Production of Agrobacterium-mediated transgenic fertile plants by direct somatic embryogenesis from immature zygotic embryos of Datura innoxia

Genetic transformation of the oilseed crop camelina using immature zygotic embryos

BACKGROUND

Camelina is an oilseed crop with particularly useful fatty acid and amino acid profiles of its seeds, high resilience to abiotic and biotic stresses, and a short life cycle. Previous genetic engineering approaches in camelina have largely relied on the floral dip method which is, however, associated with genotype-dependent efficiency and incompatibility with methods of direct biomolecule delivery.

RESULTS

Here, we established a novel method of transgenesis for camelina, taking advantage of the high regenerative capacity of immature embryos. Various culture conditions and treatments were experimentally validated, which included the duration of explant pre-cultivation, wounding of explants and its time of application, Agrobacterium strain and density of inoculum, acetosyringone concentration, duration of explant-Agrobacterium co-cultivation, as well as application time and concentration of the selective agent hygromycin. We provide convergent evidence of stable transgenicity and transgene inheritance by (1) selection for resistance to hygromycin, (2) PCR, (3) detection of the transgene product GFP, and (4) DNA gel blot analysis involving primary transgenic plants and segregating progeny. Primary transgenics examined in detail featured one to three T-DNA integration loci, with one to seven T-DNA copies being integrated in total per plant. The established method proved efficient across all three tested accessions including two current cultivars, whereby transformation efficiencies, determined as PCR-positive primary transgenic plants related to agro-inoculated explants, of between 13 and 17% were obtained.

CONCLUSION

With this method, we provide a viable platform for the functional validation of genes-of-interest and for biotechnological improvements of plant performance and quality features in camelina.

Plant Regeneration via Adventitious Shoot Formation from Immature Zygotic Embryo Explants of Camelina

Camelina is an oil seed crop that is enjoying increasing interest because it has a particularly valuable fatty acid profile, is modest regarding its water and nutrient requirements, and is comparatively resilient to abiotic and biotic stress factors. The regeneration of plants from cells accessible to genetic manipulation is an essential prerequisite for the generation of genetically engineered plants, be it by transgenesis or genome editing. Here, immature embryos were used on the assumption that their incomplete differentiation was associated with totipotency. In culture, regenerative structures appeared adventitiously at the embryos' hypocotyls. For this, the application of auxin- or cytokinin-type growth regulators was essential. The formation of regenerative structures was most efficient when indole-3-acetic acid was added to the induction medium at 1 mg/L, zygotic embryos of the medium walking stick stage were used, and their hypocotyls were stimulated by pricking to a wound response. Histological examinations revealed that the formation of adventitious shoots was initiated by locally activated cell division and proliferation in the epidermis and the outer cortex of the hypocotyl. While the regeneration of plants was established in principle using the experimental line Cam139, the method proved to be similarly applicable to the current cultivar Ligena, and hence it constitutes a vital basis for future genetic engineering approaches.

Genetic transformation protocols using zygotic embryos as explants: an overview

Genetic transformation of plants is an innovative research tool which has practical significance for the development of new and improved genotypes or cultivars. However, stable introduction of genes of interest into nuclear genomes depends on several factors such as the choice of target tissue, the method of DNA delivery in the target tissue, and the appropriate method to select the transformed plants. Mature or immature zygotic embryos have been a popular choice as explant or target tissue for genetic transformation in both angiosperms and gymnosperms. As a result, considerable protocols have emerged in the literature which have been optimized for various plant species in terms of transformation methods and selection procedures for transformed plants. This article summarizes the recent advances in plant transformation using zygotic embryos as explants.

Role of vitronectin-like protein in Agrobacterium attachment and transformation of Arabidopsis cells

The role of plant vitronectin-like protein (Vn) in Agrobacterium-host plant interactions and receptor-specific bacterial attachment is unclear and still open to debate. Using a well-established Agrobacterium-mediated Arabidopsis transformation system, the marker gene beta-glucuronidase (GUS) of Escherichia coli, and biochemical and cytological methods, such as ELISA tests, immunoblots, immunolocalization, and functional in vitro binding assays, we have reassessed the role of Vn in receptor-specific bacterial attachment and transformation. We provide evidence that Vn is present in the host plant cells and anti-human vitronectin antibody cross-reacts with a 65-kDa protein from Arabidopsis cells. The specificity of the immunological cross-reactivity of anti-vitronectin antibodies was further demonstrated by ELISA competition experiments. Immunogold labeling showed that Vn is localized in the plant cell wall, and its level increased considerably after phytohormone treatment of the petiole explants. However, Agrobacterium attachment was unaffected, and no inhibition of petiole cell transformation was detected in the presence of human vitronectin and anti-vitronectin antibodies in the media. Additionally, no correlation between the occurrence of Vn, attachment of bacteria to the cells, and susceptibility to Agrobacterium-mediated transformation was observed. Taken together, our data do not support a functional role of plant Vn as the receptor for site-specific Agrobacterium attachment leading to the transformation of Arabidopsis cells.

Transgenic grasspea (Lathyrus sativus L.): factors influencing agrobacterium-mediated transformation and regeneration

A reproducible procedure was developed for genetic transformation of grasspea using epicotyl segment co-cultivation with Agrobacterium. Two disarmed Agrobacterium tumefaciens strains, EHA 105 and LBA 4404, both carrying the binary plasmid p35SGUSINT with the neomycin phosphotransferase II (nptII) gene and the beta-glucuronidase (gus)-intron, were studied as vector systems. The latter was found to have a higher transforming ability. Several key factors modifying the transformation rate were optimized. The highest transformation rate was achieved using hand-pricked explants for infection with an Agrobacterium culture corresponding to OD(600) congruent with 0.6 and diluted to a cell density of 10(9) cells ml(-1) for 10 min, followed by co-cultivation for 4 days in a medium maintained at pH 5.6. Putative transformed explants capable of forming shoots were selected on regeneration medium containing kanamycin (100 mug ml(-1)). We achieved up to 36% transient expression based on the GUS histochemical assay. Southern hybridization of genomic DNA of the kanamycin-resistant GUS-expressive shoots to a gus-intron probe substantiated the integration of the transgene. Transformed shoots were rooted on half-strength MS containing 0.5 mg l(-1) indole-3-acetic acid, acclimated in vermi-compost and established in the experimental field. Germ-line transformation was evident through progeny analysis. Among T(1) seedlings of most transgenic plant lines, kanamycin-resistant and -sensitive plants segregated in a ratio close to 3:1.

Factors influencing secondary somatic embryogenesis inMalus x domestica Borkh. (cv 'Gloster 69')

A procedure for regeneration of apple plants through secondary somatic embryogenesis (SSE) was developed in apple 'Gloster 69'. Primary somatic embryos were produced from cotyledon-derived cultures of immature zygotic embryos. These somatic embryos were multiplied by secondary somatic embryogenesis (SSE) on media with different Plant Growth Regulator (PGR) combinations. The highest SSE rate (55.5%) was obtained with a combination of NAA (5.3 μM), BAP (0.9 μM) and KIN (0.9 μM) or with TDZ alone (10 μM). In addition, effects of explant source, somatic embryo size, type and concentrations of carbohydrates and gelling agents on SSE were investigated. The optimum SSE (>73%) was obtained by the culture of large size somatic embryos or cotyledon-like structures on medium containing a combination of NAA/BAP/KIN or TDZ (10 μM) alone, maltose (175 mM) and Phytagel (2.8 g/1).