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Artemisinin is a sesquiterpene lactone isolated from the aerial parts of Artemisia annua L. plants. Besides being currently the best therapeutic against both drug-resistant and cerebral malaria-causing strains of Plasmodium falciparum, the drug has also been shown to be effective against other infectious diseases including schistosomiasis and hepatitis. More recently, it has also been shown to be effective against numerous types of tumors. Although chemical synthesis of artemisinin is possible, it is not economically feasible. The relatively low yield (0.01–0.8%) of artemisinin in A. annua is a further serious limitation to the commercialization of the drug. Therefore, the enhanced production of artemisinin either in cell/tissue culture or in the whole plant of A. annua is highly desirable. A better understanding of the biochemical pathway leading to the synthesis of artemisinin and its regulation by both exogenous and endogenous factors is essential for facilitating increased yield. Two genes of the artemisinin biosynthetic pathway have now been identified. This critical review covers recent developments related to the biosynthesis of this important compound and related terpenoids, their regulation, and the production of these compounds both in vitro and in whole plants.
Transgenic anti-fungal gene expression in heterologous species provides a means to test resistance protein combinations across species barriers. This is the first report of transgenic anti-fungal seed storage protein accumulation in oat seed. An anti-fungal barley (Hordeum vulgare L.) hordothionin (Hth1) gene was genetically engineered into oat (Avena sativa L.) to determine the effect of hordothionin on pathogen resistance. The transgene was expressed in both leaf and seed tissue, with transgenic protein accumulation occurring only in the seed. Transgenic oat line HTH-Av5 expressed c. 94 μg HTH/g seed, 19% of native barley seed levels. The anti-fungal activities of HTH fractions from barley cv. Morex and oat (transgenic and control) were tested in an in vitro growth assay against an important small grain pathogen, Fusarium graminearum. The partially purified HTH fractions from control oat seeds did not inhibit fungal growth, while HPLC-purified HTH positive control, as well as partially purified barley and transgenic oat HTH inhibited growth similarly over a range of concentrations. These results indicate hordothionin can be expressed in a heterologous cereal species and still maintain its anti-fungal properties. Future studies with HTH targeted to additional tissues are planned to test for increased fungal resistance.
St John's wort (Hypericum perforatum) is a valuable plant used as a herbal remedy or in phytopharmaceutical drugs to treat a variety of physical ailments. Much research has been performed to study the biochemical production of secondary metabolites of in vitro cultured plants or organs. However, all of these studies have looked at the regeneration of plants from explants in only one genotype. In addition, no study has revealed the mechanism of plant regeneration in H. perforatum, i.e. organogenesis or somatic embryogenesis. We found that different genotypes Helos, Topas, Elixir, and Numi responded similarly to regeneration medium. The regeneration responses (i.e. callus, root, or shoot production) of identical explants from different genotypes were similar. However, the source of explant material (leaves, hypocotyls, and roots) from the same genotype had significant effects on the response to media and plant regeneration frequency. Using scanning electron microscopy and light microscopy, the progress of organogenesis and embryogenesis under similar culture conditions was recorded. Root segments were the most responsive explants, producing the maximum number of shoots per explant of all the genotypes.
Inflorescence proliferation is a plant tissue culture technique that can be used to obtain in vitro inflorescences year-round without the intervening development of vegetative organs. In this study, we used albino mutant inflorescences of Dendrocalamus latiflorus as the original explant material to investigate the effect of plant growth regulators on long-term inflorescence proliferation. The albino inflorescences proliferated on solidified Murashige and Skoog (MS) basal medium supplemented with thidiazuron (TDZ), and the optimal concentration for successful long-term inflorescence proliferation was 0.45 μM TDZ. A combination of α-naphthaleneacetic acid (NAA) with 0.45 μM TDZ inhibited the inflorescence proliferation. Inflorescences cultured on a TDZ-free medium supplemented with 26.82 μM NAA rooted in 21 d, vegetative shoots formed by 42 d and, in one case, flowering occurred after 63 d. The auxins 2,4-dichlorophenoxyacetic acid (2,4-D, 4.52 μM) and picloram (4.14 μM) induced shoot formation. The protocol described can be used to produce large numbers of mutant inflorescences within a relatively short period of time.
Indirect organogenesis was developed in Agave tequilana. Leaf segments and meristematic tissue from the central head (‘piña’) were evaluated as explant sources. A minimal-sized explant with high bud-forming capacity (19.5 BFC) was obtained through a cross section of meristematic tissue from in vitro plantlets. In callus culture, the best growth response was due to naphthalene acetic-acid (NAA) presenting a contrasting response compared to 2,4-dichlorophenoxyacetic acid (2,4-D). Regeneration from meristem segments and callus was obtained using 1.1 μM 2,4-D and 44 μM 6-benzylaminopurine (BA). The regeneration capacity of callus was maintained for 3 mo. Shoots regenerated were rooted in a hormone-free MS1 medium and acclimatized in a greenhouse with a 100% survival.
In vitro plantlet regeneration was obtained from cultured cotyledon and young leaf explants of five Indian chile pepper cultivars (Capsicum annuum L. cvs. Gujarat-1, Gujarat-2, Guntur-4, Selection-49, and Jwala). Adventitious shoot buds (ASB) were regenerated directly from cotyledon and young leaf explants in all the five cultivars on media containing benzyladenine (BA) alone or in combination with 1-naphthaleneacetic acid (NAA). Regeneration frequency was highly influenced by cultivar explant type, media combination and their interactions, except the interaction between cultivar and explant, for number of ASB per explant. Percent contribution of individual source suggested that selection of explant type followed by medium combination and cultivars was essential for obtaining high-frequency ASB induction. Across different cultivars the young leaf explant was found to be the most responsive explant, while Murashige and Skoog (MS) medium containing BA alone (17.8, 26.6, and 35.5 μM) was found to be the best medium for the production of maximum number of ASB. Between the two explants, shoot elongation was observed with ASB obtained from young leaf explants on MS medium containing BA (2.2 and 4.4 μM) and gibberellic acid (GA3) (1.4, 2.9, 4.3, and 5.8 μM). The MS medium fortified with 4.4 μM BA 2.9 μM GA3 was optimum for shoot elongation. Elongated shoots were rooted on liquid MS medium supplemented with 2.9 μM indole-3-acetic acid (IAA) and successfully established ex vitro.
An efficient plant regeneration protocol for rapidly propagating Rhodiola fastigiata (Hk. f. et Thoms.) S.H.FU, a traditional Chinese medicinal plant, was developed. Shoot organogenesis occurred from the leaf explants inoculated on medium with appropriate supplements of plant growth regulators. Up to 5.3 shoots formed per leaf explant cultured on a medium containing 13.32 μM 6-benzylaminopurine (BA) and 0.54 μM 1-naphthaleneacetic acid (NAA). Regenerated shoots formed complete plantlets on a medium containing 1.48 μM indole-3-butyric acid (IBA), and mature plants were established, acclimatized, and thrived in greenhouse conditions. The regeneration protocol developed in this study provides a basis for germplasm conservation and for further investigation of medicinally active constituents of the elite Chinese medicinal plant.
The bromeliad Tillandsia eizii is a striking species with large, colorful, and persistent inflorescences that can reach 1 m in length. The value of this plant as an ornamental and its importance in cultural and religious activities has led to its over-collection in the wild. Clonal propagation via tissue culture may be a means to repopulate native stands while meeting the demands for this species as an ornamental and ceremonial plant. Adventitious bud proliferation was induced from axenically germinated seedling material. Parameters evaluated were the age of explant material at the time of transfer onto bud-induction medium, the concentration of plant growth regulators, and the period of exposure to induction medium. Light and scanning electron microscopy (SEM) established the origin and development of buds. Twelve-week-old seedling explants rapidly initiated adventitious buds after a 30-d induction period on shoot-initiation medium. Adventitious buds were induced in 40% of the explants placed on media with 2 mg l−1 6-benzylaminopurine (BA) (8.88 μM) plus 0.1 mg l−1 α‐naphthaleneacetic acid (NAA) (0.54 μM) with some cultures becoming highly prolific after repeated subculture. Shoots elongated in proliferating cultures, and plants were successfully acclimatized and planted into the greenhouse. The results indicate that tissue culture may be used as a means to propagate this epiphytic bromeliad species, which is being seriously affected by deforestation and habitat destruction. In addition, adventitious bud proliferation can provide a means to propagate superior genotypes.
The effect of different cytokinins on in vitro adventitious shoot regeneration from internodal explants of Mentha×gracilis Sole (scotch spearmint) was investigated. Murashige and Skoog (MS) medium containing 100 mg l−1 myo-inositol, 0.4 mg l−1 thiamine-HCl, 2.0% (w/v) sucrose, 10% (v/v) coconut water and supplemented with 4.5 μM thidiazuron (TDZ) was effective in inducing adventitious shoot formation from callus. The greatest percentage of explants with shoots (85%) with the highest mean number of shoots per explant (29) was obtained with explants from the 1st and the 2nd internodes from 2-wk-old stock plants growing on a medium containing MS basal salts, 2% sucrose, 100 mg l−1 myo-inositol, 0.4 mg l−1 thiamine-HCl, at TDZ 4.5 μM and 10% (v/v) coconut water and solidified with 0.2% (w/v) phytagel. The regenerated shoots rooted on a medium containing MS basal salts, 100 mg l−1 myo-inositol, 0.4 mg l−1 thiamine-HCl, 2.0% sucrose, and 0.054 μM naphthalene acetic acid (NAA). Micropropagated plantlets were transplanted into soil and acclimated to greenhouse conditions. This is the first report describing adventitious shoot regeneration of scotch spearmint.
Hybrid embryos resulting from crosses between a highly regenerable maize germplasm (Hi II) and certain elite inbreds were treated with Agrobacterium tumefaciens containing the uidA (GUS) and pat genes under the control of different constitutive promoters. Six of the elite inbred lines were derived from a Lancaster background and three were derived from an Iowa Stiff Stalk background. Hybrid embryos from all three Stiff Stalk lines gave transgenic events at various frequencies, two of them at a comparable frequency to that observed with Hi II embryos. Embryos from only one Lancaster/Hi II hybrid were successfully transformed and the frequency was quite low. Additional Lancaster elite inbreds were then tested as a hybrid with Hi II and failed to produce a single transgenic event. The transgenic Hi II/elite events showed many characteristics of ‘hybrid vigor’ including more aggressive rooting, thicker stems, and taller stature than plants derived from Hi II events. The hybrid T0 plants exhibited excellent tassel development in the greenhouse with abundant pollen shed. Seed set in the greenhouse was significantly (3–5-fold) higher than with Hi II transformants. Attempts to transform embryos derived from self or sibling crosses of the four inbred lines that were successful as hybrids with Hi II did not produce any transgenic events. T0 plants having ∼50% elite genomic contribution perform nearly as well in the greenhouse as seed-derived elite inbred parents and offer a significantly reduced time line for recombinant protein product development from transgenic plants.
Sour orange (Citrus aurantium L.) rootstock has historically been a widely utilized citrus rootstock throughout the world due to its wide soil adaptability and superior horticultural performance. However, quick-decline isolates of citrus tristeza virus (CTV) have demolished entire industries of sour orange rootstock in some countries, including Brazil and Venezuela. CTV is presently destroying millions of trees of sour orange rootstock in Florida and threatens the citrus industries of Texas and Mexico, where sour orange is the predominant rootstock. Efforts to replace sour orange rootstock are combining traditional breeding and biotechnology approaches, including somatic hybridization and transformation. Molecular techniques have confirmed that sour orange is probably a hybrid of mandarin and pummelo. A major focus of our program continues to be the somatic hybridization of superior mandarins with pre-selected pummelo parents. Here, we report the regeneration of allotetraploid somatic hybrid plants from seven new mandarin pummelo combinations and one new sweet orange pummelo combination. All new somatic hybrids were confirmed by leaf morphology, ploidy analyses via flow cytometry, and random amplified polymorphic DNA analysis to show nuclear contributions from both parents in corresponding hybrids. These new somatic hybrids are being propagated by tissue culture and/or rooted cuttings for further evaluation of disease resistance and horticultural performance in field trials.
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