Oral immunization of mice with transgenic tomato fruit expressing respiratory syncytial virus-F protein induces a systemic immune response.

Respiratory syncytial virus (RSV) is one of the most important pathogens of infancy and early childhood. Here a fruit-based edible subunit vaccine against RSV was developed by expressing the RSV fusion (F) protein gene in transgenic tomato plants. The F-gene was expressed in ripening tomato fruit under the control of the fruit-specific E8 promoter. Oral immunization of mice with ripe transgenic tomato fruits led to the induction of both serum and mucosal RSV-F specific antibodies. The ratio of immunoglobulin subclasses produced in response to immunization suggested that a type 1 T-helper cell immune response was preferentially induced. Serum antibodies showed an increased titer when the immunized mice were exposed to inactivated RSV antigen.

Transformation of the limonene synthase gene into peppermint (Mentha piperita L.) and preliminary studies on the essential oil profiles of single transgenic plants.

Agrobacterium-mediated and direct gene transfer into protoplasts using PEG were both successfully used to produce stable, transformed peppermint plants (Mentha×piperita L. cultivar Black Mitcham) with the limonene synthase gene. Stem internode explants found to possess a high level of organogenesis through adventitious shoot formation were subjected to Agrobacterium tumefaciens disarmed strain GV3101 (pMP90). Following the development of an efficient protoplast-to-plant cycle from stem-isolated protoplasts, they were used in direct gene transformations. In both cases the binary vector pGA643 carrying the nptII/GUS genes, both driven by the CaMV35S promoter, was used in preliminary plant-transformation studies. Later, GUS was replaced with the limonene synthase gene. Kanamycin was used as a selective agent in all transformation experiments to obtain both transformed protoplast-derived calli as well as putative transgenic shoots regenerated from internode explants. Both types of transformation resulted in transgenic plants which were detected using PCR and confirmed by Southern-blot hybridizations. Southern analysis revealed that the method of Agrobacterium-mediated transformation is superior to the direct DNA uptake into protoplasts with regard to the stability of the insert during the transformation event. Single transgenic plants were grown to 10% flowering in a greenhouse and the plants derived both by the Agrobacterium and the protoplast-derived methods were generally observed to have essential oil profiles characterized by a high-menthone, low-menthol, high-menthofuran and -pulegone content in comparison to a typical mid-west peppermint. Limonene varied only slightly, around 1.2%, in transgenic plants produced by both methods.

Production of fertile somatic hybrid plants of sunflower and Helianthus giganteus L. by protoplast fusion.

Protoplasts of Helianthus giganteus and Helianthus annuus were fused using polyethylene glycol. Before fusion H.giganteus protoplasts were subjected to iodoacetic acid treatment to render them unable to divide. Fused protoplasts were cultured in V-KM medium containing benzylaminopurine and naphtaleneacetic acid. Hybrid calli were identified on the basis of their ability of embryogenic development contributed by the Helianthus giganteus parent. Fifty embryogenic calli were cultured on MS based medium without growth regulators to induce further development of somatic embryos. Elongated shoots were removed, rooted and transferred into growth chambers. Overall morphology of the plants was intermediate between the two parents. Their hybrid nature was confirmed by chromosome counting and by the analysis of esterase isozymes. The plants flowered within two to three months and later died. Thus the perennial nature of H.giganteus is a recessive trait in this interspecific hybrid. Seeds were obtained from two of the regenerated plants. From these seeds normal fertile F2 plants could be grown.

Somatic embryogenesis and plant regeneration from hypocotyl protoplasts of sunflower (Helianthus annum L.).

A sunflower genotype (Helianthus annuus L. cv. Florom-328) able to regenerate plants from in vitro cultures was identified by screening hybrids and inbred lines. Protoplasts of this genotype were isolated from dark grown hypocotyls and were cultured in droplets of agarose-solidified V-KM medium covered by liquid V-KM supplemented with naphthaleneacetic acid (NAA) and benzylaminopurine (BAP). One week later colonies were subjected to 2,4-dichlorophenoxyaceticacid for a one week period. Further culture in V-KM with reduced concentrations of NAA and BAP resulted in the appearence of somatic embryos. Maturation of embryos was achieved by culture on MS medium supplemented with NAA, BAP, gibberellic acid A3 and the ethylene inhibitor AgNO3. Embryos were then transferred onto hormone free MS medium for germination. The frequency of shoot formation in the best case was 9.6 percent of viable colonies (1.3 percent of protoplasts plated). Some of the shoots with roots could be transplanted into soil, others were grafted on hypocotyls of in vivo germinated seedlings. Eighty percent of grafted shoots and over 95 percent of rooted shoots survived. The plants flowered and produced 5 to 10 seeds each. Factors affecting the frequency of embryo formation and plant regeneration are discussed.

Plant regeneration from callus and protoplast cultures of Helianthus giganteus L.

Methods of plant regeneration from callus and protoplasts of Helianthus giganteus L. are described. Embryogenic callus was obtained from leaf explants and plants were regenerated from these calli on MS media with different combinations of benzyladenine and naphtaleneacetic acid. Leaf protoplasts isolated from in vitro grown plants formed somatic embryos when cultured in agarose solidified droplets of V-KM medium containing benzyladenine and naphtaleneacetic acid. Embryos developed into plantlets on media with reduced auxin contents. Regenerated plants were successfully planted in soil.