Causal analysis approaches in ingenuity pathway analysis

A Krämer, J Green, J Pollard Jr, S Tugendreich - Bioinformatics, 2014 - academic.oup.com
A Krämer, J Green, J Pollard Jr, S Tugendreich
Bioinformatics, 2014academic.oup.com
Motivation: Prior biological knowledge greatly facilitates the meaningful interpretation of
gene-expression data. Causal networks constructed from individual relationships curated
from the literature are particularly suited for this task, since they create mechanistic
hypotheses that explain the expression changes observed in datasets. Results: We present
and discuss a suite of algorithms and tools for inferring and scoring regulator networks
upstream of gene-expression data based on a large-scale causal network derived from the …
Abstract
Motivation: Prior biological knowledge greatly facilitates the meaningful interpretation of gene-expression data. Causal networks constructed from individual relationships curated from the literature are particularly suited for this task, since they create mechanistic hypotheses that explain the expression changes observed in datasets.
Results: We present and discuss a suite of algorithms and tools for inferring and scoring regulator networks upstream of gene-expression data based on a large-scale causal network derived from the Ingenuity Knowledge Base. We extend the method to predict downstream effects on biological functions and diseases and demonstrate the validity of our approach by applying it to example datasets.
Availability: The causal analytics tools ‘Upstream Regulator Analysis', ‘Mechanistic Networks', ‘Causal Network Analysis' and ‘Downstream Effects Analysis' are implemented and available within Ingenuity Pathway Analysis (IPA, http://www.ingenuity.com).
Supplementary information:  Supplementary material is available at Bioinformatics online.
Oxford University Press