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| {{Ellis Top}}
| | our lab website has now moved to http://tomellislab.com/ |
| '''Latest Update: April 2010'''
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| Research in the Ellis Lab focuses on advancing biotechnology through the use of synthetic biology. Projects in the Ellis Lab fall into one of two categories or belong in both:
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| * '''1. Foundational Synthetic Biology'''
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| Developing the tools for rapid, predictable engineering of biological devices and systems
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| ''Examples: biopart design, assembly techniques and device synthesis, part and device characterisation, standardisation, chassis systems, mathematical models, design simulations''
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| * '''2. Applied Synthetic Biology'''
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| Using the synthetic biology approach in biotechnology applications
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| ''Examples: combinatorial synthesis of regulated metabolic pathways, modular design of biosensors''
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| == Current Projects ==
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| '''Investigating device-chassis interactions'''
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| Project Type: ''Foundational''
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| Project Members: ''Rhys Algar''
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| Collaborators: ''Guy-Bart Stan''
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| Most gene devices demonstrated in synthetic biology have been high-expression strength regulatory networks hosted on mid-to-high copy number plasmids in ''E.coli''.
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| '''Combinatorial assembly of a regulated Lycopene production pathway in yeast '''
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| Project Type: ''Foundational'' ''Applied''
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| Project Members: ''Tom Ellis''
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| Most gene devices demonstrated in synthetic biology have been high-expression strength regulatory networks hosted on mid-to-high copy number plasmids in ''E.coli''.
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