Abstract
BackgroundCo-occurrence analysis is a technique often applied in text mining, comparative genomics, and promoter analysis. The methodologies and statistical models used to evaluate the significance of association between co-occurring entities are quite diverse, however.Methodology/Principal FindingsWe present a general framework for co-occurrence analysis based on a bipartite graph representation of the data, a novel co-occurrence statistic, and software performing co-occurrence analysis as well as generation and analysis of co-occurrence networks. We show that the overall stringency of co-occurrence analysis depends critically on the choice of the null-model used to evaluate the significance of co-occurrence and find that random sampling from a complete permutation set of the bipartite graph permits co-occurrence analysis with optimal stringency. We show that the Poisson-binomial distribution is the most natural co-occurrence probability distribution when vertex degrees of the bipartite graph are variable, which is usually the case. Calculation of Poisson-binomial P-values is difficult, however. Therefore, we propose a fast bi-binomial approximation for calculation of P-values and show that this statistic is superior to other measures of association such as the Jaccard coefficient and the uncertainty coefficient. Furthermore, co-occurrence analysis of more than two entities can be performed using the same statistical model, which leads to increased signal-to-noise ratios, robustness towards noise, and the identification of implicit relationships between co-occurring entities. Using NetCutter, we identify a novel protein biosynthesis related set of genes that are frequently coordinately deregulated in human cancer related gene expression studies. NetCutter is available at http://bio.ifom-ieo-campus.it/NetCutter/).ConclusionOur approach can be applied to any set of categorical data where co-occurrence analysis might reveal functional relationships such as clinical parameters associated with cancer subtypes or SNPs associated with disease phenotypes. The stringency of our approach is expected to offer an advantage in a variety of applications.
Highlights
Biological research has experienced a paradigm shift in the last decade catalyzed by the availability of genome sequences and the resulting development of high-throughput technologies
Our approach can be applied to any set of categorical data where co-occurrence analysis might reveal functional relationships such as clinical parameters associated with cancer subtypes or single nucleotide polymorphism (SNP) associated with disease phenotypes
The bipartite graph model of co-occurrence analysis Co-occurrence analysis using NetCutter is based on the abstraction of list-entry pairs
Summary
Biological research has experienced a paradigm shift in the last decade catalyzed by the availability of genome sequences and the resulting development of high-throughput technologies. The large data volumes produced by these novel technologies are often published as supplementary material and/or stored in extensive data repositories [1]. Functional interpretation of these data is an ongoing challenge. Co-occurrence analysis, based on the hypothesis that co-occurring entities are functionally linked, is a technique that has been used in three main areas of biological research: 1. Co-occurrence of genes in fully sequenced genomes. Co-occurrence analysis is a technique often applied in text mining, comparative genomics, and promoter analysis. The methodologies and statistical models used to evaluate the significance of association between co-occurring entities are quite diverse,
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