Global warming, plant paraquat resistance, and light signal transduction through nucleoside diphosphate kinase as a paradigm for increasing food supply.

Light signal transduction was studied in extracts of mycelia of the fungus Neurospora crassa, and the third internodes of dark-grown Pisum sativum cv Alaska. Both processes increased the phosphorylation of nucleoside diphosphate kinase (NDPK). NDPK may function as a carrier of reduction equivalents, as it binds NADH, thereby providing electrons to transform singlet oxygen to superoxide by catalases (CAT). As the C-termini of NDPK interact with CAT which receive singlet oxygen, emitted from photoreceptors post light perception (which is transmitted to ambient triplet oxygen), we hypothesize that this may increase phospho-NDPK. Singlet oxygen, emitted from the photoreceptor, also reacts with unsaturated fatty acids in membranes thereby forming malonedialdehyde, which in turn could release ions from, e.g., the thylacoid membrane thereby reducing the rate of photosynthesis. A mutant of Alaska pea, which exhibited two mutations in chloroplast NDPK-2 and one mutation in mitochondrial localized NDPK-3, was resistant to reactive oxygen species including singlet oxygen and showed an increase in the production of carotenoids, anthocyanine, and thereby could reduce the concentration of singlet oxygen. The reduction of the concentration of singlet oxygen is predicted to increase the yield of crop plants, such as Alaska pea, soybean, rice, wheat, barley, and sugarcane. This approach to increase the yield of crop plants may contribute not only to enhance food supply, but also to reduce the concentration of CO(2) in the atmosphere.

[Construction of expression vector with antisense Rubisco activase gene and its genetic transformation in rice].

In this research, Rubisco activase gene (rca) was amplified using specific primers and inserted into pGEM T-easy vector, and then cut with EcoRI after confirming by sequencing. The fragment was subcloned into pBluescript KS+, digested with the enzyme BamHI and inserted into the binary expression vector pCAMBIA1301, and the resulting construction with antisense rca was named pCAMR02. The pCAMR02 vector was introduced into Agrobacterium tumefaciens strain EHA105 by electroporation and transformed to embryos of rice (Oryza. Sativa L.ssp.japonica) cultivar Zhonghua11 via Agrobacterium tumefaciens system. Plantlets were regenerated in vitro by resistance selection on medium containing various concentrations of hygromycin. Both GUS histochemical assays and PCR amplification demonstrated that antisense rca was integrated into T0 genomes and inherited to T1. The measurement of phenotypes of transgenic rice plants with antisense rca showed that most of them could hardly survive at ambient CO2 concentration, even could not grow. The antisense plants that survived under natural condition were dwarf and grew slower than the wild-type controls, and their contents of RCA and Rubisco changed significantly. These plants generated in this experiment will be used to study the relationship between RCA and Rubisco and their regulation.