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A major limitation of crop biotechnology and breeding is the lack of efficient molecular technologies for precise engineering of target genomic loci. While transformation procedures have become routine for a growing number of plant species, the random introduction of complex transgenenic DNA into the plant genome by current methods generates unpredictable effects on both transgene and homologous native gene expression. The risk of transgene transfer into related plant species and consumers is another concern associated with the conventional transformation technologies. Various approaches to avoid or eliminate undesirable transgenes, most notably selectable marker genes used in plant transformation, have recently been developed. These approaches include cotransformation with two independent T-DNAs or plasmid DNAs followed by their subsequent segregation, transposon-mediated DNA elimination, and most recently, attempts to replace bacterial T-DNA borders and selectable marker genes with functional equivalents of plant origin. The use of site-specific recombination to remove undesired DNA from the plant genome and concomitantly, via excision-mediated DNA rearrangement, switch-activate by choice transgenes of agronomical, food or feed quality traits provides a versatile “transgene maintenance and control” strategy that can significantly contribute to the transfer of transgenic laboratory developments into farming practice. This review focuses on recent reports demonstrating the elimination of undesirable transgenes (essentially selectable marker and recombinase genes) from the plant genome and concomitant activation of a silent transgene (e.g., a reporter gene) mediated by different site-specific recombinases driven by constitutive or chemically, environmentally or developmentally regulated promoters. These reports indicate major progress in excision strategies which extends application of the technology from annual, sexually propagated plants towards perennial, woody and vegetatively propagated plants. Current trends and future prospects for optimization of excision-activation machinery and its practical implementation for the generation of transgenic plants and plant products free of undesired genes are discussed.
The dhlA gene of Xanthobacter autotrophicus encodes dehalogenase that hydrolyzes dihaloalkanes such as 1,2-dichloroethane (DCE) into cytotoxic halogenated alcohol and an inorganic halide. As plants do not contain dehalogenase activity, they grow normally in the presence of DCE. We tested the transgenic expression of the bacterial dhlA gene in rice as a conditional negative selection marker. We developed 24 transgenic callus lines containing dhlA gene driven by rice actin-1 promoter, verified the expression of dhlA by Northern blot analysis, and subjected these transgenic lines to DCE treatment. We found that, while untransformed callus (Nipponbare) was unaffected by the DCE treatment, most of the transformed lines displayed symptoms of toxicity, indicating that dhlA is an effective conditional negative selection marker gene for rice in vitro cultures.
Callus cultures derived from leaf segments of chrysanthemum cultivar ‘Snow Ball’ which was susceptible to Septoria obesa were successfully used for in vitro selection for resistance to this pathogenic fungus. Resistant cell lines were selected by culturing callus on growth medium containing various concentrations of S. obesa filtrate. Resistant calluses obtained after two cycles (30 d each cycle) of selection were used for plant regeneration. About 30% of the plants regenerated from the resistant calluses and 70–80% of the plants raised from cuttings had acquired considerable resistance against the pathogen in the field. No phenotypic variation was observed in the selected regenerates.
Seashore paspalum (Paspalum vaginatum Swartz) is a salt tolerant, fine textured turfgrass used on golf courses in coastal, tropical, and subtropical regions. A callus induction and plant regeneration protocol for this commercially important turfgrass species has been developed. Induction of highly regenerable callus with approximately 400 shoots per cultured immature inflorescence (1 cm in length) was achieved by culturing 0.2 cm segments on media with 3 mg l−1 3,6-dichloro-2-methoxybenzoic acid (dicamba) and 0.1 or 1.0 mg l−1 benzylaminopurine (BA). A multifactorial experiment demonstrated the combination of 3 mg l−1 dicamba and 1.0 mg l−1 BA for induction of callus resulted in 12 times higher plant regeneration frequency compared to 3 mg l−1 2,4-dichlorophenoxyacetic acid (2,4-D) alone or ten times higher plant regeneration frequency than the combination of 3 mg l−1 2,4-D and 1.0 mg l−1 BA. These results are expected to support the development of a genetic transformation protocol for seashore paspalum.
Somatic embryogenesis is an in vitro clonal propagation method with potential to contribute to the improvement of cacao varieties. Before using this technology for commercial production, it is essential that somatic embryogenesis-derived plants be tested in field conditions. Therefore, we established a field test at Union Vale Estate, Saint Lucia. Thirty- to 50-yr-old trees were selected for clonal propagation as potentially high yielding based on local farmers observations. Clonal plants were propagated in vitro from immature flowers by embryogenesis and micropropagation. Multiple plants from nine genotypes were acclimated to greenhouse conditions then returned to Saint Lucia and planted in a field. Orthotropic rooted cuttings and locally propagated open pollinated seedlings were also planted for a total of 214 trees. Growth data were collected every 4–6 mo. including: stem diameter, stem height, length of the longest jorquette branch, number of jorquette branches, and dates of first flowering and fruiting. At 4.5 yr after planting in the field there were no major differences in all growth parameters among the propagation methods evaluated with exception of the orthotropic rooted cuttings. Trees grown from seeds were slightly taller then trees propagated by the other methods. Trees propagated as orthotropic rooted cuttings exhibited smaller average stem diameters, shorter stem heights to the jorquette, and shorter jorquette branches. We concluded that somatic embryo-derived plants demonstrated normal phenotypes in field conditions and have growth parameters similar to plants propagated by traditional methods.
Podophyllum peltatum is an important medicinal plant that produces podophyllotoxin (PTOX) with anti-cancer properties. We established the embryogenic cell and adventitious root culture systems in P. peltatum and analyzed PTOX production. For the growth of embryogenic cell clumps in shake flask culture, the most efficient concentration of 2,4-dichloroacetic acid (2,4-D) was 6.78 μM, and the growth of embryogenic cell clumps was 15.9-fold increased in Murashige and Skoog MS liquid medium with 6.78 μM 2,4-D after 3 wk of culture. To induce adventitious roots, half-strength MS medium showed the best results for adventitious root induction compared to full strength MS medium and MS medium lacking NH4NO3. Optimal indole-3-butyric acid concentration for adventitious root formation was 14.78 μM. In liquid medium, the frequency of adventitious root formation from root segments was 87.7% and the number of laterally formed adventitious roots was 22.3 per segment. PTOX production in embryogenic cells and adventitious roots was confirmed by liquid chromatography and electro-spray ionization–tandem mass spectrometry analysis. High-performance liquid chromatography analysis revealed that adventitious roots contained higher PTOX than embryogenic cell clumps. Elicitor treatment (20 μM methyl jasmonate) strongly enhanced the production of PTOX in both embryogenic cell clumps and adventitious roots. This observation suggests that both embryogenic cell and adventitious root culture can be adopted to produce PTOX.
Berberis buxifolia Lam., known as “Calafate”, is a plant native to Argentina that exhibits antimicrobial activity. This biological activity is attributed to the isoquinoline alkaloid berberine. The aim of this research was to test the antimicrobial properties of different extracts of this species, taking berberine as the reference molecule, and to examine if the expression of bacterial multidrug resistance (MDR) efflux pumps could be responsible for possible resistance mechanisms. To this end, a wild-type and a mutant strain of Staphylococcus aureus with a defective MDR efflux pump were used and the minimum inhibitory concentrations of the extracts were determined. The studies were carried out with infusions of in vivo shoots and “Calafate” commercial tea, as well as with the media derived from shoot cultures incubated with different plant growth regulators (thidiazuron, picloram, and jasmonic acid). As far as antimicrobial activity is concerned, all the extracts tested were significantly more effective than berberine standard. “Calafate” commercial tea and shoot tea had inhibitory concentrations similar to the one observed for ampicillin standard. The media from the shoot cultures, however, were significantly more effective than all the others, particularly the one derived from jasmonic acid, suggesting the presence of compounds that could be acting synergistically with berberine. There were no differences in antimicrobial activity against the wild-type and the mutant S. aureus; no definite conclusions could be drawn concerning the relationship between MDR pumps and possible pathogen resistance to extracts of B. buxifolia.
Hairy root cultures were induced by inoculating cotyledonary leaves and hypocotyl segments from two cotton species, Gossypium hirsutum and Gossypium barbadense, with Rhizobium rhizogenes 15834. For both species, more hairy roots formed on inoculation sites on cotyledonary leaves than on hypocotyls. The addition of sucrose to basal Murashige–Skoog media increased the frequency of hairy root formation, whereas the addition of naphthalene acetic acid (0.54 μM) did not. After transfer to a liquid culture, hairy root growth was very rapid. After 3 wk in liquid culture, both cotton species produced gossypol, a di-sesquiterpene secondary metabolite with known anticancer activity, and two related methylated derivatives. Most (60–95%) gossypol produced by cultures was retained within the hairy root tissues, but some was found in the media. The average gossypol level observed among 96 different cultures was 15 mg/g of dry culture mass; however, some cultures produced >40 mg/g of dry culture mass. Variation in gossypol levels was greater for cultures arising from different transformation events than for multiple subclones of a single transformant. The high level of gossypol production attained by most of these cultures suggests that they will be valuable for studying the biochemical and molecular aspects of gossypol biosynthesis, capable of producing large amounts of gossypol and related compounds, and useful for generating modified forms of gossypol (e.g., radio-labeled gossypol) for understanding bioactivity mechanisms.
Plant cell culture provides an alternative means for producing secondary metabolites. In this study, experiments were carried out to study the impact of several parameters, independently and in combination, on the stimulation of menthol production in the cell suspension culture of Mentha piperita. Callus was obtained from leaf segments of in vitro grown plantlets on Murashige and Skoog (MS) medium supplemented with 0.2 mg l−1of 2,4-dichlorophenoxy acetic acid to initiate cell suspension culture. This culture was maintained in half-strength MS medium supplemented with 0.2 mg l−1of 2,4-dichlorophe-noxy acetic acid at 15 d interval and used for further studies. Precursor feeding alone, i.e., menthone, at 35 μM concentration showed slightly improved productivity. γ-Cyclodextrin alone at 60 μM concentration and in combination with menthone feeding at 35 μM increased menthol yield up to 92 and 110 mg l−1 in comparison to 77 mg l−1 of control culture. Synergistic potentiation effect of menthone feeding at 35 μM and γ-cyclodextrin at 60 μM treatment followed by in situ adsorption with RP-8 also showed potential stimulation of menthol production in M. piperita cell culture. Fungal elicitor treatment showed enhanced production level up to 140.8 mg l−1 in comparison to that of control. Further studies were carried out with the establishment of Agrobacterium tumefaciens (Ach5) gall-mediated calli, and consequently, cell suspension culture and results showed the significant enhancement of menthol yield up to 278 mg l−1.
Asparagus racemosus Willd. is an important medicinal plant of tropical and subtropical India. Its medicinal usage has been reported in the Indian and British Pharmacopoeias and in traditional systems of medicine such as Ayurveda, Unani, and Siddha. The multiple uses of this species have increased its commercial demand, resulting in over-exploitation. Because of destructive harvesting, the natural population of A. racemosus is rapidly disappearing, and it is recognized as ‘vulnerable’ (Warner et al., Some important medicinal plants of the Western Ghats, India: a profile. International Development Research Centre, Artstock, New Delhi, India, 15 pp, 2001). The development of an efficient micropropagation protocol will play a significant role in meeting the requirements for commercial cultivation, thereby conserving the species in its natural habitat. In the present study, in vitro shoot proliferation was obtained by culturing single node segments in Murashige and Skoog's (MS) medium supplemented with 3.69 μM 2-isopentyl adenine and 3% sucrose with a multiplication rate of 3.5. For proper root formation, the in vitro-formed shoot clusters were cultured on half strength (major salts reduced to half) MS medium with 1.61 μM 1-naphthalene acetic acid, 0.46 μM kinetin, 98.91 μM adenine sulfate, 500 mg/l malt extract, 198.25 μM phloroglucinol, and 3% sucrose. On this medium, 85% rooting was observed within 20 d. Following a simple hardening procedure involving sequential transfer of plants to a greenhouse, polyhouse, and shade net, the tissue-cultured plants were transferred to the field where the survival rate was 100%.
The activity of the main enzymes related to the sucrose metabolism, photosynthesis, and sucrose concentration were studied in sugarcane (Saccharum spp hybrid) plantlets. Acclimatization was developed in two steps. (1) Light intensity of 1,000 μmol m−2 s−1 and 90% relative humidity during the first 21 d; followed by 2,000 μmol m−2 s−1 and approximately 80% of relative humidity. All measurements were carried out at the end of rooting phase concomitant with day 0 of acclimatization and at 7-d intervals thereafter (0, 7, 14, 21, 28, 35, 42 d). As the in vitro plantlets were transferred to the acclimatization phase, photosynthesis increased significantly during the first 7 d. After this period, the increase was constant with only a small but nonsignificant decline after being transferred to the uncontrolled external conditions. The activity of the sucrose synthase began to show a decrease, starting from day 7, and was related to the changes that began to happen in these plants from its adaptation to new ex vitro conditions. Due to the increase of fresh weight favored by the high light intensity and lower relative humidity, an increase of the sucrose phosphate synthase activity was observed. The maximum activity of the acid and neutral invertases was reached at 14 and 21 d, respectively, after 21 d of acclimatization period. There was a marked tendency for the activity of both enzymes to decrease. The sucrose content was decreased only in the first 7 d. The metabolism of sugarcane plantlets seemed to be susceptible to the environmental changes during the acclimatization phase but did not contribute to inhibitory factors for normal development.
The effects of the herbicide isoxaflutole (IFT) on tissue growth and the detection of green fluorescent protein (GFP) in transgenic embryogenic soybean tissues were evaluated using image analysis. The inclusion of this “bleaching” herbicide at 3 or 10 mg l−1 in a standard soybean embryo proliferation medium resulted in a change in tissue color from green to non-pigmented over the course of a 4-wk experiment. Although the loss in pigmentation was observed in transgenic and non-transformed control tissues, tissue growth remained unaffected. GFP expression in three different transgenic soybean clones, representing low to moderate GFP expression levels, was easily detected and quantified using image analysis following culture of the tissues on an IFT-containing medium. Quantification of GFP in tissues from the same clones cultured in the absence of IFT, however, was difficult using image analysis. After transfer of transgenic embryogenic tissue from a medium containing IFT to a medium without IFT, the growth of pigment-containing tissue resumed. The bleaching effects from this herbicide appear to be reversible and make IFT and possibly other bleaching herbicides useful in the analysis of GFP expression in tissues, where interference from chlorophyll is problematic.
Leafy spurge (Euphorbia esula L.) is a perennial, invasive weed used as a model to study invasive plant behavior, because molecular tools (such as a deep expressed sequence tag database and deoxyribonucleic acid microarrays) have been developed for this species. However, the lack of effective in vitro regeneration and genetic transformation systems has hampered molecular approaches to study leafy spurge. In this study, we describe an efficient in vitro regeneration system. Three highly regenerative lines were selected by screening the in vitro regeneration capabilities of stem explants of 162 seedlings. The effects of various culture conditions on in vitro regeneration were then evaluated based on explant competence to form calluses and shoots. High rates of shoot regeneration can be obtained using a growth medium containing 1× woody plant basal medium and 1× Murashige and Skoog (MS) basal salts, 1× MS vitamins, 1.11 μM 6-benzylaminopur-ine, 1.97 μM indole-3-butyric acid, and 3% sucrose, pH 5.6–5.8. After 30 d culture, multiple shoots formed either directly from the stem or indirectly from the callus. This method is a requisite for the development of genetic transformation systems for leafy spurge and may be used to develop in vitro regeneration techniques for other species in the Euphorbiaceae.
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