Plant regeneration via somatic embryogenesis from protoplasts of six explants in Coker 201 (<Emphasis Type="Italic">Gossypium hirsutum</Emphasis>)

Fertile regenerated plants were obtained from protoplasts via somatic embryogenesis in Coker 201 (Gossypium hirsutum L.). Protoplasts were isolated from six different explantsleaves, hypocotyls, young roots, embryogenic callus, immature somatic embryos and suspension cultures and cultured in liquid thin layer KM8P medium. Callus-forming percentage of 20–50% was obtained in protoplast cultures from embryogenic callus, immature embryos and suspension cultures, and visible callus formed within 2 months. Callus-forming percentage of 5–20% in protoplast cultures from young roots, hypocotyls and leaves, and visible callus formed in 3 months. NAA 5.371 μM/kinetin 0.929 μM was effective to stimulate protoplast division and callus formation from six explants. Percentage of callus formation in the medium with 2,4-D 0.452 μM/kinetin 0.465 μM was over 40% from suspension cultures and immature embryos, 25% from embryogenic callus and 10% from hypocotyls. Callus from protoplasts developed into plantlets via somatic embryogenesis. Over 100 plantlets were obtained from protoplasts derived from 6 explants. Ten plants have been transferred to the soil, where they all have set seeds.     

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.     

Histology of somatic embryogenesis in <Emphasis Type="Italic">Coffea arabica</Emphasis> L.

The objective of this study was to characterize the histodifferentiation of somatic embryogenesis obtained from leaf explants of C. arabica. Therefore, we histologically analyzed the respective stages of the process: leaf segments at 0, 4, 7, 15 and 30 days of cultivation, Type 1 primary calli (primary calli with embryogenic competence) and 2 (primary calli with no embryogenic competence), embryogenic calli, globular, torpedo and cotyledonary embryos, and mature zygotic embryos. Callus formation occurred after seven days of culture, with successive divisions of procambium cell. In this cultivation phase, it was found that Type 1 primary calli are basically formed by parenchymal cells with reduced intercellular spacing, whereas Type 2 primary calli are predominantly composed of parenchymal cells with ample intercellular spaces and embryogenic calli composed entirely of meristematic cells. After 330 days, it was evident from the differentiation of somatic embryogenesis that there was formation of globular somatic embryos, consisting of a characteristic protoderm surrounding the fundamental meristem. With the maturation of these propagules after 360 days, torpedo-stage somatic embryos arose, in which tissue polarization and early differentiation of procambial strands were verified. After 390 days, cotyledonary somatic embryos were obtained, where the onset of vessel elements differentiation was verified, a characteristic also observed in mature zygotic embryos. We concluded that somatic embryogenesis obtained from C. arabica leaves initiates from procambium cell divisions that, in the course of cultivation, produce mature somatic embryos suitable for regenerating whole plants.     

Callus production, somatic embryogenesis and plant regeneration of Lycium barbarum root explants

A new micropropagation system for Lycium barbarum (L.) was developed using root explants as starting material. Callus can be produced from root explants on Murashige and Skoog (MS) medium containing 0.2 mg dm⁻³ 2,4-dichlorophenoxyacetic acid. After three subcultures on the same medium, callus was then transferred onto the MS medium supplemented with 500 mg dm⁻³ lactalbumin hydrolysate to induce somatic embryogenesis (SE). After 20 d, about 60 somatic embryos per 0.25 g(f.m.) of embryogenic callus were obtained but only about 10 % of embryos converted into plantlets. After acclimated in the greenhouse, all of the randomly selected plantlets had survived and were similar phenotypically to zygotic seedlings. In addition, the effects of irradiance, photoperiod, growth regulators, explant age and cold treatment on SE of root-derived callus were evaluated.     

Somatic embryogenesis and regeneration of Cenchrus ciliaris genotypes from immature inflorescence explants

An efficient, highly reproducible system for plant regeneration via somatic embryogenesis was developed for Cenchrus ciliaris genotypes IG-3108 and IG-74. Explants such as seeds, shoot tip segments and immature inflorescences were cultured on Murashige and Skoog (MS) medium supplemented with 2.0–5.0 mg dm^?3 2,4-dichlorophenoxyacetic acid (2,4-D) and 0.5 mg dm^?3 N⁶-benzyladenine (BA) for induction of callus. Callus could be successfully induced from all the three explants of both the genotypes. But the high frequency of embryogenic callus could be induced only from immature inflorescence explants. Somatic embryos were formed from nodular, hard and compact embryogenic calli when 2,4-D concentration was gradually reduced and BA concentration increased. Histological studies of somatic embryos indicated the presence of shoot apical meristem with leaf primordia. Ultrastructural details of globular and scutellar somatic embryos further validated successful induction and progression of somatic embryogenesis. Shoots were differentiated upon germination of somatic embryos on MS medium containing 2,4-D (0.25 mg dm^?3) and BA or kinetin (1–5 mg dm^?3). Roots were induced on ½ MS medium containing charcoal (0.8 %), and the regenerated plants transferred to pots and established in the soil showed normal growth and fertility.     

In vitro shoot growth, direct organogenesis and somatic embryogenesis promoted by silver nitrate in Coffea dewevrei

Direct differentiation of shoot buds in Coffea dewevrei was evident from the seedling shoots with collar region and also from collar region end of hypocotyl segments in presence of 40 μM AgNO₃, 8.88 μM of BA and 2.85 μM of IAA. Apart from this, shoot end of hypocotyl explants mainly supported yellow friable callus or somatic embryos. Subsequent transfer to the same medium induced secondary somatic embryogenesis. The collar region of the hypocotyl explants not only showed direct organogenesis by producing 1–3 shoots per explant and also able to produce globular somatic embryos and embryogenic yellow friable callus. Similarly direct somatic embryogenesis along with yellow friable embryogenic callus formation on 1/2 strength MS medium comprising 1.47 μM IAA, 2.22 μM BA and 40 μM AgNO₃ was noticed from cut portion of in vitro leaf and stalk of regenerated plants. The microshoots rooted well upon subculturing onto the same medium in 6 weeks and showed 60 % survival in green house and resumed growth upon hardening.     

Scale-up of somatic embryogenesis in alfalfa (Medicago sativa L.) I subculture and indirect secondary somatic embryogenisis

Three methods of increasing the productivity of somatic embryogenesis in Medicago sativa L. were investigated. In the basic procedure, somatic embryos were initiated from young petioles and carried through several phases: callus formation, suspension culture, selection of the embryogenic fraction by sieving, development, maturation, desiccation and storage. The suspensions were normally separated into three fractions by sieving. Fraction I (<200 m) containing nonembryogenic cells or cell clusters was discarded. Fraction II (200–500 m) consisting of embryogenic cell clusters was collected for embryo development and maturation. Fraction III (over 500 M) containing the mixture of petiole residues with large pieces of calli and globular somatic embryos was usually discarded. Several methods to scale-up the suspension phase were unsuccessful. Direct subculture of the entire suspension by the addition of fresh liquid medium resulted in the loss of embryogenic capacity by the third subculture. Subculture of fraction II decreased embryogenic cell mass, and hence reduced total productivity. The recycling of fraction III back to fresh B₅g liquid medium resulted in high productivity in the first culture but further subculture of this fraction resulted in a rapid decline in the embryogenic capacity.As an alternative, somatic embryos from the first tissue culture cycle were also used as explants for the initiation of secondary embryogenic callus. The embryogenic capacity of these somatic embryo explants declined rapidly as they matured. More than 100 secondary somatic embryos could be induced from embryo explants removed from development medium at 10 days after sieving the suspension, but only 40 somatic embryos were produced from each mature somatic embryo explant, and 13 from desiccated embryos. The secondary somatic embryos were comparable to the primary embryos in quality according to germination tests. The implications of the results to the efficiency of somatic embryo production of Medicago are discussed.Abbreviations ABA abscisic acid - 2,4-d 2,4-dichlorophenoxyacetic acid - DAS days after sieving - PPF photosynthetic photon flux density - SE somatic embryo     

Plant regeneration through somatic embryogenesis from immature and mature zygotic embryos of Musa acuminata ssp. burmannica

A simple and efficient protocol has been developed for in vitro regeneration of M. acuminata ssp. burmannica (AA) plants. Somatic embryos were produced when immature and mature zygotic embryo explants were cultured on Murashige and Skoog medium supplemented with plant growth regulators 2,4-dichlorophenoxyacetic acid; (2,4-D), picloram or benzyl adenine and indole acetic acid. In general, immature embryos responded better than mature embryos. Callus proliferation was highest in medium supplemented with 2,4-D (4.5???M). Subsequent transfer of callus to fresh medium produced rapidly proliferating embryogenic calli. Embryogenic calli were maintained in complete darkness for 15?d followed by cycles of 8?h dark and 16?h light, under white fluorescent lamps with a light intensity of 3,000?lm/m² and at temperature of 28?±?2°C. Regeneration of embryogenic calli into plantlets was higher for immature embryos (76.6%) than for mature embryos (50.6%). This plant regeneration protocol using mature or immature zygotic embryos, via somatic embryogenesis, has significant potential to improve germination efficiencies of hybrid progenies used in conventional breeding strategies. Furthermore, tests on seed storage showed that seed viability rapidly decline after harvesting and was negligible after 9?mo of storage. This indicates using freshly harvested seeds as explant material is necessary for maximizing the tissue culture response.     

Regeneration from intact and sectioned immature embryos of barley (Hordeum vulgare L.): the scutellum exhibits an apico-basal gradient of embryogenic capacity

Immature zygotic embryos from spring barley cv. Dissa were used to induce somatic embryogenenesis. Up to 158 germinated somatic embryos could be recovered per plated zygotic embryo. Critical factors for obtaining a high yield of regenerants were the size of the explant, the level of 2,4-D used for callus induction and the careful division of callus at each subculture. Use of microsections of immature embryos as explants revealed a pronounced gradient of callus formation and embryogenic response across the scutellum. Sections from the scutellar tissue at the coleoptilar end of the embryo gave the most callus and were highly embryogenic. The regeneration response of sectioned explants was comparable to that recovered from intact embryos of similar size.     

Direct somatic embryogenesis of potato [<Emphasis Type="Italic">Solanum tuberosum</Emphasis> (L.)] cultivar ‘Kufri Chipsona 2’

Direct somatic embryo induction was achieved from leaf and internodal explants of Solanum tuberosum (L.) cultivar ‘Kufri Chipsona 2’ on Murashige and Skoog (Physiol Plant 15:473–497, 1962) medium containing 10.0 µM silver nitrate (MS1 medium) supplemented with 2,4-dichlorophenoxyacetic acid (2,4-D; 2.5 µM) and 6-benzyladenine (BA; 1.0 µΜ). It was observed that in absence of AgNO₃, friable callus was induced from cut ends of the explants, which does not develop into any kind of organised structure; thus highlighting the requirement of AgNO₃ for somatic embryogenesis in potato. Furthermore, the effect of medium strength, sucrose concentration and heat shock treatment on somatic embryogenic potential of explants was also investigated. When the strength of basal medium was reduced to half, the frequency of internodal segments differentiating somatic embryos was almost double in comparison to full strength MS medium. Sucrose concentration and heat shock treatment were found to have interactive effect on somatic embryo induction. Explants subcultured on medium containing 174 mM sucrose and subjected to heat shock (1 h; 50 °C) showed maximum somatic embryo differentiation. Although, the percent explants differentiating somatic embryos decreased sharply with increase in sucrose concentration (>?174 mM), yet the number of somatic embryos differentiated per explant were found to increase with further increase in sucrose concentration. Histological observations revealed that somatic embryos directly developed from epidermis of leaf explant and cut ends of internodal segments progressed from globular to cotyledonary stage after passing through intermediate embryogenic stages (heart shaped and torpedo shaped). Conversion of somatic embryos into plantlets (92%) was achieved on MS1 medium supplemented with BA (10.0 µM) and gibberellic acid (15.0 µM) and all regenerated plants were found to be phenotypically alike.     

Genotype and explant-type dependent morphogenesis and silicon response of common reed (Phragmites australis) tissue cultures

The effects of silicon on the growth and development of Phragmites australis (Cav.) Trin. Ex Steud. (common reed) stem nodal and root embryogenic calli were investigated. Silicon is considered to be a beneficial or quasi-essential nutrient for several Gramineaceous plants, including reed. Seven callus lines of four geographical locations (genotypes 1-4) within Hungary were investigated. Callus lines 1A, 2A and 3A were produced from stem nodal explants, while lines 1B, 2B, 3B and 4 were produced from roots. For the assay of silicon-dependent growth of callus lines of identical genotype but originating from different explants, we measured the increase of fresh weight of lines 1A and 1B. The studied developmental parameters were the increase of the number of somatic embryos (for callus lines 1A and 1B) and plant or root production from somatic embryos (for all genotypes/callus lines). Silicon was added to the culture medium as sodium silicate. In control cultures, plant or root regeneration from embryogenic calli was strongly genotype- and explant type-dependent. Stem nodal explants developed plants on regeneration medium in case of callus lines 2A and 3A, while line 1A produced roots only. All root derived calli developed roots on regeneration medium. Silicon stimulated the growth of both stem nodal and root calli (callus lines 1A, B) however, the concentration optima were different. Somatic embryogenesis of root calli, but not of stem nodal calli, was stimulated by silicate at low concentrations. However, for both of these callus lines, root development was stimulated by silicon. It had genotype-dependent influences on plant regeneration: while stimulation was observed in case of callus line 2A, inhibition occurred for line 3A. Root morphogenesis on calli was significantly influenced by silicon and depended on the callus line studied. Root production was stimulated on callus lines 1A, B and 2B, while in case of callus line 3B, it was significantly inhibited. The morphogenetic effects of Si were similar for different explants of the same geographical origin, i.e. plant or root production was similarly stimulated or inhibited by this element. We can conclude that the effects of Si on plant or root development depend on reed genotype used for callus induction. Its effect on growth and somatic embryogenesis depends on the explant type used for callus production. This is the first detailed report on the role of silicon in plant vegetative development and morphogenesis of a Gramineaceous plant.     

Plant regeneration protocol of medicinally important <Emphasis Type="Italic">Andrographis paniculata</Emphasis> (Burm. F.) Wallich <Emphasis Type="Italic">ex</Emphasis> Nees via somatic embryogenesis

Summary In vitro propagation of Andrographis paniculata (Burm. f.) Wallich ex Nees through somatic embryogenesis, and influence of 2,4-dichlorophenoxyacetic acid (2,4-1) on induction, maturation, and conversion of somatic embryos were investigated. The concentration of 2,4-D in callus induction medium determined the induction, efficacy of somatic embryogenesis, embryo maturation, and conversion. Friable callus initiated from leaf and internode explants grown on Murashige and Skoog (MS) medium supplemented with 2.26, 4.52, 6.78, and 9.05μM 2,4-D started to form embryos at 135, 105, 150, and 185d, respectively, after explant establishment. Callus initiated at 13.56μM 2,4-D did not induce embryos even after 240 d, whereas those initiated on MS medium with 4.52μM 2,4-D was most favorable for the formation and maturation of somatic embryos. Callus subcultured on the medium with reduced concentration of 2,4-D (2.26μM) became embryogenic. This embryogenic callus gave rise to the highest number of embryos (mean of 312 embryos) after being transferred to half-strength MS basal liquid medium. The embryos were grown only up to the torpedo stage. A higher frequency of embryos developed from callus initiated on 2.26 or 4.52 μM 2,4-D underwent maturation compared to that initiated on higher concentrations of 2.4-D. The addition of 11.7μM silver nitrate to half-strength MS liquid medium resulted in 71% of embryos undergoing maturation, while 83% of embryos developed into plantlets after being transferred to agar inedium with 0.44 μMN⁶-benzyladenine and 1.44 μM gibberellic acid. Most plantlets (88%) survived under field conditions and were morphologically identical to the parent plant.     

Regeneration of Centella asiatica plants from non-embryogenic cell lines and evaluation of antibacterial and antifungal properties of regenerated calli and plants

Background

The threatened plant Centella asiatica L. is traditionallyused for a number of remedies. In vitro plant propagation and enhanced metabolite production of active metabolites through biotechnological approaches has gained attention in recent years.

Results

Present study reveals that 6-benzyladenine (BA) either alone or in combination with 1-naphthalene acetic acid (NAA) supplemented in Murashige and Skoog (MS) medium at different concentrations produced good quality callus from leaf explants of C. asiatica. The calli produced on different plant growth regulators at different concentrations were mostly embryogenic and green. Highest shoot regeneration efficiency; 10 shoots per callus explant, from non-embryogenic callus was observed on 4.42 μM BA with 5.37 μM NAA. Best rooting response was observed at 5.37 and 10.74 μM NAA with 20 average number of roots per explant. Calli and regenerated plants extracts inhibited bacterial growth with mean zone of inhibition 9-13 mm diameter when tested against six bacterial strains using agar well diffusion method. Agar tube dilution method for antifungal assay showed 3.2-76% growth inhibition of Mucor species, Aspergillus fumigatus and Fusarium moliniformes.

Conclusions

The present investigation reveals that non-embryogenic callus can be turned into embryos and plantlets if cultured on appropriate medium. Furthermore, callus from leaf explant of C. asiatica can be a good source for production of antimicrobial compounds through bioreactor.     

The histodifferentiation events involved during the acquisition and development of somatic embryogenesis in oil palm (Elaeis guineensis Jacq.)

Understanding the fate and dynamics of cells during callus formation is essential to understanding totipotency and the somatic embryogenesis (SE) mechanisms. In the present study, the histodifferentiation events involved during the acquisition and development of somatic embryogenesis in oil palm (Elaeis guineensis Jacq.) was investigated. Zygotic embryos were inoculated on SE induction medium, and at 14 days the first divisions of the procambial and perivascular cells were observed. This region progressed to the formation of meristematic masses at 21 days, indicating their procambial and perivascular origin. Primary calli emerged at 45 days of culture, followed by progression to embryogenic calli at 90 days. The formation of proembryos (PE) from the meristematic cells occurred at 135 days of cultivation. The PE were isolated from the tissue of origin by the slight thickening of the cell wall, indicating their unicellular origin. When transferred to the maturation phase, differentiation of the somatic embryos at different developmental stages (globular and torpedo) was observed. The differentiated somatic embryos presented protoderm, procambial strands and plumules. Afterwards, they were transferred to culture medium without growth regulators in which conversion of the somatic embryos from torpedo stage into plants was observed. These results enable a greater understanding of the SE process and plantlet formation in E. guineensis.     

Tissue position,explant orientation and naphthaleneacetic acid (NAA) affect initiation of somatic embryos and callus proliferation in Norway spruce (Picea abies)

Sections from mature zygotic embryos of Norway spruce exhibited different capacities for somatic embryo initiation. The upper hypocotyl part (Zone 2) was the most embryogenic, followed by the lower hypocotyl (Zone 3) and the apical zone (Zone 1); the root part (Zone 4) never initiated embryonal-suspensor masses (ESM). The embryogenic capacity of mature zygotic embryo is narrowly located in the vicinity of Zone 2. The frequency of embryos differentiating simultaneously ESM on Zones 1 and 3 is very low (0.6%) compared to those initiating ESM on Zones 1 and 2 (7%) or Zones 2 and 3 (16%). Elevated concentrations of naphthalene acetic acid (40 and 80 M) reduced ESM initiation and callus proliferation on all sections but Zone 1. Highest initiation rate was obtained when explants were cultured with an apical-end-up orientation. Placing the explant basal-end-up partially inhibited the expression of embryogenic capacity, as well as decreasing the callus proliferation on Zone 3. A weak positive correlation (r=0.19, p < 0.001) was found between embryogenic capacity of the explant and proliferation rate of the derived callus.     

Shoot apex explants for induction of somatic embryogenesis in mature Quercus robur L. trees

A procedure for inducing somatic embryos in shoot apex explants (2 mm) excised from shoot proliferation cultures established from adult oak trees (Quercus robur) was investigated. Embryogenesis was induced in shoot tip as well as leaf explants in three out of the five genotypes evaluated. Somatic embryos were formed by culture in induction medium supplemented with 21.48 μM naphthalene acetic acid and 2.22 μM benzyladenine for 8 weeks, and successive transfer of explants to expression media with a low concentration of growth regulators and without them. Both types of explants formed callus tissue from which somatic embryos developed, indicating indirect embryogenesis. Although the embryogenic frequencies were lower than 12%, it did not prevent the establishment of clonal embryogenic lines maintained by repetitive embryogenesis. Histological study confirmed an indirect somatic embryogenesis process from shoot tip explants, in which leaf primordia and the corresponding axial zones were involved in generating callus, whereas the apical meristem itself did not proliferate. The origin of embryogenic cells appeared to be associated with dedifferentiation of certain parenchymal cells in callus regions after transfer of explants to expression media without auxin. Division of embryogenic cells gave rise to proembryo aggregates of unicellular origin, although a multicellular origin from bulging embryogenic areas would also seem possible. Further development led to the formation of cotyledonary-stage somatic embryos and nodular embryogenic structures that may be considered as anomalous embryos with no clear bipolarity. Inducement of somatic embryos from explants isolated from shoot cultures ensures plant material all year round, thus providing a significant advantage over the use of leaf explants from field-grown trees.     

Somatic embryogenesis,organogenesis, and regeneration from leaf callus culture of <Emphasis Type="Italic">Decalepis hamiltonii</Emphasis> Wight &; Arn., an endangered shrub

Summary A novel protocol has been developed for inducing somatic embryogenesis from leaf cultures of Decalepis hamiltonii. Callus was obtained from leaf sections in Murashige and Skoog (MS) medium supplemented with α-naphthaleneacetic acid (NAA)+N⁶-benzyladenine (BA) or 2,4-dichlorophenoxyacetic acid (2,4-D)+BA. Nodular embryogenic callus developed from the cut end of explants on media containing 2,4-D and BA, whereas compact callus developed on media containing NAA and BA. Upon subsequent transfer of explants with primary callus onto MS media containing zeatin and/or gibberellic acid (GA₃) and BA, treatment with zeatin (13.68μM) and BA (10.65 μM) resulted in the induction of the highest number of somatic embryos directly from nodular tissue. The maturation of embryos took place along with the induction on the same medium. Embryogenic calluses with somatic embryos were subcultured onto MS basal medium supplemented with 4.56μM zeatin+10.65 μM BA. After 4wk, more extensive differentiation of somatic embryos was observed. The mature embryos developed into complete plantlets on growth regulator-free MS medium. A distinct feature of this study is the induction of somatic embryogenesis from leaf explants of Decalepis hamiltonii, which has not been reported previously. By using this protocol, complete plantlets could be regenerated through indirect somatic embryogenesis or organogenesis from leaf explants in 12–16 wk.     

Enhancement of somatic embryogenesis in Norway spruce (Picea abies L.)

Summary Embryogenic callus developed in 55% of the mature embryo explants of Norway spruce (Picea abies L.) growing on a LP medium minus the amino acids and sugars (except sucrose). This is the highest reported yield of embryogenic callus from mature embryos of P. abies that has ever been reported. Callus induction from either the middle or the end of the hypocotyl of the embryos began after 2–3 weeks. Three types of calli were recovered: (a) globular, (b) light green-compact, (c) white mucilaginous. Only the white mucilaginous calli were embryogenic. The globular and light green-compact calli never become embryogenic, even after several subcultures. The development of somatic embryos was accomplished on half-strength macro-elements of NSIII medium containing 1 M -naphthaleneacetic acid, 1 M abscisic acid, and 3% sucrose. The addition of 10^–7 M buthionine sulfoximine to the medium increased the development of somatic embryos by three fold. These results suggest that there is a great potential for increasing the frequency and development of somatic embryos in P. abies. Careful selection of the genotype and modification of the culture medium is required.