Breaking the waves: improved detection of copy number variation from microarray-based comparative genomic hybridization

Date

2007-10-25

Authors

Marioni, John C
Thorne, Natalie P
Valsesia, Armand
Fitzgerald, Tomas
Redon, Richard
Fiegler, Heike
Andrews, T Daniel
Stranger, Barbara E
Lynch, Andrew G
Dermitzakis, Emmanouil T

Journal Title

Journal ISSN

Volume Title

Publisher

BioMed Central

Abstract

BACKGROUND Large-scale high throughput studies using microarray technology have established that copy number variation (CNV) throughout the genome is more frequent than previously thought. Such variation is known to play an important role in the presence and development of phenotypes such as HIV-1 infection and Alzheimer's disease. However, methods for analyzing the complex data produced and identifying regions of CNV are still being refined. RESULTS We describe the presence of a genome-wide technical artifact, spatial autocorrelation or 'wave', which occurs in a large dataset used to determine the location of CNV across the genome. By removing this artifact we are able to obtain both a more biologically meaningful clustering of the data and an increase in the number of CNVs identified by current calling methods without a major increase in the number of false positives detected. Moreover, removing this artifact is critical for the development of a novel model-based CNV calling algorithm - CNVmix - that uses cross-sample information to identify regions of the genome where CNVs occur. For regions of CNV that are identified by both CNVmix and current methods, we demonstrate that CNVmix is better able to categorize samples into groups that represent copy number gains or losses. CONCLUSION Removing artifactual 'waves' (which appear to be a general feature of array comparative genomic hybridization (aCGH) datasets) and using cross-sample information when identifying CNVs enables more biological information to be extracted from aCGH experiments designed to investigate copy number variation in normal individuals.

Description

Keywords

data interpretation, statistical, gene dosage, microarray analysis, nucleic acid hybridization, algorithms, genetic variation

Citation

Source

Genome Biology

Type

Journal article

Book Title

Entity type

Access Statement

License Rights

Restricted until

Downloads