基因调控网络定性模型的动态推断算法。

Zheng Yun, Kwoh Chee Keong
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引用次数: 0

摘要

确定0 (N)的泛函关系仍然是一个有待解决的问题。n(k))时间对于任意域[2],其中n为学习实例的数量,n为基因调控网络(GRN)模型中基因(或变量)的数量,k为基因的程度。为了解决这个问题,本文引入了一种新的算法DFL(离散函数学习),用于从基因表达数据中重建grn的定性模型。我们分析了它的复杂度为0 (k)。N。N(2))的平均值及其数据要求。我们还对synthetic和Cho等[7]酵母细胞周期基因表达数据进行了实验,以验证DFL算法的效率和预测性能。合成布尔网络的实验表明,DFL算法在不损失预测性能的情况下比现有算法效率更高。酵母细胞周期基因表达数据的结果表明,相对于文献证据,DFL算法能够以合理的准确度、灵敏度和较高的精度识别出具有生物学意义的模型。我们进一步介绍了一种称为epsilon函数的方法来处理数据集中的噪声。实验结果表明,epsilon函数法是对DFL算法的一个很好的补充。
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Dynamic algorithm for inferring qualitative models of gene regulatory networks.

It is still an open problem to identify functional relations with o(N . n(k)) time for any domain[2], where N is the number of learning instances, n is the number of genes (or variables) in the Gene Regulatory Network (GRN) models and k is the indegree of the genes. To solve the problem, we introduce a novel algorithm, DFL (Discrete Function Learning), for reconstructing qualitative models of GRNs from gene expression data in this paper. We analyze its complexity of O(k . N . n(2)) on the average and its data requirements. We also perform experiments on both synthetic and Cho et al. [7] yeast cell cycle gene expression data to validate the efficiency and prediction performance of the DFL algorithm. The experiments of synthetic Boolean networks show that the DFL algorithm is more efficient than current algorithms without loss of prediction performances. The results of yeast cell cycle gene expression data show that the DFL algorithm can identify biologically significant models with reasonable accuracy, sensitivity and high precision with respect to the literature evidences. We further introduce a method called epsilon function to deal with noises in data sets. The experimental results show that the epsilon function method is a good supplement to the DFL algorithm.

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