Difference between revisions of "Team:Glasgow/Project/Overview/RBS"
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− | For the construction of the RBS library, we used a master sequence based on the RBS B0032 (Figure 1). 4 nucleotides within the actual ribosome binding site were randomised giving 32 different B0032-derived RBS variants. The predicted efficiency of each RBS library member was estimated using RBS Library Calculator (ref: http://msb.embopress.org/content/10/6/731) for every <i>lux</i> gene. | + | For the construction of the RBS library, we used a master sequence based on the RBS B0032 (Figure 1). 4 nucleotides within the actual ribosome binding site were randomised giving 32 different B0032-derived RBS variants. The predicted efficiency of each RBS library member was estimated using RBS Library Calculator (ref: http://msb.embopress.org/content/10/6/731) for every <i>lux</i> gene. Theoretically, with 32 different RBS variants for each of the six <i>lux</i> genes, final RBS library for <i>lux</i> operon would have over a billion different RBS arrangements. |
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Revision as of 17:25, 16 September 2015
RBS library
Summary
Aim
To optimise bioluminescence in Escherichia coli by creating a range of Ribosome Binding Sites (RBS) for each of the six genes in the luxCDABEG operon from Aliivibrio fisheri, originally submitted to the registry as a single BioBrick (K325909) in 2010 by the Cambridge team.
Results
- Designed RBS library with 32 variants for each lux gene - Made luxABG and luxCDE constructs from the RBS library – over 1000 RBS variantions for each construct - Showed that cells are able to uptake decanal from the environment and produce light when luxAB or luxABG is expressed - Visualised RBS library for luxAB, luxABG and luxCDE constructs and determined optimal RBS arrangements for E. coli
Biobricks
Documented and submitted:
- BBa_K1725340: I0500-RBS-luxA-RBS-luxB-RBS-luxG
- BBa_K1725341: I0500-RBS-luxA-RBS-luxB-RBS-luxG-K1725080-RBS-luxC-RBS-luxD-RBS-luxE
- BBa_K1725301-BBa_K1725332: RBS library
- BBa_K1725342: K1725080-RBS-luxC-RBS-luxD-RBS-luxE (High decanal production)
- BBa_K1725343: K1725080-RBS-luxC-RBS-luxD-RBS-luxE (Low decanal production)
Motivation
For the Bioluminescence part of our project we used the luxCDABEG operon from A. fischeri introduced to the iGEM by Cambridge team in 2010. Five lux genes are known to be essential for the bioluminescence production: luxA and luxB encoding bacterial luciferase and luxC, luxD and luxE encoding enzyme complex that synthesises tetradecanal, a substrate for the luciferase. Sixth gene, luxG encodes a flavin reductase that provides reduced flavin mononucleotide for the bioluminescence reaction resulting in an enhanced light ouptput. Initially we decided to optimise bioluminescence in E. coli by rearranging whole Lux operon and placing a defined relatively-weak (REF) ribosome binding site – B0032 – upstream of each of the six lux genes, as described on our Bioluminescence page. Taking this approach further, we thought of adjusting bioluminescence in E. coli by creating a B0032-derived Ribosome Binding Site library for each lux gene. The idea behind this was to create a range of RBS combinations in a lux operon and therefore, generate E. coli strains of different bioluminescence intensity. We assumed that the most favourable RBS arrangements in lux operon should be observed in the E. coli colonies emitting the most light.
Design
For the construction of the RBS library, we used a master sequence based on the RBS B0032 (Figure 1). 4 nucleotides within the actual ribosome binding site were randomised giving 32 different B0032-derived RBS variants. The predicted efficiency of each RBS library member was estimated using RBS Library Calculator (ref: http://msb.embopress.org/content/10/6/731) for every lux gene. Theoretically, with 32 different RBS variants for each of the six lux genes, final RBS library for lux operon would have over a billion different RBS arrangements.Strategy and approaches
Randomised PCR and Cloning, Cloning, Cloning
Testing pBAD.luxAB
Inviting Mr. Bright to the party: luxG
Story about luxCDE
Results
- Cell-cell comunication - Decanal experiments - Spectrum experiments and comparison to Cambridge operonReferences