This study was conducted to identify an insect species in Genus Ostrinia (Lepidoptera: Crambidae) that gave serious damage to the red bean, Vigna angularis. The species has ever been described as O. zaguliaevi in the previous presentation (Jung et al., 2010). Because, however, inconsistent information has been recognized for the species, we reviewed characteristics in morphological, molecular and sex pheromone levels, and host-range. Male genitalia had 3-lobed uncus and tibia of midleg showed massive type. The morphology indicated that the species might be one of O. zaguliaevi, O. scapulalis and O. zealis. Partial nucleotide sequences of cytochrome oxidase subunit Ⅰ(COⅠ) and Ⅱ genes were not identical with those of the 3 species in GenBank, respectively. The deduced amino acid sequence of COⅠ was not identical with that of O. zealis. In the 23 analyses that sex pheromones were checked, (Z)-9-tetradecenyl acetate, which was reported in the sex pheromone components of both O. zaguliaevi and O. zealis, was not detected at all. An intensive study in Japan has reported that the feeding habit of O. scapulalis is polyphagous, while that of O. zaguliaevi is monophagous (only in Petasites japonicus) (Ishikawa et al., 1999). After considering all these information, we concluded that it is reasonable to decide that the insect species in the red bean in Korea is O. scapulalis.

Ostrinia zaguliaevi (Lepidoptera: Crambidae) causes serious damage to pods and stems of the red bean, Vigna angularis, during the second half of the reproductive developmental stage. The temperature-dependent development studies of O. zaguliaevi were performed at several constant temperatures ranging from 7℃ to 36℃ in the laboratory, in the purpose of making temperature-dependent development models in the future. Eggs and larvae of O. zaguliaevi could not develop at lower temperatures of 7~13℃. As the temperature increased, the developmental period of the immature stage decreased. The number of larval instar was variable from 5 to 8, depending on temperature. The minimum number of larval instar was observed at only 25℃. Some larvae of colonies maintained at 16~22℃ showed highly longer developmental period. At relatively higher temperatures, 34℃ and 36℃, the larval developmental rates were not slowed down, and the larval survival rates was relatively high, above 60%. The egg mortality was relatively high at 36℃. Using these temperature-dependent development data of O. zaguliaevi, preliminary linear regression equations were estimated to look for a relationship between temperature and developmental rate in egg and larval stages.