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Exploratory Data Analysis of High Density Oligonucleotide Array

Exploratory Data Analysis of High Density Oligonucleotide Array. Rafael A. Irizarry, Bridget Hobbs, Terry Speed http://biosun01.biostat.jhsph.edu/~ririzarr/Raffy. Outline. Review of technology Form of Data Description of Data Normalization Future/current work: Defining expression. *. *.

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Exploratory Data Analysis of High Density Oligonucleotide Array

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  1. Exploratory Data Analysis of High Density Oligonucleotide Array Rafael A. Irizarry, Bridget Hobbs, Terry Speed http://biosun01.biostat.jhsph.edu/~ririzarr/Raffy

  2. Outline • Review of technology • Form of Data • Description of Data • Normalization • Future/current work: Defining expression

  3. * * * * * Probe Arrays Hybridized Probe Cell GeneChipProbe Array Single stranded, labeled RNA target Oligonucleotide probe 24µm Millions of copies of a specific oligonucleotide probe 1.28cm >200,000 different complementary probes Image of Hybridized Probe Array Compliments of D. Gerhold

  4. Image analysis • About 100 pixels per probe cell • These intensities are combined to form one number representing expression for the probe cell oligo • What about genes?

  5. PM MM

  6. Data and notation PMijn , MMijn= Intensity for perfect/mis-match probe cell j, in chip i, in gene n i = 1,…, I (ranging from 1 to hundreds) j=1,…, J (usually 16 or 20) n = 1,…, N (between 8,000 and 12,000)

  7. $64K Question • How do we define expression? or • What is the one number summary of the 20 PMs and 20 MMs that best quantifies expression? • How about differential expression?

  8. Current default • GeneChip® software uses Avg.diff with A a set of “suitable” pairs chosen by software. • Log ratio version is also used. • For differential expression Avg.diffs are compared between chips.

  9. What is the evidence? Lockhart et. al. Nature Biotechnology 14 (1996)

  10. Chips used in Lockhart et. al. contained around 1000 probes per gene • Current chips contain 20 probes per gene • These are different situations • We haven’t seen a plot like the previous one, for current chips

  11. Possible problems What if • a small number of the probe pairs hybridize much better than the rest? • removing the middle base does not make a difference for some probes? • some MM are PM for some other gene? • there is need for normalization? We explore these possibilities using data from 3 experiments

  12. Experiment 1 • 8 Rats, under 4 experimental conditions • Control NV21 • Ventilation V21 • Oxygen NV100 • Oxygen and Ventilation V100 • 2 rats in each condition • RNA is pooled and divided to form 2 technical replicates for each condition

  13. Notice • Experimental condition is confounded with couples: we can’t distinguish between biological variability and variability due to experimental condition • NV21, V21 and NV100,V100 processed in different scanners/fluidic stations: Oxygen effect confounded with scanner/fluidic station effect

  14. Experiment 2 • 6 Rats, under 3 experimental conditions • Control • ENOS • NNOS • 2 rats in each condition • RNA is pooled and divided to form 2 technical replicates

  15. Notice • One of the chips for NNOS did not “work” • Biological variability confounded with variability due to experimental condition • About 1/5 of the probes on chips used where defective.

  16. Experiment 3 • Five mice with different characteristics: • 4 week old female NOD (J4FD, R4FD) • 4 week old female NOD (J4FD) • 4 week old male NOD (J4MD) • 4 week old female homozygous transgenic mouse which can't get diabetes (R4FN)

  17. Notice • Each of the 5 chips were scanned twice • Two separate stains are used • This gives us 10 sets of results

  18. Properties of Data that make defining expression hard • There can be saturation • log2(PM / MM) and PM-MM are noisy • MM >> PM for many probes • PMs of the same probe vary about 5 times less from chip to chip than from probe to probe within the same probe set.

  19. Saturation problem Probes reaching maximum in experiment 1 Scanner Chip PM MM Value 2 NV21a 354 25 46140 2 NV21b 564 57 46144 2 V21a 1004 83 46141 2 V21b 665 51 46139 1 NV100a 1917 328 46154 1 NV100b 1265 168 46160 1 V100a 3399 1085 46155 1 V100b 2267 446 46149

  20. log2(PM/MM) for defective and normal probe sets in a chip from experiment 2

  21. The Good News

  22. Histograms of log2(PM/MM) stratifies by log2(PMxMM)/2 for one of the chips in experiment 1

  23. Histograms of log2(PM/MM) stratifies by log2(PMxMM)/2 for chip in experiment 2 for defective and normal probe

  24. Histograms of log2(PM/MM) stratifies by log2(PMxMM)/2 for one of the chips in experiment 3

  25. ANOVA

  26. Normalization • There are many sources of experimental variation: • During preparation: e.g. mRNA extraction, introduction of labeling • During manufacture of array: e.g. amount of oligos on cells • During hybridization: e.g. amount of sample applied, amount of target hybridized • After hybridization: e.g. optical measurements, label intensity, scanner • Proper normalization is need before intensities from different chips are compared

  27. Log ratio vs. average log intensity (MVA) plots of PM,MM

  28. Log ratio vs. avg log intensity (MVA) plots for PM / MM

  29. Normalization • Pair-wise normalization? • Which chips do we compare? • The following three plots show the 3 pairwise comparisons of chips Control A, ENOB, and NNOA

  30. Normalization based on combined PMs and MMs

  31. Cyclic algorithm (version 0.1) • For chip j, with entries X1 define the functions f1,…,fj-1,fj+1,…,fJ to be the results of smoothing the scatter plot {Xj-Xk , (Xj+Xk)/2} • Define the normalized chip as Xj’= Xj- (f1+…+fj-1+fj+1+…+fJ)/J • Chips X1,…,XJ are normalized in the same way • We iterate until Xi’, Xi are very similar for all i.

  32. Before and after normalization

  33. Experiment 1

  34. Experiment 2

  35. Experiment 2Combined PM and MM

  36. Experiment 2PM / MM

  37. Experiment 2PM – MM in a hybrid log scale

  38. Experiment 3Combined PM and MM

  39. Competing definitions of expression • Li and Wong fit a model Consider expression in chip i • Efron et. al. consider log PM – 0.5 log MM • Another is second largest PM

  40. How do we compare? • We want small variance, small bias. • Up to now we don’t know truth in any of our data sets so hard to assess bias. • One possibility is to assume some gene is differentially expressed in the experiments we study, find it, and look at its probe profile.

  41. Conclusion • Features of data suggest that avg.diff may be improved as a definition of expression • It seems that normalization is needed to remove experimental variation and make meaningful comparison of data from different chips fair

  42. Acknowledgements • JHU: Leslie Cope, Tom Coppola, Shwu-Fan Ma, Skip Garcia • CNMC: Rehannah Borup, Josephine Chen, Eric Hoffman • UC Berkeley: Ben Bolstad • WEHI: Runa Daniel, Len Harrison

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