Microbial hazards in plant tissue and cell cultures

Summary A wide range of microorganisms (filamentous fungi, yeasts, bacteria, viruses and viroids) and micro-arthropods (mites and thrips) have been identified as contaminants in plant tissue cultures. Contaminant may be introduced with the explant, during manipulations in the laboratory or by micro-arthropod vectors. Contaminants may express themselves immediately or can remain latent for long periods of time. This often makes it difficult to identify the source of contamination. Disinfection protocols have now been developed for a wide range of plant species including those infected with viruses/viroids or endophytic bacteria. They may include the selection of pathogen-free donor plants or donor plant treatments such as thermotherapy. Also microbiological quality assurance systems (e.g. Hazard Analysis Critical Control Point; HACCP procedures) have been adapted to the needs of commercial plant tissue culture laboratories. These are aimed at, preventing the introduction of pathogens, into tissue cultures at establishment and in the laboratory. In established in vitro cultures preventative strategies have proved to be essential, since it is extremely difficult to eliminate environmental bacterial and fungal contaminants using, antibiotics and fungicides. In many cases anti-microbial treatments only inhibit contaminants and low levels of contamination persist. In particular, the use of antibiotics against Gram-negative bacteria (including plant pathogenic bacteria and Agrobacterium tumefaciens vector systems used in genetic engineering) has been shown frequently to be extremely difficult or unsuccessful. Detection of latent contamination may involve the use of general and semi-selective microbial growth media or serological and PCR-based molecular techniques for specific pathogens. However, it is often difficult to detect low numbers of latent bacterial contaminants (e.g. levels present following antibiotic treatment or when acidified plant media are used). This poses a particular risk in the production of transgenic plants where the elimination or detection of Agrobacterium tumefaciens-based vector systems cannot be guaranteed with the currently available methodologies. Recent research has also shown that there is a risk of the transmission of human pathogens in plant tissue cultures.     

Expression of the Hypersensitive Response-assisting Protein in <Emphasis Type="Italic">Arabidopsis</Emphasis> Results in Harpin-dependent Hypersensitive Cell Death in Response to <Emphasis Type="Italic">Erwinia carotovora</Emphasis>

Active defense mechanisms of plants against pathogens often include a rapid plant cell death known as the hypersensitive cell death (HCD). Hypersensitive response-assisting protein (HRAP) isolated from sweet pepper intensifies the harpin_Pss-mediated HCD. Here we demonstrate that constitutive expression of the hrap gene in Arabidopsis results in an enhanced disease resistance towards soft rot pathogen, E. carotovora subsp. carotovora. This resistance was due to the induction of HCD since different HCD markers viz. Athsr3, Athsr4, ion leakage, H₂O₂ and protein kinase were induced. One of the elicitor harpin proteins, HrpN, from Erwinia carotovora subsp. carotovora was able to induce a stronger HCD in hrap-Arabidopsis than non-transgenic controls. To elucidate the role of HrpN, we used E. carotovora subsp. carotovora defective in HrpN production. The hrpN⁻ mutant did not induce disease resistance or HCD markers in hrap-Arabidopsis. These results imply that the disease resistance of hrap-Arabidopsis against a virulent pathogen is harpin dependent.     

Endophytic Pseudomonasspp. populations of pathogen-infected potato plants analysed by 16S rDNA- and 16S rRNA-based denaturating gradient gel electrophoresis

The diversity of abundant and metabolically active pseudomonads in potato plants was analysed using a culture-independent approach. The effect of two plant varieties, Agria and Bionta, as well as the presence of a plant pathogen Erwinia carotovora ssp. atroseptica on this bacterial group was tested. A combination of Pseudomonas-specific PCR, DGGE analysis, cloning and sequencing of partial 16S rDNA genes was performed using DNA and RNA extracted from potato stem tissue. Sequence analysis revealed a high species diversity, with the most prominent ones being Pseudomonas stutzeri and Pseudomonas gingeri. Some species showed high rRNA contents indicating high metabolic activity. Both, highly abundant and metabolically active Pseudomonaspopulations were more affected by the plant genotype than by the presence of E. carotovora.     

Establishment of papaya banker plant system for parasitoid, Encarsia sophia (Hymenoptera: Aphilidae) against Bemisia tabaci (Hemiptera: Aleyrodidae) in greenhouse tomato production

The silverleaf whitefly, Bemisia tabaci biotype B (Gennadius) (Hemiptera: Aleyrodidae), is a key pest of tomato (Solanum lycopersicum L.) and other vegetable crops worldwide. To combat this pest, a non-crop banker plant system was evaluated that employs a parasitoid, Encarsia sophia (Girault & Dodd) (Hymenoptera: Aphelinidae) with whitefly, Trialeurodes variabilis (Quaintance) (Hemiptera: Aleyrodidae), as an alternative host for rearing and dispersal of the parasitoid to the target pest. (a) Multi-choice and no-choice greenhouse experiments were conducted to determine host specificity of T. variabilis to papaya (Carica papaya L.) and three vegetable crops including tomato, green bean (Phaseolus vulgaris L.), and cabbage (Brassica oleracea L.). The result showed that papaya was an excellent non-crop banker plant for supporting the non-pest alternative host, T. variabilis, whose adults had a strong specificity to papaya plants for feeding and oviposition in both multi-choice and no-choice tests. (b) The dispersal ability of E. sophia was investigated from papaya banker plants to tomato and green bean plants infested with B. tabaci, as well as to papaya control plants infested with T. variabilis; and (c) the percent parasitism by E. sophia on T. variabilis reared on papaya plants and on B. tabaci infested on tomato plants was also evaluated. These data proved that E. sophia was able to disperse at least 14.5 m away from papaya plants to target tomato, bean or papaya control plants within 48–96 h. Furthermore, E. sophia was a strong parasitoid of both T. variabilis and B. tabaci. There was no significant difference in percent parasitism by E. sophia on T. variabilis (36.2–47.4%) infested on papaya plants or B. tabaci (29–45.9%) on tomato plants. Thus, a novel banker plant system for the potential management of B. tabaci was established using papaya as a non-crop banker plant to support a non-pest alternative host, T. variabilis for maintaining the parasitoid to control B. tabaci. The established banker plant system should provide growers with a new option for long-term control of B. tabaci in greenhouse vegetable production. Ongoing studies on the papaya banker plant system are being performed in commercial greenhouses.     

Ecology of Microbial Saprophytes and Pathogens in Tissue Culture and Field-Grown Plants: Reasons for Contamination Problems In Vitro

This review compares published surveys of microbial populations in plant tissue and cell cultures with the microbial saprophytes and pathogens found on field grown plants and microbial populations in the laboratory environment. From this comparison and the measured reduction in contamination after improvements in working practices in the laboratory, conclusions can be drawn about the importance of the explant and the laboratory as sources of contamination.

Mechanisms of pathogenicity in vitro are described to explain why bacteria, fungi, and yeasts that are not pathogenic to plants in the field become pathogens in plant tissue cultures. Conversely, plant metabolism and its effect on the tissue culture environment are described to explain why prokaryotes, viruses, and viroids that cause disease in the field can stay latent in vitro.

Detection methods for latent contaminants in plant tissue cultures are summarized, and the strategies and methods for prevention or treatment of contamination are discussed.     

Structure and regulation of the Erwinia carotovora subspecies carotovora SCC3193 cellulase gene celV1 and the role of cellulase in phytopathogenicity

The ceIV1 gene encoding a secreted cellulase (CelV1) of Erwinia carotovora subsp. carotovora SCC3193 was cloned and its nucleotide sequence determined. The gene contains an open reading frame of 1511 by and codes for an exported protein of 504 amino acids. The predicted amino acid sequence of Ce1V1 was highly similar to that of CeIV of another E. c. subsp. carotovora strain SCRI193 but completely different from the previously characterized cellulase, CelS, of the strain SCC3193. Gene fusions to the lacZ reporter were employed to characterize the regulation of celV1 and celS. Both genes are coordinately induced in a growth phase-dependent manner and are catabolite repressed. Expression of celV1 but not celS was stimulated by plant extracts. The celS gene was expressed at a much lower level than celV1 under all conditions tested. Inactivation of the celV1 gene in E. c. subsp. carotovora strain SCC3193 by marker exchange showed that celV1 encodes the major cellulase of strain SCC3193, as the resulting mutant strain SCC6001 was devoid of cellulase activity. Ce1Vl mutants exhibited reduced virulence suggesting that CelV1, although not absolutely required for pathogenicity, enhances the ability of strain SCC3193 to macerate plant tissue. Inactivation of the celS gene in the celV1 mutant did not lead to any further decrease in virulence.     

The production of callus capable of plant regeneration from immature embryos of numerous Zea mays genotypes

In the summer of 1983, immature embryos from 101 selfed inbred lines and germplasm stocks of Zea mays L. were examined for their ability to produce callus cultures capable of plant regeneration (regenerable cultures) using a medium with which some limited success had previously been obtained. Forty-nine of the genotypes (49%) produced callus which visually appeared similar to callus previously cultured and shown to be capable of plant regeneration. After five months, 38 of these genotypes were alive in culture and plants were subsequently regenerated from 35 (92%) of them. No correlation was observed between plant regeneration and callus growth rate, the vivipary mutation (genes vp1, 2, 5, 7, 8 and 9), or published vigor ratings based on K⁺ uptake by roots. When F₁ hybrid embryos were cultured, 97% of the hybrids having at least one regenerable parent also produced callus capable of plant regeneration. No regenerable cultures were obtained from any hybrid lacking a parent capable of producing a regenerable callus culture.In the summer of 1984, immature embryos from 218 additional inbred lines and germplasm stocks were plated and examined for their ability to produce regenerable callus cultures on media containing altered micronutrient concentrations, 3,6-dichloro-o-anisic acid (dicamba), glucose, and elevated levels of vitamin-free casamino acids and thiamine. Of these genotypes 199 (91%) produced callus that was regenerable in appearance. In the 1984 study, plant regeneration was noted in many commercially important inbreds, including B73, Mo17, B84, A632, A634, Ms71, W117, H99³H95 and Cm105. Thus tissue-culture techniques are now available to obtain callus cultures capable of plant regeneration from immature embryos of most maize genotypes.Abbreviations trade names 2,4-D 2,4-dichlorophenoxyacetic acid - dicamba 3,6-dichloro-o-anisic acid     

Microbial populations,fungal species diversity and plant pathogen levels in field plots of potato plants expressing theBacillus thuringiensis var.tenebrionis endotoxin

The environmental release of genetically engineered (transgenic) plants may be accompanied by ecological effects including changes in the plant-associated microflora. A field release of transgnic potato plants that produce the insecticidal endotoxin ofBacillus thuringiensis var.tenebrionis (Btt) was monitored for changes in total bacterial and fungal populations, fungal species diversity and abundance, and plant pathogen levels. The microflora on three phenological stages of leaves (green, yellow and brown) were compared over the growing season (sample days 0, 21, 42, 63 and 98) for transgenic potato plants, commercial Russet Burbank potato plants treated with systemic insecticide (Di-Syston) and commercial Russet Burbank potato plants treated with microbialBtt (M-Trak). In addition, plant and soil assays were performed to assess disease incidence ofFusarium spp.,Pythium spp.,Verticillium dahliae, potato leaf roll virus (PLRV) and potato virus Y (PVY). Few significant differences in phylloplane microflora among the plant types were observed and none of the differences were persisent. Total bacterial populations on brown leaves on sample day 21 and on green leaves on sample day 42 were significantly higher on the transgenic potato plants. Total fungal populations on gree leaves on sample day 63 were significantly different among the three plant types; lowest levels were on the commerical potato plants treated with systemic insecticide and highest levels were on the commercial potato plants treated with microbialBtt. Differences in fungal species assemblages and diversity were correlated with sampling dates, but relatively consistent among treatments.Alternaria alternata, a common saprophyte on leaves and in soil and leaf litter, was the most commonly isolated fungus species for all the plant treatments. Rhizosphere populations of the soilborne pathogensPythium spp.,Fusarium spp. andV. dahliae did not differ between the transgenic potato plants and the commercial potato plants treated with systemic insecticide. The incidence of tuber infection at the end of the growing season by the plant pathogenV. dahliae was highest for the transgenic potato plants but this difference was related to longer viability of the transgenic potato plants. This difference in longevity between the transgenic potato plants and the commercial + systemic insecticide potato plants also made comparison of the incidence of PVY and PLRV problematic. Our results indicate that under field conditions the microflora of transgenicBtt-producing potato plants differed minimally from that of chemically and microbially treated commerical potato plants.     

Isolation and Preliminary Characterization of Cryptic Plasmids from Erwinia carotovora

Of the fifty-two Erwinia carotovorastrains studied, sixteen were found to contain extrachromosomal DNA (plasmids) from 2.5 to 129 kbp in size. Some E. carotovorastrains bore two to five different plasmids. Experiments showed that the cryptic plasmids of erwinia are not responsible for their resistance to antibiotics and are not involved in the synthesis of macromolecular colicin-like carotovoricins. At the same time, one of the E. carotovorastrains, 13A, augmented the production of carotovoricin after curing from one of its plasmids, the 47.7-kbp pCA 6-2. Three E. carotovorasubsp.carotovorastrains and one E. carotovorasubsp.atrosepticastrain contained large 129-kbp plasmids, which may play a role in the ecology of phytopathogenic pectinolytic erwinia.     

Callus formation and plant regeneration from tubercles of Coryphantha elephantidens (Lem.) Lem.

Summary Callus cultures were established from pith tissue of Coryphantha elephantidens (Lem.) Lem. on Murashige and Skoog (MS) basal medium supplemented with 9.05 μM 2,4-dichlorophenoxyacetic acid (2,4-D) and 2.3 μM kinetin. Highest shoot regeneration frequency was observed on a medium containing 6.9 μM kinetin and 2.3 μM 2,4-D under 30 μE m⁻² s⁻¹ light intensity with a 16-h photoperiod. Calluses retained organogenic potential throughout several passages of subculture (18 mo.). Shoots were rooted on MS medium without plant growth regulators. All (100%) plantlets transplanted to soil survived acclimatization. Regenerated plants showed good overall growth and were morphologically similar to the mother plants.     

Evaluation of formulations of Bacillus licheniformis for the biological control of tomato gray mold caused by Botrytis cinerea

Bacillus licheniformis N1, which has previously exhibited potential as a biological control agent, was investigated to develop a biofungicide to control the gray mold of tomato caused by Botrytis cinerea. Various formulations of B. licheniformis N1 were developed using fermentation cultures of the bacteria in Biji medium, and their ability to control gray mold on tomato plants was evaluated. The results of pot experiments led to the selection of the wettable powder formulation N1E, based on corn starch and olive oil, for evaluation of the disease control activity of this bacterium after both artificial infection of the pathogen and natural disease occurrence under production conditions. In plastic-house artificial infection experiments, a 100-fold diluted N1E treatment was found to be the optimum biofungicide spray formulation. This treatment resulted in the significant reduction of symptom development when N1E was applied before Bo. cinerea infection, but not after the infection. Both artificial infection experiments in a plastic house and natural infection experiments under production conditions revealed that the N1E significantly reduced disease severity on tomato plants and flowers. The disease control value of N1E on tomato plants was 90.5% under production conditions, as compared to the 77% conferred by a chemical fungicide, the mixture of carbendazim and diethofencarb (1:1). The prevention of flower infection by N1E resulted in increased numbers of tomato fruits on each plant. N1E treatment also had growth promotion activity, which showed the increased number of tomato fruits compared to fungicide treatment and non-treated control and the increased fruit size compared the non-treated control under production conditions. This study suggests that the corn starch-based formulation of B. licheniformis developed using liquid fermentation will be an effective tool in the biological control of tomato gray mold.     

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.     

In vitro chili pepper biotechnology

Summary Chili pepper is an important horticultural crop that can surely benefit from plant biotechnology. However, although it is a Solanaceous member, developments in plant cell, tissue, and organ culture, as well as on plant genetic transformation, have lagged far behind those achieved for other members of the same family, such as tobacco (Nicotiana tabacum), tomato (Lycopersicon esculentum), and potato (Solanum tuberosum), species frequently used as model systems because of their facility to regenerate organs and eventually whole plants in vitro, and also for their ability to be genetically engineered by the currently available transformation methods. Capsicum members have been shown to be recalcitrant to differentiation and plant regeneration under in vitro conditions, which in turn makes it very difficult or inefficient to apply recombinant DNA technologies via genetic transformation aimed at genetic improvement against pests and diseases. Some approaches, however, have made possible the regeneration of chili pepper plants from in vitro-cultured cells, tissues, and organs through organogenesis or embryogenesis. Anther culture has been successfully applied to obtain haploid and doubledhaploid plants. Organogenic systems have been used for in vitro micropropagation as well as for genetic transformation. Application of both tissue culture and genetic transformation techniques have led to the development of chili pepper plants more resistant to at least one type of virus. Cell and tissue cultures have been applied successfully to the selection of variant cells exhibiting increased resistance to abiotic stresses, but no plants exhibiting the selected traits have been regenerated. Production of capsaicinoids, the hot principle of chili pepper fruits, by cells and callus tissues has been another area of intense research. The advances, limitations, and applications of chili pepper biotechnology are discussed.     

Erwinia soft rot resistance of potato cultivars expressing antimicrobial peptide tachyplesin I

Tachyplesin I is a 2.3 kDa antimicrobial peptide isolated from Southeast Asian horseshoe crabs. Bacterial suspensions containing 1×10⁶ colony-forming units/ml of six isolates of pectolytic Erwinia spp., the causal pathogens of potato soft rot and blackleg, were killed in vitro by 1.4 to 11.1 g/ml of tachyplesin I. In an attempt to enhance resistance to Erwinia spp., each of the potato cultivars Bintje, Karnico and Kondor were transformed with two gene constructs encoding different precursor tachyplesin I proteins under the control of a cauliflower mosaic virus 35S promotor. Northern and western blot analysis showed that the tachyplesin I gene was expressed in transgenic plants. Small tubers of 17 transgenic clones were screened twice for soft rot resistance to Erwinia carotovora ssp. atroseptica. Under aerobic or anaerobic conditions, transgenic clones showed slightly less rot than control tubers.Abbreviations AP acidic carboxyl terminal polypeptide - Eca Erwinia carotovora ssp. atroseptica - Ecc E. carotovora ssp. carotovora - Ech E. chrysanthemi - IF intercellular fluid - SP signal peptide - TPNI (tpnI) tachyplesin I     

Detection of mycoplasma contamination in tissue cultures by fluorescence microscopy

Summary The in situ staining method of Chen (1977) for the detection of mycoplasma contaminants in tissue cultures was tested in cultures of human skin fibroblasts after controlled contamination with Mycoplasma arginini. It is concluded that this method is reliable only at infection rates of 100% or higher, i.e., at one mycoplasma or more per tissue-culture cell.     

Goldenseal (<Emphasis Type="Italic">Hydrastis canadensis</Emphasis> L.): <Emphasis Type="Italic">In vitro</Emphasis> regeneration for germplasm conservation and elimination of heavy metal contamination

Summary Hydrastis canadensis L. (Goldenseal) is an endangered medicinal plant used in the treatment of many ailments, such as gastrointestinal disturbances, urinary disorders, hemorrhage, skin, mouth and eye infections, and inflammation. Commercial preparations of wild-harvested goldenseal were found to contain heavy metal contaminants including aluminum (848 μgg⁻¹), cadmium (0.4μgg⁻¹), lead (18.7μgg⁻¹), and mercury (0.1 μgg⁻¹). As well, goldenseal is an endangered species listed in the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES) Appendix II. Therefore, the practice of wild-harvest is actually decimating natural populations of goldenseal and endangering its genetic diversity. In vitro propagation protocol by tissue culture was developed for producing high-quality tissues of goldenseal. Significantly more de novo regeneration was induced on stem explants of 3-mo.-old plants cultured on a medium containing 10 μM 6-benzylaminopurine (BA) (22 regenerants per explant) than any other treatment. Subculture of the regenerants on a medium devoid of growth regulators resulted in the development of complete plants that were acclimatized and thrived in standard greenhouse conditions. The plants regenerated in vitro contained the lowest levels of heavy metals. The findings of this study provide the first evidence that heavy metal contaminants bioaccumulate in goldenseal tissues and also provide a method for germplasm conservation, mass multiplication, and production of goldenseal tissues free from abiotic contamination.     

Agrobacterium rhizogens mediated transformation of Rauvolfia serpentina: Regeneration and alkaloid synthesis

Shoot cultures of Rauvolfia serpentina infected with Agrobacterium rhizogenes 15834 produced tumourous tissue at the site of injection, which eventually developed callus with hairy roots. Sporadic shoot formation occurred from the hairy roots. The shoots were grown to maturity in the green house. The mature transformed plants (RST) showed distinct variations in their physiological characteristics. The flowers of the transformed plants were more delicate and less pigmented when compared to the flowers of the mature normal plants. The roots of the transformed plants were hairy with a number of lateral branches, whereas the roots of the normal plant had very few lateral branches. The biomass of the transformed plant was 86.39 g/plant (fresh wt), significantly higher than the normal plant which was 77.3 g/plant (fresh wt). The total alkaloid content in the mature transformed plant (0.073 g per plant) was similar to the normal plant (0.078 g per plant), although the hairy roots contained little alkaloid.Abbreviations MS Murashige & Skoog's basal medium - MLS modified Linsmaier & Skoog's basal medium - BA benzyladenine - NAA naphthalene acetic acid - TLC thin layer chromatography - HPLC high performance liquid chromatography     

The Sweet Pepper Ferredoxin-Like Protein (pflp) Conferred Resistance Against Soft Rot Disease in Oncidium Orchid

Genetic engineering to date has not been used to introduce disease resistance genes into the orchid gene pool. The ferredoxin-like protein gene originally isolated from sweet pepper is thought to function as a natural defense against infection due to its antimicrobial properties. Hence it was reasoned that introduction of this gene might produce Oncidium plants resistant to Erwinia carotovora, the causal agent for the soft rot disease. An expression vector containing sweet pepper ferredoxin-like protein (pflp) cDNA, hph and gusA coding sequence was successfully transformed into protocorm-like bodies (PLBs) of Oncidium orchid, using Agrobacterium tumefaciens strain EHA105. A total of 17 independent transgenic orchid lines was obtained, out of which six transgenic lines (-glucuronidase (GUS) positive) were randomly selected and confirmed by Southern, northern and western blot analyses. A bioassay was conducted on the transgenic lines. Transgenic plants showed enhanced resistance to E. carotovora, even when the entire plant was challenged with the pathogen. Our results suggest that pflp may be an extremely useful gene for genetic engineering strategies in orchids to confer resistance against soft rot disease.     

Steroidal glycoalkaloids in cell and shoot teratoma cultures ofSolanum dulcamara

Bittersweet (Solanum dulcamara L., Solanaceae) is of interest as a source of steroidal alkaloids for the commercial production of hormones. Since glycoalkaloid production is positively correlated to differentiation, tumor and teratoma cultures of the soladulcidine chemotype were established by transformation withAgrobacterium tumefaciens. A newly developed HPLC-system, which allowed separation and sensitive quantitation of the glycoalkaloids soladulcidine-tetraoside, solamargine and solasonine, was used to analyse glycoalkaloid profiles in plants and cultures. Tumors and teratoma were charcterized by a shift in their alkaloid pattern from soladulcidine tetraoside to the solasodine glycosides solamargine and solasonine. Shoot teratoma showed a total glycoalkaloid content of 1% dw, which is about fivefold higher than in the source plant. A regenerated plant retained the altered alkaloid spectrum; the levels, however, equalled those of the source plant. From the alteration of alkaloid pattern in the transformed cultures suggestions can be made concerning the biosynthetic pathway. Completion of the biosynthesis of the aglycone is likely to be complete before glycosylation occurs.