Pulse treatments of penicillin-G and streptomycin minimise internal infections and have post-treatment effects on the morphogenesis of ginseng root culture

This study was initiated to determine whether antibiotic pulse treatments (APT) could effectively eliminate internal infections of ginseng (Panax ginseng) root explants containing vascular tissue, and subsequently have post-treatment effects on changing explant behaviors in callus induction and organogenesis or somatic embryogenesis. For contamination control, a treatment of 40 min with an antibiotic solution consisting of 1000 mg/1 of penicillin-G and 1000 mg/1 of streptomycin immediately following Na-hypochlorite sterilisation significantly decreased contamination rate. Extending treatment time to 2–3 h further lowered the contamination rate to 30–40%. On the other hand, explants treated with antibiotics for 20 min or less were all contaminated. APT also had post-treatment effects; it delayed callus induction for 1–12 months depending on pulse duration and stimulated the generation of more hardand darker looking than fragile- and lighter looking callus. The induced callus proliferated at a depressed rate, increasing subculture intervals from 1 to several weeks, and not until after five subcultures did it fully recover. The regeneration ability of the recovered callus was also affected by APT: the regeneration of adventitious roots was promoted, whereas somatic embryos were not observed.Abbreviations APT Antibiotic pulse treatments - 2,4-D 2,4-dichlorophenoxyacetic acid     

Somatic embryogenesis in Eucalyptus globulus

Somatic embryos were obtained from 1% of cotyledon pieces and hypocotyls of mature embryos of Eucalyptus globulus Labill. cultured on media containing a high concentration of picloram or IBA. 2,4-D and other synthetic auxins did not yield somatic embryos or embryogenic callus. Somatic embryos arose indirectly via callus, being visible after four months, and directly, where little callus or adventitious root initiation occurred. Somatic embryos, formed directly from explants, were visible within five weeks. Various structural abnormalities of somatic embryos were observed, especially after induction on media containing picloram. Only two out of fifteen somatic embryos showed hypocotyl and radical elongation, but plantlets did not develop further.     

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.     

In vitro culture ofBellevalia romana (L.) Rchb. I. Plant regeneration through adventitious shoots and somatic embryos

Summary Callus induction, adventitious shoot and root formation, and somatic embryogenesis were investigated in root, cotyledon and mesocotyl cultures ofBellevalia romana (L.) Rchb. grown on a synthetic nutrient medium containing different plant hormones. The combination of naphtaleneacetic acid plus benzylaminopurine was very effective in causing callus growth and plant regeneration from mesocotyl explants. On the contrary 2,4-dichlorophenoxyacetic acid caused suppression of shoot bud development in the same type of callus. Both cotyledon and root derived calli showed a low growth rate and did not regenerate shoots but only roots. Differentiation of somatic embryos which eventually developed into plantlets was promoted by 2,4-dichlorophenoxyacetic acid in suspension cultures. The results are discussed in relation to studies on nuclear behaviour during different morphogenetic pathways.     

Cyclic somatic embryogenesis and efficient plant regeneration from callus of safflower

Efficient plant regeneration through somatic embryogenesis was established for safflower (Carthamus tinctorius L.) cv. NARI-6. Embryogenic calli were induced from 10 to 17-d-old cotyledon and leaf explants from in vitro seedlings. High frequency (94.3 %) embryogenic callus was obtained from cotyledon explants cultured on Murashige and Skoog’s germination (MSG) basal medium supplemented with thidiazuron, 2-isopentenyladenine and indole-3-butyric acid. Primary, secondary and cyclic somatic embryos were formed from embryogenic calli in a different media free of plant growth regulators, however, 100 % cyclic somatic embryogenesis was obtained from cotyledon derived embryogenic calli cultured on MSG. Somatic embryos matured and germinated in quarter-strength MSG medium supplemented with gibberellic acid. Cotyledons with root poles or non root poles were converted to normal plantlets and produced adventitious roots in rooting medium. Rooted plants were acclimatized and successfully transferred to the field.     

Somatic Embryogenesis and Plant Regeneration from Papaya Suspension Cultures

Compact embryogenetic calli were obtained from explants on P3 medium after 4 weeks of culture and high-frequency somatic embryogenesis occurred after these calli were transferred into suspension culture. Experimental data showed that low level (0.2%W/V) of activated charcoal had beneficial effects on somatic embryogenesis. Abundant calli on P4 medium however, showed no embryogenesis. On the other hand, callus induction and somatic embryogenesis varied with different rarities of exptants. The efficiency of somatic embryogenesis was much higher, if roots were used as explants, whereas stems were more suitable for callus formation Mature somatic embryos with cotyledons were cultured on MS medium containing different plant hormones. The optimum medium for germination and growth of entire plantlet was Mso medium. The somatic embryos on MS2, MS and MS3 media germinated rapidly, but formed excessive callus from the surface of germinating embryos.     

Large-scale somatic embryogenesis and regeneration of <Emphasis Type="Italic">Panax notoginseng</Emphasis>

An efficient system for inducing somatic embryogenesis in Panax notoginseng was established using shaker flasks and bioreactor cultures; furthermore, regenerated plantlets were successfully transferred to ex vitro soil conditions. Embryogenic callus was induced from segments of adventitious roots incubated on Murashige and Skoog (MS) medium containing 1.0 mg/L 2,4-dichlorophenoxyacetic acid (2,4-D) after 5 weeks of culturing. The highest frequency (100%) of somatic embryogenesis, with a mean of 32.7 somatic embryos per callus, was obtained on embryogenic callus incubated on a medium containing 0.5 mg/L 2,4-D. To scale-up somatic embryo formation, 10 g (~1.65 × 10⁴) of early globular-stage somatic embryos were incubated in a 3 L airlift bioreactor containing 1.5 L 1/2 MS medium without plant growth regulators (PGRs) for a period of 4 weeks; these globular-stage somatic embryos then developed into cotyledonary embryos. When maintained on PGR-free medium, the cotyledonary embryos developed roots but did not develop shoots. However, when they were treated with gibberellic acid (GA₃), they continued to germinate and transformed into plantlets after 2 weeks of culture. Plantlets with well-developed shoots and roots were transferred to an autoclaved vermiculite and perlite mixture, acclimatized for a period of 3 months and successfully transferred to forest mountain soil. Following overwintering, these plants produced new growth.     

Comparison of the effects of kanamycin and geneticin on regeneration of papaya from root tissue

Kanamycin and geneticin are commonly used for the selection of neomycin phosphotransferase II (npt II) transformed plants. Since papaya tissue is sensitive to both antibiotics, it is difficult to explore their effects on the regeneration process solely based on using non-transformed tissues. Adventitious roots derived from npt II-transgenic and non-transgenic papaya shoots in vitro were used as explants in this investigation. The effects of kanamycin and geneticin on callus formation, embryogenesis, and conversion of somatic embryos to shoots were compared. Callus growth derived from npt II-transformed root explants was apparently enhanced on kanmycin within 50–200 mg l^–1 or on geneticin within 12.5–50 mg l^–1 as compared to those on antibiotic-free controls. The percentages of npt II-transformed somatic embryo-forming callus were not significantly different (16.3–18.3%) on geneticin less than 6.25 mg l^–1 and only slightly reduced (11.2–15.7%) on geneticin within 12.5–50 mg l^–1, whereas, formation of somatic embryos was strongly suppressed on kanamycin media. Conversion rates of npt II-transformed somatic embryos to shoots were not significantly different among all kanamycin or geneticin treatments. Percentages of the callus derived from non-transformed root explants were greatly reduced on the medium containing more than 25 mg l^–1 kanamycin or geneticin, and no somatic embryos formed from untransformed callus on any kanamycin or geneticin media. Our results indicated that somatic embryogenesis of callus derived from npt II-transformed root explants of papaya was strongly inhibited by kanamycin. Thus, to regenerate npt II-transformed cells from papaya root tissue, we recommend using the lower concentration geneticin (12.5–25 mg l^–1) to avoid the adverse effects of kanamycin on embryogenesis.     

The Agrobacterium rhizogenes rolC-gene-induced somatic embryogenesis and shoot organogenesis in Panax ginseng transformed calluses

Expression of the Agrobacterium rhizogenes rolC gene in Panax ginseng callus cells results in formation of tumors that are capable to form roots. The selection of non-root forming tumor clusters yielded the embryogenic 2c3 callus line, which formed somatic embryos and shoots independently of external growth factors. Although the 2c3 somatic embryos developed through a typical embryogenesis process, they terminated prematurely and repeatedly formed adventitious shoot meristems and embryo-like structures. A part of the shoots and somatic embryos formed enlarged and fasciated meristems. This is the first indication of the rolC gene embryogenic effect and, to our knowledge, the first indication that a single gene of non-plant origin can induce somatic embryogenesis in plants.     

Genetic variability of somatic embryogenesis in tissue cultures of sugar beet breeding lines

Genetic variability of callus initiation and plant regeneration has been investigated among three sugar beet genotypes. It was found that TDZ has a genotype-independent effect on callus initiation and is responsible for more than a two-fold increase in the friable callus induction rate and more than a three-fold increase in the shoot regeneration rate from this callus. Along with the genotype-independent organogenesis, regeneration from callus occasionally went through the process of somatic embryogenesis in a highly genotype-specific manner. Despite fast and uncontrollable conversion of embryos to normal plants, it was possible to select and maintain repetitive embryogenic culture without loosing regeneration and root formation capabilities. Extensive experimenting with medium composition and culture conditions resulted in an optimal medium for maintenance of repetitive embryos. Comparing with BAP, low concentrations of TDZ provide higher level of adventitious shoot formation and do not induce vitrification of tissues.     

Somatic embryogenesis in clonal neem, <Emphasis Type="Italic">Azadirachta indica</Emphasis> A. Juss. and analysis for <Emphasis Type="Italic">in vitro</Emphasis> azadirachtin production

Summary Efficient and highly reproducible induction of somatic embryogenesis was obtained in four out of seven selected clones of neem, Azadirachta indica A. Juss. This was achieved either directly from root and nodal explants or indirectly from callus cultures initiated from leaf explants excised from 1-yr-old axenic plants. Direct induction of somatic embryogenesis was achieved both from nodal and root segments within 8 wk of culture on MS1 medium without growth regulators. However, the addition of 2.3–4.5 μM thidiazuron and 0.5 μM 2,4-dichlorophenoxyacetic acid into the medium were necessary to induce somatic embryogenesis via callus phase from leaf explants. Repetitive embryogenesis was observed within 3–4 wk following transfer of somatic embryos to a plant growth regulator-free medium. When somatic embryos of nodal and root segments were left on the induction medium without subculturing, approximately 15% of the somatic embryos developed into whole plantlets after passing through a series of developmental stages. Plantlets thus produced were hardy, lush green, and acclimatized casily under greenhouse conditions. However, somatic embryos derived from leaf explants showed low conversion rates (<5%). HPLC analysis revealed no detectable levels of azadirachtin in somatic embryos.     

Somatic embryogenesis and plantlet regeneration in American ginseng (Panax quinquefolium L.)

Summary Somatic embryogenesis in American ginseng (Panax quinquefolium L.) was investigated from three explant sources (root, leaf and epicotyl) with Murashige and Skoog (MS) medium containing different growth regulators. Mature roots and leaves obtained from 3- to 5-yr-old field-grown plants, and seedling leaves and epicotyls from plantlets grownin vitro, were evaluated. From root and epicotyl explants, callus development was optimal with 3,6-dichloro-o-anisic acid (dicamba) (9.0 μM) and kinetin (KN) (5.0 μM) as the growth regulators. When these calluses were transferred after 3 mo. to dicamba alone (9.0 μM), somatic embryo formation was observed at an average frequency of 15.6% in root explants after an additional 3 mo., and 2% in epicotyl explants after an additional 6 mo. No plantlets were recovered because the embryos germinated to form shoots with no roots. From leaf explants, callus growth was optimal with α-naphthaleneacetic acid (NAA) at 10.0 μM and 2,4-dichlorophenoxyacetic acid (2,4-D) at 9.0 μM. Somatic embryos developed on this medium, with the highest frequency (40%) obtained after 3 mo. from seedling-leaf explants. Calluses on mature leaves formed somatic embryos after 7 mo. with NAA/2,4-D at an average frequency of 30%. Transfer of these somatic embryos to 6-benzyladenine/gibberellic acid (4.4/2.9 μM) promoted shoot development but no roots were observed. Up to 100% of germination was observed within 6 wk on half-strength MS salts containing activated charcoal (1%) and on NAA/2,4-D (5.0/4.5 μM) with charcoal (1%). On the latter medium, somatic embryos enlarged and frequently gave rise to new somatic embryos after a brief callusing phase. The embryos germinated through a two-stage process, involving the elongation of the root followed by the formation of a shoot. The highest recovery of ginseng plantlets from germinated embryos was 61.0%. Following transfer to potting medium and maintenance under conditions of high humidity and low light intensity, the plantlets elongated and developed new leaves. A high percentage (50%) of these plants have been acclimatized to soil.     

Plant regeneration via somatic embryogenesis in Schlumbergera truncata

Somatic embryogenesis was induced from phylloclade explants of Schlumbergera truncata cv. Russian Dancer. Callus developed on phylloclade explants and sub-cultured over a period of 16 months on MS medium containing mainly cytokinins was superior for the induction of somatic embryos compared to callus grown for a shorter time in the establishment medium. Sub-culture of callus grown in SH-or MS-based liquid media supplemented with 7.0 μM kinetin and transferred onto solid MS-based medium with either 0.45 μM 2,4-D or without hormones resulted in the differentiation into somatic embryos. SH-based medium proved better than MS-based medium when used as the first medium for the induction of somatic embryogenesis. However, somatic embryogenesis, contrary to adventitious shoot formation, was reduced when 2,4-D was included in the MS-based medium used for final transfer compared to the medium without growth regulators, indicating that a critical hormonal balance was reached. Somatic embryos developed root and shoot poles when grown on G medium. On this medium approximately 70% germination was recorded in the embryos that were differentiated earlier from the callus that was grown for a longer time in the establishment medium. This callus was grown on either SH- or MS-based medium supplemented with 7.0 μM kinetin, and then transferred after 30 days (from SH medium) onto MS medium without hormones or after 40 days (from MS medium) onto MS medium with 0.45 μM 2,4-D. Furthermore, plants from somatic embryos were successfully potted in soil and showed further growth and formation of a second set of phylloclades (secondary phylloclades). Histological studies showed that somatic embryos had no detectable connection with the mother explants and that advanced stages of somatic embryos had a contained vascular system. In addition to the normal dicotyledonous embryos, anomalous embryos with multiple cotyledons and vase-like embryos were observed. Secondary embryos were also recorded in this study.     

Direct somatic embryogenesis and shoot organogenesis from leaf explants of Primulina tabacum

An efficient propagation system via somatic embryogenesis and shoot organogenesis and plant regeneration system for endangered species Primulina tabacum Hance was established. Thidiazuron (TDZ) was the key plant growth regulator for inducing somatic embryogenesis and kinetin (KIN) and 6-benzylaminopurine (BAP) were the key cytokinins for inducing shoot organogenesis from leaf explants. TDZ combined with BAP or KIN in the induction Murashige and Skoog medium induced both somatic embryos and adventitious shoots. Leaf explants with abaxial site in contact with the medium induced less somatic embryos or adventitious shoots compared to inversely placed leaf explants and the optimum pH was 6.5–7.0. Secondary somatic embryos or adventitious shoot could be induced from primary somatic embryos using TDZ and BAP. Shoots developed adventitious roots on rooting medium containing 0.5 μM indole-3-butyric acid and 0.2 % activated carbon. Over 90 % of plantlets survived following acclimatization and transfer to potting mixture (sand:Vermiculite:limestone; 1:2:1).     

Improvement of somatic embryogenesis in highland-papaya cell suspensions

Axillary buds (2 mm) from 3-year-old Carica pubescens Lenné et Koch (highland papaya) fruit-bearing plants grown in the greenhouse were cultivated in NN-medium supplemented with different growth regulators naphthaleneacetic acid and indoleacetic acid in combination with Zeatin, benzyladenine, Kinetin and thidiazuron. Several responses were observed within 2–3 months; namely, sprouting of the preformed axillary buds, bud branching into multiple shoots, callus formation at the basal end of the explant and somatic embryogenesis in the preformed callus. Somatic embryogenesis was frequent in most of the tested growth regulator combinations, with the exception of thidiazuron which showed no effect. A much higher yield of somatic embryos could be obtained in suspensions. Somatic embryogenesis was enhanced by the occurence of adventive embryogenesis on single embryos as globular embryo clusters. This was observed in cell suspensions initially grown in a WPM-medium with 2,4-dichlorophenoxyacetic acid, or in combination with benzyladenine or zeatin, for 6 days, then maintained in a growth regulator-free medium under continuous agitation (50 RPM) on an orbital shaker for 3 months. Single cells grown in the absence of 2,4-dichlorophenoxyacetic acid did not initiate embryogenesis and de-differentiated into callus. Plantlets were recovered after transfer of mature embryos from cell suspensions into Magenta flasks. In a second subculture, adventitious embryogenesis occurred spontaneously in clusters at the globular embryo stage under the same growth conditions, yielding a high number of embryos. The culture conditions described above allowed initiation of a large number of somatic embryos directly from cell suspensions through adventive somatic embryogenesis and indirectly from callus on axillary buds.Abbreviations 2,4-d dichlorophenoxyacetic acid - CH casein enzymatic hydrolysate - BA benzyladenine - FAA formalin:acetic acid:alcohol - Glu l-glutamine - IAA indoleacetic acid - NAA naphthaleneacetic acid - NN Nitsch and Nitsch-medium (1969) - TDZ thidiazuron - SD standard deviation     

Stimulation of root and somatic embryo production in Euonymus europaeus L. by an inhibitor of polyamine biosynthesis

In vitro formation of roots and somatic embryos is obtained from cotyledon explants of a Spindle tree (Euonymus europaeus L.) cultured on two different media: a medium inducing callus formation and the production of roots, and a medium inducing callus formation, root and somatic embryo production. We studied the effects of α-difluoromethylornithine (DFMO), a specific, irreversible inhibitor of ornithine decarboxylase (ODC) on root and somatic embryo production, growth and titers of putrescine in Euonymus explants and explant-derived calli. Early changes in putrescine levels were detected in both cultures before the visible emergence of roots or somatic embryos. DFMO rapidly inhibited putrescine accumulation and growth in non-embryogenic calli and highly stimulated rooting activity. DFMO partially inhibited putrescine accumulation in embryogenic calli. This inhibition had no effects on callus growth but significantly reduced the time of emergence of roots and highly stimulated somatic embryo production. The relationship among putrescine, putrescine metabolism, growth, root and somatic embryo formation is discussed.     

In vitro morphogenic response in cotyledon explants of Semecarpus anacardium L.

Three different morphogenic responses??caulogenesis, direct somatic embryogenesis, and callusing??were noted in cotyledon explants of Semecarpus anacardium L. cultured in woody plant medium (WPM) containing thidiazuron (TDZ). Thidiazuron, at all concentrations tested, induced organogenic as well as embryogenic responses. The organogenic buds differentiated to shoots and the embryogenic mass (EM) gave rise to globular embryos which differentiated up to cotyledon-stage embryos on repeated culture in growth regulator (GR)-free WPM medium containing 0.2% activated charcoal after the removal of TDZ. The organogenic and embryogenic responses were optimal in 9.08???M TDZ after the removal of TDZ. Elongated shoots rooted in half-strength liquid WPM medium with 2.46???M indole butyric acid. Plants were successfully acclimatized and transferred to soil. Histological studies confirmed the direct origin of the organogenic buds from the cotyledon explants. The EMs produced somatic embryos on repeated culture in charcoal incorporated GR-free medium. Morphogenic callus formation from the cotyledon explants was also noted. This callus on repeated culture in WPM medium with charcoal differentiated into somatic embryos. Repetitive somatic embryogenesis was evident from direct and indirectly formed primary embryos. The somatic embryos did not convert into plantlets, though sporadic germination of embryos was observed through the emergence of roots.     

Somatic embryogenesis and bud formation from immature embryos of buckwheat (Fagopyrum esculentum Moench.)

Immature embryos of Fagopyrum esculentum cv. Pennquad were isolated from field-grown plants and cultured on media containing a high benzylaminopurine to indole-3-acetic acid ratio. Part of the embryos were grown in the presence of 2,4-dichlorophenoxyacetic acid and kinetin for the first 5 days, and then transferred to benzylaminopurine + indole-3-acetic acid medium. From callus tissues developed on hypocotyls and cotyledons, 3 types of tissue were selected in later subcultures: (a) callus tissue strains that produced buds, (b) embryogenic tissue, and (c) unorganized callus tissue, lacking any organogenic capacity. Pretreatment with 2,4-dichlorophenoxyacetic acid increased the number of explants which gave rise to bud forming and embryogenic tissue, but was not essential for morphogenesis. Somatic embryogenesis was confirmed by histological observation. Plantlets could be easily obtained by inducing adventitious roots on shoots, but spontaneous root development in somatic embryos was infrequent.Abbreviations BAP benzylaminopurine - IAA indole-3-acetic acid - 2,4-D dichlorophenoxyacetic acid - IBA indole-3-butyric acid     

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.     

Stimulation of root and somatic embryo production in Euonymus europaeus L. by an inhibitor of polyamine biosynthesis

In vitro formation of roots and somatic embryos is obtained from cotyledon explants of a Spindle tree (Euonymus europaeus L.) cultured on two different media: a medium inducing callus formation and the production of roots, and a medium inducing callus formation, root and somatic embryo production. We studied the effects of -difluoromethylornithine (DFMO), a specific, irreversible inhibitor of ornithine decarboxylase (ODC) on root and somatic embryo production, growth and titers of putrescine in Euonymus explants and explant-derived calli. Early changes in putrescine levels were detected in both cultures before the visible emergence of roots or somatic embryos. DFMO rapidly inhibited putrescine accumulation and growth in non-embryogenic calli and highly stimulated rooting activity. DFMO partially inhibited putrescine accumulation in embryogenic calli. This inhibition had no effects on callus growth but significantly reduced the time of emergence of roots and highly stimulated somatic embryo production. The relationship among putrescine, putrescine metabolism, growth, root and somatic embryo formation is discussed.