6533b863fe1ef96bd12c795f
RESEARCH PRODUCT
Analyzing Illumina Gene Expression Microarray Data from Different Tissues: Methodological Aspects of Data Analysis in the MetaXpress Consortium
Henri WallaschofskiThomas MeitingerPhilipp S. WildChristian HerderMaren CarstensenGeorg HomuthRainer RettigChristian P. MüllerHenry VölzkeAndreas ZieglerJochen KruppaUwe VölkerMarcus DörrHolger ProkischAlexander TeumerKarlhans EndlichStefan BlankenbergStephan B. FelixWolfgang HoffmannMichael RodenKonstantin StrauchKatharina HeimChristian GiegerArne SchillertHarald GrallertClaudia SchurmannSimone WahlAnnette PetersMatthias NauckThomas IlligTanja Zellersubject
MicroarraysArray ProcessingClinical Research DesignScienceGene ExpressionSingle-nucleotide polymorphismBiologyPolymorphism Single NucleotideMolecular Genetics03 medical and health sciencesEngineering0302 clinical medicineGenome Analysis ToolsGermanyWhite blood cellGene expressionGenome-Wide Association StudiesGeneticsmedicineHumansGenome SequencingStatistical MethodsBiologyOligonucleotide Array Sequence Analysis030304 developmental biologyWhole bloodGenetics0303 health sciencesMultidisciplinaryGene Expression ProfilingQRComputational BiologyReproducibility of ResultsHuman GeneticsGenomicsGene expression profilingMinor allele frequencymedicine.anatomical_structure030220 oncology & carcinogenesisSignal ProcessingMedicineRNA extractionFunctional genomicsResearch Articledescription
Microarray profiling of gene expression is widely applied in molecular biology and functional genomics. Experimental and technical variations make meta-analysis of different studies challenging. In a total of 3358 samples, all from German population-based cohorts, we investigated the effect of data preprocessing and the variability due to sample processing in whole blood cell and blood monocyte gene expression data, measured on the Illumina HumanHT-12 v3 BeadChip array. Gene expression signal intensities were similar after applying the log(2) or the variance-stabilizing transformation. In all cohorts, the first principal component (PC) explained more than 95% of the total variation. Technical factors substantially influenced signal intensity values, especially the Illumina chip assignment (33-48% of the variance), the RNA amplification batch (12-24%), the RNA isolation batch (16%), and the sample storage time, in particular the time between blood donation and RNA isolation for the whole blood cell samples (2-3%), and the time between RNA isolation and amplification for the monocyte samples (2%). White blood cell composition parameters were the strongest biological factors influencing the expression signal intensities in the whole blood cell samples (3%), followed by sex (1-2%) in both sample types. Known single nucleotide polymorphisms (SNPs) were located in 38% of the analyzed probe sequences and 4% of them included common SNPs (minor allele frequency >5%). Out of the tested SNPs, 1.4% significantly modified the probe-specific expression signals (Bonferroni corrected p-value<0.05), but in almost half of these events the signal intensities were even increased despite the occurrence of the mismatch. Thus, the vast majority of SNPs within probes had no significant effect on hybridization efficiency. In summary, adjustment for a few selected technical factors greatly improved reliability of gene expression analyses. Such adjustments are particularly required for meta-analyses.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2012-01-01 | PLoS ONE |