Biolistic Particle Bombardment Research Articles

Transformation of nuclear and plastomic plant genomes by biolistic particle bombardment.

Microprojectile bombardment is a powerful method for the transformation of various organisms and tissues. For plants, the biolistic approach is primarily used for transformation of cereals and other monocotyledons, as well as for dicotyledonous plants shown to be recalcitrant to Agrobacterium-based transformation of organellar genomes, and transformation of plant and algal chloroplasts has recently been reported. In this protocol paper we provide methods for nuclear and plastomic transformation of plants using the biolistic technique.

Introduction of Immunomodulatory Genes Into Isolated Pancreatic Islets via Biolistic Particle Bombardment

Introduction of Immunomodulatory Genes Into Isolated Pancreatic Islets via Biolistic Particle Bombardment

Somatic embryo cycling: Evaluation of a novel transformation and assay system for seed-specific gene expression in soybean

Somatic embryo cycling, a modification of soybean somatic embryogenic suspension culture, was developed as an efficient and rapid method of producing tissue suitable for stable transformation of soybean germplasm by biolistic particle bombardment. Instead of using immature seed explants, cotyledon-staged somatic embryo hypocotyls were placed on auxin-containing medium, where they initiated new somatic embryos primarily from single epidermal cells. By bombarding hypocotyls prior to initiation of subsequent embryo formation, we have effectively transformed soybean somatic embryos with the reporter genes neomycin phosphotransferase,gb-glucuronidase, and a mammalian stearyl CoA delta-9 desaturase, controlled by a seed-specific promoter. These embryos contain significantly reduced levels of saturated palmitic and stearic fatty acids, and significant amounts of monounsaturated palmitoleic acid, which is not normally abundant in soybean seeds. This study demonstrates the effectiveness of somatic embryo cycling for soybean transformation, and for testing expression of genes for seed-specific proteins. Abnormal flower development in recovered plants is a limitation for application of the technique to produce transgenic seed at present.

Protection against Mycoplasma pulmonis infection by genetic vaccination.

The induction of an immune response against a foreign protein usually requires purification of that protein, which is injected into animals. The isolation of pure protein is time consuming and costly. Recently, a technique called biolistic transformation (biological ballistic system) microparticle injection, gene gun, or particle bombardment was developed. The basic idea is that DNA or biological material coated onto heavy tungsten or gold particles is shot into target cells or animals. We have vaccinated mice by introducing the gene (Mycoplasma pulmonis DNA or a specific fragment) encoding a protein recognized by a protective monoclonal antibody directly into the skin or muscle of mice by two methods: (i) using a hand-held form of the biolistic system that can propel DNA-coated gold microprojectiles (2 micrograms of DNA) directly into the skin; (ii) using a conventional intramuscular injection of the DNA (100 micrograms) into quadricep muscles of transfected mice. HeLa cells were transfected in vitro by the gene gun or by the liposomal delivery system. Indirect immuno-fluorescent antibody (IFA) assay of culture cells indicated that both methods could be successful. Production of antibody and cell-mediated immunity against M.pulmonis were monitored by assaying serum IFA and enzyme-linked immunosorbent assay (ELISA), and delayed type hypersensitivity. In addition, macrophage migration inhibition and lymphocyte transformation to antigen in spleen cells were also tested. Both delivery systems induced humoral and cellular immunity, and vaccinated the mice against infection. Genetic immunization by using the gene gun saves time, money, and labor; moreover, this general method is also applicable to gene therapy.

Stable transformation of barley callus using biolistic� particle bombardment and the phosphinothricin acetyltransferase (bar) gene

Suspension culture cells of barley (Hordeum vulgare L. cv. Klages) were collectec on filters and bombarded with gold particles carrying the Basta® resistance (bar) gene, or both bar and the β-glucuronidase (uidA) genes in a Biolistic® Particle Accelerator. Filters carrying the bombarded tissues were selected on basal medium with increasing concentrations (maximum of 200 mg I-1) of phosphinothricin. Surviving calli were assayed for the presence of phosphinothricin acetyltransferase activity. All positive calli were shown to have the bar gene integrated into their genome. Nine independent stable transformation events have been analyzed with substantial variation in the integration pattern and transgene copy number. Some albino plantlets were produced, but no mature plants were obtained.