Difference between revisions of "Computational Synthetic Biology"
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|abstract= The large-scale engineering of novel bacterial systems is a complex, challenging task. Although small circuits can be designed manually, using the domain knowledge of the designer, this approach is not feasible for designs involving multiple pathways or even complete genomes. In this chapter, we address the value of computational intelligence approaches to the design of synthetic genetic circuits. Computational intelligence algorithms were designed to operate in complex, poorly understood domains in which the quality of a solution is more important than the route taken to achieve it and, as such, are potentially valuable to synthetic biology. To date, evolutionary computation has been used extensively in this field, but other computational intelligence algorithms, of potentially equal value, have been neglected. We review the basic principles of these algorithms and the way in which they have been, and may in the future be, of value in synthetic biology. | |abstract= The large-scale engineering of novel bacterial systems is a complex, challenging task. Although small circuits can be designed manually, using the domain knowledge of the designer, this approach is not feasible for designs involving multiple pathways or even complete genomes. In this chapter, we address the value of computational intelligence approaches to the design of synthetic genetic circuits. Computational intelligence algorithms were designed to operate in complex, poorly understood domains in which the quality of a solution is more important than the route taken to achieve it and, as such, are potentially valuable to synthetic biology. To date, evolutionary computation has been used extensively in this field, but other computational intelligence algorithms, of potentially equal value, have been neglected. We review the basic principles of these algorithms and the way in which they have been, and may in the future be, of value in synthetic biology. | ||
}} | }} | ||
| + | {{PDF | ||
| + | |authors= Myers, CJ. | ||
| + | |year= 2013 | ||
| + | |title= Platforms for Genetic Design Automation | ||
| + | |journal= Methods in Microbiology | ||
| + | |volume= 40 | ||
| + | |pages= 177-202 | ||
| + | |URL= http://www.sciencedirect.com/science/article/pii/B9780124170292000078 | ||
| + | |doi= 10.1016/B978-0-12-417029-2.00007-8 | ||
| + | |file= Myers(2013)GeneticDesignAutomation.pdf | ||
| + | |abstract= Crucial to the success of synthetic biology is the development of platforms for genetic design automation (GDA). This chapter presents the current state-of-the-art in GDA tools. This chapter also briefly describes the standards used for data representation that enable these GDA tools to work together to complete a genetic design task and the emerging repositories that are available to archive and share these data. Finally, this chapter compares tool capabilities and discusses future requirements for a complete GDA workflow.}} | ||
{{#pmid:21885772}} | {{#pmid:21885772}} | ||
{{#pmid:20192780}} | {{#pmid:20192780}} | ||
Revision as of 22:30, 14 January 2014
Computational Synthetic Biology
This page is a placeholder, or under current development; it is here principally to establish the logical framework of the site. The material on this page is correct, but incomplete.
Apparently, at the time of his death, the phrase "What I cannot create, I do not understand." was written on Richard Feynman's blackboard. If there is truth to that, computational synthetic biology is the ultimate test of computational biology as a whole. Beyond systems models in general, computational synthetic biology focusses on ways to integrate systems models and to support experimental design and engineering.
Introductory reading
| Bashor et al. (2010) Rewiring cells: synthetic biology as a tool to interrogate the organizational principles of living systems. Annu Rev Biophys 39:515-37. (pmid: 20192780) |
| MacDonald et al. (2011) Computational design approaches and tools for synthetic biology. Integr Biol (Camb) 3:97-108. (pmid: 21258712) |
Contents
Further reading and resources
- Standards
| Müller & Arndt (2012) Standardization in synthetic biology. Methods Mol Biol 813:23-43. (pmid: 22083734) |
| Smolke (2009) Building outside of the box: iGEM and the BioBricks Foundation. Nat Biotechnol 27:1099-102. (pmid: 20010584) |
| Cai et al. (2010) GenoCAD for iGEM: a grammatical approach to the design of standard-compliant constructs. Nucleic Acids Res 38:2637-44. (pmid: 20167639) |
| Cooling et al. (2010) Standard virtual biological parts: a repository of modular modeling components for synthetic biology. Bioinformatics 26:925-31. (pmid: 20160009) |
- Examples
| Rekhi & Qutub (2013) Systems approaches for synthetic biology: a pathway toward mammalian design. Front Physiol 4:285. (pmid: 24130532) |
| Hallinan, JS. (2013) Computational Intelligence in the Design of Synthetic Microbial Genetic Systems. Methods in Microbiology 40:1-37. |
| (pmid: None) [ Source URL ][ DOI ] Abstract |
| Myers, CJ. (2013) Platforms for Genetic Design Automation. Methods in Microbiology 40:177-202. |
| (pmid: None) [ Source URL ][ DOI ] Abstract |
| Nandagopal & Elowitz (2011) Synthetic biology: integrated gene circuits. Science 333:1244-8. (pmid: 21885772) |
| Bashor et al. (2010) Rewiring cells: synthetic biology as a tool to interrogate the organizational principles of living systems. Annu Rev Biophys 39:515-37. (pmid: 20192780) |
| Rothschild (2010) A powerful toolkit for synthetic biology: Over 3.8 billion years of evolution. Bioessays 32:304-13. (pmid: 20349441) |
| Grünberg & Serrano (2010) Strategies for protein synthetic biology. Nucleic Acids Res 38:2663-75. (pmid: 20385577) |
| Zheng & Sriram (2010) Mathematical modeling: bridging the gap between concept and realization in synthetic biology. J Biomed Biotechnol 2010:541609. (pmid: 20589069) |
| Liang et al. (2011) Synthetic biology: putting synthesis into biology. Wiley Interdiscip Rev Syst Biol Med 3:7-20. (pmid: 21064036) |
| Marchisio (2012) In silico implementation of synthetic gene networks. Methods Mol Biol 813:3-21. (pmid: 22083733) |
| Fange & Elf (2006) Noise-induced Min phenotypes in E. coli. PLoS Comput Biol 2:e80. (pmid: 16846247) |
| Stricker et al. (2008) A fast, robust and tunable synthetic gene oscillator. Nature 456:516-9. (pmid: 18971928) |
