CellML & Synthetic Biology

1. CellML & Synthetic Biology James Lawson Friday 16th May 2008

2. Overview • Rundown on what the CellML team do here • What is “synthetic biology?” • What does CellML have to do with it?

3. ABI Team We have grown! (arrows show people who joined last year)

4. 2001 - present “CellML is intended to support the definition of models of cellular and subcellular processes. CellML facilitates the re-use of models and parts of models by using a component-based architecture. Models are split into logical sub-parts called components that are connected together to form a model.” – CellML 1.0 specification

5. What is CellML? • Language for description of mathematical models • Developed at ABI (mainly) • Open XML standard • Describes structure, mathematics, metadata • MathML for mathematics • RDF for metadata

6. Why is there a need for CellML? • Designed for storage & exchange of models • Reference implementation of a model • Publication of model code • Model reuse ERRORS A model is created and translated into parameter sets and equations then read and interpreted and finally reimplemented

7. Why is there a need for CellML? • If the model author published their model in CellML, this process could be avoided ERRORS A model is created and translated into parameter sets and equations then read and interpreted and finally reimplemented

8. Scope of CellML • CellML 1.1 current version, 1.2 in pipeline • Flexible: not limited to biological systems • Philosophy: • Only describes structure and maths. All else is metadata. • Multiscalar: from biochemistry to physiology

9. Signal transduction Electrophysiology Biomechanics CellML can describe multiscalar systems

10. IUPS Physiome Project Nickerson et al. Computational multiscale modeling in the physiome project: modeling cardiac electromechanics., IBM J. Res. & Dev., 50(6), 617-630, 2006

11. PCEnv • Physiome CellML Environment • Developed at ABI • Open source / free environment for editing and simulating CellML models • Uses CellML API • Built using Mozilla/XUL framework • Platform agnostic

13. CellML Model Repository • www.cellml.org/models started life as set of test-cases for CellML • Now a repository of >330 unique CellML models based on peer reviewed publications • Approximately half curated • Models can be uploaded concurrent with publication • Locus for sharing and reuse of models

16. Model Curation • Important element of the work done in the CellML community • Purpose is to provide validated, tested reference implementations of models • Errors produced in code > publication > reproduction process must be eliminated • Metadata and documentation • Ontological annotation • Authorship, citation and revision histories

17. CellML in CMISS • Use CellML models to inform cell behaviour in heart (and other) models • John Davidson, Jesse Ashton, Jichao Zhao • Know more than me • Are very friendly • Are not the only people doing this

18. CellML Community • Active international community of developers and users • Cellml.org serves as focal point • CellML specifications • CellML Model Repository • User profiles • Hosts proposals, wikis, tutorials, FAQs etc. • Meeting minutes, news, conference proceedings • Software downloads • Tracker

19. Projects in the Pipeline • CellML 1.2 • Metadata • Working with CellML in PCEnv • The new CellML Model Repository “PMR2” • Using CellML: plans for community and curation

20. CellML 1.2 • Latest stable version of CellML is 1.1 • Last changed in 2002, frozen in 2006 • Community canvassing process • ‘Purification’ of CellML according to philosophy

21. CellML 1.2 • CellML too large to be implemented in entirety • => concept of secondary specifications which represent a subset of CellML • Individual tools can implement these in entirety • E.g. ‘stochastic CellML’

22. CellML 1.2 • Reaction element removal • Ontologies and constrained vocabularies: increasing CellML’s specificity in a modular fashion – CellMLBio Ontology • New typing system • Implementation of a complex typing system • Multiple subsets: each subset introduces one core functionality • E.g. vectors, matrices, operations over these • Lambda calculus being considered

23. CellML Metadata • Metadata specification to be frozen • Development of CellMLBio Ontology • Annotation of variables and components with biologically relevant information • Automatic generation of diagrams of CellML models • Use of graphing & simulation metadata to reproduce figures from publications

25. PCEnv • PCEnv development strongly coupled to development of CellML API • Ability to link to and display references to web accessible databases • Further support for metadata editing and processing • Rendering of and user interaction with model diagrams • Non-linear solver

26. CellML Model Repository – “PMR2” • Current version of CellML Model Repository does not adequately handle multi-file CellML 1.1 models • “PMR2” currently in development • Current prototype software uses distributed version control system, will allow full revision histories, treatment of CellML as code. • Will allow models in the repository to reference each other using import element

27. PMR2 • Facilitates decomposition of models into modular components. • Models are then composed of networks of these components and descriptions of the relationships between these. • Curated, ontologically annotated components able to be searched, sorted, combined

28. Future cellml.org community • Web-based communities are becoming commonplace • International scientific collaboration demands effective communication media • Project-centric workspaces • Meeting minutes, project descriptions, seminars / posters, software downloads

29. Synthetic Biology

31. Synthetic Biology • Wikipedia: “A new area of research that combines science and engineering in order to design and build ("synthesize") novel biological functions and systems” • SB1.0 held in 2004, SB4.0 in Hong Kong, October this year • Synthetic biology tipped to be key technology of early 21st century

32. True Genetic Engineering • An engineering approach to genetic engineering! • Abstraction • Standardisation • Modularity • CAD • Refinement of natural products • Resources need to be refined before their behaviour can be reliably described in calculations • MIT has lead the charge with their “Registry of Standard Biological Parts”

35. You might also have heard the term “Biobrick” What is a ‘Biological Part’? Definition is shaky, but: “A nucleic acid sequence that encodes a definable biological function” – Shetty et al. 2008 Specification information for a Biological Part – looks like it was written by an engineer….

36. “International Genetically Engineered Machine” competition • Undergraduate competition started in 2004 • Central to current synthetic biology community • 2008: 53 teams registered, 31 pending registration

37. What has this got to do with us? • I have been following synthetic biology since about mid 2005 • Mike Cooling is also very interested • We have been sneakily bouncing ideas off each other in our spare time

38. CellML & Synthetic Biology • Synthetic biology currently DNA-centric, with much time spent cloning genes in the lab • We propose that more can be done in silico • We are interested in creating a ‘Registry of Standard Biological Models’ • We are collaborating with researchers from MIT, Imperial College and Newcastle to create a repository of modular, reusable curated models – c.f. the CellML Model Repository and write a paper about it…

39. So Mike and I recently visited the UK

40. And we had a great time • We visited Neil Wipat’s group at the School of Computing Science at Newcastle University • We also attended the BioSysBio 2008 conference at Imperial College, London • Focuses on systems and synthetic biology You may recognise Neil – he spent his sabbatical at the ABI over the summer. During this time Mike and I got to know him and started doing some work together.

41. Newcastle University • Mike and I gave a tag team talk • Mike on modularity in CellML • My talk was a general ‘CellML now and in the future’ overview • Newcastle is fielding a 2008 iGEM team • Their team has a heavy focus on modeling of Standard Biological Parts • CellML is one of the chief technologies involved in their project • Mike and I are official advisors to their team

42. Newcastle University • Bio-ontologies • Philip Lord is a bio-ontologies expert • Was very interested in the CellML-Bio Ontology • Much important feedback received regarding CellML & associated services • E.g. Java bridges to API, programmatic access to CellML repository, stochastic modeling in CellML

45. BioSysBio2008 • Academic content of keynotes was average • Workshops and ‘quality’ of attendees 10/10 • Interesting to see what people knew / thought of CellML • Physiome Project, CellML, Peter Hunter got big mention in introductory talk of conference • Many people knew little about CellML and simply saw it as SBML’s ‘poor cousin’

46. Standards in Synthetic Biology • Dedicated workshop at BioSysBio • Mike and Neil presented on why ‘Standard Parts’ need to be modeled and why CellML is the best technology for this • Explicit modularity very important • SBML is incumbent but lacking • Synthetic Biology ontology being developed

47. Open Science • Open access journals – “BMC” • “Open notebook science” • Universal Scientific Brownie Points • Problem of rewarding non-publication contributions such as blog posts, reviews etc. • Movement may have ramifications for ABI • Watch this space…

48. Synthetic Biology & CellML • Mike and I are working on a paper with Neil Wipat, Barry Canton from MIT and Vincent Rouilly from Imperial College • Aim to model ‘Standard Biological Parts’ in a manner that allows these models to be combined and simulated • Aim to provide a curated repository of these models

49. Synthetic Biology & ABI • Synthetic biology is primarily an engineering discipline. Currently wet-lab oriented but starting to involve more in silico work • Will have vast industrial relevance within 10 years • ABI needs to consider whether it wants to get involved • iGEM team could be perfect 4th year project • Upcoming ABI wet lab capabilities could be used • Collaboration with wet-lab specialists required

50. Acknowledgements • Peter Hunter & Poul Nielsen for allowing me to indulge my imagination • The CellML team • Mike Cooling