Abstract
BackgroundBiological networks connect genes, gene products to one another. A network of co-regulated genes may form gene clusters that can encode proteins and take part in common biological processes. A gene co-expression network describes inter-relationships among genes. Existing techniques generally depend on proximity measures based on global similarity to draw the relationship between genes. It has been observed that expression profiles are sharing local similarity rather than global similarity. We propose an expression pattern based method called GeCON to extract Gene CO-expression Network from microarray data. Pair-wise supports are computed for each pair of genes based on changing tendencies and regulation patterns of the gene expression. Gene pairs showing negative or positive co-regulation under a given number of conditions are used to construct such gene co-expression network. We construct co-expression network with signed edges to reflect up- and down-regulation between pairs of genes. Most existing techniques do not emphasize computational efficiency. We exploit a fast correlogram matrix based technique for capturing the support of each gene pair to construct the network.ResultsWe apply GeCON to both real and synthetic gene expression data. We compare our results using the DREAM (Dialogue for Reverse Engineering Assessments and Methods) Challenge data with three well known algorithms, viz., ARACNE, CLR and MRNET. Our method outperforms other algorithms based on in silico regulatory network reconstruction. Experimental results show that GeCON can extract functionally enriched network modules from real expression data.ConclusionsIn view of the results over several in-silico and real expression datasets, the proposed GeCON shows satisfactory performance in predicting co-expression network in a computationally inexpensive way. We further establish that a simple expression pattern matching is helpful in finding biologically relevant gene network. In future, we aim to introduce an enhanced GeCON to identify Protein-Protein interaction network complexes by incorporating variable density concept.
Highlights
Biological networks connect genes, gene products to one another
A gene co-expression network (CEN) is a collection of genes in a cell which interact with each other and with other molecules in the cell such as proteins or metabolites, thereby governing the rates at which genes in the network are transcribed into mRNA
A CEN is normally represented as an undirected graph, where a node represents a gene or gene product and an undirected edge represents a significant co-expression relationship [3,4] between the genes considering a series of gene expression measurements
Summary
A network of co-regulated genes may form gene clusters that can encode proteins and take part in common biological processes. Gene pairs showing negative or positive co-regulation under a given number of conditions are used to construct such gene co-expression network. We construct co-expression network with signed edges to reflect up- and down-regulation between pairs of genes. We exploit a fast correlogram matrix based technique for capturing the support of each gene pair to construct the network. A Gene Regulatory Network (GRN) is a directed graph, where a node represents a gene and a directed edge represents a biochemical process such as a reaction, transformation, interaction, activation or inhibition. A module extracted from a co-expression network [5] may contain co-regulated gene clusters which interact among themselves and take part in a common biological process
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