Establishing the infrastructure for sharing microarray data

1. Establishing the infrastructurefor sharing microarray data Alvis Brazma European Bioinformatics Institute EMBL-EBI Microarray Gene Expression Data Society

2. Outline • Establishing the infrastructure for sharing microarray data – MGED, MIAME, MAGE-ML, databases • Microarray Informatics at the EBI

3. Microarrays - a tool for the golden age of genome discoveries

4. Some questions for the golden age of genomics • How gene expression differs in different cell types? • How gene expression changes when the organism develops and cells are differentiating? • How gene expression differs in a normal and diseased (e.g., cancerous) cell? • How gene expression changes when a cell is treated by a drug? • How gene expression is regulated – which genes regulate which and how?

5. Potential amounts of microarray data • Experiments: ~ 30 000 genes in a human genome ~ 320 cell types in a human organism • 2000 compounds for screening • 2 concentrations • 3 time points • 5 replicates • Data ~ 1012 data-points 1 Tera Byte

6. Making microarray data available to the public • Authors web-sites • Local, lab based public databases (Stanford University, Whitehead,…) • Journal web-sites • There is a wide community consensus that there is a need for public repositories for microarray data, analogous to DDBJ/EMBL/Genbank for sequence data

7. Quantitation matrices Gene expression data matrix Raw data Array scans Quantitations Samples Spots Genes Gene expression levels Which data to share?

8. Sample annotations problem 1 Gene expression levels – problem 2 Gene annotations Annotations Samples Gene expression matrix Genes

9. source Sample Design treatment protocols RNA extract elements (spots) labelled nucleic acid array image quantitation matrix hybridisation Sample annotation Gene annotation

10. Sample Sample Sample Sample Sample Design Design Design Design Design RNA extract RNA extract RNA extract RNA extract RNA extract elements (spots) elements (spots) elements (spots) elements (spots) elements (spots) labelled nucleic acid labelled nucleic acid labelled nucleic acid labelled nucleic acid labelled nucleic acid hybridisation hybridisation hybridisation hybridisation hybridisation array array array array array Gene expression data matrix transformation integration Experiment Gene expression measurements

11. Problem 4 • The nature and structure of the above described gene expression data and annotations are complex • For the public repositories to make the maximum use out of these data, standards for representing and communicating it should be established

12. Standards for microarray data • Understanding and agreement what data and annotations should be provided • Standard controlled vocabularies (ontologies) that can be used in such annotations • Standard format for exchange of annotated data • Understanding how to compare different datasets

13. Microarray Gene Expression Database meeting was organised in Cambridge, UK, November 1999 to discuss these problems

14. Affymetrix DDBJ DKFZ EMBL Gene Logic Incyte Max Plank Institute NCGR NHGRI Sanger Centre Stanford University Uni Pennsylvania Uni Washington, Seattle Whitehead Institute MGED 1 – some participants

15. MGED working groups • Experiment annotation • Data exchange format and modelling • Ontologies • Data normalisation and transformations • Queries

16. MGED meetings MGED 2, Heidelberg, May 2000 MGED 3, Stanford University, April 2001 MGED 4, Boston, February 2002 MGED 5, Tokyo, September 2002

17. MGED Society was founded in June 2002 Microarray Gene Expression Data (MGED) society is an international organisation for facilitating sharing of functional genomics and proteomics array data Board of 17 directors www.mged.org

18. MGED standards • Annotation content – MIAME • Data representation and exchange format MAGE-OM (MAGE-ML) – jointly with OMG

19. MIAME – Minimum Information About a Microarray experiment An attempt to outline the minimum information required to interpret unambiguously and potentially reproduce and verify an array based gene expression experiment www.mged.org/miame

20. MGED standards

21. Sample Sample Sample Sample Sample Design Design Design Design Design RNA extract RNA extract RNA extract RNA extract RNA extract elements (spots) elements (spots) elements (spots) elements (spots) elements (spots) labelled nucleic acid labelled nucleic acid labelled nucleic acid labelled nucleic acid labelled nucleic acid hybridisation hybridisation hybridisation hybridisation hybridisation array array array array array Gene expression data matrix normalization integration Experiment MIAME – the content (annotation) of all boxes and lines should be given

22. MIAME ‘checklist’ to authors and reviewers • Experimental design • Samples used, RNE extraction and labelling • Hybridisation • Measurement data and specifications • Array Design • (Row images) • Image quantitation (data and specification) • Gene expression data matrix (data and transformations)

23. MIAME ‘checklist’ • An open letter was sent to the journals last week - all the information in MIAME ‘checklist’ should be made available as a requirement for accepting publications • The Lancet has indicated that it will adopt MIAME checklist as a requirement • Nature will adjust its policy in the line with MIAME recommendations

24. A need for a supporting infrastructure • MIAME itself will not solve the problem • A standard format is needed for representing and exchanging this information

25. MGED standards 2 • Data exchange format – MicroArray Gene Expression Mark-up language – MAGE-ML – an XML based file format able to capture all MIAME required information • Based on object model MAGE-OM (Paul Spellman, Michael Miller, Jason Stewart, Ugis Sarkans, …) • Adopted by OMG as a standard for microarrays www.mged.org/mage

26. BioEvent Protocol Treatment HigherLevelAnalysis Transformation Experiment BioMaterial BioAssayData BioAssay Description QuantitationType Array BQS DesignElement ArrayDesign Measurement AuditAndSecurity BioSequence UML Packages of MAGE

27. MAGE – an example diagram

28. Use case of MAGE:ArrayExpress architecture MAGE-OM MAGE-ML (DTD) ArrayExpress (Oracle) data loader Tomcat object/ relational mapping Castor MAGE-ML (doc) MAGE-ML (doc) Java servlets MAGE-ML (doc) Velocity template engine MIAMEexpress Web page template Web page template Browser

29. MGED standards 3 • MGED ontologies – organism part, cell type, diseased state, genotype, chemical compounds (Chris Stoeckert, Helen Parkinson, Susanna Sansone,…) • Symposium “Standards and Ontologies for Functional Genomics” – November 17-20, Cambridge, UK www.mged.org/ontology

30. MGED standards 4 • Data transformation and normalisation (Cathy Ball, John Quackenbush, Gavin Sherlock, …) www.mged.org/normalization

31. Infrastructure for sharing microarray data • Standard for experiment annotation • Standard for data exchange • Public repositories • Local databases and LIMS • Ways of comparing the data

32. ArrayExpress – a MIAME/MAGE supportive public repository for microarray data at EBI ArrayExpress MAGE-ML MAGE-ML MIAMExpress Expression Profiler Internet Submissions Queries, Analysis www

33. Public repositories MAGE-ML Microarray data sharing infrastructure Data submissions Data queries, retrieval, and analysis www Array descriptions (from manufacturers) www Data analysis software LIMS MAGE-ML MAGE-ML LIMS Data analysis software MIAMExpress local instalations MAGE-ML www Other databases www html www html

34. MIAME/MAGE supportive software • Sanger Institute LIMS (MIDAS) • TIGR LIMS • Gene Traffic (Iobion) • Affymetrix • MAXDB (Manchester) • Rosetta Resolver (Rosetta Biosoftware) • Base (Lund) • J-Express (Molmine) • MIAMExpress (EBI) • ArrayExpress (EBI)

35. Acknowledgements • MGED supporters • Rob Andrews (Sanger) • Wilhelm Ansorge (EMBL) • Mike Cherry (Stanford) • Peter Dansky (Affymetrix) • David Hancock (Manchester) • Frank Holstege (Utrecht) • Michael Miller (Rosetta) • Kate Rice (Sanger) • Christian Schwager (EMBL) • Joe White (TIGR) • Rick Young (MIT) • EBI Microarry Team • Niran Abeygunawardena • Helen Parkinson • Philippe Rocca-Sera • Susanna Sansone • Ugis Sarkans • Mohammadreza Shojatalob • Jaak Vilo • MGED board • Cathy Ball (Stanford) • Helen Causton (Imperial Col) • Terry Gaasterland (Rockefel) • Jason Gonzales (Iobion) • Pascal Hingamp (Marseille) • Barbara Jasny (Science) • Helen Parkinson (EBI) • John Quackenbush (TIGR) • Martin Ringwald (Jackson) • Gavin Sherlock (Stanford) • Paul Spellman (Berkely) • Jason Stewart (Open Inf) • Chris Stoeckert (Uni Penns) • Yoshio Tateno (DDBJ) • Ron Taylor (Colorado) • Charles Troup (Agilent)

36. Microarray informatics at the EBI • ArrayExpress (Helen Parkinson) • Expression profiler data analysis tool and promoter analysis (Jaak Vilo) • Reconstructing and analysing gene networks

37. Gene Networks – graphs: nodes are genes, arcs are relationships

38. - The product of gene G1 is a transcription factor, which binds to the promoter of gene G2 – physical interaction network G1 G2 - The disruption of gene G1 changes the expression level of gene G2 – data interpretation network G1 G2 - Gene G2 is mentioned in a paper about gene G1 – literature networks G1 G2 Different ways to build a gene network

39. Data for over 200 gene disruptions in Yeast Hughes et al, Cell, 102 (2000)

40. Discretization of the data: The normalized expression log(ratios) are discretized using different thresholds  = 2, 2.1  , … , 4 : X <    d(X) = 1   X   d(X) = 0 X >   d(X) = 1

41. DA DC DB C A gene A gene B gene C B D gene D Gene disruption network

42. Data for over 200 gene disruptions in Yeast Hughes et al, Cell, 102 (2000)

43. Mutation network for S. Cerevisiae

44. Mutation network Dg=2, filtered for the genes marked in red (mating) Thomas Schlitt, Johan Rung

45. Comparison to literature network derived from YPD Result Overlap between calculated networks and YPD-graph is always larger than overlap between randomised networks and the YPD-graph

46. Network modularity • Is there one “big” dominant connected component and possibly a number of small components, or several components of comparable sizes? • Can the network be broken down in several components of comparable size by removing nodes of high degree (i.e., nodes with many incoming or outgoing edges)?

50. Number of connected components in the networks