HighlightsWe have evaluated the role of carbon sources in controlling excessive phenolic secretion from callus culture of cotton.Maltose was found to control phenolic secretion when it is used as a sole carbon source.Efficient protocol was developed for high frequency callus induction and proliferation for SVPR-2 cotton cultivar using different plant growth regulators.Adjustment of carbon source concentrations was found to play an important role in cotton callus culture.The present work will be helpful for establishing callus culture and getting regeneration to carry out genetic transformation studies in SVPR-2 cotton cultivar.
A simple and efficient protocol for Agrobacterium-mediated genetic transformation of tomato was developed using combination of non-tissue culture and micropropagation systems. Initially, ESAM region of 1-day-old germinated tomato seeds were microinjected for one to five times with Agrobacterium inoculums (OD(600) = 0.2-1.0). The germinated seeds were cocultivated in the MS medium fortified with (0-200 mM) acetosyringone and minimal concentrations of (0-20 mg L(-1)) kanamycin, and the antibiotic concentration was doubled during the second round of selection. Bacterial concentration of OD(600) = 0.6 served as an optimal concentration for infection and the transformation efficiency was significantly higher of about 46.28 %. In another set of experiment, an improved and stable regeneration system was adapted for the explants from the selection medium. Four-day-old double cotyledonary nodal explants were excised from the microinjected seedlings and cultured onto the MS medium supplemented with 1.5 mg L(-1) thidiazuron, 1.5 mg L(-1) indole-3-butyric acid, 30 mg L(-1) kanamycin, and 0-1.5 mg L(-1) adenine sulphate. Maximum of 9 out of 13 micropropagated shoots were shown positive to GUS assay. By this technique, the transformation efficiency was increased from 46.28 to 65.90 %. Thus, this paper reports the successful protocol for the mass production of transformants using microinjection and micropropagation techniques.
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