[논문]곤충과 응애의 분류군별 공통고유최적온도, 발육최적온도 및 산란최적온도의 분포 양상

안정준; 최경산

doi:10.5656/ksae.2022.01.1.056

곤충과 응애의 분류군별 공통고유최적온도, 발육최적온도 및 산란최적온도의 분포 양상
Distribution Patterns of Intrinsic Optimal Temperature, Optimal Development Temperature and Optimal Fecundity Temperature by Classification Group of Insects and Mites 원문보기

한국응용곤충학회지 = Korean journal of applied entomology, v.61 no.1, 2022년, pp.165 - 172

안정준 (농촌진흥청 국립원예특작과학원 온난화대응농업연구소) , 최경산 (농촌진흥청 국립원예특작과학원 온난화대응농업연구소)

초록
AI-Helper

곤충은 주변환경에 적응하며 발육과 번식을 통해 진화하여 왔다. 온도발육모형을 이용하여 곤충과 응애 분류군별 공통고유최적온도, 발육최적온도, 산란최적온도를 산출하기 위해 112편의 논문에서 응애류 14종, 딱정벌레목 8종, 파리목 5종, 노린재목 31종, 벌목 7종, 나비목 18종, 메뚜기목 1목, 다듬이벌레목 5종, 총채벌레목 5종의 온도발육과 산란자료를 분석하였다. 분석을 통하여 총채벌레목을 제외하고 공통고유최적온도는 발육최적온도보다는 산란최적온도와 차이가 적었다. 본 종설을 통해 공통고유최적온도는 발육최적온도보다는 산란최적온도와 밀접한 관계가 있을 가능성이 높음을 제안하였다.

Abstract ▼ AI-Helper

Insects have evolved successfully by adapting to their environments through development and reproduction. Temperature-dependent models have been used to calculate the intrinsic optimal, optimal development, and optimal fecundity temperatures of insects and mites; for this study, we reviewed 112 works that focused on these parameters. The insects and mites investigated in this study include 14 Acari, 8 Coleoptera, 5 Diptera, 31 Hemiptera, 7 Hymenoptera, 18 Lepidoptera, 1 Orthoptera, 5 Psocoptera, and 5 Thysanoptera species. The results of this study showed that the interval distance between the intrinsic optimal and optimal fecundity temperatures was smaller than that between the intrinsic optimal and optimal development temperatures of the all insects and mites investigated except for those in the order Thysanoptera. We found that there is a close relationship between the intrinsic optimal and optimal fecundity temperatures.

주제어

표/그림 (4)

그림 Fig. 1. A: Insect development rate curve for Riptortus pedestris. B: Probability that the rate-controlling enzyme is in the active stage for R. pedestris. The closed three squares, from left to right, the development rates at T_L, T_Φ and T_H . T_L and T_H represent the temperatures at which the control enzyme has an equal probability of being activated or inactivated by low or high temperatures, and T_Φ is the intrinsic optimum temperature. C: Temperature-dependent mean fecundity curve for R. pedestris. ODT is the optimal development temperature. OFT is the optimal fecundity temperature (A and B cited from Ahn et al., 2019a; C from Ahn et al., 2019b).
표 Table 1. Mean values of intrinsic optimum temperature (T_Φ), optimal development temperature (ODT), and optimal fecundity temperature of each order
그림 Fig2. Distribution patterns of the intrinsic optimal temperature (top), optimal development temperature (center), and optimal fecundity temperature (bottom) derived from insects and mites. Tphi: intrinsic optimal temperature, TODT: optimal development temperature, and TOFT: optimal fecundity temperature. Cole: Coleoptera, Dipt: Diptera, Hemi: Hemiptera, Homo: Homoptera, Hyme: Hymenoptera, Lepi: Lepidoptera, Orth: Orthoptera, Psoc: Psocoptera, Thysa: Thysanoptera. Means followed by the same letter indicate there are not significant differences (P < 0.05, Duncan multiple range test).
그림 Fig. 3. Comparison of the interval distance between the intrinsic optimal temperature (Tphi) and optimal development temperature (TODT), and that between Tphi and the optimal fecundity temperature (TOFT) in insects and mites. Cole: Coleoptera, Dipt: Diptera, Hemi: Hemiptera, Homo: Homoptera, Hyme: Hymenoptera, Lepi: Lepidoptera, Orth: Orthoptera, Psoc: Psocoptera, Thysa: Thysanoptera. * means there is a significant difference (P < 0.05, t-test) and ns means there is no significant difference.

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