Artículos de revistas
Improving information retrieval in functional analysis
Fecha
2016-12Registro en:
Rodriguez, Juan Cruz; Gonzalez, Germán Alexis; Fresno Rodríguez, Cristóbal; Llera, Andrea Sabina; Fernandez, Elmer Andres; Improving information retrieval in functional analysis; Pergamon-Elsevier Science Ltd; Computers In Biology And Medicine; 79; 12-2016; 10-20
0010-4825
CONICET Digital
CONICET
Autor
Rodriguez, Juan Cruz
Gonzalez, Germán Alexis
Fresno Rodríguez, Cristóbal
Llera, Andrea Sabina
Fernandez, Elmer Andres
Resumen
Transcriptome analysis is essential to understand the mechanisms regulating key biological processes and functions. The first step usually consists of identifying candidate genes; to find out which pathways are affected by those genes, however, functional analysis (FA) is mandatory. The most frequently used strategies for this purpose are Gene Set and Singular Enrichment Analysis (GSEA and SEA) over Gene Ontology. Several statistical methods have been developed and compared in terms of computational efficiency and/or statistical appropriateness. However, whether their results are similar or complementary, the sensitivity to parameter settings, or possible bias in the analyzed terms has not been addressed so far. Here, two GSEA and four SEA methods and their parameter combinations were evaluated in six datasets by comparing two breast cancer subtypes with well-known differences in genetic background and patient outcomes. We show that GSEA and SEA lead to different results depending on the chosen statistic, model and/or parameters. Both approaches provide complementary results from a biological perspective. Hence, an Integrative Functional Analysis (IFA) tool is proposed to improve information retrieval in FA. It provides a common gene expression analytic framework that grants a comprehensive and coherent analysis. Only a minimal user parameter setting is required, since the best SEA/GSEA alternatives are integrated. IFA utility was demonstrated by evaluating four prostate cancer and the TCGA breast cancer microarray datasets, which showed its biological generalization capabilities.