iSimBioSys: an 'in silico' discrete event simulation framework for modeling biological systems

2005 IEEE Computational Systems Bioinformatics Conference - Workshops (CSBW'05) Pub Date : 2005-08-08 DOI:10.1109/CSBW.2005.80

Samik Ghosh, P. Ghosh, K. Basu, Sajal K. Das

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引用次数: 9

Abstract

The genome projects have provided comprehensive information about the basic building blocks of life. The next challenge is to understand how biological functions emerge from complex interactions of these building blocks. In this work, we present a generic, extensible in silico simulation framework which allows the experimenter to lest various hypotheses of an experiment 'in silico' and develop a model for subsequent wet test analysis. Undertaking a systems approach, we abstract a biological process as a set of interacting functions driven in time by a set of discrete events. We focus on three two-component gene regulatory networks, (a) PhoP/PhoQ network (b) barA/sirA network and (c) pmrB/pmrA network involved in bacterial pathogenesis in Salmonella Typhimurium and capture their interactions in various stages of infection. We report results on the expression of various gene and gene products from these pathways. We conclude that such a stochastic framework can provide insight into how collective interaction of different molecules manifests in physiology and diseases.

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iSimBioSys:一个用于建模生物系统的“在硅”离散事件模拟框架

基因组计划提供了关于生命基本组成部分的全面信息。下一个挑战是了解生物功能是如何从这些构建模块的复杂相互作用中产生的。在这项工作中，我们提出了一个通用的、可扩展的硅模拟框架，它允许实验者在硅中避免实验的各种假设，并为随后的湿测试分析开发一个模型。采用系统方法，我们将生物过程抽象为由一组离散事件在时间上驱动的一组相互作用的功能。我们专注于三个双组分基因调控网络，(a) PhoP/PhoQ网络，(b) barA/sirA网络和(c) pmrB/pmrA网络参与鼠伤寒沙门菌的细菌发病机制，并捕获它们在感染不同阶段的相互作用。我们报道了这些途径中各种基因和基因产物的表达结果。我们的结论是，这样一个随机框架可以深入了解不同分子的集体相互作用如何在生理和疾病中表现出来。

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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2005 IEEE Computational Systems Bioinformatics Conference - Workshops (CSBW'05)

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