Waveform distortion for temperature compensation and synchronization in circadian rhythms: An approach based on the renormalization group method

Shingo Gibo, Teiji Kunihiro, Tetsuo Hatsuda, Gen Kurosawa
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Abstract

Numerous biological processes accelerate as temperatures increase, but the period of circadian rhythms remains constant, known as temperature compensation, while synchronizing with the 24h light-dark cycle. We theoretically explores the possible relevance of waveform distortions in circadian gene-protein dynamics to the temperature compensation and synchronization. Our analysis of the Goodwin model provides a coherent explanation of most of temperature compensation hypotheses. Using the renormalization group method, we analytically demonstrate that the decreasing phase of circadian protein oscillations should lengthen with increasing temperature, leading to waveform distortions to maintain a stable period. This waveform-period correlation also occurs in other oscillators like Lotka-Volterra and van der Pol models. A reanalysis of known data nicely confirms our findings on waveform distortion and its impact on synchronization range. Thus we conclude that circadian rhythm waveforms are fundamental to both temperature compensation and synchronization.
用于温度补偿和昼夜节律同步的波形失真:基于重正化群法的方法
许多生物过程随着温度的升高而加快,但昼夜节律的周期却保持不变,即温度补偿,同时与 24 小时光暗周期同步。我们从理论上探讨了昼夜节律基因-蛋白质动力学的波形失真与温度补偿和同步的可能关系。我们对古德温模型的分析为大多数温度补偿假说提供了连贯的解释。利用归一化群方法,我们分析证明了昼夜节律蛋白振荡的递减相应该随着温度的升高而延长,从而导致波形畸变以维持稳定的周期。这种波形与周期的相关性也出现在其他振荡器中,如 Lotka-Volterra 和 van der Pol 模型。对已知数据的重新分析很好地证实了我们关于波形失真及其对同步范围影响的发现。因此,我们得出结论,昼夜节律波形对于温度补偿和同步都是至关重要的。
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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