SummaryPlants contain two genes that code for poly(ADP-ribose) polymerase (PARP): parp1 and parp2. Both PARPs are activated by DNA damage caused by, example reactive oxygen species. Upon activation polymers of ADPribose are synthesized on a range of nuclear enzymes using NAD + as substrate. Here, we show that in plants stresses such as drought, high light and heat activate PARP causing NAD + breakdown and ATP consumption.When the PARP activity is reduced by means of chemical inhibitors or by gene silencing, cell death is inhibited and plants become tolerant to a broad range of abiotic stresses like high light, drought and heat. Plant lines with low poly(ADP-ribosyl)ation activity maintain under stress conditions their energy homeostasis by reducing NAD + breakdown and consequently energy consumption. The higher energy-use efficiency avoids the need for a too intense mitochondrial respiration and consequently reduces the formation of reactive oxygen species. From these results it can be concluded that breeding or engineering for a high energy-use efficiency under stress conditions is a valuable, but until today nearly unexploited, approach to enhance overall stress tolerance of crops.
An efficient and largely genotype-independent transformation method for Brassica napus and Brassica oleracea was established based on neo or bar as selectable marker genes. Hypocotyl explants of Brassica napus and Brassica oleracea cultivars were infected with Agrobacterium strains containing chimeric neo and bar genes. The use of AgNO3 was a prerequisite for efficient shoot regeneration under selective conditions. Vitrification was avoided by decreasing the water potential of the medium, by decreasing the relative humidity in the tissue culture vessel, and by lowering the cytokinin concentration. In this way, rooted transformed shoots were obtained with a 30% efficiency in 9 to 12 weeks. Southern blottings and genetic analysis of SI-progeny showed that the transformants contained on average between one and three copies of the chimeric genes. A wide range of expression levels of the chimeric genes was observed among independent transformants. Up to 25% of the transformants showed no detectable phosphinotricin acetyltransferase or neomycin phosphotransferase 11 enzyme activities although Southern blottings demonstrated that these plants were indeed transformed.
Oilseed rape ( Brassica napus L.) genotypes with no or small petals are thought to have advantages in photosynthetic activity. The flowers of field-grown oilseed rape form a bright-yellow canopy that reflects and absorbs nearly 60% of the photosynthetically active radiation (PAR), causing a severe yield penalty. Reducing the size of the petals and/or removing the reflecting colour will improve the transmission of PAR to the leaves and is expected to increase the crop productivity. In this study the 'hairpin' RNA-mediated (hpRNA) gene silencing technology was implemented in Arabidopsis thaliana (L.) Heynh. and B. napus to silence B-type MADS-box floral organ identity genes in a second-whorl-specific manner. In Arabidopsis, silencing of B-type MADS-box genes was obtained by expressing B. napus APETALA3( BAP3) or PISTILLATA ( BPI) homologous self-complementary hpRNA constructs under control of the Arabidopsis A-type MADS-box gene APETALA1 ( AP1) promoter. In B. napus, silencing of the BPI gene family was achieved by expressing a similar hpRNA construct as used in Arabidopsis under the control of a chimeric promoter consisting of a modified petal-specific Arabidopsis AP3 promoter fragment fused to the AP1 promoter. In this way, transgenic plants were generated producing male fertile flowers in which the petals were converted into sepals ( Arabidopsis) or into sepaloid petals ( B. napus). These novel flower phenotypes were stable and heritable in both species.
Protoplast fusion studies between various auxotrophic mutants of Nicotiana plumbaginifolia were performed to optimize conditions for PEG-mediated fusion and to identify factors influencing the plant protoplast fusion process. Numerous parameters in the isolation, culture, and fusion of protoplasts were tested, and established fusion protocols were compared. Fusion rates, calculated on the basis of colony growth on selection medium (genetic complementation), ranged from 10(-4) to 10(-2). Conditions that allow rapid and reproducible fusions at the highest rates were established. Particular emphasis was given to fusion of mesophyll-derived protoplasts, for which the ability to regenerate fertile plants from fusion products was shown to be particularly high. Preliminary experiments using electric-field mediated fusion suggest that electrofusion may offer significant advantages over the traditional chemical fusion.
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