遗传调控网络定理的形式化证明

2009 11th International Symposium on Symbolic and Numeric Algorithms for Scientific Computing Pub Date : 2009-09-26 DOI:10.1109/SYNASC.2009.44

Maxime Dénès, Benjamin Lesage, Yves Bertot, A. Richard

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引用次数: 3

摘要

我们描述了理论生物学的两个定理的形式化验证。这些定理涉及遗传调控网络:它们在一个离散的建模框架中给出了这些生物网络的拓扑结构和动态之间的关系。在考虑的离散建模框架中，动态由过渡图描述，其中顶点是指示每个基因表达水平的向量，其中边缘表示这些表达水平的演变。拓扑结构也由一个称为交互图的图来描述，其中顶点是基因，而边缘对应于基因之间的影响。我们形式化的两个结果表明，如果某些行为在过渡图中是可能的，那么在交互图中一定存在某种电路。这项工作是通过Coq系统的ssreflect扩展来完成的。

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Formal Proof of Theorems on Genetic Regulatory Networks

We describe the formal verification of two theorems of theoretical biology. These theorems concern genetic regulatory networks: they give, in a discrete modeling framework, relations between the topology and the dynamics of these biological networks. In the considered discrete modeling framework, the dynamics is described by a transition graph, where vertices are vectors indicating the expression level of each gene, and where edges represent the evolution of these expression levels. The topology is also described by a graph, called interaction graph, where vertices are genes and where edges correspond to influences between genes. The two results we formalize show that circuits of some kind must be present in the interaction graph if some behaviors are possible in the transition graph. This work was performed with the ssreflect extension of the Coq system.

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2009 11th International Symposium on Symbolic and Numeric Algorithms for Scientific Computing

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