细菌应激反应中的随机脉冲调控。
Stochastic pulse regulation in bacterial stress response.
机构信息
Howard Hughes Medical Institute, Division of Biology and Bioengineering, Broad Center, California Institute of Technology, 1200 East California Boulevard, Pasadena, CA 91125, USA.
出版信息
Science. 2011 Oct 21;334(6054):366-9. doi: 10.1126/science.1208144. Epub 2011 Oct 6.
Abstract
Gene regulatory circuits can use dynamic, and even stochastic, strategies to respond to environmental conditions. We examined activation of the general stress response mediated by the alternative sigma factor, σ(B), in individual Bacillus subtilis cells. We observed that energy stress activates σ(B) in discrete stochastic pulses, with increasing levels of stress leading to higher pulse frequencies. By perturbing and rewiring the endogenous system, we found that this behavior results from three key features of the σ(B) circuit: an ultrasensitive phosphorylation switch; stochasticity ("noise"), which activates that switch; and a mixed (positive and negative) transcriptional feedback, which can both amplify a pulse and switch it off. Together, these results show how prokaryotes encode signals using stochastic pulse frequency modulation through a compact regulatory architecture.
摘要
基因调控回路可以使用动态的,甚至是随机的策略来响应环境条件。我们检查了替代 sigma 因子 σ(B)介导的一般应激反应在单个枯草芽孢杆菌细胞中的激活情况。我们观察到,能量应激以离散的随机脉冲激活 σ(B),随着应激水平的增加,脉冲频率也随之升高。通过干扰和重新布线内源性系统,我们发现这种行为是由 σ(B) 回路的三个关键特征引起的:超敏磷酸化开关;随机性(“噪声”),它激活该开关;以及混合(正和负)转录反馈,它既能放大脉冲又能使其关闭。总之,这些结果表明,原核生物如何通过紧凑的调控架构使用随机脉冲频率调制来编码信号。
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