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MetaCyc and AraCyc: Plant Metabolic Databases

MetaCyc and AraCyc: Plant Metabolic Databases. Hartmut Foerster Carnegie Institution. Overview. MetaCyc: Explore the Database AraCyc: The Metabolic Network of Arabidopsis. MetaCyc. http://www.metacyc.org. What is MetaCyc ?.

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MetaCyc and AraCyc: Plant Metabolic Databases

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  1. MetaCyc and AraCyc: Plant Metabolic Databases Hartmut Foerster Carnegie Institution

  2. Overview • MetaCyc: Explore the Database • AraCyc: The Metabolic Network of Arabidopsis

  3. MetaCyc http://www.metacyc.org

  4. What is MetaCyc ? • MetaCyc is a multi-organism database that collects any known pathways across all kingdoms • MetaCyc is a curated, literature-based biochemical pathways database • Collaboration between SRI International and Carnegie Institution

  5. Goal and Applications Goal • Universal repository of metabolic pathways • Up-to-date, literature-curated catalogue of commented enzymes and pathways for use in research, metabolic engineering and education Applications • Database of reference used to generate predicted Pathway/Genome DataBases (PGDBs)

  6. The Content of MetaCyc • Pathways from primary and secondary (specialized) metabolism • Reactions with compound structures • Proteins • Genes • Mostly from microorganism and plant kingdoms, and several animal pathways • Does not contain sequence information

  7. Curation Team • PhD-level curators • Extract data from literature • oNLY experimentally verified data • ideally protein information • Follow MetaCyc Curator’s guide • http://bioinformatics.ai.sri.com/ptools/curatorsguide.pdf

  8. MetaCyc Version 10.5to bereleased in August, 2006 Note: The statistics for each year pertain to the last MetaCyc version released in that year. Note: The statistics for each year pertain to the last MetaCyc version released in that year

  9. MetaCyc – Browse the Database Explore class hierarchy of pathways, compounds, reactions, genes and cell components

  10. MetaCyc – Browse the Database (cont’d) Explore class hierarchy of pathways, compounds, reactions, genes and cell components

  11. MetaCyc – Explore the Metabolic Universe Query the database (pathways, reactions, compounds, genes)

  12. MetaCyc – Query Page Type your search term and click submit Luteolin

  13. MetaCyc – Query Result Page

  14. MetaCyc – Pathway Detail Page Part I The pathway diagram shows compounds,reactions and metabolic links

  15. MetaCyc – Pathway Detail Page Part II Pathway commentary comprises general and specific information about the pathway

  16. MetaCyc – More Detail Extend or collapse the detail level of the pathway detail page

  17. MetaCyc – More Detail (cont’d) In depth information about reaction, EC number, enzymes, genes, regulatory aspects, and metabolic links to related pathways

  18. MetaCyc – More Detail (cont’d) More detail reveals structural information about compounds

  19. MetaCyc – Reaction Detail Page

  20. MetaCyc – Enzymes and Genes Contains enzyme commentary, references, and physico-chemical properties of the enzyme

  21. MetaCyc – Enzymes and Genes (cont’d)

  22. MetaCyc – Evidence Codes Intuitive icons Pathway Level Enzyme Level Evidence codes provide assessment of data quality, i.e. the affirmation for the catalytic activity of an enzyme Evidence codes provide assessment of data quality, i.e. the affirmation for the existence of an pathway

  23. MetaCyc – Evidence Codes (cont’d)

  24. Variants, Related Pathways and Links • Pathway variants are created as separate pathways • IAA biosynthesis I (tryptophane-dependent) IAA biosynthesis II (tryptophane-independent) • Links are added between interconnected pathways • Related pathways are grouped into superpathways • e.g.superpathway of choline biosynthesis

  25. Creation of a Superpathway choline biosynthesis III Superpathway choline biosynthesis choline biosynthesis I choline biosynthesis II phosphoryl-choline ethanolamine L-serine CDP-choline-choline ethanolamine N-monomethylethanolamine a phosphatidylcholine N-dimethylethanolamine phosphoryl-ethanolamine Choline biosynthesis II choline N-methylethanolamine phosphate choline N-dimethylethanolamine phosphate phosphoryl-choline choline biosynthesis III choline

  26. Applications: Pathways Prediction Goal • Universal repository of metabolic pathways • Up-to-date, literature-curated catalogue of commented enzymes and pathways for use in research, metabolic engineering and education Applications • Database of reference used to generate predicted Pathway/Genome DataBases (PGDBs)

  27. Pathway Tools Software Suite • Software for generating, curating, querying, displaying PGDBs • Developed by Peter Karp and team • PathoLogic – Infers pathways from genome or transcripts sequencing • Pathway/Genome Editors – Curation interface • Pathway/Genome Navigator – Query, visualization, analysis and Web publishing • OMICS Viewer

  28. The PGDB Family Pathway/Genome Database (AraCyc) Pathways Annotated Genome Arabidopsis thaliana Reactions PathoLogic Software compounds Gene products Reference Pathway Database (MetaCyc) genes

  29. AraCyc: The Arabidopsis thaliana specific metabolic database http://www.arabidopsis.org/tools/aracyc

  30. The Computational Build of AraCyc • In 2004, the Arabidopsis genome contained 7900 genes annotated to the GO term ‘catalytic activity’ • 4900 enzymes in small molecule metabolism (19% of the total genome) • PathoLogic inferred 219 pathways and mapped 940 (19% enzyme-coding) genes to the pathways

  31. Cleaning of a Newborn Database • PathoLogic errs on the side of over-prediction • First round of curation to remove false-positives • Add missing pathways • Improve the quality of information • Introduce new pathways • Increase number of pathway and protein comments • Refine computational assignment of protein

  32. Pathway Validation Criteria • A pathway that is described in the Arabidopsis literature • A pathway whose critical metabolites are described in the Arabidopsis literature • A pathway that contains unique reactions and having genes assigned to those unique reactions

  33. Validation Procedure • Delete non-plant pathways: • Pathway variants of bacteria-origin • Pathways not operating in plants at all (e.g. glycogen biosynthesis) • Add new plant-specific pathways: • Pathway variants of plant-origin • Plant-specific metabolites (e.g. plant hormones) • Plant-specific metabolism (e.g. xanthophyll cycle)

  34. AraCyc - Curation Progress Additional 66 new pathways were added to MetaCyc

  35. How to Link to AraCyc From the TAIR home page click on the link to AraCyc pathways

  36. AraCyc – The Home Page Paint data from high-throughput experiments on the metabolic map Browse pathways, enzymes, genes, compounds Display of the Arabidopsis metabolic network User submission form

  37. AraCyc – All the Help you can get

  38. AraCyc’s Content

  39. Computationally Predicted Enzymes

  40. Experimentally Verified Enzymes

  41. AraCyc: Pathway Detail Page (cont’d)

  42. AraCyc: OmicsViewer

  43. OMICS Viewer • Part of the Pathway Tools Software Suite • Displays bird-eye view of the Metabolic Overview diagram • Allows to paint data values from the user's high-throughput onto the Metabolic Overview diagram • Microarray Expression Data • Proteomics Data • Metabolomics Data

  44. OmicsViewer Submission Page Load sample file and provide information about your data Step 1 Step 2 Sample data file (text tab-delimited) 0 1 2 3 4

  45. Step 4 Step 5 Step 6 OmicsViewer Submission Page (cont’d) Choose relative or absolute values Choose to display a single or multiple step experiment Check the box if you have log values or negative fold change numbers Select the type of data you want to display (refers to your loading file) Step 3

  46. OmicsViewerSubmission Page (cont’d) For single or multiple time points add the corresponding column number(s) Step 7

  47. OmicsViewerSubmission Page (cont’d) Choose your cutoff to visualize your expression values Step 8 Step 9

  48. The Omics Viewer Result Page compounds (icons) are color-coded according to the concentration of compounds reactions (lines) are color-coded according to the gene expression level

  49. The Omics Viewer Result Page (cont’d) The statistics for the expression map (single time points only) is provided at the bottom of the page

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