Induction of somatic embryogenesis in woody plants

Somatic embryogenesis, the in vitro developmental program by which somatic cells are reprogrammed to undergo cellular and molecular changes that make them competent to produce somatic embryos, has been achieved with many woody plants. The program involves the stages of competence acquisition, induction and expression of the morphogenic pathway by the cultured cells and tissues. The ability to express the program in cultured cells/tissues is regulated by many factors, including genotype, explant type and age and culture conditions. In many woody plants, somatic embryogenesis was achieved with mature, immature explants or both. Juvenile tissues as immature and mature zygotic embryos are regarded best explants to establish embryogenic cultures in woody plants and potential to obtain the cultures decline with increasing maturity of the explant.     

Enhanced post-germinative growth of encapsulated somatic embryos of Siberian ginseng by carbohydrate addition to the encapsulation matrix

Based on a protocol for microspore culture in apple (Malus domestica Borkh.), the embryo induction phase has been improved with regard to pretreatment of microspores for initiation of microspore embryogenesis, the concentration of carbon source in the induction medium and the microspore density in the suspension. Furthermore, the effect of the genotype was studied. To determine the efficiency of in vitro androgenesis, both methods, via anther and microspore culture, were investigated using the same bud material. A comparison of the efficiency of embryo induction in anther and microspore cultures showed that microspore culture resulted in an increase up to 10 times, depending on the genotype. The regeneration route in microspore culture is similar to that of androgenic embryos via anther culture and showed adventitious shoot formation in most cases after a long period of secondary embryogenesis.Communicated by H. Lörz     

Plant regeneration from embryo-derived tissue cultures of soybeans

Summary Routine regeneration of fertile plants from a tissue culture of soybean has been achieved. Serially propagated embryogenic cultures were initiated from immature embryos of many genotypes. Organized tissues developed only on the cotyledons of embryos. Genotypic variation in the frequency of initiation of embryogenic tissue was noted. However, embryogenic tissue cultures were generated from all genotypes tested. Embryogenic tissue was serially increased and underwent morphogenesis. Whole fertile plants were recovered. Cultures have been maintained for two years without loss of morphogenic competency. Editor's Statement This procedure for initiating embryogenic tissue cultures from commerical cultivars of soybean and the subsequent development of fertile plants establishes a framework for studying the processes of embryogenesis and embryogenyin vitro as well as providing a system for tissue culture propagation and in vitro modification of soybean. Robert B. Horsch     

Mass production of Siberian ginseng plantlets through large-scale tank culture of somatic embryos

Siberian ginseng (Eleutherococcus senticosus) is an endangered medicinal woody plant that is distributed throughout the cold regions of northeast Asia. Its propagation is very difficult. In the present article we describe the mass production of Siberian ginseng plantlets by large-scale tank cultures. High-frequency somatic embryogenesis was achieved through suspension culture of embryogenic cells in Murashige and Skoog (MS) liquid medium lacking 2,4-D. About 12,000 embryos were produced per 500-ml flask after 4 weeks of culture. Cotyledonary somatic embryos were germinated, and these converted into plantlets following a pretreatment of the embryos with gibberellic acid (20 µM) and subsequent transfer to a 10-l plastic tank. Low-strength MS medium (1/5-, 1/3-strength) was more effective than its full-strength counterpart for the production of plantlets. After 40 days, an initial 35-g inoculum of embryos was converted to 567 g fresh mass of plantlets in 1/3-strength MS medium. This result indicates that an efficient protocol for the mass production of Siberian ginseng plantlet can be achieved by tank culture of somatic embryos. The Siberian ginseng plantlets produced can be used as a source of medicinal raw materials.     

Induction of multiple shoots by thidiazuron from caryopsis cultures of minor millet (Paspalum scrobiculatum L.) and its effect on the regeneration of embryogenic callus cultures

Caryopsis culture of a minor millet (Paspalum scrobiculatum L. cv. PSC 1) on N₆ medium supplemented with high concentrations of thidiazuron (TDZ, 11.25 µM and 22.5 µM), a phenylurea derivative known to simulate cytokinin action, resulted in the formation of multiple shoots from the base of the seedling. This is the first time that multiple-shoot formation by a seedling cultured on TDZ without a callus interphase has been reported in graminaceous crop plants. The presence of a cytokinin, 6-benzylaminopurine (BAP), at low or high concentrations failed to evoke any morphogenic response. The presence of the auxin 2,4-dichlorophenoxyacetic acid (2,4-D, 4.5 µM) either alone or with BAP (4.5 µM) resulted in the formation of embryogenic callus from the base of the seedlings, which subsequently differentiated into somatic embryos. The combination of TDZ and the auxin (4.5 µM, 2,4-D) in the medium stimulated the differentiation of shoot buds in embryogenic callus cultures. This effect of TDZ, noted for the first time in a monocotyledonous plant, was evident in terms of a significant increase in the frequency of shoot-bud formation in embryogenic callus cultures and occurred only at a high concentration of TDZ (11.25 µM). This requirement for a high concentration of TDZ for the induction of multiple shoots from cultured seedlings or shoot buds in an embryogenic callus culture of a monocot is contrary to its effect at low concentrations in dicotyledonous plants. Complete plantlets, derived either from somatic embryos or shoot buds, could be regenerated on hormone-free basal medium or on basal medium fortified with activated charcoal (0.5%). Following a gradual acclimatization in a culture room, these regenerants survived on transfer to soil and ultimately set seed.     

Characterization of competence during induction of somatic embryogenesis in alfalfa tissue culture

Systematic manipulations of the culture protocol leading to somatic embryogenesis in alfalfa petiole-derived callus were performed to study the competence phase during somatic embryogenesis in alfalfa. These demonstrated a requirement for the acquisition of competence prior to the induction of the embryogenesis pathway. Induction was triggered by a number of synthetic auxins including 2,4-dichlorophenoxyacetic acid (2,4-d). Competence could be acquired in the presence of these auxins as well as phenylacetic acid (PAA), an auxin that did not induce embryogenesis. Different degrees of competence were apparently acquired by exposure to 2,4-d and PAA. Some degree of competence was acquired in the absence of auxin treatment. The current understanding of the concept of competence is discussed.PRC contribution no. 1431     

Xanthan gum: an economical substitute for agar in plant tissue culture media

Xanthan gum, a microbial desiccation-resistant polysaccharide prepared commercially by aerobic submerged fermentation from Xanthomonas campestris, has been successfully used as a solidifying agent for plant tissue culture media. Its suitability as a substitute to agar was demonstrated for in vitro seed germination, caulogenesis and rhizogenesis of Albizzia lebbeck, androgenesis in anther cultures of Datura innoxia, and somatic embryogenesis in callus cultures of Calliandra tweedii. Culture media used for eliciting these morphogenic responses were gelled with either 1% xanthan gum or 0.9% agar. Xanthan gum, like agar, supported all these responses.     

In vitro germination and establishment of tissue cultures of Bulbine caulescens and of two Kniphofia species (Asphodelaceae)

A protocol for the in vitro germination and the establishment of tissue cultures of Bulbine caulescens Linn., Kniphofia pumila Kunth, and K. uvaria Hook has been developed. The members of the family Asphodelaceae contain interesting substances with antiplasmodial activity against several strains of Plasmodium falciparum. With respect to species of Bulbine, this is the first time that in vitro germination has been achieved. For seeds of K. pumila and K. uvaria, a facilitated germination was attained by an optimized pretreatment of the seeds. After in vitro germination, root explants of Kniphofia and bulb explants of B. caulescens were successfully transformed into callus cultures. From these, liquid cultures of the two species of Kniphofia were easily produced. Studies on shoot multiplication of Kniphofia in vitro were also performed.     

Picomolar concentrations of salicylates induce cellular growth and enhance somatic embryogenesis in Coffea arabica tissue culture

Embryogenic cell suspension cultures of Coffea arabica cv. Caturra Rojo were treated with salicylic acid (SA). Two concentrations, 10^-12 and 10^-10 M, had a significant effect on the growth rate of the cell cultures when compared to the control, and this effect was concentration-dependent. These two SA concentrations also had a dramatic effect on both the number of somatic embryos and quality, in terms of embryo size and development. In general, the use of SA had a positive effect on cellular growth and somatic embryogenesis, causing a twofold increase in both processes. The increase in the number of somatic embryos could be a reflection of an increase in the number of embryogenic cells induced with SA treatment.     

Exploring plant tissue culture in Withania somnifera (L.) Dunal: in vitro propagation and secondary metabolite production

Withania somnifera (L.) Dunal (family: Solanaceae), commonly known as “Indian Ginseng”, is a medicinally and industrially important plant of the Indian subcontinent and other warmer parts of the world. The plant has multi-use medicinal potential and has been listed among 36 important cultivated medicinal plants of India that are in high demand for trade due to its pharmaceutical uses. The medicinal importance of this plant is mainly due to the presence of different types of steroidal lactones- withanolides in the roots and leaves. Owing to low seed viability and poor germination, the conventional propagation of W. somnifera falls short to cater its commercial demands particularly for secondary metabolite production. Therefore, there is a great need to develop different biotechnological approaches through tissue and organ culture for seasonal independent production of plants in large scale which will provide sufficient raw materials of uniform quality for pharmaceutical purposes. During past years, a number of in vitro plant regeneration protocols via organogenesis and somatic embryogenesis and in vitro conservation through synthetic seed based encapsulation technology have been developed for W. somnifera. Several attempts have also been made to standardize the protocol of secondary metabolite production via tissue/organ cultures, cell suspension cultures, and Agrobacterium rhizogenes-mediated transformed hairy root cultures. Employment of plant tissue culture based techniques would provide means for rapid propagation and conservation of this plant species and also provide scope for enhanced production of different bioactive secondary metabolites. The present review provides a comprehensive report on research activities conducted in the area of tissue culture and secondary metabolite production in W. somnifera during the past years. It also discusses the unexplored areas which might be taken into consideration for future research so that the medicinal properties and the secondary metabolites produced by this plant can be exploited further for the benefit of human health in a sustainable way.     

An effective and reproducible transformation protocol for the model resurrection plant Craterostigma plantagineum Hochst.

Procedures previously established for plant regeneration and Agrobacterium tumefaciens-mediated genetic transformation of the desiccation-tolerant plant, Craterostigma plantagineum, have been further developed. A highly effective tissue culture system was established based on the integrated optimisation of antioxidant and growth regulator composition and the stabilisation of the pH of the culture media by means of a potassium phosphate buffer. The undesirable hyperhydricity of Craterostigma tissue in tissue culture was also circumvented by these modifications, which serve as an alternative to the previously described procedures. The high efficiency of plant regeneration from the callus phase provided the basis for optimising genetic transformation in Craterostigma. For gene delivery, both a standard (method A) and a modified protocol (method B), the latter having previously resulted in successful Agrobacterium-mediated transformation of monocot cereals, were applied. Physical and biochemical key variables in transformation were evaluated, such as gene gun-mediated microwounding of plant explants, infiltration of Agrobacterium suspension cultures into target tissues and the influence of in vitro pre-induction of vir genes. While the physical enhancement of Agrobacterium infection (microwounding, infiltration) had no positive effect, the in vitro pre-induction of vir genes (biochemical enhancement) resulted in a twofold increase in the transformation frequency as compared to the conventional protocol (method A).     

Effects of light conditions and 2,4-D concentration in soybean anther culture

The morphogenic response of anther walls and connective tissue is the greatest obstacle to androgenesis in soybean anther culture. Whereas induction to microspore embryogenesis occurs in the dark in almost all plant species, soybean anthers have been cultured under light. In an attempt to establish culture conditions that simultaneously stimulate microspore embryogenesis and inhibit epidermal and connective cell proliferation, the effect of light and two 2,4-dichlorophenoxyacetic acid (2,4-D) concentrations (2 and 10 mg l^–1) on the induction process was investigated. Higher 2,4-D concentration speeded up microspore plasmolysis and did not improve androgenesis. Callogenesis and embryogenesis induction from sporophytic cells were significantly lower in the dark, and some microspores showed major alterations in the sporoderm. Auxin 2,4-D and induction under light contributed to the morphogenic response of the anther walls and connective tissue under the conditions previously recommended to trigger microspore embryogenesis.     

<Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated production of transgenic plants of<Emphasis Type="Italic"> Muscari armeniacum</Emphasis> Leichtl. ex Bak.

A system for the production of transgenic plants has been developed for the Liliaceous ornamental plant Muscari armeniacum Leichtl. ex Bak via Agrobacterium-mediated transformation of embryogenic cultures. Leaf-derived embryogenic cultures were co-cultivated with each of three A. tumefaciens strains, all of which harbored the binary vector carrying the neomycin phosphotransferase II (nptII), hygromycin phosphotransferase (hpt) and intron-containing #-glucuronidase (gus-intron) genes in the T-DNA region. Following co-cultivation, the embryogenic cultures were cultured on a medium containing 500 mg l^-1 cefotaxime for 1 week followed by a medium containing 75 mg l^-1 hygromycin in addition to cefotaxime. After 4-5 weeks, several hygromycin-resistant (Hyg^r) cell clusters were produced from the co-cultivated embryogenic cultures. The highest efficiency of production of Hyg^r cell clusters was obtained when embryogenic cultures were inoculated with A. tumefaciens EHA101/pIG121Hm in the presence of 100 µM acetosyringone (AS) and 0.1% (v/v) of a surfactant (Tween20) followed by co-cultivation in the presence of 100 µM AS. Hyg^r embryogenic cultures developed into complete plants via somatic embryogenesis, and most of them were verified to be transgenic by GUS histochemical assay and polymerase chain reaction analysis. Southern blot analysis revealed the integration of one to five copies of the transgene into the genome of transgenic plants, but most of them had one or two copies.     

4-Hydroxybenzyl alcohol accumulates in suspension-cell cultures and inhibits somatic embryogenesis in carrot

Somatic embryogenesis in carrot ( Daucus carota L.) is strongly inhibited by certain factors that accumulate in culture medium of high-density cultures of embryogenic cells. We previously identified 4-hydroxybenzyl alcohol (4HBA) as one of the inhibitory factors. In this study, we analyzed the accumulation pattern of 4HBA in the cultures of carrot suspension cells. When somatic embryogenesis was induced by culturing embryogenic cells in phytohormone-free Murashige and Skoog medium at various initial cell densities, 4HBA accumulated in the culture medium. The concentration of 4HBA in high cell density cultures was higher than in low cell density cultures. The accumulation of 4HBA in high cell density cultures was rapid during the early days of culture. This rapid accumulation of 4HBA in high cell density cultures might result in the strong inhibition of somatic embryogenesis. The production of 4HBA decreased as the somatic embryos developed. In addition, embryogenic cells released larger amount of 4HBA into the culture medium compared with non-embryogenic cells. These results suggest that the production of 4HBA is both related to embryogenic competence and developmentally regulated during somatic embryogenesis.     

High frequency regeneration of plantlets from the leaf-bases via somatic embryogenesis and comparison of polypeptide profiles from morphogenic and non-morphogenic calli in wheat (Triticum aestivum)

High frequency regeneration via somatic embryogenesis was achieved in the leaf-base cultures of wheat ( Triticum aestivum L. cv Sonalika) by optimizing the concentration of the hormone, 2,4-dichlorophenoxy acetic acid, and selecting for the appropriate part of the leaf base as explant. It was possible to distinguish compact (morphogenic) and friable (non-morphogenic) calli by the naked eye, after about 60 days of culture on medium enriched with 2,4-dichlorophenoxy acetic acid. The fact that the compact calli are morphogenic, while the friable ones are not, was evident from the observation that only the former formed plantlets after transfer to the basal medium. The morphogenic and non-morphogenic cultures showed substantial difference in soluble protein content on a fresh weight basis. A comparison of silver-stained profiles of soluble polypeptides from morphogenic and non-morphogenic calli revealed many polypeptides specifically associated with either type of calli.     

Changes in endogenous polyamines during the formation of somatic embryos from isogenic lines of Dactylis glomerata L. with different regenerative capacities

The endogenous levels of polyamines (PAs) in leaf-base explants isolated from plants of two isogenic lines of Dactylis glomerata L., differing in their competence for somatic embryogenesis, were compared. Leaf-bases isolated from plants with a high level of competence for somatic embryogenesis (HEC) contained four times the level of polyamines compared to those isolated from plants with a low level of competence for somatic embryogenesis (LEC). When the levels of individual polyamines in the HEC and LEC lines were compared, leaf-bases from plants of the HEC line had much lower PUT/SPD ratios than those from the LEC line. When changes in the levels of PAs were monitored during the first 28 d of culture, on a medium which promotes initiation of somatic embryogenesis, leaf-base cultures from plants of the HEC line showed a 50% increase in the levels of PAs during the first 7 d of culture, after which time levels began to decline. By day 21, levels had dropped below those found in freshly isolated leaf bases. While PUT and SPM levels increased by about 30%, the greatest increase was shown by SPD, which increased by more than 100% during the first 7 d of culture, before declining. In contrast much smaller changes in PA levels were found when leaf-bases from plants of the LEC line were cultured.     

Plant regeneration from leaf and seed-derived calli and suspension cultures of the African perennial wild rice,Oryza longistaminata

Plant regeneration from 2-month-old callus cultures derived from immature leaves of 7-day-old aseptic seedlings and mature embryos of the African wild rice Oryza longistaminata was achieved at 20% and 100% frequency, respectively. The morphogenic potential of the embryo-derived calluses dropped from 100% at the third subculture to 12.5 % at the 12th subculture. Five-month-old morphogenic calluses were used to establish a fast-growing suspension culture which, when plated onto semisolid medium, still retained its ability to regenerate plantlets 9 months after initiation. Histological analyses demonstrated that late plant regeneration from established callus and suspension cultures occured through organogenesis, although some embryogenesis events may have taken place during initiation of these cultures.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - NAA -naphthalenacetic acid - BAP 6 benzylaminopurine - PAS Periodic acid shiff     

Genetic transformation and regeneration of transgenic plants in grapevine (Vitis rupestris S.)

Isolated somatic embryos from petiole-derived callus cultures ofVitis rupestris Scheele have been employed in experiments on genetic transformation. Co-cultivation of somatic embryos during embryogenesis induction withAgrobacterium tumefaciens strain LBA4404, which contains the plasmid pBI121 carrying the neomycin phosphotranspherase and the-glucuronidase genes, produced transformed cellular lines capable of recurrent somatic embryogenesis. Precocious selection for high levels of kanamycin (100 mgl^-1) was an important part of our transformation protocol. Transformed lines still have strong-glucuronidase expression as well as stable insertion of the marker genes after 3 years of in-vitro culture, during which they have maintained their capacity to organize secondary embryos and to regenerate transgenic plants with an agreeable efficiency (13%).