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Myung Eul-Jae,Kwon Yong-Woong,Lee Byun-Woo The Korean Society of Crop Science 2004 Korean journal of crop science Vol.49 No.5
The deep irrigation of rice plants brings about some beneficial effects such as reduced tiller production which results in the formation of bigger panicles, prevention of chilling injury, reduced weed growth, etc. The present study was carried out to examine the involvement of ethylene in the suppression of tiller production due to deep water irrigation in rice (cv. Dongjinbyeo). The ethylene production was induced in leaf sheath within 24 hours after the deep water irrigation and has increased even until 30 days after the treatment, recording 4.5-fold increase as compared to the shallow-irrigated rice plants. In the deep water irrigated rice plants, ethylene was accumulated to a high concentration in the air space of submerged leaf sheath as the irrigated water deterred the diffusion of ethylene out of the leaf sheath and ethylene biosynthesis was accelerated by the deep irrigation as well. The ethylene concentration recorded 35-fold increase in the deep-irrigated rice plants for 35 days. The tiller production was reduced significantly by the deep irrigation with water, the tiller bud, especially tertiary tiller bud differentiation being suppressed by the deepwater irrigation treatment, whereas the rice plants deep-irrigated with solutions containing $10^{-5}$ M or $10^{-6}$ M silver thiosulfate (STS), an action inhibitor of ethylene, showed the same or even higher production of tillers than those irrigated shallowly with water. This implies that the ethylene is closely linked with the suppression of tiller production due to deep water irrigation. In conclusion, ethylene, which was induced by hypoxic stress and accumulated in the leaf sheath due to submergence, played a key role in suppressing the tiller production of the deepwater irrigated rice.
Eul-Jae Myung,권용웅,이변우 한국작물학회 2004 Korean journal of crop science Vol.49 No.6
The deep irrigation of rice plants brings about some beneficial effects such as reduced tiller production which results in the formation of bigger panicles, prevention of chilling injury, reduced weed growth, etc. The present study was carried out to examine the involvement of ethylene in the suppression of tiller production due to deep water irrigation in rice (cv. Dongjinbyeo). The ethylene production was induced in leaf sheath within 24 hours after the deep water irrigation and has increased even until 30 days after the treatment, recording 4.5-fold increase as compared to the shallow-irrigated rice plants. In the deep water irrigated rice plants, ethylene was accumulated to a high concentration in the air space of submerged leaf sheath as the irrigated water deterred the diffusion of ethylene out of the leaf sheath and ethylene biosynthesis was accelerated by the deep irrigation as well. The ethylene concentration recorded 35-fold increase in the deep-irrigated rice plants for 35 days. The tiller production was reduced significantly by the deep irrigation with water, the tiller bud, especially tertiary tiller bud differentiation being suppressed by the deepwater irrigation treatment, whereas the rice plants deep-irrigated with solutions containing 10-5 M or 10-6 M silver thiosulfate (STS), an action inhibitor of ethylene, showed the same or even higher production of tillers than those irrigated shallowly with water. This implies that the ethylene is closely linked with the suppression of tiller production due to deep water irrigation. In conclusion, ethylene, which was induced by hypoxic stress and accumulated in the leaf sheath due to submergence, played a key role in suppressing the tiller production of the deepwater irrigated rice.
Eul-Jae Myung,Yong-Woong Kwon,Byun-Woo Lee 韓國作物學會 2004 Korean journal of crop science Vol.49 No.5
The deep irrigation of rice plants brings about some beneficial effects such as reduced tiller production which results in the formation of bigger panicles, prevention of chilling injury, reduced weed growth, etc. The present study was carried out to examine the involvement of ethylene in the suppression of tiller production due to deep water irrigation in rice (cv. Dongjinbyeo). The ethylene production was induced in leaf sheath within 24 hours after the deep water irrigation and has increased even until 30 days after the treatment, recording 4.5-fold increase as compared to the shallow-irrigated rice plants. In the deep water irrigated rice plants, ethylene was accumulated to a high concentration in the air space of submerged leaf sheath as the irrigated water deterred the diffusion of ethylene out of the leaf sheath and ethylene biosynthesis was accelerated by the deep irrigation as well. The ethylene concentration recorded 35-fold increase in the deep-irrigated rice plants for 35 days. The tiller production was reduced significantly by the deep irrigation with water, the tiller bud, especially tertiary tiller bud differentiation being suppressed by the deepwater irrigation treatment, whereas the rice plants deep-irrigated with solutions containing 10-5 M or 10-6 M silver thiosulfate (STS), an action inhibitor of ethylene, showed the same or even higher production of tillers than those irrigated shallowly with water. This implies that the ethylene is closely linked with the suppression of tiller production due to deep water irrigation. In conclusion, ethylene, which was induced by hypoxic stress and accumulated in the leaf sheath due to submergence, played a key role in suppressing the tiller production of the deepwater irrigated rice
신명자(Myung Ja Shin),김경근(Kyoung Keun Kim),임재환(Jae Hwan Lim),정형진(Hyung Jin Jeong),서을원(Eul Won Seo) 한국생명과학회 2009 생명과학회지 Vol.19 No.2
본 연구에서는 호랑나비의 용기 동안 혈림프, 지방체, 표피, 큐티클 및 중장에서 항산화효소의 활성을 조사하였다. 혈림프와 지방체에서 항산화효소 활성의 변화가 두드러지게 나타났다. SOD, CAT 및 GST의 활성은 높은 활성을 보인 반면, GPX와 GR은 상대적으로 활성이 매우 낮으므로 곤충의 변태기 동안 항산화과정에서 이들 효소의 역할은 매우 미미할 것으로 생각된다. 더불어 CAT의 활성은 대부분의 조직에서 용화 직후에 높은 활성을 보이며 상대적인 활성도 매우 높게 나타나고 있어 과산화수소의 분해에는 GPX보다는 CAT가 주로 관여할 것으로 생각된다. 또한 GPX와 GR의 활성보다는 GST의 활성이 전 조직에서 비교적 높게 나타나는 것으로 보아 lipid peroxidation을 통한 항산화 과정에도 GPX보다는 주로 GST가 관여할 것으로 생각된다. The purpose of this study is to evaluate the activities of five different antioxidant enzymes in various tissues of Papilio xuthus during pupal stage. Superoxide dismutase (SOD) activity in haemolymph was the highest just after pupation and then decreased gradually until 7 days after pupation but the activity in other tissue was constant during metamorphosis. This result indicates that primary antioxidant process of reactive oxygen species proceed in haemolymph. Catalase (CAT) activity in studied tissues was also the highest just after pupation and its relative activity was also high during pupal stage, suggesting that CAT is the primary enzyme in catalysis of hydrogen peroxide. Glutathion peroxidase (GPX) activity was constant and its relative activity was very low in all tested tissues. Glutathione S-transferase (GST) activity in haemolymph was high at 3 days and 5 days after pupation, and the activity in fat body was the highest at the 1 day after pupation and then decreased gradually for 7 days after pupation. Glutathion reductase (GR) activity in haemolymph and fat body was high at 1 day after pupation, but relatively low GR activity was detected in the rest tissues. Based on these results, GST activity was higher than that of GPX and GR, and it is also believed that GST was more involved in reduction process through lipid peroxidation than GPX.