Winter jujube, a species that originated in China, is the most prominent elite variety of jujube (Zizyphus jujuba Mill.). Due to its economic value and its recalcitrance to improvements through traditional plant breeding approaches, genetic transformation techniques may have a great potential in providing the means to transfer one or more selected desirable traits into the plant genome. We reported here an improved protocol for the Agrobacterium-mediated transformation of shoot tips of winter jujube. We have identified a set of optimum transformation conditions that take into account Agrobacterium inoculum density, Agrobacterium incubation period, co-cultivation conditions, and vacuum (use of a vacuum pump to create a negative-pressure environment). The highest transformation frequency (5.2%) was obtained when the shoot-tip explants were infected for 10 min and co-cultured for 4 days with Agrobacterium at OD 600 0.8 under a negative pressure of 0.5 9 10 5 Pa. PCR and southern blot analyses confirmed the presence of transgenic plants and the stable integration of the target gene into the genome of regenerated plants. A histochemical staining analysis for GUS activity in the transgenic shoot tips also validated the efficiency of the transformation system.
Casuarina equisetifolia is widely used in agroforestry plantations for soil stabilization, ecosystem rehabilitation, reclamation, and coastal protection. Moreover, C. equisetifolia has remarkable resistance to typhoons, desert, low soil fertility, drought, and salinity, but not cold. Therefore, it is significant to breed high-quality Casuarina varieties to improve the tolerance and adaptability to cold weather by molecular techniques. The establishment of a rapid and efficient callus induction and regeneration system via tissue culture is pre-requisite for the genetic transformation of C. equisetifolia, which is so far lacking. In this study, we reported an efficient and rapid regeneration system using stem segment explants, in which callus induction was found to be optimal in a basal medium supplemented with 0.1 mg⋅L–1 TDZ and 0.1 mg⋅L–1 NAA, and proliferation in a basal medium containing 0.1 mg⋅L–1 TDZ and 0.5 mg⋅L–1 6-BA. For bud regeneration and rooting, the preferred plant growth regulator (PGR) in basal medium was 0.5 mg⋅L–1 6-BA, and a combination of 0.02 mg⋅L–1 IBA and 0.4 mg⋅L–1 IAA, respectively. We also optimized genetic a transformation protocol using Agrobacterium tumefaciens harboring the binary vector pCAMBIA1301 with β-glucuronidase (GUS) as a reporter gene. Consequently, 5 mg L–1 hygromycin, 20 mg L–1 acetosyringone (As), and 2 days of co-cultivation duration were optimized to improve the transformation efficiency. With these optimized parameters, transgenic plants were obtained in about 4 months. Besides that, Agrobacterium rhizogenes-mediated transformation involving adventitious root induction was also optimized. Our findings will not only increase the transformation efficiency but also shorten the time for developing transgenic C. equisetifolia plants. Taken together, this pioneer study on tissue culturing and genetic transformation of C. equisetifolia will pave the way for further genetic manipulation and functional genomics of C. equisetifolia.
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