系统识别信号激活的随机基因调控。
Systematic identification of signal-activated stochastic gene regulation.
机构信息
Departments of Physics and Biology and Koch Institute for Integrative Cancer Research, Massachusetts Institute of Technology, Cambridge, MA 02139, USA.
出版信息
Science. 2013 Feb 1;339(6119):584-7. doi: 10.1126/science.1231456.
Abstract
Although much has been done to elucidate the biochemistry of signal transduction and gene regulatory pathways, it remains difficult to understand or predict quantitative responses. We integrate single-cell experiments with stochastic analyses, to identify predictive models of transcriptional dynamics for the osmotic stress response pathway in Saccharomyces cerevisiae. We generate models with varying complexity and use parameter estimation and cross-validation analyses to select the most predictive model. This model yields insight into several dynamical features, including multistep regulation and switchlike activation for several osmosensitive genes. Furthermore, the model correctly predicts the transcriptional dynamics of cells in response to different environmental and genetic perturbations. Because our approach is general, it should facilitate a predictive understanding for signal-activated transcription of other genes in other pathways or organisms.
摘要
尽管已经做了很多工作来阐明信号转导和基因调控途径的生物化学,但要理解或预测定量反应仍然很困难。我们将单细胞实验与随机分析相结合,以确定酿酒酵母渗透胁迫反应途径转录动力学的预测模型。我们生成具有不同复杂性的模型,并使用参数估计和交叉验证分析来选择最具预测性的模型。该模型深入了解了几个动态特征,包括几个对渗透压敏感的基因的多步骤调节和开关式激活。此外,该模型正确预测了细胞对不同环境和遗传扰动的转录动力学反应。由于我们的方法具有通用性,因此它应该有助于对其他途径或生物体中其他基因的信号激活转录进行预测性理解。
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