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【目的】明确金纹细蛾Lithocolletis ringoniella自身生理状态下的飞行能力,了解其飞行生物学的基础参数。【方法】利用昆虫飞行磨系统,室内测定了金纹细蛾雌雄成虫不同日龄和性别以及5日龄雌雄成虫补充营养(5%蜂蜜水)与交配状态下的飞行距离、飞行时间、飞行速度等参数。【结果】连续吊飞12 h的结果显示,金纹细蛾3-6日龄成虫飞行能力较强,5日龄成虫飞行能力最强; 5日龄雌成虫的平均
飞行距离、飞行时间和飞行速度分别为2.293±0.254 km, 5.341±0.617 h和0.711±0.126 km/h, 5日龄雄成虫的平均飞行距离、飞行时间和飞行速度分别为2.142±0.276 km, 5.132±0.628 h和0.620±0.132 km/h, 说明雌雄成虫间飞行能力差异不显著。金纹细蛾5日龄雌雄成虫取食5%蜂蜜水后其飞行能力较对照显著提高,取食5%蜂蜜水后5日龄雌成虫的飞行距离、飞行时间和飞行速度较对照(取食清水)的分别提高46.945%, 15.430%和15.978%;5日龄雄成虫的飞行距离、飞行时间和飞行速度较对照分别提高42.610%, 13.590%和6.529%。交配后5日龄雌成虫的飞行距离、飞行时间和飞行速度较未交配雌成虫的分别提高41.628%, 7.152%和39.925%,而5日龄雄成虫交配后飞行能力则较未交配雄成虫的分别降低35.823%, 17.888%和46.129%。【结论】金纹细蛾成虫具有一定的飞行能力,补充营养和雌雄交配状态对飞行能力有重要影响。 相似文献
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Physiology of diapause and cold hardiness in overwintering pupae of the apple leaf miner Phyllonorycter ringoniella in Japan 总被引:1,自引:0,他引:1
Abstract The apple leaf miner Phyllonorycter ringoniella (Matsumura) (Lepidoptera: Gracillariidae) overwinters as a diapausing pupa. The diapause rate reaches 100% in early October. Diapause intensity decreases gradually from early October and diapause terminates in early February. The fresh body weight of diapausing pupae is 1.6 times that of non-diapausing pupae. The main cryoprotectant in P. ringoniella pupae is trehalose. Three stages are distinguishable as indicated by the correlations between diapause intensity, levels of cold hardiness and the trehalose content: diapause induction occurred in October, diapause development from November to December, and post-diapause quiescence from January to April. During diapause induction, the pupae accumulate low levels of trehalose and do not survive exposure to −15 °C. During diapause development, the pupae gradually accumulate more trehalose and show some ability to survive exposure to −15 °C, but not to −20 °C. During post-diapause quiescence, the pupae accumulate relatively more trehalose and cold hardiness fully develops, but decreases quickly in April. The trehalose content in pupae sampled in December is unaffected by acclimation temperatures in the range 0–30 °C, but decreases in pupae sampled in March after acclimation at temperatures from 5 to 15 °C. These results suggest that overwintering pupae of P. ringoniella have the ability to accumulate trehalose and develop a high level of cold hardiness during diapause development. 相似文献
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氯虫苯甲酰胺对苹果树桃小食心虫及金纹细蛾的控制作用 总被引:2,自引:0,他引:2
2006~2007年,对35%氯虫苯甲酰胺水分散粒剂进行田间药效试验。结果表明,35%氯虫苯甲酰胺水分散粒剂是防治苹果树桃小食心虫Carposina niponensisi Walsingham和金纹细蛾Lithocolletis ringoniella Mats的有效药剂。其有效成分为35~50mg/kg处理防治桃小食心虫,药后5d的防效在83%~100%之间,药后35d防效在77%以上,整体防效不及对照药剂4.5%高效氯氰菊酯乳油30mg/kg处理;10~20mg/kg处理防治金纹细蛾,药后5~15d防效在58%~100%之间,各期防效优于生产常用药剂25%灭幼脲悬浮剂125mg/kg处理。 相似文献
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Abstract. 1. The univoltine leaf-mining moth, Lithocolletis quercus Ams., is endemic to Israel, where it spends its 10.5 month larval period feeding only in the leaves of Quercus calliprinos Webb.
2. We compared patterns of egg deposition and sources of larval mortality to test whether oviposition patterns and site preferences confer an enhanced likelihood of larval survival.
3. Dominant sources of larval mortality were premature leaf abscission and death from unknown causes, whereas predation, parasitism and intraspecific interference accounted for relatively little larval mortality.
4. Eggs, and thus mines, were aggregated among leaves of host trees even though premature leaf abscission was positively correlated with density of mines per leaf. Interference competition among larvae was the only other density-dependent mortality factor.
5. Oviposition patterns within leaves mitigated the probability of death from larval interference, and probably also from early leaf abscission.
6. Despite these density-dependent mortality factors, overall probability of larval survival to pupation was independent of initial density of mines on a leaf.
7. The long larval period allows synchrony between oviposition flights and times of predictable resource availability. 相似文献
2. We compared patterns of egg deposition and sources of larval mortality to test whether oviposition patterns and site preferences confer an enhanced likelihood of larval survival.
3. Dominant sources of larval mortality were premature leaf abscission and death from unknown causes, whereas predation, parasitism and intraspecific interference accounted for relatively little larval mortality.
4. Eggs, and thus mines, were aggregated among leaves of host trees even though premature leaf abscission was positively correlated with density of mines per leaf. Interference competition among larvae was the only other density-dependent mortality factor.
5. Oviposition patterns within leaves mitigated the probability of death from larval interference, and probably also from early leaf abscission.
6. Despite these density-dependent mortality factors, overall probability of larval survival to pupation was independent of initial density of mines on a leaf.
7. The long larval period allows synchrony between oviposition flights and times of predictable resource availability. 相似文献
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