MOTIVATION: The identification of condition specific sub-networks from gene expression profiles has important biological applications, ranging from the selection of disease-related biomarkers to the discovery of pathway alterations across different phenotypes. Although many methods exist for extracting these sub-networks, very few existing approaches simultaneously consider both the differential expression of individual genes and the differential correlation of gene pairs, losing potentially valuable information in the data. RESULTS: In this article, we propose a new method, COSINE (COndition SpecIfic sub-NEtwork), which employs a scoring function that jointly measures the condition-specific changes of both 'nodes' (individual genes) and 'edges' (gene-gene co-expression). It uses the genetic algorithm to search for the single optimal sub-network which maximizes the scoring function. We applied COSINE to both simulated datasets with various differential expression patterns, and three real datasets, one prostate cancer dataset, a second one from the across-tissue comparison of morbidly obese patients and the other from the across-population comparison of the HapMap samples. Compared with previous methods, COSINE is more powerful in identifying truly significant sub-networks of appropriate size and meaningful biological relevance. AVAILABILITY: The R code is available as the COSINE package on CRAN: http://cran.r-project.org/web/packages/COSINE/index.html.
MOTIVATION: The identification of condition specific sub-networks from gene expression profiles has important biological applications, ranging from the selection of disease-related biomarkers to the discovery of pathway alterations across different phenotypes. Although many methods exist for extracting these sub-networks, very few existing approaches simultaneously consider both the differential expression of individual genes and the differential correlation of gene pairs, losing potentially valuable information in the data. RESULTS: In this article, we propose a new method, COSINE (COndition SpecIfic sub-NEtwork), which employs a scoring function that jointly measures the condition-specific changes of both 'nodes' (individual genes) and 'edges' (gene-gene co-expression). It uses the genetic algorithm to search for the single optimal sub-network which maximizes the scoring function. We applied COSINE to both simulated datasets with various differential expression patterns, and three real datasets, one prostate cancer dataset, a second one from the across-tissue comparison of morbidly obesepatients and the other from the across-population comparison of the HapMap samples. Compared with previous methods, COSINE is more powerful in identifying truly significant sub-networks of appropriate size and meaningful biological relevance. AVAILABILITY: The R code is available as the COSINE package on CRAN: http://cran.r-project.org/web/packages/COSINE/index.html.
Authors: Timothy S Wells; Anna T Bukowinski; Tyler C Smith; Besa Smith; Leslie K Dennis; Laura K Chu; Gregory C Gray; Margaret A K Ryan Journal: Prostate Date: 2010-05-15 Impact factor: 4.104
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Authors: Gil Speyer; Divya Mahendra; Hai J Tran; Jeff Kiefer; Stuart L Schreiber; Paul A Clemons; Harshil Dhruv; Michael Berens; Seungchan Kim Journal: Pac Symp Biocomput Date: 2017
Authors: Ilana Lichtenstein; Michael A Charleston; Tiberio S Caetano; Jennifer R Gamble; Mathew A Vadas Journal: BMC Bioinformatics Date: 2013-02-21 Impact factor: 3.169