Abstract
Many methods for inferring genetic networks have been proposed, but the regulations they infer often include false-positives. Several researchers have attempted to reduce these erroneous regulations by proposing the use of a priori knowledge about the properties of genetic networks such as their sparseness, scale-free structure, and so on. This study focuses on another piece of a priori knowledge, namely, that biochemical networks exhibit hierarchical structures. Based on this idea, we propose an inference approach that uses the hierarchical structure in a target genetic network. To obtain a reasonable hierarchical structure, the first step of the proposed approach is to infer multiple genetic networks from the observed gene expression data. We take this step using an existing method that combines a genetic network inference method with a bootstrap method. The next step is to extract a hierarchical structure from the inferred networks that is consistent with most of the networks. Third, we use the hierarchical structure obtained to assign confidence values to all candidate regulations. Numerical experiments are also performed to demonstrate the effectiveness of using the hierarchical structure in the genetic network inference. The improvement accomplished by the use of the hierarchical structure is small. However, the hierarchical structure could be used to improve the performances of many existing inference methods.
Highlights
A genetic network is a functioning circuit in living cells at the gene level
The target networks are artificial, the experiments we describe here could confirm the effectiveness of the use of the hierarchical structure for the genetic network inference
Note that we transformed the genetic networks inferred by the BSLPM inference method into undirected graphs for detecting their hierarchical structure
Summary
A genetic network is a functioning circuit in living cells at the gene level. From one viewpoint, a genetic network can be seen as an abstract mapping of an actual biochemical network consisting of genes, proteins, metabolites, and so on. Many studies have sought to develop computational methods for inferring genetic networks from observed gene expression patterns (Larrañaga et al, 2006; Chou and Voit, 2009; Hecker et al, 2009). Often, these methods infer false-positive regulations along with true-positive regulations. These methods infer false-positive regulations along with true-positive regulations These erroneous regulations must be decreased if we are to successfully analyze the inferred genetic networks. One possible approach to remove these erroneous regulations from the inferred genetic networks is to use a priori knowledge about the networks. Several researchers have introduced a priori knowledge about the properties of genetic networks, such as their sparseness, scale-free structure, and so on, into methods for inferring genetic networks (see, e.g., Kikuchi et al, 2003; Daisuke and Horton, 2006)
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