development in recovered plants is a limitation for application of the technique to produce transgenic seed at present.     

Genetic transformation and full recovery of alfalfa plants via secondary somatic embryogenesis

A genetic transformation method via secondary somatic embryogenesis was developed for alfalfa (Medicago sativa L.). Mature somatic embryos of alfalfa were infected by Agrobacterium strain GV3101 containing the binary vector pCAMBIA2301. pCAMBIA2301 harbors the uidA Gus reporter gene and npt II acts as the selectable marker gene. Infected primary embryos were placed on SH2K medium containing plant growth regulators to induce cell dedifferentiation and embryogenesis under 75 mg/L kanamycin selection. The induced calli were transferred to plant medium free of plant growth regulators for embryo formation while maintaining selection. Somatic embryos germinated normally upon transfer to a germination medium. Plants were recovered and grown in a tissue culture room before transfer to a greenhouse. Histochemical analysis showed high levels of GUS activity in secondary somatic embryos and in different organs of plants recovered from secondary somatic embryos. The presence and stable integration of transgenes in recovered plants were confirmed by polymerase chain reaction using transgene-specific primers and Southern blot hybridization using the npt II gene probe. The average transformation efficiency achieved via secondary somatic embryogenesis was 15.2%. The selection for transformation throughout the cell dedifferentiation and embryogenic callus induction phases was very effective, and no regenerated plants escaped the selection procedure. Alfalfa transformation is usually achieved through somatic embryogenesis using different organs of developed plants. Use of somatic embryos as explants for transformation can avoid the plant development phase, providing a faster procedure for introduction of new traits and facilitates further engineering of previously transformed lines.     

Origin of somatic embryos from repetitively embryogenic cultures of walnut (Juglans regia L.): Implications forAgrobacterium-mediated transformation

Early stages of somatic embryo development from embryogenic cultures ofJuglans regia (Persian or English walnut) are described. Histological examination reveals that secondary somatic embryos arise from cotyledons and hypocotyls of primary embryos cultured in the dark. The embryos originate by transverse to oblique divisions of surface cells. Single-cell origin of the secondary embryos confirms the potential of the repetitive embryogenesis system forAgrobacterium-mediated transformation and regeneration of non-chimeric, transgenic walnut plants.     

Plant regeneration via somatic embryogenesis in cotton

An efficient in vitro plant regeneration system characterized by rapid and continuous production of somatic embryos using leaf and stem explants of abnormal seedling as an explant have been developed in Gossypium hirsutum L. Embryogenic callus and somatic embryos have been obtained directly from the explants of cotton abnormal seedlings. Plant growth regulators influenced the induction of cotton somatic embryogenesis. The optimal medium for direct somatic embryogenesis was modified MS medium supplemented with 0.1 mg l^-1 ZT and 2 g l^-1 activated carbon. On this medium, an average of 28.0 and 28.1 matured somatic embryos formed from per leaf and stem explants respectively. The highest frequency of somatic embryogenesis was 100%. The somatic embryos were converted into normal plantlets when cultured on modified MS medium supplemented with 0.1 mg l^-1 ZT. Upon transfer to soil, plants grew well and appeared normal. Plants could be regenerated within 60–80 days. The system of cotton somatic embryogenesis and plant regeneration described here will facilitate the application of plant tissue culture and genetic engineering on cotton genetic improvement. This revised version was published online in June 2006 with corrections to the Cover Date.     

Somatic embryogenesis in tamarillo (<Emphasis Type="Italic">Cyphomandra betacea</Emphasis>): approaches to increase efficiency of embryo formation and plant development

Somatic embryogenesis induction and somatic embryo development of the solanaceous tamarillo tree were previously established and successfully used for plant regeneration from different explants and varieties. Somatic embryogenesis was induced in Murashige and Skoog medium containing 2,4-dichlorophenoxyacetic acid (2,4-D) or picloram and high sucrose concentrations (0.25 M). The embryogenic tissues were transferred to an auxin-free medium, with reduced sucrose levels, to permit embryo development and conversion into plantlets. This two-step protocol is often impaired by an ineffective transition from the proembryogenic masses to embryo development. In this work, attempts to optimize the somatic embryogenesis system of tamarillo by improving the quality of somatic embryo and embryo conversion were carried out. The results showed that the presence of a high number of abnormal somatic embryos did not significantly inhibit plant conversion, hence indicating that shoot apical meristem development was not affected in abnormal somatic embryos. It was also shown that the manipulation of sucrose concentration in the development medium (0.11 M) and dark conditions before conversion increased the number of morphologically normal somatic embryos. The comparison between mature cotyledonary zygotic and somatic embryos showed an inefficient accumulation of storage compounds, mainly lipids, in somatic embryos. These reduced levels of lipid storage could be responsible for the abnormal patterns of embryo development found in tamarillo somatic embryos.