MGED IV Meeting Considerations in the Design of Local Research Microarray Databases

1. MGED IV MeetingConsiderations in the Design of Local Research Microarray Databases Jason Gonçalves Slides available at http://www.iobion.com/slides/

2. Public Repositories vs. Local Microarray Databases Aims - Public Microarray Repositories: • Exchange of published (complete) microarray datasets • Facilitate meta-analysis of previously published microarray datasets Aims - Local Microarray Databases: • Storage of all microarray data (images, etc) • Facilitate analysis of microarray data • Enable validation and debugging of local microarrays, reagents and equipment

5. MIAME Components

6. MIAME Components

7. Array Design – MIAME++

8. MIAME Components

9. Measurement Data – MIAME++

10. MIAME Components

11. Sample Annotation – MIAME++ Detailed description of replication: At what level is this a replicate?

12. Data Analysis and Variability Evolving Microarray Analysis • Develop statistical methods for microarray data analysis • Study and understand the multiple sources of variability • Develop methods to reduce variability and develop experimental designs with the sources of variability in mind s s s “Replication does not ensure duplication of results, of course this is not obvious when replication is not used”

13. Quality Views To Find Variability Sources

14. Quality Views To Find Variability Sources Time Points Time Course Hyb Dates Print Batch ID Slide Batch ID

15. Dissecting Spatial Effects Background - Simulated Original Image Data Ratio View - Simulated Quantified Microarray Data

16. Using Replicate Statistics within a Hybridization Group to Identify Variable Genes Note: SD of the Hybridization Group Standard Deviations • Z-score values identify genes that are highly variable relative the other genes in the group while individual variance values report the absolute levels • Identify genes with extreme standard deviations - z-score > 3

17. Clustering SD Z-Scores to Identify Random and Systematic Sources of Variability Gene with Z-Score > 3 • Calculated Z-score for all genes • and hybridization groups • Filtered data set to include • genes with at lease one observed • z-score > 3 • Random Noise: • Dust spots • Incorrect patch placement • Ghost spots • Systematic Variability: • Using poor gene annotation (e.g. using Unigene vs. Clone ID) • Microarray production problems • PCR failure, double bands, end of print plate errors

18. Dust Spot Examples

19. Systematic Production Problem Example Unique PCR Amplifications Unique Hybridizations

20. Multiple Myeloma Cell Lines Interesting Genes: p53, x-actin, ras, etc. Other Genes (49 clones) Lambda Ig light chain (62 clones) Validate with RT-PCR Kappa Ig light chain (74 clones) All interesting genes are artifacts Other Genes (12 clones)

21. Iobion - GeneTraffic www.iobion.com

22. Acknowledgements • Iobion Informatics LLC. • Daniel Iordan • Harry Liu • WL Marks • William Roboly • Faye Barron • Bogdan Georgescu University Health Network, University of Toronto • Mark Takahashi • Neil Winegarden • James R. Woodgett • All UHN Microarray Center Staff