利用刺激反应实验和大规模模型选择揭示生化网络的调节结构。

S A Wahl, M D Haunschild, M Oldiges, W Wiechert
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引用次数: 37

摘要

为了揭示生物化学网络复杂的体内调节相互依赖性,活体实验是绝对必要的。刺激反应实验(SREs)近年来受到越来越多的关注。通过现代分析方法监测中枢代谢所有主要部分的代谢物浓度随时间的变化,产生数千个数据点。SREs被用于确定酶的动力学参数和发现未知的酶调节机制。由于代谢网络的复杂调控结构和测量数据的数量,SRE的评估必须得到建模的广泛支持。如果酶调节机制是研究的一部分,那么必须测试大量具有不同酶动力学的模型,以确定它们重现所观察到的行为的能力。在这一贡献中,为数据驱动的探索性建模引入了一个系统的模型构建过程,目的是发现生物系统的基本特征。该过程基于数据预处理、基于相关性的假设生成、自动模型族生成、大规模模型选择和最佳拟合模型的统计分析,然后提取共同特征。以大肠杆菌的芳香族氨基酸合成途径为例说明了这一点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Unravelling the regulatory structure of biochemical networks using stimulus response experiments and large-scale model selection.

To unravel the complex in vivo regulatory interdependences of biochemical networks, experiments with the living organism are absolutely necessary. Stimulus response experiments (SREs) have become increasingly popular in recent years. The response of metabolite concentrations from all major parts of the central metabolism is monitored over time by modem analytical methods, producing several thousand data points. SREs are applied to determine enzyme kinetic parameters and to find unknown enzyme regulatory mechanisms. Owing to the complex regulatory structure of metabolic networks and the amount of measured data, the evaluation of an SRE has to be extensively supported by modelling. If the enzyme regulatory mechanisms are part of the investigation, a large number of models with different enzyme kinetics have to be tested for their ability to reproduce the observed behaviour. In this contribution, a systematic model-building process for data-driven exploratory modelling is introduced with the aim of discovering essential features of the biological system. The process is based on data pre-processing, correlation-based hypothesis generation, automatic model family generation, large-scale model selection and statistical analysis of the best-fitting models followed by an extraction of common features. It is illustrated by the example of the aromatic amino acid synthesis pathway in Escherichia coli.

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