Dennis E. McCabe

Gene gun-based nucleic acid immunization : elicitation of humoral and cytotoxic T lymphocyte responses following epidermal delivery of nanogram quantities of DNA

Particle-mediated (gene gun) DNA transfer to the epidermis was evaluated for its ability to elicit humoral and cytotoxic T lymphocyte responses using decreasing quantities of plasmid DNA-based antigen expression vectors. Using plasmids encoding human growth hormone, human alpha-1-antitrypsin, and influenza virus nucleoprotein, strong immune responses were observed in mice following immunization with as little as 16 ng of DNA using an electric discharge gene delivery system. Significant antibody titers were observed against these antigens following a primary immunization, with responses rising dramatically following a boost. Increasing the DNA dose above 16 ng per immunization had little beneficial effect. In contrast to particle-mediated DNA delivery, intramuscular or intradermal inoculation required greater than 5000-fold more DNA to achieve comparable results. Data are also presented demonstrating that a simple, hand-held version of the Accell DNA delivery system, employing compressed helium as the particle motive force, achieves immune responses comparable to the traditional electric discharge device.

Soybean genetic engineering - commercial production of transgenic plants

Abstract Until recently, the improvement of soybean ( Glycine max ) by genetic engineering has been limited due to the lack of an efficient transformation system for introducing foreign genes into regenerable tissues. We report the production of transgenic plants using an electric discharge to inject DNA-coated gold particles into soybean meristems; the transformed phenotype segregated in a mendelian fashion and the introduced genes were stable for up to six generations. The technique has been developed into a commercially viable process for introducing any foreign gene into any variety of soybean.

Direct DNA transfer using electric discharge particle acceleration (ACCELL™ technology)

Direct DNA transfer methods based on particle bombardment have revolutionized plant genetic engineering. Major agronomic crops previously considered recalcitrant to gene transfer have been engineered using variations of this technology. In many cases variety-independent and efficient transformation methods have been developed enabling application of molecular biology techniques to crop improvement. The focus of this article is the development and performance of electric discharge particle bombardment (ACCELL™) technology. Unique advantages of this methodology compared to alternative propulsion technologies are discussed in terms of the range of species and genotypes that have been engineered, and the high transformation frequencies for major agronomic crops that enabled the technology to move from the R&D phase to commercialization.Creation of transgenic soybeans, cotton, and rice will be used as examples to illustrate the development of variety-independent and efficient gene transfer methods for most of the major agronomic crops. To our knowledge, no other gene transfer method based on particle bombardment has resulted in variety-independent and practical generation of large numbers of independently-derived crop plants. ACCELL™ technology is currently being utilized for the routine transfer of valuable genes into elite germplasm of soybean, cotton, bean, rice, corn, peanut and woody species.

Transgenic cotton resistant to herbicide bialaphos

Resistance to bialaphos, a non-selective herbicide, was intro duced into cotton through genetic engineering. A gene encoding phosphinothric in acetyltransferase (bar) from Streptomyces hygroscopicus was inserted into elite varieties of cotton through particle bombardment. Based on the marker gene, β-glucuronidase (gus) expression, a total of 18 Pima (Gossypium barbadense), 45 DP50 (G. hirsutum L.), 20 Coker 312 (G. hirsutum) and 2 El Dorado (G. hirsutum) transgenic plants were recovered. Integration of the bar gene into cotton genomic DNA was confirmed by Southern blot analysis and gene expression was confirmed by northern blot and enzyme assays. Herbicide (Basta®) tolerance up to 15 000 ppm was demonstrated in greenhouse trials. The newly introduced herbicide tolerance trait is inherited in a Mendelian fashion in the progenies of germline transformants. This study demonstrates the potential for particle bombardment to introduce commerically important genes directly into elite varieties of cotton. This mode of gene transfer can expedite the introduction of transgenic cotton products into world markets

Particle‐Mediated Gene Delivery In Vivo and In Vitro

Particle‐mediated or “gene gun” technology has been developed as a nonviral method for gene transfer into various mammalian tissues. Gene delivery is achieved by physical force: a strong shock wave is generated that accelerates DNA‐coated gold particles to high speeds, providing them with the momentum needed to penetrate the targeted cells. This unit describes general procedures for in vivo and in vitro DNA and RNA transfections by particle‐mediated delivery. The and an alternate protocol address in vivo delivery to mouse skin. In vitro delivery to cryopreserved and adherent cells is also described.

Methods for Particle-Mediated Gene Transfer into Skin

During the past 5 yr, particle-mediated delivery techniques have been developed as a physical means for gene transfer into various eukaryotic systems, including plants, insects, fish, and mammals (1-7). For mammalian somatic tissues, this technology, popularly known as the gene gun method, has been shown effective in transfection of skin, liver, pancreas, muscle, spleen, and other organs in vivo (3,4); brain, mammary, and leukocyte pnmary cultures or explants ex vivo (2,5-7); and a wide range of different mammalian cell lines in vitro (3,6,7).