通过时间序列数据学习受限布尔网络模型

Hongjia Ouyang, Jie Fang, Liangzhong Shen, Edward R Dougherty, Wenbin Liu
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摘要

限制性布尔网络是简化的布尔网络,基因之间的负向或正向调控都需要它。Higa 等人(BMC Proc 5:S5, 2011)提出了一种从时间序列数据推断限制性布尔网络的三规则算法。然而,该算法存在一个主要缺点,即对噪声非常敏感。在本文中,我们根据目标基因的状态开关系统地分析了基因之间的调控关系,并提出了一种可以从时间序列数据中推断出受限布尔网络的算法。我们将所提出的算法与三规则算法和最佳拟合算法进行了比较,这两种算法都是基于合成网络和经过充分研究的萌发酵母细胞周期网络。算法的性能通过三个距离指标来评估:归一化边汉明距离[公式:见正文]、状态转换的归一化汉明距离[公式:见正文]和稳态分布距离μ (ssd)。结果表明,根据[公式:见正文]和[公式:见正文],拟议算法的性能优于其他算法,而根据μ (ssd),其性能介于最佳拟合算法和三规则算法之间。因此,我们的新算法更适合从时间序列数据中推断基因间的相互作用。
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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Learning restricted Boolean network model by time-series data.

Restricted Boolean networks are simplified Boolean networks that are required for either negative or positive regulations between genes. Higa et al. (BMC Proc 5:S5, 2011) proposed a three-rule algorithm to infer a restricted Boolean network from time-series data. However, the algorithm suffers from a major drawback, namely, it is very sensitive to noise. In this paper, we systematically analyze the regulatory relationships between genes based on the state switch of the target gene and propose an algorithm with which restricted Boolean networks may be inferred from time-series data. We compare the proposed algorithm with the three-rule algorithm and the best-fit algorithm based on both synthetic networks and a well-studied budding yeast cell cycle network. The performance of the algorithms is evaluated by three distance metrics: the normalized-edge Hamming distance [Formula: see text], the normalized Hamming distance of state transition [Formula: see text], and the steady-state distribution distance μ (ssd). Results show that the proposed algorithm outperforms the others according to both [Formula: see text] and [Formula: see text], whereas its performance according to μ (ssd) is intermediate between best-fit and the three-rule algorithms. Thus, our new algorithm is more appropriate for inferring interactions between genes from time-series data.

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