This study was conducted to investigate the impacts of male incubating behaviour on hatching rate of giant water bug from May 2, 2011 to September 2, 2012 in the laboratory(24.1±0.2℃) in HECRI. The giant water bug, Lethocerus deyrollei, is the largest aquatic insect in Korea (length, Female: 63.5±0.4mm, Male: 54.0±0.3mm). L. deyrollei has been designated as an endangered species by the Ministry of Environment of Korea since 1997. L. deyrollei lay eggs as clusters on stems or vegetation of aquatic plants above the water. Males do not leave the stems which eggs are sticked until eggs hatched because they protect eggs against predators and supply water to eggs. The incubating behavior of male L. deyrollei was observed three times a day, 06:00, 13:00 and 19:00 respectively and 32 egg-clusters were used. Three treatment - presence of male incubation, absence of male incubation, and artificial removing male - were manipulated to observe the hatching rate of egg masses. There were different hatching rates between presence (67.2%) and absence (1.9%) of male incubatng behavior. In case of artificial removing male, eggs could not hatch. The mean diameter of eggs(2.87±0.03mm) which male incubated was bigger than that of eggs(2.18±0.03mm) which male did not care.

Papilio macilentus is the longest tail butterfly of Papilionidae found in Japan, China and Korea and has distinctive morphological differences between male and female. P .macilentus feeds on Zanthoxylum schinifolium and has three generations per year. The lower developmental threshold and thermal constant for adult emergence of P. macilentus overwintering pupae were estimated at four different constant temperatures (15, 20, 25 and 30°C) with photoperiod 10:14 (L:D). The lower developmental threshold of both sexes combined was 7.95°C. The development of overwintering pupae decreased with increasing temperature between 15 and 30°C. Thermal constant of both sexes combined was 251.26DD. The relationship between the developmental rate and temperature was fitted by linear and five nonlinear developmental rate models (Logan 6, Lactin 1, 2 and Briere 1, 2). The development of overwintering P. macilentus pupae was described by the two-parameter Weibull distribution model. The temperature-dependent adult emergence model of P. macilentus developed in this study could be used to predict the full-cycle phenology model of P. macilentus and applied to understand the effects of climate change on the emergence distribution of overwintering pupae.