Temperature dependence of gas exchange patterns shift as diapause progresses in the butterfly Pieris napi

IF 2.3 2区农林科学 Q1 ENTOMOLOGY

Journal of insect physiology Pub Date : 2023-11-17 DOI:10.1016/j.jinsphys.2023.104585

Philip Süess , Kevin T. Roberts , Philipp Lehmann

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引用次数: 0

Abstract

Insects have the capacity to significantly modify their metabolic rate according to environmental conditions and physiological requirement. Consequently, the respiratory patterns can range from continuous gas exchange (CGE) to discontinuous gas exchange (DGE). In the latter, spiracles are kept closed during much of the time, and gas exchange occurs only during short periods when spiracles are opened. While ultimate causes and benefits of DGE remain debated, it is often seen during insect diapause, a deep resting stage that insects induce to survive unfavourable environmental conditions, such as winter. The present study explores the shifts between CGE and DGE during diapause by performing long continuous respirometry measurements at multiple temperatures during key diapause stages in the green-veined white butterfly Pieris napi. The primary goal is to explore respiratory pattern as a non-invasive method to assess whether pupae are in diapause or have transitioned to post-diapause. Respiratory pattern can also provide insight into endogenous processes taking place during diapause, and the prolonged duration of diapause allows for the detailed study of the thermal dependence of the DGE pattern. Pupae change from CGE to DGE a few days after pupation, and this shift coincides with metabolic rate suppression during diapause initiation. Once in diapause, pupae maintain DGE even at elevated temperatures that significantly increase CO₂ production. Instead of shifting respiratory pattern to CGE, pupae increase the frequency of DGE cycles. Since total CO₂ released during a single open phase remains unchanged, our results suggest that P. napi pupae defend a maximum internal ρCO₂ set point, even in their heavily suppressed diapause state. During post-diapause development, CO₂ production increases as a function of development and changes to CGE during temperature conditions permissive for development. Taken together, the results show that respiratory patterns are highly regulated during diapause in P. napi and change predictably as diapause progresses.

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随着滞育的进行，气体交换模式的温度依赖性发生了变化。

昆虫具有根据环境条件和生理需要显著改变自身代谢率的能力。因此，呼吸模式可以从连续气体交换(CGE)到不连续气体交换(DGE)。在后者中，气门在大部分时间内保持关闭，气体交换只在气门打开时的短时间内发生。虽然DGE的最终原因和益处仍存在争议，但它经常出现在昆虫滞育期间，昆虫诱导其在不利环境条件下(如冬季)生存的深度休息阶段。本研究通过对绿脉白蝴蝶在关键滞育阶段的多个温度下进行长时间连续呼吸测量，探讨滞育期间CGE和DGE的变化。主要目的是探索呼吸模式作为一种非侵入性方法来评估蛹是否处于滞育或已过渡到滞育后。呼吸模式也可以帮助我们了解滞育期间发生的内源性过程，而滞育持续时间的延长使得我们可以详细研究DGE模式的热依赖性。蛹在化蛹后数天内就会从普通白蚁转变为普通白蚁，这种转变与滞育起始时代谢率的抑制一致。一旦进入滞育，即使在显著增加二氧化碳产量的高温下，蛹也能保持DGE。而不是将呼吸模式转移到CGE，蛹增加了DGE周期的频率。由于在单个开放阶段释放的总CO2保持不变，我们的研究结果表明，即使在严重抑制的滞育状态下，napi蛹也能捍卫最大的内部ρCO2设设点。在滞育后发育过程中，CO2产量随着发育而增加，而在适宜发育的温度条件下，CGE的变化也随之增加。综上所述，这些结果表明，在稻稻滞育期间，呼吸模式受到高度调控，并随着滞育的进行而发生可预测的变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of insect physiology 生物-昆虫学

CiteScore

4.50

自引率

4.50%

发文量

审稿时长

57 days

期刊介绍： All aspects of insect physiology are published in this journal which will also accept papers on the physiology of other arthropods, if the referees consider the work to be of general interest. The coverage includes endocrinology (in relation to moulting, reproduction and metabolism), pheromones, neurobiology (cellular, integrative and developmental), physiological pharmacology, nutrition (food selection, digestion and absorption), homeostasis, excretion, reproduction and behaviour. Papers covering functional genomics and molecular approaches to physiological problems will also be included. Communications on structure and applied entomology can be published if the subject matter has an explicit bearing on the physiology of arthropods. Review articles and novel method papers are also welcomed.