Correcting gene expression data when neither the unwanted variation nor the factor of interest are observed

Correcting gene expression data when neither the unwanted variation nor the factor of interest are observed

When dealing with large scale gene expression studies, observations are commonly contaminated by sources of unwanted variation such as platforms or batches. Not taking this unwanted variation into account when analyzing the data can lead to spurious associations and to missing important signals. Whe...

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Bibliographic Details
Published in:Biostatistics (Oxford, England) Vol. 17; no. 1; pp. 16 - 28
Main Authors: Jacob, Laurent, Gagnon-Bartsch, Johann A, Speed, Terence P
Format: Journal Article
Language:English
Published: England Oxford Publishing Limited (England) 01-01-2016
Oxford University Press (OUP)
Oxford University Press
Subjects:
Data Interpretation, Statistical
Estimates
Gene expression
Gene Expression - genetics
Genes
Genetic Variation - genetics
Humans
Life Sciences
Microarray Analysis - methods
Normalization
Replicate samples
Control genes
Gene expression
Batch effect
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Summary:When dealing with large scale gene expression studies, observations are commonly contaminated by sources of unwanted variation such as platforms or batches. Not taking this unwanted variation into account when analyzing the data can lead to spurious associations and to missing important signals. When the analysis is unsupervised, e.g. when the goal is to cluster the samples or to build a corrected version of the dataset--as opposed to the study of an observed factor of interest--taking unwanted variation into account can become a difficult task. The factors driving unwanted variation may be correlated with the unobserved factor of interest, so that correcting for the former can remove the latter if not done carefully. We show how negative control genes and replicate samples can be used to estimate unwanted variation in gene expression, and discuss how this information can be used to correct the expression data. The proposed methods are then evaluated on synthetic data and three gene expression datasets. They generally manage to remove unwanted variation without losing the signal of interest and compare favorably to state-of-the-art corrections. All proposed methods are implemented in the bioconductor package RUVnormalize.
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PMCID: PMC4679071
ISSN:1465-4644
1468-4357
DOI:10.1093/biostatistics/kxv026