Polydnaviruses (PDVs) are a group of insect viruses and symbiotic to some endoparasitoid wasps. Genome analyses of different PDVs provide a number of genes putatively associated with alteration of host insect physiological processes. Especially, PDV gene products assist host wasp development by suppressing immune responses and delaying larval development of parasitized lepidopteran hosts. Thus, PDV genes can be applied to control insect pests by incorporating them into crop genomes. This talk illustrates two examples of PDV genes: CpBV-CST1 and CpBV-ELP1. CpBV-CST1 has been known to inhibit insect cysteine proteases to suppress immune and development, while CpBV-ELP1 exhibits a high cytotoxicity to insect cells. Transgenic tobaccos expressing CpBV-CST1 or CpBV-ELP1 were constructed by using Agrobacterium-mediated transgenic system and exhibited antixenosis against chewing and sucking insect pests on tobacco.

To assess resistance of transgenic tobacco plants which overexpress superoxide dismutase (SOD) and ascorbate peroxidase (APX) in chloroplasts to water stress, changes in leaf water potential, turgor potential, stomatal conductance and transpiration rate were measured. Leaf water potential in all plants remained high up to day 4 after withholding water but thereafter decreased markedly. In spite of a remarkable decrease in leaf water potential, some of transgenic plants maintained higher turgor potential compared with control plant on day 12. In particular, the transgenic plant expressing MnSOD showed an outstanding maintenance in turgor pressure by osmotic adjustment throughout the experiment, resulting in high stomatal conductance and transpiration rate. However, among transgenic plants, osmotic potential was reduced more effectively in multiple transformants such as the double transformant expressing both MnSOD and APX, and the triple transformant expressing CuznSOD, MnSOD and APX than single transformants. Consequently, further research is needed to get general agreement on the tolerance of transgenic plants to water stress at different growth stages for each transgenic plant.