细胞信号处理中的基序和模块:在微生物应激反应途径中的应用

Computational Systems Bioinformatics. CSB2003. Proceedings of the 2003 IEEE Bioinformatics Conference. CSB2003 Pub Date : 2003-08-11 DOI:10.1109/CSB.2003.1227299

A. Arkin

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引用次数: 0

摘要

细菌和动物细胞是动态的机器，其内部化学网络执行数百个复杂的控制和信号处理任务，以管理细胞随时间的发展，并响应来自环境的确定性和随机信号。后基因组生物学的核心挑战是发现这些网络的完整物理性质，并确定是否存在这些细胞运作和进化的控制和信号处理原则。如果存在这样的原理，那么细胞工程师就可以通过它们来确定外部信号(如药物)的最佳位置，从而使细胞从不想要的状态转移到想要的状态。在这里，初步尝试确定控制的原则，可能的模块化结构和信号流的性质在蜂窝网络简要介绍。我们使用从细菌应激反应途径和酵母缺失活力研究的例子来说明原则和方法。

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Motifs and modules in cellular signal processing: applications to microbial stress response pathways

Bacterial and animal cells are dynamic machines whose internal chemical networks perform hundreds of complex control and signal processing tasks to govern cellular development over time and in response to deterministic and stochastic signals from the environment. A central challenge in post-genomic biology is to discover the complete physical nature of these networks and to determine if there are principles of control and signal processing by which these cell operate and evolve. If such principles exist then they are handles by which cellular engineers can determine the best placement of external signals (such as Pharmaceuticals) to cause a cell to move from an undesired state to a desired state. Here, initial attempts at determining the principles of control, the possible modular structure and the nature of signal flow in cellular networks are briefly introduced. We use examples from bacterial stress response pathways and yeast deletion viability studies to illustrate the principles and approaches.

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Computational Systems Bioinformatics. CSB2003. Proceedings of the 2003 IEEE Bioinformatics Conference. CSB2003

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