Withania somnifera chemotypes NMITLI 101R, NMITLI 118R, NMITLI 128R and withaferin A protect Mastomys coucha from Brugia malayi infection.

Withania somnifera is an ayurvedic Indian medicinal plant whose immunomodulatory activities have been widely used as a home remedy for several ailments. We recently observed immunostimulatory properties in the root extracts of chemotypes NMITLI-101, NMITLI-118, NMITLI-128 and pure withanolide, withaferin A. In the present study, we evaluated the potential immunoprophylactic efficacies of these extracts against an infective pathogen. Our results show that administration of aqueous ethanol extracts (10 mg/kg) and withaferin A (0·3 mg/kg), 7 days before and after challenge with human filarial parasite Brugia malayi, offers differential protection in Mastomys coucha with chemotype 101R offering best protection (53·57%) as compared to other chemotypes. Our findings also demonstrate that establishment of B. malayi larvae was adversely affected by pretreatment with withaferin A as evidenced by 63·6% reduction in adult worm establishment. Moreover, a large percentage of the established female worms (66·2%) also showed defective embryogenesis. While the filaria-specific immunological response induced by withaferin A and NMITLI-101 showed a mixed Th1/Th2 phenotype, 118R stimulated production of IFN-γ and 128R increased levels of IL-4. Taken together, our findings reveal potential immunoprophylactic properties of W. somnifera, and further studies are needed to ascertain the benefits of this plant against other pathogens as well.

Arabidopsis shoot organogenesis is enhanced by an amino acid change in the ATHB15 transcription factor.

The hoc mutant displays high organogenic competence for in vitro shoot regeneration without addition of exogenous phytohormones. The genetic basis of this phenotype is investigated here. Using genetic mapping, the HOC locus was identified on chromosome 1. A point mutation was found in the At1g52150 gene, which encodes ATHB15/CORONA/INCURVATA4, a class III HD-ZIP transcription factor. The mutation replaced a serine with a cysteine in the MEKHLA domain of the protein. The wild-type ATHB15 gene was able to complement the hoc phenotype. Organogenesis response experiments revealed that hoc organogenic capacity was affected by the genetic background, and that it was not caused by a loss of ATHB15 function but by an effect of the mutation on protein function.

Barley anther culture: effects of annual cycle and spike position on microspore embryogenesis and albinism.

The effect of donor plants annual cycle and anther/spike position on the production of microspore-derived plants and albinism were studied. We used the winter cv. Igri and the spring cv. Cork, known to respond similarly in anther culture but to produce 78% and 2% of green plants, respectively. In both cvs. the number of microspore-derived plants was significantly higher when the anthers were collected from January to July than from August to December. However, during this period the proportion of albino plants was not altered. Conversely, the anther response decreased from 76.6 to 31.5% in Igri and from 58.8 to 32.0% in Cork when the donor spike originates from the main shoot or the fourth tiller. Significantly, anthers collected from spike of the second tiller enabled us to drastically increase the proportion of regenerated green plantlets, by 16% in Igri and 1800% in Cork.

Efficient in vitro direct shoot organogenesis and regeneration of fertile plants from embryo explants of Bambara groundnut ( Vigna subterranea L. Verdc.).

An efficient protocol has been developed for direct shoot organogenesis from embryo axes derived from mature seeds of two different landraces of Bambara groundnut. Multiple shoots were initiated on several media containing different concentrations and combinations of benzylaminopurine (BAP) or thidiazuron (TDZ). Efficient regeneration occurred when the embryo axes were first plated for 6 days on a medium containing high concentrations of BAP (1 mg/l) and alpha-naphthaleneacetic acid (NAA, 1 mg/l) and then cut transversely and transferred onto a medium containing 1.5 mg/l BAP. Shoot regeneration frequency was 100% and from five to eight shoots per explant were obtained. The importance of using embryo explants and cytokinins in the culture media, with respect to controlling the development of a highly organogenic system, was demonstrated. Histological studies revealed that proliferating buds originated directly from the superficial layers of the explants without an intermediate callus phase. The regenerated shoots were rooted on a medium containing 1 mg/l NAA and then transferred to the greenhouse. Flow cytometric analyses and chloroplast counts of guard cells suggested that the regenerants were diploid. All were morphologically normal and fertile. The short duration, high efficiency and low frequency of somaclonal variation of this system make it well suited for wider biotechnological applications of Bambara groundnut-a neglected and under-utilized crop.

Brassinosteroids, microtubules and cell elongation in Arabidopsis thaliana. I. Molecular, cellular and physiological characterization of the Arabidopsis bull mutant, defective in the delta 7-sterol-C5-desaturation step leading to brassinosteroid biosynthesis.

Although cell elongation is a basic function of plant morphogenesis, many of the molecular events involved in this process are still unknown. In this work an extremely dwarf mutant, originally named bul, was used to study one of the main processes of plant development, cell elongation. Genetic analyses revealed that the BUL locus was linked to the nga172 marker on chromosome 3. Recently, after mapping the new dwf7 mutation of Arabidopsis, which is allelic to ste1, it was reported that dwf7 is also linked to the same marker. Sterol analyses of the bull-1 mutant indicated that bul1-1 is defective in the delta 7-sterol-C5-desaturation step leading to brassinosteroid biosynthesis. Considering these findings, we designated our bul mutant as bul1-1/dwf7-3/ste1-4. The bul1-1 mutant was characterized by a very dwarf phenotype, with delayed development and reduced fertility. The mutant leaves had a dark-green colour, which was probably due to continuous stomatal closure. The bul1-1 mutant showed a partially de-etiolated phenotype in the dark. Cellular characterization and rescue experiments with brassinosteroids demonstrated the involvement of the BUL1-1 protein in brassinosteroid-dependent plant growth processes.

Brassinosteroids, microtubules and cell elongation in Arabidopsis thaliana. II. Effects of brassinosteroids on microtubules and cell elongation in the bul1 mutant.

In order to elucidate the involvement of brassinosteroids in the cell elongation process leading to normal plant morphology, indirect immunofluorescence and molecular techniques were use to study the expression of tubulin genes in the bul1-1 dwarf mutant of Arabidopsis thaliana (L.) Heynh., the characteristics of which are reported in this issue (M. Catterou et al., 2001). Microtubules were studied specifically in the regions of the mutant plant where the elongation zone is suppressed (hypocotyls and petioles), making the reduction in cell elongation evident. Indirect immunofluorescence of alpha-tubulin revealed that very few microtubules were present in mutant cells, resulting in the total lack of the parallel microtubule organization that is typical of elongating cells in the wild type. After brassinosteroid treatment, microtubules reorganized and became correctly oriented, suggesting the involvement of brassinosteroids in microtubule organization. Molecular analyses showed that the microtubule reorganization observed in brassinosteroid-treated bul1-1 plants did not result either from an activation of tubulin gene expression, or from an increase in tubulin content, suggesting that a brassinosteroid-responsive pathway exists which allows microtubule nucleation/organization and cell elongation without activation of tubulin gene expression.

Integration and expression of Sorghum C(4) phosphoenolpyruvate carboxylase and chloroplastic NADP(+)-malate dehydrogenase separately or together in C(3) potato plants(1).

We have integrated two cDNAs expressing Sorghum photosynthetic phosphoenolpyruvate carboxylase (C(4)-PEPC) and NADP-malate dehydrogenase (cpMDH), two key enzymes involved in the primary carbon fixation pathway of NADP-malic enzyme-type C(4) plants, separately or together into a C(3) plant (potato). Analysis of the transgenic plants showed a 1.5-fold increase in PEPC and cpMDH activities compared to untransformed plants. Immunolocalization confirmed an increase at the protein level of these two enzymes in the transgenic plants and indicated that the Sorghum cpMDH was specifically addressed to the chloroplasts of potato mesophyll cells. However, integration of either or both of the cDNAs into the potato genome did not appear to significantly modify either tuber starch grain content or the rate of photosynthetic O(2) production compared to control untransformed plants. The low level of transgene expression probably explains the lack of influence on carbon metabolism and photosynthetic rates. This general observation suggests that some complex mechanism may regulate the level of production of foreign C(4) metabolism enzymes in C(3) plants.

Brassinolide may control aquaporin activities in Arabidopsis thaliana.

It is usually assumed that aquaporins present in the cellular membranes could be an important route in the control of water flux in plants, but evidence for this hypothesis is scarce. In this paper, we report measurements of the osmotic permeability (P(os) of protoplasts isolated from hypocotyls of wild-type and mutant Arabidopsis thaliana (L.) Heynh. Mutants were affected in their growth and exhibited different sensitivities to the phytohormone, brassinolide. For the two mutants studied (cpd: constitutive photomorphogenesis and dwarfism; bril: brassinosteroid insensitive), hypocotyl length was correlated to P(os) for the protoplasts. Under experimental conditions where hypocotyl growth had ceased, restoration of root, hypocotyl and petiole growth by brassinolide was correlated with an increase in P(os) of the hypocotyl protoplasts. We consider that the increase in Pos of the hypocotyl cells was needed because these cells were part of the transcellular water pathway of the plant. This is the first time, to our knowledge, that brassinolide has been shown to be involved in the modification of the water-transport properties of cell membranes. Our results also emphasize the importance of aquaporins and the transcellular pathway in water transport under normal growth conditions.

Immunolocalization of glutamine synthetase in senescing tobacco (Nicotiana tabacum L.) leaves suggests that ammonia assimilation is progressively shifted to the mesophyll cytosol.

Glutamine synthetase (GS) catalyses the formation of glutamine (a major form of nitrogen transport in plants) in an ATP-dependent reaction using ammonium and glutamate. This enzyme is present in the plastids and/or in the cytosol depending on the plant or the organ examined. In order to understand the role of GS isoforms in the remobilization of leaf nitrogen, we studied the localization of GS isoenzymes during natural senescence of tobacco (Nicotiana tabacum L.) leaves. Parallel to the progression of leaf senescence, an increase in cytosolic GS polypeptides was detected in the mesophyll cytosol of senescing leaves while a significant decrease in GS protein content was observed in the phloem companion cells. The presence of GS polypeptides in the leaf cytosol of senescing leaves appears to be the result of an induction of the Gln1-3 gene, the transcripts of which are not detected in mature leaves but are abundant in senescing leaves. Alltogether, our results suggest that during senescence, ammonia assimilation is progressively shifted from the chloroplasts to the cytosol of leaf mesophyll cells.

Engineering direct fructose production in processed potato tubers by expressing a bifunctional alpha-amylase/glucose isomerase gene complex.

Manipulation of starch biosynthesis/degradation and formation of novel molecules in storage organs of plants through genetic engineering is an attractive but technically challenging goal. We report here, for the first time, that starch was degraded and glucose and fructose were produced directly when crushed potato tubers expressing a starch degrading bifunctional gene were heated for 45 minutes at 65 degrees C. To achieve this, we have constructed a fusion gene encoding the thermostable enzymes: alpha-amylase (Bacillus stearothermophilus) and glucose isomerase (Thermus thermophilus). The chimeric gene was placed under the control of the granule-bound-starch synthase promoter. This enzymatic complex produced in transgenic tubers was only active at high temperature (65 degrees C). More than 100 independent transgenic potato plants were regenerated. Molecular analyses confirmed the stable integration of the chimeric gene into the potato genome. The biochemical analyses performed on young and old tubers after high-temperature treatment (65 degrees C) revealed an increase in the formation rate of fructose and glucose by a factor of 16.4 and 5. 7, respectively, in the transgenic tubers as compared to untransformed control tubers. No adverse discernible effect on plant development and metabolism including tuber formation and starch accumulation was observed in the transgenic plants before heat treatment. Our results demonstrate that it is possible to replace starch degradation using microbial enzymes via a system where the enzymes are produced directly in the plants, but active only at high temperature, thus offering novel and viable strategies for starch-processing industries.

Competence of Arabidopsis thaliana genotypes and mutants for Agrobacterium tumefaciens-mediated gene transfer: role of phytohormones.

Many plant species and/or genotypes are highly recalcitrant to Agrobacterium-mediated genetic transformation, and yet little is known about this phenomenon. Using several Arabidopsis genotypes/ecotypes, the results of this study indicated that phytohormone pretreatment could overcome this recalcitrance by increasing the transformation rate in the known recalcitrant genotypes. Transient expression of a T-DNA encoded ss-glucuronidase (GUS) gene and stable kanamycin resistance were obtained for the ten Arabidopsis genotypes tested as well as for the mutant uvh1 (up to 69% of petioles with blue spots and up to 42% resistant calli). Cultivation of Arabidopsis tissues on phytohormones for 2-8 d before co-cultivation with Agrobacterium tumefaciens significantly increased transient GUS gene expression by 2-11-fold and stable T-DNA integration with petiole explants. Different Arabidopsis ecotypes revealed differences in their susceptibility to Agrobacterium-mediated transformation and in their type of reaction to pre-cultivation (three types of reactions were defined by gathering ecotypes into three groups). The Arabidopsis uvh1 mutant described as defective in a DNA repair system showed slightly lower competence to transformation than did its progenitor Colombia. This reduced transformation competence, however, could be overcome by 4-d pre-culture with phytohormones. The importance of pre-cultivation with phytohormones for genetic transformation is discussed.

RAPD profile based genetic characterization of chemotypic variants of Artemisia annua L.

The annual herbaceous plant, Artemisia annua L., belonging to family Asteraceae, is the natural source of the highly potent antimalarial compound, artemisinin, besides producing valuable essential oil. The plant is at present the sole commercial source for artemisinin production since all the chemical syntheses are non-viable. Therefore, economic and practical considerations dictate that plants with maximum content of artemisinin be found and/or ways to increase their artemisinin content be sought. The key to this selection and breeding is a comprehension of chemical and genetic variability and suitable selection(s) of elites from within the available population. In the present study, RAPD analyses of selected chemotypes from a decade old introduced population in India were carried out using arbitrary primers. The RAPD data clearly indicate the distinction amongst these plants. Further, the detection of highly polymorphic profiles (97 polymorphic markers out of a total of 101 markers) suggests the existence of very high levels of genetic variation in the Indian population despite geographical isolation and opens out a strong possibility of further genetic improvement for superior artemisinin content. UPGMA analyses of RAPD and phytochemical trait data indicate that the wide phytochemical diversity is included within the genetic diversity. These results further support the prospects for selection and breeding of superior artemisinin containing lines.

Identification of cytosolic Mg2+-dependent soluble inorganic pyrophosphatases in potato and phylogenetic analysis.

Using polyclonal antibodies raised against a previously cloned potato Mg2+-dependent soluble inorganic pyrophosphatase (ppa1 gene) [8], a second gene, called ppa2, could be isolated. A single locus homologous to ppa2 was mapped on potato chromosomes, unlinked to the two loci identified for ppa1. From a phylogenetic and structural point of view, the PPA1 and PPA2 polypeptides are more closely related to prokaryotic than to eukaryotic Mg2+-dependent soluble inorganic pyrophosphatases (soluble PPases). Subcellular localization by immunogold electron microscopy, using sections from leaf parenchyma cells, showed that PPA and PPA2 are localized to the cytosol. Based on these observations, the likely phylogenetic origin and the physiological significance of the cytosolic soluble pyrophosphatases are discussed.

Effect of ploidy and homozygosity on transgene expression in primary tobacco transformants and their androgenetic progenies.

Expression of a transgene is rarely analysed in the androgenetic progenies of the transgenic plants. Here, we report differential transgene expression in androgenetic haploid and doubled haploid (DH) tobacco plants as compared to the diploid parental lines, thus demonstrating a gene dosage effect. Using Agrobacterium-mediated transformation, and bacterial reporter genes encoding neomycin phosphotransferase (nptII) and beta-glucuronidase (uidA/ GUS), driven respectively by the mas 1' and mas 2' promoters, we have generated more than 150 independent transgenic (R0) Nicotiana tabacum plants containing one or more T-DNA copies. Transgene analyses of these R0, their selfed R1 lines and their corresponding haploid progenies showed an obvious position effect (site of T-DNA insertion on chromosome) on uidA expression. However, transgene (GUS) expression levels were not proportional to transgene copy number. More than 150 haploids and doubled haploids, induced by treatment with colchicine, were produced from 20 independent transgenic R0 plants containing single and multiple copies of the uidA gene. We observed that homozygous DH plants expressed GUS at approximately 2.9-fold the level of the corresponding parental haploid plants. This increase in transgene expression may be attributed mainly to the increase (2-fold) in chromosome number. Based on this observation, we suggest a strong link between chromosome number (ploidy dosage effect) and transgene expression. In particular, we demonstrate the effect on its expression level of converting the transgene from the heterozygous (in R0 plants) to the homozygous (DH) state: e.g. an increase of 50% was observed in the homozygous DH as compared to the original heterozygous diploid plants. We propose that ploidy coupled with homozygosity can result in a new type of gene activation, creating differences in gene expression patterns.

Direct fluorometry of phase-extracted tryptamine-based fast quantitative assay of L-tryptophan decarboxylase from Catharanthus roseus leaf.

An assay for the enzyme L-tryptophan decarboxylase (TDC; EC 4.1.1.28) is described. It is based on direct fluorometry of the enzymatic reaction product (tryptamine) selectively recovered in ethyl acetate from the reaction mixture. Catalytically formed tryptamine from tryptophan in the incubation mixture is selectively (free from tryptophan) physically separated as ethyl acetate solution under basic (pH > or = 11) conditions and subjected to direct fluorescence measurement in the organic solvent using a spectrofluorometer with excitation and emission wavelengths of 280 and 350 nm, respectively. Tryptamine production rate was quantitated from the luminescence response curve of tryptamine drawn under similar extraction and measurement conditions. Luminescence calibration curves were drawn for tryptamine in aqueous (water or buffer system) as well as in organic solvent as recovered from the varied aqueous solution conditions including those similar to the enzyme incubation mixture. The luminescence calibration graphs were linear for at least 0.5 to 10 microM tryptamine. The examination of interassay variations and the comparative magnitude of fluorescence response allowed to infer that a satisfactory and sufficient sample luminescence response was retained under the varied conditions including those akin to the enzymatic assay mixture, allowing adaptation of the fluorometry for the TDC activity quantitation. The assay was found to follow the proportionality principle of product formation with respect to catalytic reaction time as well as protein concentration in the assay mixture using Catharanthus roseus leaf crude homogenate as well as the enzyme preparation at different states of purity. The rate of tryptamine formation under the catalytic conditions was linear for at least 1 h at 30 degrees C. Though the assay has been demonstrated to use the C. roseus leaf as the enzyme source, it should be equally applicable to other plant and nonplant sources. The merits and precautions of the protocol have been discussed.

Flow cytometric analyses in embryogenic and non-embryogenic callus lines of Cyclamen persicum Mill.: relation between ploidy level and competence for somatic embryogenesis.

Embryogenic and non-embryogenic callus lines derived from the same diploid Cyclamen persicum genotype (`Purple Flamed') were analyzed by flow cytometry and compared to the initial plant material. The DNA content of the diploid plant in the greenhouse was 1.12 pg DNA/2C as estimated in relation to the internal standards tomato nuclei and chicken erythrocytes. In both callus lines the majority of cells contained the same amount of DNA as the initial plant, indicating that no polyploidization has taken place after 5 years of culture on medium containing 2.0 mg/l 2,4-dichlorophenoxyacetic acid (2,4-D) and 0.8 mg/l 6-(γ-γ-dimethylallylamino)purine(zip). Thus, our data suggest that in Cyclamen callus lines there was no strict correlation between the ploidy level and the ability to produce somatic embryos. Furthermore, following the proportion of cells in the three phases of the cell cycle (G0/G1, S, G2/M) during one subculture period of 4 weeks revealed high division activity within the first 2 weeks for both callus lines cultured on the 2,4-D-containing medium. However, when transferred to hormone-free medium, the division activity of the embryogenic cell line decreased markedly, corresponding to the differentiation of somatic embryos. In contrast, for the non-embryogenic callus an increase in cells in the G2/M phase was observed.

Localization of tobacco cytosolic glutamine synthetase enzymes and the corresponding transcripts shows organ- and cell-specific patterns of protein synthesis and gene expression.

The subcellular localization of glutamine synthetase in tobacco and the differential expression of two genes encoding cytosolic enzyme was investigated using both immunocytochemistry and in situ hybridization. Two full length cDNA clones each encoding cytosolic GS (Gln 1-3 and Gln 1-5) were isolated from a tobacco seeding cDNA library. A strong homology was found in the coding region of the two clones whereas the 3'- and 5'-untranslated sequences were dissimilar. In order to determine the levels of transcription, specific sequences from Gln1-3 and Gln1-5 were used in an RNAse protection assay. This experiment clearly showed that the gene encoding Gln1-3 is expressed in roots and flowers whereas the gene encoding Gln1-5 is transcribed at a high level in stems and at a lower level in roots and flowers. Immunogold labelling was used to examine the subcellular and cellular distribution of glutamine synthetase in vegetative and reproductive organs of tobacco plants. In mature leaf tissue or petals and sepals, plastidic GS was visualised only in the stroma matrix of chloroplasts and plastids. Cytosolic GS was detected in a number of vegetative or reproductive organs including leaves and flowers. In leaves cytosolic GS was preferentially located in the vascular tissue. In situ hybridization was performed using sections of tobacco organs and specific antisense RNA probes to the genes encoding Gln1-3 and Gln1-5. Gln1-5 transcripts were localised in the vascular tissues of stems and roots whereas Gln1-3 transcripts were detected in all root cells and floral organs including petals, sepals and anthers.

Identification of a tobacco cDNA encoding a cytosolic NADP-isocitrate dehydrogenase.

A cDNA which encodes a specific member of the NADP-dependent isocitrate dehydrogenase (ICDH) multi-isoenzyme family has been isolated from a tobacco cell suspension library, and the expression pattern of ICDH transcripts examined in various plant tissues. To assign this cDNA to a specific ICDH isoenzyme, the major, cytosolic ICDH isoenzyme of tobacco leaves (ICDH1) was purified to homogeneity and its N-terminus as well as several tryptic peptides, representing 30% of the protein, were sequenced. The comparison of these amino acid sequences with the deduced protein sequence of the cDNA confirmed that this clone encodes for ICDH1. The total ICDH specific activity and protein content were higher in vascular-enriched tobacco leaf tissue than in deveined (depleted in midrib and first-order veins) leaves. Taking advantage of antibodies raised against either ICDH1 or the chloroplastic ICDH2 isoenzyme from tobacco cell suspensions, an immuno-cytochemical approach indicated that the ICDH1 isoenzyme, located in the cytosolic compartment of tobacco leaf cells, is responsible for this expression pattern. This observation was confirmed by northern blot analyses, using a specific probe obtained from the 3' non-coding region of the ICDH1 cDNA. A comparison of ICDH protein sequences shows a large degree of similarity between eukaryotes (> 60%) but a poor homology is observed when compared to Escherichia coli ICDH (< 20%). However, it was found that the amino acids implicated in substrate binding, deduced from the 3-dimensional structure of the E. coli NADP-ICDH, appear to be conserved in all the deduced eukaryotic ICDH proteins reported until now.

In planta 2,3,5 truodobenzoic acid treatment promotes high frequency and routine in vitro regeneration of sugarbeet (Beta vulgaris L.) plants.

The effect ofin planta treatments with auxin inhibitors such as 2,3,5 triiodobenzoic acid (TIBA) on regeneration of plantsin vitro is not known. Here, we show the beneficial effect of preconditioning sugarbeet plants in the greenhouse with TIBA (3 mg/1) for efficientin vitro plant regeneration via a callus phase from cultured leaf explants. Without this treatment, no shoot developed on the control leaf-calluses. Several hundred plants were routinely regenerated using this protocol. More importantly, the number of shoots per explantcallus increased drastically over the subsequent subculture period. The most favorable media for callus induction contained a combination of an auxin and a cytokinin (0.1 mg/1 2,4-dichlorophenoxyacetic acid and 1 mg/1 N-6 benzylaminopurine) or a cytokinin alone (2.2 mg/1 thidiazuron). However, only the callus derived from leaves of TIBA-treated genotypes and induced on thidiazuron-medium produced numerous shoots. Histological studies showed the formation of meristematic zones only in the organogenic callus developed on thidiazuron-coutaining medium. The analysis of peroxidase activity showed that the activity was higher for the TIBA-treated plants than for the untreated control plants.

Factors influencing secondary somatic embryogenesis inMalus x domestica Borkh. (cv 'Gloster 69').

A procedure for regeneration of apple plants through secondary somatic embryogenesis (SSE) was developed in apple 'Gloster 69'. Primary somatic embryos were produced from cotyledon-derived cultures of immature zygotic embryos. These somatic embryos were multiplied by secondary somatic embryogenesis (SSE) on media with different Plant Growth Regulator (PGR) combinations. The highest SSE rate (55.5%) was obtained with a combination of NAA (5.3 µM), BAP (0.9 µM) and KIN (0.9 µM) or with TDZ alone (10 µM). In addition, effects of explant source, somatic embryo size, type and concentrations of carbohydrates and gelling agents on SSE were investigated. The optimum SSE (>73%) was obtained by the culture of large size somatic embryos or cotyledon-like structures on medium containing a combination of NAA/BAP/KIN or TDZ (10 µM) alone, maltose (175 mM) and Phytagel (2.8 g/1).