RedundancyMiner: De-replication of redundant GO categories in microarray and proteomics analysis

Autor: Reinhold William, Larionov Vladimir L, Brooks Brian P, Brown Jacob D, Bonner Robert F, Rajapakse Vinodh N, Ehler Martin, Kahn Ari B, Liu Hongfang, Zeeberg Barry R, Weinstein John N, Pommier Yves G
Jazyk: angličtina
Rok vydání: 2011
Předmět:
Zdroj: BMC Bioinformatics, Vol 12, Iss 1, p 52 (2011)
Druh dokumentu: article
ISSN: 1471-2105
DOI: 10.1186/1471-2105-12-52
Popis: Abstract Background The Gene Ontology (GO) Consortium organizes genes into hierarchical categories based on biological process, molecular function and subcellular localization. Tools such as GoMiner can leverage GO to perform ontological analysis of microarray and proteomics studies, typically generating a list of significant functional categories. Two or more of the categories are often redundant, in the sense that identical or nearly-identical sets of genes map to the categories. The redundancy might typically inflate the report of significant categories by a factor of three-fold, create an illusion of an overly long list of significant categories, and obscure the relevant biological interpretation. Results We now introduce a new resource, RedundancyMiner, that de-replicates the redundant and nearly-redundant GO categories that had been determined by first running GoMiner. The main algorithm of RedundancyMiner, MultiClust, performs a novel form of cluster analysis in which a GO category might belong to several category clusters. Each category cluster follows a "complete linkage" paradigm. The metric is a similarity measure that captures the overlap in gene mapping between pairs of categories. Conclusions RedundancyMiner effectively eliminated redundancies from a set of GO categories. For illustration, we have applied it to the clarification of the results arising from two current studies: (1) assessment of the gene expression profiles obtained by laser capture microdissection (LCM) of serial cryosections of the retina at the site of final optic fissure closure in the mouse embryos at specific embryonic stages, and (2) analysis of a conceptual data set obtained by examining a list of genes deemed to be "kinetochore" genes.
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