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Enhancement of in vitro growth of papaya multishoots by aeration   总被引:2,自引:0,他引:2  
Efficient micropropagation of papaya (Carica papaya L.) has become crucial for multiplication of specific sex types of papaya or transgenic lines resistant to virus infection. In this study, aeration at different intervals with a 0.02 μm filter disc in the closure of culture flasks ensured exchange of gas components. The effect of aeration on development of multibuds to multishoots was investigated. Multibuds grown in culture flasks after one-week without aeration followed by a two-week aeration treatment caused a 41% increase in the number of shoots ≥0.5 cm, 42% increase in leaf expansion, and 17% increase in leaf numbers in comparison with unaerated materials. Ethylene and oxygen concentrations in the culture flasks were measured by gas chromatography and oxygen electrode at weekly intervals during the culture period. Oxygen concentrations were slightly different between aerated and unaerated culture flasks. Ethylene in the unaerated flask reached the highest level (0.11 ppm) 2 weeks after the treatment, while accumulation of ethylene in the aerated flasks was not detected. The multishoots grown for 3 weeks without aeration showed growth retardation on leaves and epinasty on petioles. This revised version was published online in June 2006 with corrections to the Cover Date.  相似文献   
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Summary In order to establish a model system for introduction of foreign genes into papaya (Carica papaya L.) plants by Agrobacterium-mediated transformation, petioles from multishoots were used as explant source and bacterial neomycin phosphotransferase II (NPT II) gene and -glucuronidase (GUS) gene were used as a selection marker and a reporter, respectively. Cross sections of papaya petioles obtained from multishoots micropropagated in vitro were infected with A. tumefaciens LBA4404 containing NPTII and GUS genes and co-cultured for 2 d. The putative transformed calluses were identified by growth on the selective medium containing kanamycin and carbenicillin, and consequently regenerated to plants via somatic embryogenesis. Thirteen putative transgenic lines were obtained from a total of 415 petiole fragments treated. Strong GUS activity was detected in the selected putative transgenic calli or plants by fluorogenic assay. Western blot analysis using GUS antiserum confirmed that the GUS protein was expressed in putative transformed papaya cells and transgenic plants. The presence of the GUS gene in the papaya tissues was detected by PCR amplification coupled with Southern blot.  相似文献   
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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.  相似文献   
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Efficient rooting for establishment of papaya plantlets by micropropagation   总被引:2,自引:0,他引:2  
A low cost micropropagation protocol to produce high quality root systems which are easy and economical to acclimatize is essential for large-scale micropropagation of papaya (Carica papaya L.). In this study, individual shoots (>0.5 cm) with 23 leaves from in vitro papaya multiple shoots were cultured on MS agar medium containing 2.5 μM IBA under dark conditions for 1 week for root induction. They were then transferred to agar or vermiculite media, containing half strength MS medium, under aerated or non-aerated conditions, for root development. Rooting percentage of shoots cultured for 2 weeks in aerated vermiculite was 94.5%, compared with 90.0% in non-aerated vermiculite, 71.1% in aerated agar, and 62.2% in non-aerated agar. Shoots with roots were acclimated in vermiculite under 100% RH for 1 week and then under ambient conditions for 2 weeks in a temperature-controlled growth chamber (28 °C). The survival rates of the plantlets were 94.5% from aerated vermiculite, 87.8% from non-aerated vermiculite, 42.2% from aerated agar, and 35.6% from non-aerated agar. Thus, root induction in low-concentration IBA agar medium followed by root development in vermiculite containing half strength MS medium under aerated conditions results in efficient rooting of in vitro papaya shoots. This revised version was published online in June 2006 with corrections to the Cover Date.  相似文献   
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Viral diseases are very detrimental to watermelon production. Watermelon silver mottle virus (WSMoV) is a major limiting factor for the production of watermelon and other cucurbit fruits. There are no effective natural sources of resistance to WSMoV, making transgenic resistance an appropriate solution for attenuating virus infection. Hyperhydricity is an important problem in watermelon culture in vitro, resulting from lower multiplication rates, poor quality shoots and tissue necrosis. In this study, we report an Agrobacterium-mediated genetic transfer protocol for commercial watermelon cultivars expressing the nucleocapsid (N) gene of WSMoV and a suitable approach to overcome hyperhydricity in watermelon culture in vitro. Murashige and Skoog (MS) salts containing Schenk and Hildebrandt (SH) vitamins + 50 mg l−1 thiamine HCl could diminish the hyperhydric phenotype. The proximal halves of cotyledons from 3-day-old seedlings were cut into 1.5 × 1.5 mm segments as explants. Four days after co-cultivation, the explants were transferred to a selection medium for shoot regeneration. The putative transgenic shoots developed within 6 weeks of culture and were then transferred to stringent medium for 8 weeks to eliminate ‘escape type’ shoots. Fifty putative transgenic watermelon lines were obtained from three cultivars. PCR and Southern blot analysis confirmed that the foreign gene was incorporated into the genomic DNA of the transgenic lines.  相似文献   
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Lisianthus (Eustoma grandiflorum) is a cut or ornamental flower that is popular all over the world. This ornamental crop, however, lacks an effective weed control method due to its susceptibility to herbicide. In this study, transgenic plants of a lisianthus cultivar were produced using Agrobacterium-mediated delivery of the plasmid pCAMBIA3300, which carried the bialaphos resistance (bar) gene under driven by the CaMV 35S promoter. The transgenic calli were derived from wounded edges of the leaves grown on a shoot regeneration medium containing 100 mg l?1 cefotaxime and 2 mg l?1 glufosinate ammonium for 4 weeks. The callus that was detached from the wounded edge of the leaf was transferred to the shoot regeneration medium with 100 mg l?1 cefotaxime and 5 mg l?1 glufosinate ammonium for 4 weeks for shoot regeneration. The bar gene integration and expression in the transgenic plants were confirmed by Southern and Northern blot analyses, respectively. Subsequently, the transgenic lines were assessed in vitro and under greenhouse conditions for their resistance to the commercial herbicide Basta®, which contains glufosinate ammonium as the active component. Six transgenic lines showed high percentages (67–80%) of survival in vitro under the selection condition with glufosinate ammonium (up to 216 mg l?1). Under greenhouse conditions, the plants from these six lines remained healthy and exhibited a normal phenotype after spraying with glufosinate ammonium (up to 1,350 mg l?1). This is the first paper to provide a detailed survey of transgenic lisianthus expressing the bar gene and exhibiting herbicide-resistance under greenhouse conditions.  相似文献   
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