Meta-analysis based on control of false discovery rate: combining yeast ChIP-chip datasets

doi:10.1093/bioinformatics/btl439

Bioinformatics Advance Access originally published online on August 14, 2006
Bioinformatics 2006 22(20):2516-2522; doi:10.1093/bioinformatics/btl439

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Meta-analysis based on control of false discovery rate: combining yeast ChIP-chip datasets

Saumyadipta Pyne ¹^,*, Bruce Futcher ² and Steve Skiena ¹

¹ Department of Computer Science, Stony Brook University NY 11794, USA
² Department of Molecular Genetics and Microbiology, Stony Brook University NY 11794, USA

^*To whom correspondence should be addressed.

Motivation: High-throughput microarray technology can be usedto examine thousands of features, such as all the genes of anorganism, and measure their expression. Two important issuesof microarray bioinformatics are first, how to combine the significancevalues for each feature across experiments with high statisticalpower, and second, how to control the proportion of false positives.Existing methods address these issues separately, in spite oftheir linked usage.

Results: We present a novel method (ESP) to address the tworequirements in an interdependent way. It generalizes the truncatedproduct method of Zaykin et al. to combine only those significancevalues which clear their respective experiment-specific falsediscovery restrictive thresholds, thus allowing us to controlthe false discovery rate (FDR) for the final combined result.Further, we introduce several concepts that together offer FDRcontrol, high power, quality control and speed-up in meta-analysisas done by our algorithm. Computational and statistical methodsof research synthesis like the one described here will be increasinglyimportant as additional genome-wide datasets accumulate in databases.

We apply our method to combine three well-known ChIP-chip transcriptionfactor binding datasets for budding yeast to identify significantintergenic regulatory sequences for nine cell cycle regulatingtranscription factors, both with high power and controlled FDR.

Contact: spyne{at}cs.sunysb.edu

Supplementary Materials and Appendices: http://www.cs.sunysb.edu/~compbio/Meta

Received on June 15, 2006; revised on August 2, 2006; accepted on August 9, 2006

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