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수원 지방에서 조명나방 휴면과 발생 세대수 및 휴면유도에 대한 유충의 민감성

Diapause and Voltinism in Ostrinia furnacalis (Lepidoptera: Crambidae) in Suwon, and Larval Instar Sensitivity to Diapause Induction

  • 김은영 (국립식량과학원 재배환경과) ;
  • 김이현 (국립식량과학원 재배환경과) ;
  • 서보윤 (국립농업과학원 작물보호과) ;
  • 김용균 (안동대학교 식물의학과) ;
  • 박창규 (국립한국농수산대학 산업곤충과) ;
  • 정진교 (국립식량과학원 재배환경과)
  • Kim, Eun Young (Crop Cultivation and Environment Research Division, National Institute of Crop Science, Rural Development Administration) ;
  • Kim, I Hyeon (Crop Cultivation and Environment Research Division, National Institute of Crop Science, Rural Development Administration) ;
  • Seo, Bo Yoon (Crop Protection Division, National Institute of Agricultural Sciences, Rural Development Administration) ;
  • Kim, Yonggyun (Department of Plant Medicals, Andong National University) ;
  • Park, Chang-Gyu (Department of Industrial Entomology, Korea National College of Agriculture and Fisheries) ;
  • Jung, Jin Kyo (Crop Cultivation and Environment Research Division, National Institute of Crop Science, Rural Development Administration)
  • Received : 2020.04.29
  • Accepted : 2020.07.23
  • Published : 2020.09.01

Abstract

수원 지방에서 조명나방(Ostrinia furnacalis)(나비목: 포충나방과) 성충 발생횟수와 유충 휴면이 유도되는 시기를 분석하였다. 성충은 일년에 3회 발생 하였는데, 1화기는 5월 초부터 7월 초까지, 2화기는 7월 초중순부터 8월 초중순까지, 3화기는 8월 중순부터 10월까지이었다. 7월말부터 8월 중순 사이에 갓부화 유충을 야외에서 사육하기 시작하였을 때, 그 해와 이듬해 용화한 개체들이 같이 발생하였다. 이후 사육된 집단에서는 모두 월동 유충들만 출현하였다. 야외에서 7월과 8월 중 채집된 유충들에서는 월동하거나 월동하지 않는 개체들이 같이 발생하였고, 이후 채집된 개체들에서는 모두 월동하는 개체들만 나타났다. 이 결과들은 수원에서 조명나방은 연중 2세대와 3세대를 경과하는 개체들이 같이 발생하는 복합 생활사를 갖는 것을 보였다. 실험실에서, 조명나방 유충을 영기별로 탈피 직후(9시간 이내)에 휴면유도 조건(11:13 시간 = 명:암 광주기, 20℃)에 처음 처리하였을 때, 거의 모든 유충들에서 휴면이 유도되었다. 유사한 처리를 5령으로 탈피한 유충 나이별로 적용하였을 때, 5령 3일과 4일 나이의 유충에 대한 처리에서는 휴면유도율이 감소하였다. 한편 알에서 갓 부화했을 때부터 휴면유도 조건에서 사육하던 유충들을 3령, 4령, 5령 탈피 직후에 비휴면 조건으로 옮겼을 때, 거의 대부분의 유충들은 휴면에 유도되지 않았다. 그 결과로부터 5령 초기 나이의 유충들이 휴면유도 자극에 반응하는 최종 단계라고 추정되었다. 비휴면 유충들에 비해, 휴면이 유도된 유충들에서는 혈림프 내 트레할로스 함량이 증가하였고, 몸체 과냉각점이 낮아졌다.

The diapause induction season in Ostrinia furnacalis (Lepidoptera: Crambidae) was estimated in Suwon. Three batches of adult generations were observed, the first one from early May to early July, the second from early or mid-July to early or mid-August, and the third from mid-August to October. In outdoor larval rearing, colony rearing occurring from mid-July to mid-August produced both non-overwintering and overwintering larvae, whereas late-reared colonies produced only overwintering larvae. Larvae collected during July and August in maize fields produced both non-overwintering and overwintering larvae, whereas late-collected larvae produced only overwintering larvae. The results indicated that O. furnacalis has a bi- or trivoltine complex life cycle in this area. In the laboratory, when larvae of all instars within 9 h after molting were first treated to a diapause induction condition (11:13 h = light:dark photoperiod and 20℃), almost all larvae were induced to diapause. However, when similar treatments were conducted age-specifically for the 5th instar larvae, diapause induction rates in 3- and 4-day-old larvae of the 5th instar decreased. In contrast, when larvae were subjected to the diapause induction treatment only during the periods from the hatching stage to the 2nd, 3rd, and 4th instar, almost all larvae were not induced to diapause. The results suggest that the early age of the 5th larval instar is the last stage for sensitivity to diapause induction stimuli. In the diapause-induced larvae, hemolymph trehalose content increased and body supercooling points dropped, compared with those in non-diapause larvae.

Keywords

References

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