频率调节定时器调节不同小型哺乳动物冬眠期间的休眠-唤醒周期

Shingo Gibo, Yoshifumi Yamaguchi, Elena O. Gracheva, Sviatoslav N. Bagriantsev, Isao T. Tokuda, Gen Kurosawa
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摘要

冬眠使哺乳动物能够通过降低基础代谢和体温(Tb)来减少能量消耗,从而忍受严酷的季节。在叙利亚仓鼠和13线地松鼠等小型动物冬眠期间,体温会降低到环境温度(5 °C),并在数天至数周内保持恒定,这种生理状态被称为深度冬眠。冬眠会被唤醒期打断,在唤醒期Tb会恢复到热量水平(约37 °C),冬眠期间会多次重复这种冬眠-唤醒循环。然而,人们对冬眠期间Tb的波动机制知之甚少。在这项研究中,我们对Tb数据采用了一种无偏的模型选择方法,结果发现一个包含频率调制的模型定量地再现了叙利亚仓鼠冬眠期间的Tb波动。我们发现,一个意想不到的120-430天的长周期会对一个几天的短周期进行调制。此外,上述模型还再现了13线地松鼠的Tb波动,这种松鼠可以在恒定的实验室条件下根据内在的年周期节律反复冬眠。这是首次定量研究证明,在不同哺乳动物的冬眠-唤醒周期中,有两个内生周期协同作用,一个持续几天,另一个持续一年。我们预计,我们对Tb波动的理论分析将成为定量比较不同冬眠物种冬眠模式的起点。此外,利用模型对Tb数据进行量化将有助于我们了解冬眠的分子机制,揭示冬眠期的生物学过程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Frequency-modulated timer regulates torpor–arousal cycles during hibernation in distinct small mammalian hibernators

Frequency-modulated timer regulates torpor–arousal cycles during hibernation in distinct small mammalian hibernators
Hibernation allows mammals to endure harsh seasons by reducing their basal metabolism and body temperature (Tb) to minimize energy expenditure. During hibernation in small animals such as Syrian hamsters and 13-lined ground squirrels, Tb decreases to an ambient level ( < 5 °C) and remains constant for days to weeks in a physiological condition termed deep torpor. Torpor is interrupted by periods of arousal, during which Tb recovers to a euthermic level (approximately 37 °C), and these torpor–arousal cycles are repeated multiple times during hibernation. However, little is known about the mechanisms governing Tb fluctuations during hibernation. In this study, we employed an unbiased model selection approach to Tb data and revealed that a model incorporating frequency modulation quantitatively reproduced Tb fluctuation during hibernation in Syrian hamsters. We found that an unexpectedly long period of 120–430 days modulates a shorter period of several days. In addition, the aforementioned model reproduced Tb fluctuation in 13-lined ground squirrels, which can undergo repeated hibernation according to intrinsic circannual rhythms in constant laboratory conditions. This is the first quantitative study to demonstrate the concerted action of two endogenous periods, one lasting a few days and the other lasting a year, in the torpor–arousal cycles of distinct mammalian hibernators. We anticipate that our theoretical analysis of Tb fluctuation will be a starting point for quantitative comparisons of hibernation patterns across various hibernating species. Furthermore, quantification of Tb data using models will foster our understanding of the molecular mechanisms of hibernation by revealing the biological processes operating within these periods.
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