温度诱导昼夜节律的数学建模

Lingjun Lu, Yannuo Li, Rene Schloss, Ioannis P. Androulakis
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摘要

嗜铬细胞上核(SCN)中枢昼夜节律起搏器通过生理、神经、激素和新陈代谢信号,使外周细胞中自主分子振荡器的相位和周期与每日的光/暗周期相一致。在不同的诱导因素中,温度诱导被认为是体外诱导和维持昼夜节律的重要选择。虽然人们对糖皮质激素等激素的同步机制进行了广泛研究,但对体温作为系统线索的关键作用却知之甚少。在这项研究中,我们建立了一个半机制数学模型,描述了外周时钟对温度节律的诱导。该模型纳入了一个涉及热休克转录因子-1(HSF1)和热休克反应(HSR)途径的温度感应-传导级联,以模拟时钟基因的诱导。该模型用于研究哺乳动物细胞在不同振幅和幅度的温度振荡下的温度诱导和同步问题,并研究在不同温度时间表之间转换的影响。我们对该系统动态响应的计算分析表明:1)单个细胞通过重置其内在相位逐渐与有节律的温度信号同步,以实现一致的动态,而在没有温度节律性的情况下,振荡会被取消;2)温度节律的振幅和周期的改变会影响外围同步行为;3)个性化的同步策略允许对温度节律做出不同的适应性响应。我们的研究结果表明,温度是昼夜节律的有效诱导因素。因此,体外温度调节系统可作为研究昼夜节律调整或破坏的潜在工具。
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Mathematical modeling of temperature-induced circadian rhythms
The central circadian pacemaker in the suprachiasmatic nuclei (SCN) aligns the phase and period of autonomous molecular oscillators in peripheral cells to daily light/dark cycles via physiological, neuronal, hormonal, and metabolic signals. Among different entrainment factors, temperature entrainment has been proposed as an essential alternative for inducing and sustaining circadian rhythms in vitro. While the synchronization mechanisms for hormones such as glucocorticoids have been widely studied, little is known about the crucial role of body temperature as a systemic cue. In this work, we develop a semi-mechanistic mathematical model describing the entrainment of peripheral clocks to temperature rhythms. The model incorporates a temperature sensing-transduction cascade involving a heat shock transcription factor-1 (HSF1) and heat shock response (HSR) pathway to simulate the entrainment of clock genes. The model is used to investigate the mammalian temperature entrainment and synchronization of cells subject to temperature oscillations of different amplitudes and magnitudes and examine the effects of transitioning between temperature schedules. Our computational analyses of the system’s dynamic responses reveal that 1) individual cells gradually synchronize to the rhythmic temperature signal by resetting their intrinsic phases to achieve coherent dynamics while oscillations are abolished in the absence of temperature rhythmicity; 2) alterations in the amplitude and period of temperature rhythms impact the peripheral synchronization behavior; 3) personalized synchronization strategies allow for differential, adaptive responses to temperature rhythms. Our results demonstrate that temperature can be a potent entrainer of circadian rhythms. Therefore, in vitro systems subjected to temperature modulation can serve as a potential tool for studying the adjustment or disruption of circadian rhythms.
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