小型遗传回路中延迟诱导的降解激发振荡
Delay-induced degrade-and-fire oscillations in small genetic circuits.
作者信息
Mather William, Bennett Matthew R, Hasty Jeff, Tsimring Lev S
机构信息
Department of Bioengineering, University of California San Diego, La Jolla, California, 92093, USA.
出版信息
Phys Rev Lett. 2009 Feb 13;102(6):068105. doi: 10.1103/PhysRevLett.102.068105.
Abstract
Robust oscillations have recently been observed in a synthetic gene network composed of coupled positive and negative feedback loops. Here we use deterministic and stochastic modeling to investigate how a small time delay in such regulatory networks can lead to strongly nonlinear oscillations that can be characterized by "degrade-and-fire" dynamics. We show that the period of the oscillations can be significantly greater than the delay time, provided the circuit components possess strong activation and tight repression. The variability of the period is strongly influenced by fluctuations near the oscillatory minima, when the number of regulatory molecules is small.
摘要
最近在一个由耦合的正反馈和负反馈回路组成的合成基因网络中观察到了稳健的振荡。在这里,我们使用确定性和随机模型来研究这种调节网络中的小时间延迟如何导致强烈的非线性振荡,这种振荡可以用“降解并激发”动力学来表征。我们表明,只要电路组件具有强激活和紧密抑制作用,振荡周期就可以显著大于延迟时间。当调节分子数量较少时,振荡最小值附近的波动会强烈影响周期的变异性。
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