计算模型证实机械传导是哺乳动物昼夜节律时钟的有效调节器。

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-09-01 Epub Date: 2024-09-09 DOI:10.1242/jcs.261782
Emmet A Francis, Padmini Rangamani
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引用次数: 0

摘要

机械传导(Mechanotransduction)是将细胞外部环境的机械信号与细胞内信号变化相结合的过程,它控制着许多细胞功能。最近的研究表明,细胞的机械状态也与细胞昼夜节律有关。为了研究昼夜节律和细胞机械传导之间可能存在的相互作用,我们建立了一个将这两种途径整合在一起的计算模型。我们推测,转录调节因子 YAP/TAZ 和 MRTF 转位至细胞核会导致昼夜节律蛋白的表达发生改变。根据我们的模型模拟预测,较低水平的细胞骨架活动与较长的昼夜节律振荡周期和较高的振荡幅度有关,这与最近的实验观察结果一致。此外,YAP/TAZ 和 MRTF 在细胞核中的积累会导致昼夜节律振荡衰减。这些效应在单细胞水平和种群水平框架内均有效。最后,我们研究了 YAP 或层粘蛋白 A 突变的影响,后者会导致一类被称为层粘蛋白病的疾病。昼夜节律蛋白的振荡在YAP或片层蛋白A发生硅突变的细胞群中大大减弱,这表明在某些疾病状态下,机械传导的缺陷会破坏昼夜节律时钟。然而,通过降低基质硬度,我们能够恢复正常的振荡行为,这表明可能存在一种补偿机制。因此,我们的研究表明,机械传导可能是细胞时钟的一种有效调节线索,这种串扰可被用来挽救疾病状态下的昼夜节律时钟。
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Computational modeling establishes mechanotransduction as a potent modulator of the mammalian circadian clock.

Mechanotransduction, which is the integration of mechanical signals from the external environment of a cell to changes in intracellular signaling, governs many cellular functions. Recent studies have shown that the mechanical state of the cell is also coupled to the cellular circadian clock. To investigate possible interactions between circadian rhythms and cellular mechanotransduction, we have developed a computational model that integrates the two pathways. We postulated that translocation of the transcriptional regulators MRTF (herein referring to both MRTF-A and MRTF-B), YAP and TAZ (also known as YAP1 and WWTR1, respectively; collectively denoted YAP/TAZ) into the nucleus leads to altered expression of circadian proteins. Simulations from our model predict that lower levels of cytoskeletal activity are associated with longer circadian oscillation periods and higher oscillation amplitudes, which is consistent with recent experimental observations. Furthermore, accumulation of YAP/TAZ and MRTF in the nucleus causes circadian oscillations to decay in our model. These effects hold both at the single-cell level and within a population-level framework. Finally, we investigated the effects of mutations in YAP or lamin A, the latter of which result in a class of diseases known as laminopathies. In silico, oscillations in circadian proteins are substantially weaker in populations of cells with mutations in YAP or lamin A, suggesting that defects in mechanotransduction can disrupt the circadian clock in certain disease states; however, reducing substrate stiffness in the model restores normal oscillatory behavior, suggesting a possible compensatory mechanism. Thus, our study identifies that mechanotransduction could be a potent modulatory cue for cellular clocks and that this crosstalk can be leveraged to rescue the circadian clock in disease states.

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