Mamestra brassicae (cabbage moth) is a common European moth of the order Lepidoptera and the family Noctuidae. The larval stage is highly polyphagous and is known to feed on more than 70 species of host plants from 22 families, including Brassica species, lettuce, onion, potato, pea, tomato and apple. M. brassicae has become a significant pest also in Asia due to the damage caused to agriculturally and economically important Brassica crops. It is difficult to control M. brassicae using chemical insecticide because of its rapid development of resistance. The objective of our study, therefore, was the mass production and formulation of a local strain of M. brassicae nucleopolyhedrovirus-K1 (MabrNPV-K1) for the development of viral insecticide to control it. In production efficiency of MabrNPV-K1 using M. brassicae larvae, the mortality of the 3rd instar larvae was 100% when inoculated with 1.0 × 105 PIBs/larva and the yield of MabrNPV-K1 was maximal. Regarding the mortality, yield of polyhedra, inoculation doses and required time, the 1.0 × 104 PIBs/larva at 30°C was determined as optimal conditions producing polyhedra efficiently. To formulate MabrNPV-K1, feeding toxicities of various supplements including spreader and ultraviolet (UV) -protectant were determined. Tinopal UNPA-GX which is UV-protectants was effective for protection of polyhedra from UV and showed the increased mortality when added with 1% concentration. Other supplements did not influence significantly the mortality of MabrNPV-K1. Formulated MabrNPV-K1 with several supplements showed higher pathogencity than un-formulated MabrNPV-K1.

The diamondback moth, Plutella xylostella is a one of the most important pests of various cruciferous crops and has a geographically wide ranging habitat. The heavy dependence on chemical pesticides has created severe pesticide resistance problems. In recent years, Bacillus thuringiensis product have been widely used for P. xylostella control bus genetic resistance in populations to some B. thuringiensis strains, compounded by cross-resistance to several different B. thuringiensis toxins, has also been identified. Such recent resistance problems serve to emphasize the urgent need for alternative control agents and their use within an integrated pest management approach. Baculoviruses have been used as agents for the biological control of certain insect pest species. the granuloviruses (GVs), based on the structure of the occluded virus and the occlusion body (OB). Several reports have showed P. xylostella granulovirus (PxGV) as a promise control agent for P. xylostella. However, it is very difficult to study GV because its OB, granule, has very small size and could be observed exactly under the electron microscopy (EM). This study was performed to develop rapid quantification method for granule of PxGV. After the exact quantification of granule with latex beads using EM, the universal extraction method of viral DNA was established for consistent experiment. The number of granules was calculated by the quantification of PCR products for granuline gene using spectrophotometer and densitometer. This novel calculation method for granule would be useful to study GV.