Effects of photoperiod and temperature on the rhythm and free‐running of adult eclosion in the Indian meal moth Plodia interpunctella

The rhythm of adult eclosion in the Indian meal moth Plodia interpunctella Hübner (Lepidoptera: Pyralidae) is investigated under various photoperiods and temperatures aiming to determine the nature of the temperature compensation and the free‐running period. Insects that are committed to a nondiapause larval development show diel rhythms of adult eclosion at 30, 25 and 20 °C. At 30 °C, the eclosion peak (i.e. the mean time of eclosion) occurs approximately 20 h after lights off under an LD 4 : 20 h photocycle, and at approximately 15 h under an LD 20 : 4 h photocycle. At 25 °C, the peak of eclosion occurs approximately 19 h after lights off under an LD 2 : 20 h photocycle and at approximately 16 h under an LD 20 : 4 h photocycle. At 20 °C, the eclosion peak is significantly advanced under long days of >12 h (i.e. approximately 20 h after lights off under an LD 4 : 20 h photocycle and approximately 9 h under an LD 20 : 4 h photocycle), indicating an effect of both lights‐off and lights‐on signals on the timing of the adult eclosion. To determine the involvement of a self‐sustained oscillator, the rhythm of adult eclosion is examined under darkness at different temperatures (30 to 21 °C). The mean free‐running periods are 22.4, 22.8, 22.0 and 22.5 h at 30, 24, 23 and 22 °C, respectively, indicating that the eclosion rhythm is temperature‐compensated. However, this rhythm does not free‐run under constant darkness at 21 °C. Because a clear diel rhythm is observed under 24‐h photocycles at 20 °C, the oscillator might be damped out within 24 h at the lower temperature.     

Analysis of Rice Mutants by Low Temperature-Derivative Spectrophotometry in Relation to Pigment Compositions and Photochemical Activities

The chloroplasts of five rice (Oryza sativa) mutants examined in the present study possessed the following pigment and activity characteristics as compared with those of normal strain (Nohrin No. 8); a) less chlorophylls (especially, chlorophyll b, the molar ratio of a to b= 6 ～ 41) and less carotenoids but higher ratios of β-carotene to chlorophylls; b) only photosystem 1 particles were obtained by density gradient centrifugation of digitonin-treated mutant chloroplasts while both photosystem 1 and 2 particles were obtained from normal strain chloroplasts; c) the photosystem 2 activities of mutant chloroplasts were lower (48 ～ 81 %) than that of normal chloroplasts while their photosystem 1 activities were 1.9 ～ 2.4 times higher. The derivative absorption spectrum of the normal chloroplasts (a/b= 4) measured at liquid nitrogen temperature showed many small but distinct maxima and minima in the red region in addition to those observable for chlorophylls in solution. These band structures including the French inflection were lost partially in the derivative spectra of three mutants with a/b= 6, 8 and 11 and almost completely in those of the remaining two mutants with a/b= 18 and 41. The lack of such band structures reflecting specific states of chlorophylls in vivo was attributed to the absence of some conformational structures such as those expected in photosystem-2 particles, which are formed by the presence of chlorophyll b and are resistant to the digitonin treatment. Chlorophylls in specific states in such structures were thought to exhibit a higher photosystem 2 activity.