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Analysis of Exon Arrays Slides provided by Dr. Yi Xing.

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Presentation on theme: "Analysis of Exon Arrays Slides provided by Dr. Yi Xing."— Presentation transcript:

1 Analysis of Exon Arrays Slides provided by Dr. Yi Xing

2 Outline –Design of exon arrays –Background correction –Probe selection, expression index computation –Evaluation of gene level index –Exon level analysis –Conclusion

3 1. Basic design of Exon Array 3’ ArraysExon Arrays 1 gene --- 1 or 2 probesets1 gene --- many probesets Probes from 600 bps near 3’ end Probes from each putative exon Probeset has 11 PM, 11 MM probesProbeset has 4 PM probes 54,000 probesets1.4 Million probesets, 6 M features Average16 probes per RefSeq geneAverage147 probes per RefSeq gene

4 Exon Array Probesets Classified by Annotational Confidence Core probesets target exons supported by RefSeq mRNAs. Extended probesets target exons supported by ESTs or partial mRNAs. Full probesets target exons supported purely by computational predictions.

5 2. Background modeling: predict non- specific hybridization from probe sequence Wu and Irizarry (2005) use probe effect modeling to obtain more accurate expression index on 3’ arrays Johnson et al (2006) use probe effect modeling to detect ChIP peaks for Tiling arrays Kapur et al (2007) use probe effect modeling to correct background for Exon array

6 Background modeling in Exon Arrays logB i = α*n iT + ∑ β jk I ijk + ∑ γ k n ik 2 + ε i Estimate parameters from either –Background probes (n = 37,687) –Full probes (n = 400,000) test on a different array (with single scaling constant) Full probes useful for modeling background

7 Arraystem cell mPromoter R 2 exon array R 2 H9-38-3B0.606440.632071 H9-38-3C0.5970050.623045 H9-38-3CM_80.5892890.603118 H9-38-7B0.5809490.596331 H9-39-7B0.5425810.555235 H9-41-7B0.6037420.631153 H9-43-3B0.6124220.634044 H9-43-7B0.5942460.61426 Promoter array may be used to train exon array background

8 Preliminary conclusions Background correction based on background probe effect modeling can greatly reduce background noise Model parameters are similar for different ChIP- DNA samples, or for different RNA samples, but not across DNA and RNA. The data may be rich enough to support learning of more complex models with even better predictive power.

9 3. Probe selection and expression index computation

10 Probes Samples Core probes Gene-level visualization: Heatmap of Intensities major histocompatibility complex, class II, DM beta

11 Heatmap of Pairwise Correlations Probes HLA_DMB

12 First observations Heapmap of correlations is a useful complement to heatmap of intensities Core probes have higher intensity than extended and full probes

13 Probe selection for gene-level expression Most full and extended probes are not suitable for estimating gene-level expression –Probes may target false exon predictions Even some core probes may not be suitable –Bad probes with low affinity, or cross-hybridize –Probes targeting differentially spliced exons Probe selection –Selecting a suitably large subset of good probes targeting constitutively spliced regions of the gene –Use only to selected probes to estimate gene expression

14 _____________ ________________________ _____________ constitutive alternatively spliced constitutive Heatmap of CD44 core probes (Ordered By Genomic Locations)

15 ataxin 2-binding protein 1

16 These examples motivated our Probe Selection Strategy Probe selection procedure (on core probes) –Hierarchical clustering of the probe intensities across 11 tissues (33 samples), and cut the tree at various heights (0.1,0.2,…1.0). –Choose a height cutoff to strike a balance between the size of the largest sub-group and the correlation within the sub-group. –Iteratively remove probes if they do not correlate well with current expression index –At least 11 core probes need to be chosen. –If the total number of core probes is less than 11 for the entire transcript cluster, we skip probe selection. (Xing Y, Kapur K, Wong WH. PLoS ONE. 2006 20;1:e88)

17 Hierarchical Clustering of CD44 Core Probes (distance=1-corr, average linkage) h=0.1 44 (42%) probes

18 Computation of gene level expression index Background correction Normalization Probe selection Computation of Overall Gene Expression Indexes GeneBASE: Gene-level Background Adjusted Selected probe Expression Download: http://biogibbs.stanford.edu/~kkapur/GeneBASE/ Xing, Kapur, Wong, PLoS ONE, 1:e88, 2006 Kapur, Xing, Wong, Genome Biology, 8:R82, 2007 (linear scaling or none) (dChip type model) Gene level quantile normalization optional

19 In most cases selection does not affect fold changes

20 spectrin, beta, non-erythrocytic 4 (SPTBN4) Sometimes, selections change fold-change significantly BetaIV spectrins are essential for membrane stability and the molecular organization of nodes of Ranvier along neuronal axons

21 4. Evaluations of gene level index

22 Before selection After selection Fold-change of liver over muscle, in 438 genes with high fold-change in 3’ expression array data 1 st evaluation: tissue fold change

23 Before selection After selection Probe selection allows more sensitive detection of fold-changes Zoom-in

24 Before selection After selection FC of muscle over liver, in 500 genes detected to be overexpressed in muscle over liver by 3’ array

25 Before selection After selection Zoom-in FC of muscle over liver

26 2 nd evaluation: Presence/Absence calls Use SAGE data to construct gold-standard Presence in tissue if 100 tags per million Absence if no tags in given tissue but >100 tpm in at least another tissue Exon array A/P calls: use sum of z-scores for core probes (z-score is computed based on background model)

27 (a) (b) (c) Cerebellum Heart Kidney ROC curves shows that background correction improves A/P calls. Red: Exon, Z-score call Blue: Exon Affy call Brown: 3’ Affy call, max probeset Purple: 3’ Affy call, min probe set

28 3 rd evaluation: Cross-species conservation 3’ and Exon array data for six adult tissues in both human and mouse Expression computed for about 10,000 pairs of human-mouse ortholog pairs

29 3’ arrays Exon arrays Similarity of gene expression profiles in six human tissues and six corresponding mouse tissues. For each ortholog pair we calculated the Pearson correlation coefficient (PCC) of expression indexes across six tissues (solid line). We also permutated ortholog relationships and calculated the PCC for random human-mouse gene pairs (dashed line). (Xing Y, Ouyang Z, Kapur K, Scott MP, Wong WH. Mol Biol Evol. April 2007)

30 3’ arrays correlationsExon arrays correlations 3’ arrays scatter plotExon arrays scatter plot Exon arrays also reveal conservation of absolute abundance of transcripts in individual tissues!

31 4 th evaluation: q-PCR On log scale, exon array fold change estimate is correlated with qPCR fold change (corr = 0.9)

32 5. Issues in exon level analysis

33 Challenges The experimental validation rate in several published exon array studies are highly variable. –Gardina et al. BMC Genomics 7:325, 21% –Kwan et al. Genome Res 17:1210, 45% –Hung et al. RNA 14:284, 22%-56% –Clark et al. Genome Biol 8:R64, 84%. Most exons are targeted by no more than four probes. No probes for splice junctions. Noise in observed probe intensities (due to background, cross-hybridization) can make the inferred splicing pattern unreliable.

34 MADS: Microarray Analysis of Differential Splicing 1. Correction for background (non- specific hybridization) 2. Probe selection and expression index calculation 4. Detection of differential splicing 3. Correction for cross- hybridization 1. Kapur, Xing, Wong, Genome Biology, 8:R82, 2007 2. Xing, Kapur, Wong WH. PLoS ONE. 2006 20;1:e88 3. Xing et.al., 2008, RNA, 2008, 14(8): 1470-1479

35 Splicing Index: Corrected Probe Intensity Estimated Gene Expression Level

36 Analysis of “gold-standard” alternative splicing data via PTB knockdown experiments Our “gold-standard” - a list of exons with pre-determined inclusion/exclusion profiles in response to PTB depletion (Boutz P, et.al. Genes Dev. 2007, 21(13):1636-52.) We used shRNA to knock-down PTB, generated Exon array data, and analyzed data on “gold- standard” exons. MADS detected all exons with large changes (>25%) in transcript inclusion levels, and offered improvement over Affymetrix’s analysis procedure. Collaboration with Douglas Black (UCLA) Boutz P, et.al. Genes Dev. 2007, 21(13):1636-52.

37 MADS sensitivity correlates with the magnitude of change in exon inclusion levels of “gold-standard exons” Xing et.al., 2008, RNA, 2008, 14(8): 1470-1479

38 Exon array detection of novel PTB- dependent splicing events control shRNA knockdown of splicing repressor PTB

39 Detection of alternative 3’-UTR and Poly-A sites of Ncam1 30 differentially spliced exons were tested; 27 were validated. Validation rate: 27/30=90%

40 Cross-Hybridization Probes are designed to hybridize to their target transcripts Often probes have 0,1,2,3 base pair mismatches to non-target transcripts Cross-hyb seriously complicates exon- level analysis.

41 Mapping mismatches to probes 6,000,000 probes Each 25bp long 3,000,000,000bp genome sequence For 1-bp mismatch, a naïve search needs O(6M x 3G x 25) ~ years of CPU time Fast matching algorithm (by Hui Jiang) makes this feasible in hours

42 Distribution of Number of Cross-hyb Transcripts 0 Trans.1 Trans.2 Trans.3 Trans.≥ 4 Trans. 0 bp97.052.140.400.180.23 0-1 bp96.142.600.590.270.40 0-2 bp95.592.790.690.330.60 0-3 bp92.365.061.120.480.98 0-4 bp80.5013.373.101.091.93 Full Probes 0 Trans.1 Trans.2 Trans.3 Trans.≥ 4 Trans. 0 bp99.520.400.050.010.02 0-1 bp99.210.62 0.100.03 0-2 bp98.900.840.150.050.06 0-3 bp97.491.980.290.100.13 0-4 bp88.259.671.360.350.36 Core Probes

43 Correction of sequence-specific cross- hybridization to off-target transcripts PAN3 Estimated expression levels of off-target transcripts of EEF1A1 Intensities of four probes of the target exon of PAN3

44 Conclusion Gene level index is accurate and reflects absolute abundance We show that sequence-specific modeling of microarray noise (background and cross-hybridization) improves the precision of exon- level analysis of exon array data. Overall, our data demonstrate that exon array design is an effective approach to study gene expression and differential splicing. Development of future “probe rich” exon arrays, with increased probe density on exons and inclusion of splice junction probes, will offer more powerful tools for global or targeted analysis of alternative splicing.

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