三蛋白生物钟振荡器的稳健性和相干性:景观和通量视角。
Robustness and coherence of a three-protein circadian oscillator: landscape and flux perspectives.
机构信息
State Key Laboratory of Electroanalytical Chemistry, Changchun Institute of Applied Chemistry, Chinese Academy of Sciences, Changchun, Jilin, China.
出版信息
Biophys J. 2009 Dec 2;97(11):3038-46. doi: 10.1016/j.bpj.2009.09.021.
Abstract
Three-protein circadian oscillations in cyanobacteria sustain for weeks. To understand how cellular oscillations function robustly in stochastic fluctuating environments, we used a stochastic model to uncover two natures of circadian oscillation: the potential landscape related to steady-state probability distribution of protein concentrations; and the corresponding flux related to speed of concentration changes which drive the oscillations. The barrier height of escaping from the oscillation attractor on the landscape provides a quantitative measure of the robustness and coherence for oscillations against intrinsic and external fluctuations. The difference between the locations of the zero total driving force and the extremal of the potential provides a possible experimental probe and quantification of the force from curl flux. These results, correlated with experiments, can help in the design of robust oscillatory networks.
摘要
在蓝细菌中,三种蛋白质的生物钟振荡可以持续数周。为了理解细胞振荡如何在随机波动的环境中稳健地发挥作用,我们使用随机模型揭示了生物钟振荡的两个特性:与蛋白质浓度稳态概率分布相关的势能景观;以及与浓度变化速度相关的通量,后者驱动了振荡。从景观上的振荡吸引子中逃脱的势垒高度为振荡对内在和外在波动的稳健性和相干性提供了定量的度量。总驱动力为零的位置与势的极值之间的差异提供了一个可能的实验探测和对旋度通量力的量化。这些与实验相关的结果有助于设计稳健的振荡网络。
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