Molecular and Neural Mechanisms of Temperature Preference Rhythm in Drosophila melanogaster.

IF 2.9 3区 生物学 Q2 BIOLOGY Journal of Biological Rhythms Pub Date : 2023-08-01 Epub Date: 2023-05-24 DOI:10.1177/07487304231171624
Tadahiro Goda, Yujiro Umezaki, Fumika N Hamada
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Abstract

Temperature influences animal physiology and behavior. Animals must set an appropriate body temperature to maintain homeostasis and maximize survival. Mammals set their body temperatures using metabolic and behavioral strategies. The daily fluctuation in body temperature is called the body temperature rhythm (BTR). For example, human body temperature increases during wakefulness and decreases during sleep. BTR is controlled by the circadian clock, is closely linked with metabolism and sleep, and entrains peripheral clocks located in the liver and lungs. However, the underlying mechanisms of BTR are largely unclear. In contrast to mammals, small ectotherms, such as Drosophila, control their body temperatures by choosing appropriate environmental temperatures. The preferred temperature of Drosophila increases during the day and decreases at night; this pattern is referred to as the temperature preference rhythm (TPR). As flies are small ectotherms, their body temperature is close to that of the surrounding environment. Thus, Drosophila TPR produces BTR, which exhibits a pattern similar to that of human BTR. In this review, we summarize the regulatory mechanisms of TPR, including recent studies that describe neuronal circuits relaying ambient temperature information to dorsal neurons (DNs). The neuropeptide diuretic hormone 31 (DH31) and its receptor (DH31R) regulate TPR, and a mammalian homolog of DH31R, the calcitonin receptor (CALCR), also plays an important role in mouse BTR regulation. In addition, both fly TPR and mammalian BTR are separately regulated from another clock output, locomotor activity rhythms. These findings suggest that the fundamental mechanisms of BTR regulation may be conserved between mammals and flies. Furthermore, we discuss the relationships between TPR and other physiological functions, such as sleep. The dissection of the regulatory mechanisms of Drosophila TPR could facilitate an understanding of mammalian BTR and the interaction between BTR and sleep regulation.

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黑腹果蝇温度偏好节律的分子和神经机制
温度影响动物的生理和行为。动物必须设定适当的体温,以维持体内平衡并最大限度地提高存活率。哺乳动物通过新陈代谢和行为策略来设定体温。体温的日常波动称为体温节律(BTR)。例如,人的体温在清醒时升高,在睡眠时降低。体温节律受昼夜节律钟控制,与新陈代谢和睡眠密切相关,并影响位于肝脏和肺部的外周时钟。然而,BTR 的基本机制在很大程度上还不清楚。与哺乳动物不同,果蝇等小型外温动物通过选择适当的环境温度来控制体温。果蝇喜欢的温度在白天升高,晚上降低;这种模式被称为温度偏好节律(TPR)。由于果蝇是小型外温动物,它们的体温与周围环境的温度接近。因此,果蝇的温度偏好节律产生 BTR,其模式与人类的 BTR 相似。在这篇综述中,我们总结了TPR的调控机制,包括最近描述将环境温度信息传递给背侧神经元(DNs)的神经元回路的研究。神经肽利尿激素 31(DH31)及其受体(DH31R)可调控 TPR,而 DH31R 的哺乳动物同源物降钙素受体(CALCR)也在小鼠 BTR 的调控中发挥着重要作用。此外,苍蝇的 TPR 和哺乳动物的 BTR 都分别受另一种时钟输出--运动活动节律--的调控。这些发现表明,BTR调控的基本机制在哺乳动物和苍蝇之间可能是一致的。此外,我们还讨论了TPR与睡眠等其他生理功能之间的关系。对果蝇TPR调控机制的剖析有助于理解哺乳动物BTR以及BTR与睡眠调控之间的相互作用。
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来源期刊
CiteScore
6.10
自引率
8.60%
发文量
48
审稿时长
>12 weeks
期刊介绍: Journal of Biological Rhythms is the official journal of the Society for Research on Biological Rhythms and offers peer-reviewed original research in all aspects of biological rhythms, using genetic, biochemical, physiological, behavioral, epidemiological & modeling approaches, as well as clinical trials. Emphasis is on circadian and seasonal rhythms, but timely reviews and research on other periodicities are also considered. The journal is a member of the Committee on Publication Ethics (COPE).
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