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Plant genetic engineering has contributed substantially to the understanding of gene regulation and plant development, in the generation of transgenic organisms for widespread usage in agriculture, and has increased the potential uses of crops for industrial and pharmaceutical purposes. As the application of genetically engineered plants has widened, so has the need to develop methods to fine-tune control of transgene expression. The availability of a broad spectrum of promoters that differ in their ability to regulate the temporal and spatial expression patterns of the transgene can dramatically increase the successful application of transgenic technology. Indeed, a variety of promoters is necessary at all levels of genetic engineering in plants, from basic research discoveries, concepts and questions, to development of economically viable crops and plant commodities, to addressing legitimate concerns raised about the safety and containment of transgenic plants in the environment. This review covers the characterization and usage of a broad range of promoters employed in plant genetic engineering, including the widespread use of plant promoters with viral and plant origin that drive constitutive expression. Also covered are selected tissue-specific promoters from fruit, seed and grain, tubers, flowers, pistils, anther and pollen, roots and root nodules, and leaves and green tissue. Topics also include organellar promoters, and those found in specific cell types, as well as the development and evaluation of inducible (endogenous and exogenous origin) and synthetic plant promoter systems. Discussions on the relevance and potential pitfalls within specific applications are included.
Somatic embryogenesis represents a promising tool for mass propagation of elite genotypes of conifers. The efficiency of the technique strongly depends on cultivation conditions, with the exogenous saccharide supply being one of the most important factors. Different types and concentrations of saccharides have been empirically evaluated with respect to production of acceptable numbers and quality of somatic embryos for particular conifer species. Only a few recently published papers have focused on deeper studies of carbohydrate metabolism, enabling insight into the physiological background of the crucial effects of carbohydrates. Generally, saccharides are known to serve as carbon and energy sources, osmotic agents, stress protectants, and signal molecules in plants. This review collects and critically discusses the experimental data on exogenous saccharide supplies, resulting endogenous levels, and key enzyme activities obtained from the most thoroughly described genus Picea. In conclusion, it stresses the necessity to broaden the studies and consider the multiple roles of saccharides during conifer somatic embryogenesis.
Since the success of Agrobacterium-mediated transformation of rice in the early 1990s, significant advances in Agrobacterium-mediated transformation of monocotyledonous plant species have been achieved. Transgenic plants obtained via Agrobacterium-mediated transformation have been regenerated in more than a dozen monocotyledonous species, ranging from the most important cereal crops to ornamental plant species. Efficient transformation protocols for agronomically important cereal crops such as rice, wheat, maize, barley, and sorghum have been developed and transformation for some of these species has become routine. Many factors influencing Agrobacterium-mediated transformation of monocotyledonous plants have been investigated and elucidated. These factors include plant genotype, explant type, Agrobacterium strain, and binary vector. In addition, a wide variety of inoculation and co-culture conditions have been shown to be important for the transformation of monocots. For example, antinecrotic treatments using antioxidants and bactericides, osmotic treatments, desiccation of explants before or after Agrobacterium infection, and inoculation and co-culture medium compositions have influenced the ability to recover transgenic monocots. The plant selectable markers used and the promoters driving these marker genes have also been recognized as important factors influencing stable transformation frequency. Extension of transformation protocols to elite genotypes and to more readily available explants in agronomically important crop species will be the challenge of the future. Further evaluation of genes stimulating plant cell division or T-DNA integration, and genes increasing competency of plant cells to Agrobacterium, may increase transformation efficiency in various systems. Understanding mechanisms by which treatments such as desiccation and antioxidants impact T-DNA delivery and stable transformation will facilitate development of efficient transformation systems.
The regal pelargonium, cv. Dubonnet, was transformed using the disarmed Agrobacterium tumefaciens strains LBA4404 or EHA105 containing the binary vector pLN70. This plasmid carries on its T-DNA the rolC gene from Agrobacterium rhizogenes under control of the CaMV 35S promoter and the nptII selectable marker gene under a NOS promoter. Six independent transformants were produced and grouped according to their phenotypic characteristics. Two transformants showed the same phenotype as the untransformed control plants. Three transformants exhibited a dwarf phenotype and one displayed a super-dwarf phenotype. Southern hybridization analyses of the T-DNA left border region using a nptII probe showed that the six transformants all arose from independent transformation events. Northern hybridization analyses showed that the rolC gene was expressed only in the four transformants that exhibited a dwarf phenotype. Our data show that the phenotypic effects of rolC expression in regal pelargoniums include reductions in plant height, leaf area, petal area, and corolla length. Earlier flowering of the rolC transgenics by up to 22 d was also observed.
An Agrobacterium-mediated transformation system for Eleutherococcus sessiliflorus was established using uidA gene coding for the β-glucuronidase (GUS) and pat gene that confers resistance to the herbicide Basta® (bialaphos). Either fine embryogenic calluses or early globular embryo clusters were cocultivated with A. tumefaciens for 3 d. Transient GUS expression levels were higher in globular embryo clusters than in embryogenic calluses. The high level of transient expression coincided with stable expression of the uidA gene. The frequency of GUS-positive somatic embryos increased following continuous subculture of explants (once every 2 wk) on selection medium containing 200 mg l−1 cefotaxime and 25 mg l−1 kanamycin. After 10 subcultures, more than 95% of somatic embryos were GUS-positive. Cotyledonary embryos were transferred to a medium containing 14.4 μM gibberellic acid to induce germination and plantlet conversion. Transgenic plantlets were confirmed by polymerase chain reaction (PCR) and Southern analysis. Each transgenic line was cloned by induction of embryogenic callus from roots and hypocotyls. Transgenic plants grown in soil medium were resistant to 200 mg l−1 phosphinothricin (Basta®) application.
The use of plant genetic engineering to augment plant breeding programs is significantly strengthened if novel trait(s) can be introduced directly into elite germplasm. Implementing this technology to sorghum breeding programs has been hampered by the lack of an efficient and transferable protocol that is suitable with elite genotypes. This study was conducted to identify parameters that maximize in vitro culture performance in sorghum targeting a specific elite genotype, C2-97, which possesses enhanced agronomic characteristics. Three different tissue culture media formulations, MS, N6, and M11 were evaluated. M11 medium contains approximately 16% and 85% more total nitrogen and sevenfold and threefold higher levels of potassium phosphate than MS and N6 formulations, respectively. Culture performance of C2-97 across the three media formulations was compared to sorghum genotypes that were previously reported to be amenable to genetic engineering, namely Tx430, P898012, Bwheatland, and C401. Maximum embryogenesis induction was observed on M11 medium for all genotypes tested, with greater than 70% embryogenic calluses occurring on immature embryos derived from the C2-97 genotype cultured on M11 medium.
The glutathione–glutathione disulfide redox pair was utilized to improve white spruce somatic embryo development. Mature cotyledonary-stage somatic embryos were divided into two groups (A and B) based on morphological normality and the ability of the mature somatic embryos to convert into plantlets. Group A embryos had four or more cotyledons and converted readily upon germination after a partial drying treatment. Group B embryos had three or fewer cotyledons with a low conversion frequency. The addition of reduced glutathione (GSH) at a concentration of 0.1 mM resulted in an increase in embryo production (total population) with a mean total number of 64 embryos per 100 mg embryogenic tissue as well as an increase in post-embryonic root growth. However, at a higher concentration (1 mM), GSH inhibited embryo formation. The manipulation of the tissue culture environment via the inclusion of glutathione disulfide (GSSG), at concentrations of 0.1 and 1.0 mM, enhanced the development of better-quality embryos. This quality was best exemplified when embryos forming four or more cotyledons increased by at least twofold to 73.9% when treated with 1.0 mM GSSG, compared to 38% in control. Furthermore, this improved quality was reflected by an increased conversion frequency. A 20% increase in the ability of the somatic embryo to produce both root and shoot structures during post-embryonic development was noted when embryos were matured on maturation medium supplemented with 1.0 mM GSSG over the control.
We have developed efficient methods for plant regeneration, via both embryogenesis and organogenesis, of Smooth Cayenne pineapple, Ananas comosus(L.) Merr. Leaf bases and core (stem) sections of in vitro shoots, produced from culture of crown tip meristem, were used as explants for plant regeneration as follows: (1) Leaf base and core section explants cultured on Murashige and Skoog (MS) medium containing 41 μM 4-amino-3,5,6-trichloropicolinic acid (picloram, P) or thidiazuron (T)/P combinations produced embryogenic tissues. Different types of embryogenic tissues (friable emryogenic tissue, embryogenic cell cluster, and chunky embryogenic tissue) have been developed with varying properties in terms of growth rate and state of development. The embryogenic tissues regenerated shoots upon culture on MS medium containing 13 μM 6-benzylaminopurine (BA) and 1 μM α-naphthaleneacetic acid (NAA) followed by culture on MS medium containing 4 μM BA. (2) Crown tip meristems cultured on MS medium containing 13 μM BA followed by leaf explants cultured on MS medium with 27 μM NAA and 1 μM BA produced shoots via direct organogenesis. (3) Explants cultured on MS medium containing 5 μM T and 0.5 μM indole-3-butyric acid (IBA) produced nodular globular structures, which produced shoots upon culture on MS medium containing 1 μM BA and 1 μM gibberellic acid. Shoots obtained from all of the above methods were rooted in half-strength MS medium containing 3 μM NAA and 2.5 μM IBA. Plants were transferred to the greenhouse or shipped to Costa Rica for field trials. Somatic embryo-derived plants exhibited 21% spininess, and organogenic-derived plants exhibited 5% spininess in the field trials.
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 μg g−1), cadmium (0.4 μg g−1), lead (18.7 μg g−1), and mercury (0.1 μg g−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.
Various plant secondary products have been implicated in the promotion of good health or the prevention of disease in humans, but little is known about the way they are absorbed in the gut, or in which tissues they are deposited throughout the body. While these issues could be studied if the phytochemicals were isotopically labeled, generating labeled molecules often is problematic because many compounds of interest can be synthesized only in planta at present. In order to generate 14C-labeled phytochemicals of high radioactive enrichment, we developed an enclosed-chamber labeling system in which cell suspension cultures can be safely and efficiently grown when supplied with 14C-enriched precursors. The system is designed to hold culture flasks within a clear, polyacrylic compartment that is affixed to the top of a rotary shaker. The flow-through gas exchange nature of the system allows for O2 replenishment and complete capture of respired 14CO2 throughout the entire period of cell culture. Air is circulated internally with the aid of a small fan, and chamber air temperature is monitored continuously with an internal temperature probe and data logger. Production runs of 12–14 d with Vaccinium pahalae (ohelo berry) and Vitis vinifera (grape) suspension cultures, using [14C]sucrose as the carbon source, demonstrated a 20–23% efficiency of 14C incorporation into the flavonoid-rich fractions. Further studies with ohelo cell cultures showed that flavonoids were produced with either sucrose or glucose as the carbohydrate source, although flavonoid productivity (measured as anthocyanins) was higher with sucrose. This comprehensive chamber system should have broad applicability with numerous cell types and can be used to generate a wide array of labeled phytochemicals.
Stem segments from apical shoot tips of Polygala myrtifolia were used as primary explants to establish in vitro cultures. Axillary shoots produced on non-contaminated explants were excised and recultured in the same medium to increase the stock of shoot cultures. Equal molar concentrations of five cytokinins [2-isopentenyladenine, kinetin, zeatin, N6-benzyladenine (BA), and adenine] were tested for ability to induce axillary shoot development from double-node stem segments. The highest rate of axillary shoot proliferation was induced on Murashige and Skoog agar medium supplemented with 1.8 μM BA. Seven indole-3-acetic acid (IAA) concentrations (0, 2.9, 5.7, 8.6, 11.4, 14.3, 17.1 μM) were tested to determine the optimum conditions for in vitro rooting of microshoots. Up to 72% of the microshoots rooted with 14.3 μM IAA. Other auxins tested, α-naphthaleneacetic acid and indole-3-butyric acid, were less effective than IAA in inducing adventitious root formation. All rooted plantlets having more than three roots were successfully established in soil.
Germination of coconut (Cocos nucifera L.) zygotic embryos was tested in liquid or solid medium. Percent germination was greater when embryos were cultured in solid medium, particularly when embryos were placed with their micropyle end facing upwards in relation to the vial orientation, independently of orientation in relation to gravity. This occurred because solid medium allowed embryos to be positioned with their micropyle end exposed to the ambient atmosphere of the vial. Germination of embryos facing upwards was suppressed when the ambient atmosphere was replaced with N2 or when aerobic respiration inhibitors were added to the medium, whereas it was not suppressed when the atmosphere was replaced with a N2/O2 (50:50, v/v) mixture, thus indicating that aerobic respiration is required for embryos to germinate. Germination in facing upwards mode also resulted in improved conversion and plantlet development. These improvements in recovery are important since they will help to avoid unintentional selection due to low in vitro germination and corresponding conversion of a population subset. These results set the basis for the improvement of current protocols for in vitro coconut embryo culture, allowing safe movement of germoplasm both in terms of phytosanitation and conservation of genetic diversity in a population of interest.
N. SANTANA, M. E. GONZÁLEZ, M. VALCÁRCEL, A. CANTO-FLICK, M. M. HERNÁNDEZ, C. F. J. FUENTES-CERDA, F. BARAHONA, J. MIJANGOS-CORTÉS, V. M. LOYOLA-VARGAS
The behavior of four coffee (Coffea canephora cv. Robusta) clones was evaluated in this work to define the conditions that would allow somatic embryogenesis to be induced at different seasons of the year. The objective was to have an adaptive methodology for in vitro propagation of these four coffee clones that were selected for their agronomic characteristics. The use of 2,4-dichlorophenoxyacetic acid and Picloram in the culture medium at concentrations between 2.07 and 4.14 μM resulted in high-frequency somatic embryogenesis when leaves were collected between April and June for genotype C-R, and between April and July for M-229. Callus from 28 to 35 d of induction showed better results throughout the whole regeneration process, particularly in liquid medium. There was a clear difference in the behavior of the clones evaluated.
Acacia mangium microshoots from juvenile and mature genotypes were micropropagated through a regular subculture regime for more than 3 yr in vitro. Average multiplication rates of 5.5 for the juvenile source and of 3.9 for the mature clone were obtained during this period on the 6-benzylaminopurine-enriched multiplication medium. Although the juvenile material displayed higher potential for axillary shoot and root formation than the mature clone overall, the differences were not statistically significant with noticeable variations in the course of time from one subculture to another. On specific rooting media, the juvenile material rooted overall in greater proportions than the mature material, notwithstanding noteworthy interactions between the age of the plant material and the various experimental factors tested, i.e. sucrose concentration, macrosalt formulation and light regime. The stimulating effect of darkness on juvenile plant material rooting rates was more obvious than for the mature clone, which responded more inconsistently. Addition of 4 μM indole-3-acetic acid, indole-3-butyric acid, or 1-naphthaleneacetic acid in the rooting medium significantly increased the proportion of rooted microshoots of both origins. The rooting criteria observed were also prone to vary depending on the experimental date. The data indicate that rooting of juvenile and mature Acacia mangium materials have average rates of 90% and 77%, respectively. These are high enough to consider possible applications of these procedures toward operational activities.
St. John's wort (Hypericum perforatum L.) is a medicinal plant used in the treatment of neurological disorders and has been recently shown to have anticancer potential. The principle medicinal components of St. John's wort are hypericin, pseudohypericin, and hyperforin. One of the problems associated with medicinal plant preparations including St. John's wort is the extreme variability in the phytochemical content, mostly due to environmental variability, and biotic and abiotic contamination during cropping. The current study was undertaken to transplant St. John's wort plants from in vitro bioreactors in a closed controlled environment system (CCES) with CO2 enrichment for the optimized production of biomass and phytochemicals. The growth and levels of hypericin, pseudohypericin, and hyperforin in plants grown in CCES were compared with those of the greenhouse and in vitro-grown plants. The environmental parameters in the greenhouse were found to be variable whereas in the CCES these parameters were controlled. Generally, all the growth parameters and hypericin and pseudohypericin levels were significantly higher in the plants grown in the CCES. These results provide the first indication that growing St. John's wort plants under CO2 enrichment in a closed environment system can enhance the biomass and medicinal contents. The adaptation of this growing system may be useful for the production of optimized products of St. John's wort and other medicinal species.
A micropropagation method for Orthosiphon stamineus, using stem nodal segments, has been developed. The highest number of regenerated shoots was obtained on Murashige and Skoog (MS) medium supplemented with 6.7 μM benzyladenine with the formation of an average of 6.1 shoots per explant over a period of 4 wk. The number of shoots increased with longer culture duration on proliferation medium. Multiple shoots which were maintained on the proliferation medium for 6 wk had the highest proliferation rate. Separation of multiple shoots and culturing in larger flasks significantly promoted the growth and formation of plantlets. All the in vitro plantlets survived when transferred to the field and showed no significant morphological differences from the mother plants.
Degradative changes in tissue during protoplast isolation were a contributing factor to low protoplast yields in the salt-sensitive Grevillea arenaria (R. Brown) and the salt-tolerant Grevillea ilicifolia (R. Brown). Protein and malondialdehyde content decreased significantly during the protoplast isolation procedure. Acid and neutral proteases were identified, and high acid protease activities were correlated to low protoplast yields. Acid phosphatase, catalase, polyphenol oxidase and lipoxygenase activities increased in both Grevillea species with cell wall digestion. High activities of catalase and low levels of polyphenol oxidase were correlated with high protoplast yields. Levels of acid phosphatase and lipoxygenase were not good indicators of final protoplast yields. The addition of the anti-oxidant, reduced glutathione, and the acid protease inhibitor, pepstatin A, significantly increased protoplast yields. Strategies were identified to minimize deleterious degradative effects during the isolation of protoplasts, including strict pH control, testing a number of cell wall digestion enzymes, and the addition of anti-oxidative metabolites and protease inhibitors.
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