Simultaneous analysis of the bidirectional African cassava mosaic virus promoter activity using two different luciferase genes.

The expression of geminivirus genes is controlled by bidirectional promoters which are located in the large intergenic region of the circular DNA genomes and specifically regulated by virus encoded proteins. In order to study the simultaneous regulation of both orientations of the DNA A and DNA B promoters of African cassava mosaic virus (ACMV), they were cloned between two different luciferase genes with the firefly luciferase gene in complementary-sense and the Renilla luciferase gene in virion-sense orientation. The regulation of the ACMV promoters by proteins encoded by the complete DNA A, as well as by the individually expressed transactivator (TrAP) or replication-associated (Rep) proteins was assessed in tobacco and cassava protoplasts using dual luciferase assays. In addition, the regulation of the DNA A promoter integrated into tobacco genome was also assessed. The results show that TrAP activates virion-sense expression strongly both in cassava and tobacco protoplasts, but not in transgenic tobacco plants. In contrast to this, DNA A encoded proteins activate virion-sense expression both in protoplasts and in transgenic plants. At the same time they reduce the expression of the complementary-sense Rep gene on DNA A but activate the expression of the complementary-sense movement protein (MPB) gene on DNA B. The degree of MBP activation is higher in cassava than in tobacco protoplasts, indicating that the plant host also influences the promoter strength. Transient transformation experiments using linearized DNA indicate that the different regulation of the ACMV DNA A promoter in protoplasts and transgenic plants could be due to different DNA curvature in free plasmids and in genes integrated in plant genomic DNA.

Efficient production of transgenic cassava using negative and positive selection.

In order to improve the efficiency of cassava (Manihot esculenta Crantz) transformation, two different selection systems were assessed, a positive one based on the use of mannose as the selective agent, and a negative one based on hygromycin resistance encoded by an intron-containing hph gene. Transgenic plants selected on mannose or hygromycin were regenerated for the first time from embryogenic suspensions cocultivated with Agrobacterium. After the initial selection using mannose and hygromycin, 82.6% and 100% of the respective developing embryogenic callus lines were transgenic. A system allowing plant regeneration from only transgenic lines was designed by combining chemical selection with histochemical GUS assays. In total, 12 morphologically normal transgenic plant lines were produced, five using mannose and seven using hygromycin. The stable integration of the transgenes into the nuclear genome was verified using PCR and Southern analysis. RT-PCR and northern analyses confirmed the transgene expression in the regenerated plants. A rooting test on mannose containing medium was developed as an alternative to GUS assays in order to eliminate escapes from the positive selection system. Our results show that transgenic cassava plants can be obtained by using either antibiotic resistance genes that are not expressed in the micro-organisms or an antibiotic-free positive selection system.

PIG-mediated cassava transformation using positive and negative selection.

In order to develop new selection systems for production of transgenic cassava (Manihot esculenta Crantz), two different selection regimes were assessed for their efficiency on regeneration of transgenic cassava plants: positive selection using mannose and negative selection using hygromycin. Explants from somatic cotyledons and embryogenic suspensions were used as target tissues in the transformation experiments and bombarded using the particle inflow gun. Different culture and selection strategies were assessed to optimise the selection protocols. For the first time transgenic plants could be obtained using positive, and in the case of embryogenic suspensions, hygromycin-based negative selection. The stably transformed nature of the regenerated cassava plant lines and the expression of the transgenes were verified with PCR, RT-PCR, Southern and northern analyses. A rooting test for transgenic plants on a medium supplemented with mannose was developed to further improve the efficacy of the positive selection system. Our results demonstrate that it is possible to obtain transgenic cassava plants using non-antibiotic positive selection.

Production of stably transformed cassava plants via particle bombardment.

A novel protocol, based on biolistics and regeneration via organogenesis, was developed for genetic transformation of cassava (Manihot esculenta Crantz). The in vitro performance of cassava cultivars CMC40, MPer183 and MCol22 was evaluated, and the regeneration protocol was modified to improve shoot production from explants for transformation experiments. Somatic cotyledons were used as a target tissue in the transformation experiments using the Particle Inflow Gun and a plasmid containing the uidA gene in transient assays. The effect of different parameters for particle bombardment efficiency, including the amount of DNA used, the flying distance of the projectiles and the pre- and post-plasmolysis time of the target tissue, was evaluated and the conditions were partially optimised. Stably transformed cassava plants of cvs. MCol22 and TMS60444 were produced using the partially optimised conditions and two different vector constructs carrying the hpt gene as the selectable marker. The selection protocol was optimised further, and a rooting test was developed for screening the regenerants for antibiotic resistance to reduce the number of escapes obtained after primary selection. The production of stably transformed cassava lines and the expression of the transgenes was verified by Southern blot analysis and RT-PCR.

Regeneration of cassava plants via shoot organogenesis.

A novel regeneration system based on direct shoot organogenesis is described for cassava. Plants could be regenerated at high frequency by inducing shoot primordia on explants derived from cotyledons of cassava somatic embryos. After a passage on elongation medium, the regenerated shoots were easily rooted in hormone-free medium and could be successfully transplanted to soil. Using the shoot-organogenesis-based regeneration method, up to eight transplantable plantlets per explant could be regenerated. The system was optimised first for one cassava cultivar, and then its transferability to three other cultivars was demonstrated. This method widens the scope of in vitro regeneration modes of cassava, and is also compatible with Agrobacterium-mediated transformation. To develop an efficient system for production of somatic embryos for regeneration experiments, conditions for inducing primary and cycling somatic embryos were also studied, and highly efficient plant regeneration via germination of somatic embryos was achieved using maltose instead of sucrose in the culture medium, and combining paclobutrazol with 2,4-dichlorophenoxyacetic acid in the embryo induction medium.

Genetic transformation of cassava (Manihot esculenta Crantz).

Genetic engineering can be used to complement traditional breeding methods in crop plant improvement. Transfer of genes from heterologous species provides the means of selectively introducing new traits into crop plants and expanding the gene pool beyond what has been available to traditional breeding systems. The prerequisites for genetic engineering are efficient transformation and tissue culture systems that allow selection and regeneration of transgenic plants. Cassava, an integral plant for food security in developing countries, has until now been recalcitrant to transformation approaches. We report here a method for regenerating stably transformed cassava plants after cocultivation with Agrobacterium tumefaciens, which opens cassava for future improvement via biotechnology.

Inheritance of a bacterial hygromycin phosphotransferase gene in the progeny of primary transgenic pea plants.

An analysis of the progeny of primary transgenic pea plants in terms of transmission of the transferred DNA, fertility and morphology is presented. A transformation system developed for pea that allows the regeneration of fertile transgenic pea plants from calli selected for antibiotic resistance was used. Expiants from axenic shoot cultures were co-cultivated with a nononcogenic Agrobacterium tumefaciens strain carrying a gene encoding hygromycin phosphotransferase as selectable marker, and transformed callus could be selected on callus-inducing media containing 15 mg/l hygromycin. After several passages on regeneration medium, shoot organogenesis could be reproducibly induced on the hygromycin resistant calli, and the regenerated shoots could subsequently be rooted and transferred to the greenhouse, where they proceeded to flower and set seed. The transmission of the introduced gene into the progeny of the regenerated transgenic plants was studied over two generations, and stable transmission was shown to take place. The transgenic nature of the calli and regenerated plants and their progeny was confirmed by DNA and RNA analysis. The DNA and ploidy levels of the progeny plants and primary regenerants were studied by chromosome analysis, and the offspring of the primary transformants were evaluated morphologically.

Production of transgenic pea (Pisum sativum L.) plants by Agrobacterium tumefaciens - mediated gene transfer.

A transformation system that allows regeneration of transgenic pea plants from calli selected for antibiotic resistance was developed. Explants from axenic shoot cultures and seedling epicotyls were cocultivated with nononcogenic Agrobacterium tumefaciens strains, and transformed callus could be selected on callus-inducing media containing either 15 mg/l hygromycin or 75 mg/l kanamycin. After several passages on regeneration medium, shoot organogenesis could be reproducibly induced on hygromycin-resistant calli, but not on the calli selected for kanamycin resistance. Regenerated shoots could subsequently be rooted and transferred into the greenhouse. In addition, the effects of different callus-inducing and growth media on organogenesis were investigated. The transformation of the calli and regenerated plants was confirmed by DNA analysis.

Transformation of pea (Pisum sativum L.) byAgrobacterium tumefaciens.

Explants fromPisum sativum shoot cultures and epicotyls were transformed by cocultivation withAgrobacterium tumefaciens vectors carrying plant selectable markers and transformants could be selected on a medium containing kanamycin. Transformants could also be obtained at a low frequency by cocultivating small protoplast-derived colonies. The transformed nature of the calli obtained from selection was confirmed by opine assay and DNA analysis. In addition five cultivars of pea were tested for their response to seven differentAgrobacterium tumefaciens strains. The response pattern coincided largely between the different pea cultivars, being more dependent on the bacterial strain than the cultivar used.

Improved protoplast culture and regeneration of shoots in pea (Pisum sativum L.).

An improved system involving a modification of the bead culture system was developed for culturing pea protoplasts. Using this method, sustained divisions and callus growth could be obtained in all 10 cultivars tested. In the best responding cultivar division frequency could be raised from 17% in liquid culture to 80% in the bead system. Shoot regeneration with a reproducible frequency of about 1% could be obtained from protoplast-derived calli in two of the tested cultivars.