Analysis of promoters in transgenic barley and wheat

Advances in the genetic transformation of cereals have improved the prospects of using biotechnology for plant improvement, and a toolbox of promoters with defined specificities would be a valuable resource in controlling the expression of transgenes in desired tissues for both plant improvement and molecular farming. A number of promoters have been isolated from the important cereals (wheat, barley, rice and maize), and these promoters have been tested mostly in homologous cereal systems and, to a lesser extent, in heterologous cereal systems. The use of these promoters across the important cereals would add value to the utility of each promoter. In addition, promoters with less sequence homology, but with similar specificities, will be crucial in avoiding homology-based gene silencing when expressing more than one transgene in the same tissue. We have tested wheat and barley promoters in transgenic barley and wheat to determine whether their specificity is shared across these two species. The barley bifunctional α-amylase/subtilisin inhibitor ( Isa ) promoter, specific to the pericarp in barley, failed to show any activity in wheat, whereas the wheat early-maturing ( Em ) promoter showed similar activity in wheat and barley. The wheat high-molecular-weight glutenin ( HMW-Glu ) and barley D-hordein ( D-Hor ) and B-hordein ( B-Hor ) storage protein promoters maintained endosperm-specific expression of green fluorescent protein (GFP) in wheat and barley, respectively. Using gfp , we have demonstrated that the Isa and Em promoters can be used as strong promoters to direct transgenes in specific tissues of barley and wheat grain. Differential promoter activity across cereals expands and adds value to a promoter toolbox for utility in plant biotechnology.     

Agrobacterium rhizogenes-mediated transformation of scented geranium

A method is described for producing genetically transformed plants from explants of three scentedPelargonium spp. Transgenic hairy root lines were developed fromPelargonium spp leaf explants and microcuttings after inoculation withAgrobacterium rhizogenes strains derived from the agropine A4 strain. Hairy root lines grew prolifically on growth regulator-free medium. Transgenic shoots were regenerated from hairy roots and the plants have been successfully transferred to soil. The phenotype of regenerated plants has been characterized as having abundant root development, more leaves and internodes than the controls, short internodes and highly branched roots and aerial parts. Southern blot analyses have confirmed the transgenic nature of these plants.     

Cowpea embryo rescue. 1. Influence of culture media composition on plant recovery from isolated immature embryos

Factors responsible for successful rescue of immature embryos of cowpea [Vigna unguiculata (L.) Walp.] and V. vexillata (L.) and for in vitro embryo development were studied. A new basal medium for embryo development in vitro was formulated on the basis of the mineral composition of embryos. Sucrose, fructose and glucose were compared as carbohydrate sources. The highest frequency of embryos developing into plants was obtained with sucrose. Adding casein hydrolysate to the medium increased plant recovery by 30%. Among the plant growth factors used, cytokinins, zeatin, 6-benzylaminopurine and kinetin were the most effective in promoting embryo maturation and development. A method that can routinely ensure high plant recovery from cultured immature cowpea embryos is proposed. Received: 4 June 1996 / Revision received: 28 October 1996 / Accepted: 22 November 1996     

In vitro plant regeneration via organogenesis of cowpea [Vigna unguiculata (L.) Walp.]

Shoot regeneration via organogenesis was achieved from axenic cowpea [Vigna unguiculata subsp. unguiculata L. (Walp.) Verde.] hypocotyls and cotyledons of advanced breeding lines and varieties. Cotyledons and embryos were excised from green immature pods. The apical parts of the embryos were removed and the hypocotyls were transferred to regeneration media. Cotyledons and hypocotyls were tested on media with gradients of several hormonal and putrescine combinations. Cowpea cotyledons and hypocotyls exhibited a pattern of shoot formation that occurred in three distinct phases. Multiple shoots developed within 45 days from the wounded region of the primary hypocotyl and cotyledons in different media containing a high cytokinin concentration. The induced plant explants were then grown for 20 days in low-intensity light (10 μmol m^–2 s^–1) on the same medium and numerous shoot buds emerged de novo from the upper part of the hypocotyl and the wounded part of the cotyledons. These buds had no apparent vascular connection with the parent tissues. The plant regeneration capability of this procedure was tested with several cowpea genotypes, five of which (83D-442, 86D-1010, 93K-624, Vita 3 and Ife Brown) responded positively with shoot development and were able to form roots and whole plants. Some somaclonal variation was observed. Received: 14 June 1996 / Revision received: 14 December 1996 / Accepted: 25 January 1997     

Increase of rooting ability in the woody species kiwi (Actinidia deliciosa A. Chev.) by transformation with Agrobacterium rhizogenes rol genes

Summary The woody species kiwi (Actinidia deliciosa A. Chev.), a male and late flowering clone of the cv Hayward, has been transformed by a T-DNA fragment encompassing rol A, B, C genes of A. rhizogenes. Transgenic plants, regenerated from leaf disc callus, showed the typical hairy root phenotype as described in herbaceous species. Explants from these plants (both leaf discs or 3 to 4 node leafy microcuttings) showed an increased ability to produce roots. Since root formation is one of the limiting factors in the vegetative propagation of woody species, the results have been discussed in relation to the use of A. rhizogenes rol genes in improving root morphogenesis in trees.     

Agrobacterium rhizogenes-mediated transformation of scented geranium

A method is described for producing genetically transformed plants from explants of three scentedPelargonium spp. Transgenic hairy root lines were developed fromPelargonium spp leaf explants and microcuttings after inoculation withAgrobacterium rhizogenes strains derived from the agropine A4 strain. Hairy root lines grew prolifically on growth regulator-free medium. Transgenic shoots were regenerated from hairy roots and the plants have been successfully transferred to soil. The phenotype of regenerated plants has been characterized as having abundant root development, more leaves and internodes than the controls, short internodes and highly branched roots and aerial parts. Southern blot analyses have confirmed the transgenic nature of these plants.     

Effect of 2,4-Dichlorophenoxyacetic Acid and NaCl on the Establishment of Callus and Plant Regeneration in Durum and Bread Wheat

Optimal callus induction and plant regeneration were obtained in bread and durum wheat by manipulating the NaCl concentration in the induction medium. Immature embryos from a high regeneration line of spring wheat (Triticum aestivum L.), 'MPB-Bobwhite 26', and an elite durum wheat (Triticum turgidum var. durum L.), 'Mexicali', were cultured in E3 induction medium consisting of Murashige and Skoog (MS) medium, 2.5 mg l^–1 2,4-dichlorophenoxyacetic acid (2,4-D), 2% sucrose and 0.9% Bacto agar. The treated embryos were transferred to E3 liquid medium supplemented with various levels of 2,4-D and NaCl. Incubation on medium containing 2.5 mg l^–1 2,4-D for 45 days produced callus and plant regeneration in 'MPB-Bobwhite 26', but lower callus yield and plant regeneration in 'Mexicali', indicating that 2,4-D alone was not sufficient for callus induction and plant regeneration in this durum variety. Callus yield and regeneration frequencies were higher in 'Mexicali' embryos that were incubated in media containing 2 mg l^–1 2,4-D and 2 mg l^–1 NaCl. The presence of NaCl in the medium beyond the initiation phase was detrimental to plant regeneration. The use of NaCl in the callus formation could form the basis for improved transformation of durum wheat varieties.     

Identification of highly transformable wheat genotypes for mass production of fertile transgenic plants.

The efficiency of wheat biolistic transformation systems strongly depends on the bombardment parameters, the condition of the donor plant, and the plant genotype chosen for the transformation process. This paper analyzes the transformation efficiency of the 129 wheat sister lines generically called 'Bobwhite', originally obtained from the cross 'Aurora'//'Kalyan'/'Bluebird 3'/'Woodpecker'. A number of factors influencing the transformation were examined, such as the ability to produce embryogenic callus, regeneration in selection medium, and overall transformation performance. Of the 129 genotypes evaluated, eight demonstrated transformation efficiencies above 60% (60 independent transgenic events per 100 immature embryos bombarded). Among the eight genotypes identified, we studied agronomic characteristics such as earliness to identify the most adaptable line(s) for different lab conditions. 'Bobwhite' SH 98 26 was identified as a super-transformable wheat line.