Inferring biochemical routes from biochemical networks

2013 Biomedical Sciences and Engineering Conference (BSEC) Pub Date : 2013-05-21 DOI:10.1109/BSEC.2013.6618500

Soma Ghosh, S. Vishveshwara, N. Chandra

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Abstract

Metabolism is a defining feature of life, and its study is important to understand how a cell works, alterations that lead to disease and for applications in drug discovery. From a systems perspective, metabolism can be represented as a network that captures all the metabolites as nodes and the interconversions among pairs of them as edges. Such an abstraction enables the networks to be studied by applying graph theory, particularly, to infer the flow of chemical information in the networks by identifying relevant metabolic pathways. In this study, different weighting schemes are used to illustrate that appropriately weighted networks can capture the quantitative cellular dynamics quite accurately. Thus, the networks now combine the elegance and simplicity of representation of the system and ease of analysing metabolic graphs. Metabolic routes or paths determined by this therefore are likely to be more biologically meaningful. The usefulness of the approach is demonstrated with two examples, first for understanding bacterial stress response and second for studying metabolic alterations that occurs in cancer cells.

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从生化网络推断生化路线

代谢是生命的一个决定性特征，对它的研究对于理解细胞如何工作、导致疾病的变化以及在药物发现中的应用都很重要。从系统的角度来看，代谢可以表示为一个网络，将所有代谢物捕获为节点，将它们之间的相互转换捕获为边缘。这种抽象使网络能够通过应用图论来研究，特别是通过识别相关的代谢途径来推断网络中化学信息的流动。在本研究中，使用不同的加权方案来说明适当的加权网络可以相当准确地捕获定量的细胞动力学。因此，网络现在结合了系统表示的优雅和简单性以及分析代谢图的便利性。因此，由此确定的代谢途径可能更具有生物学意义。通过两个例子证明了该方法的实用性，首先用于理解细菌应激反应，其次用于研究癌细胞中发生的代谢变化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2013 Biomedical Sciences and Engineering Conference (BSEC)

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