Team:Cambridge/Experiments/Periplasmic Export
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- | [[File:Cam Periplasm Export Attempt 1.jpg |thumb| 400px| | + | [[File:Cam Periplasm Export Attempt 1.jpg |thumb| 400px| left | Bacteria expressing a TorA-ReflectinA1-GFP construct appear to produce some fluorescent inclusion bodies, not a green halo in the periplasm as hoped.]] |
We hoped to see a halo effect of GFP in the periplasm, demonstrating correct export of our TorA-Reflectin-GFP fusion. Unfortunately, our preliminary observations do not support this hope. If time allows we will refine our protocol to see if reflectins can be exported by this pathway. | We hoped to see a halo effect of GFP in the periplasm, demonstrating correct export of our TorA-Reflectin-GFP fusion. Unfortunately, our preliminary observations do not support this hope. If time allows we will refine our protocol to see if reflectins can be exported by this pathway. | ||
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==Conclusion== | ==Conclusion== |
Revision as of 09:06, 21 September 2011
Contents |
Periplasmic export
As reflectins appear to spontaneously associate with membranes, we hoped to promote correct assembly by directing our recombinant reflectins to the [http://en.wikipedia.org/wiki/Periplasmic_space periplasmic space of E. coli].
Design of constructs
Choice of signal sequences
The signal sequence from TorA [http://www.ncbi.nlm.nih.gov/pubmed/11123687 has been used to export GFP to the periplasm] via the TAT pathway. We focused our export plan on this sequence as the TAT pathway exports proteins in their fully folded state, allowing GFP to remain fluorescent (it cannot form a fluorophore in a reducing environment). This allows us to use our reflectin-GFP fusions to provide an easy reporter of export using a confocal microscope.
The amino acid sequence given by Thomas et al was 4 residues shorter than [http://partsregistry.org/Part:BBa_K233307 part BBa_K233307], allowing us to directly synthesise it more cheaply from two primers. Our revised sequence has been submitted as an improved part.
We also designed reflectin fusions with two other signal sequences, from the PelB and PhoD proteins. We are very grateful to Nick Thompson (Physics of Medicine) and Dr David Summers (Dept of Genetics) for their help and advice with choosing signal sequences, and regret that we did not have time to follow through on their suggestions.
Assembly of constructs for expression of fusion proteins
We assembled constructs for export of TorA-Reflectin and TorA-Reflectin-GFP (to give an easy control for reflectin export)
Sequences of the primers used in the experiment and their predicted melting temperatures are the following:
Name | Sequence | Tm |
---|---|---|
TorA Fwd | ATGGCGAACAACGACTTATTTCAGGCTTCTCGGCGTCGCTTTCTGGCGCAGCTGGGCGGATTAACGGTGGCGGGT | 70.98°C |
TorA Rev | TGCGGCTTGTGCTGCCGTCGCTCTGCGAGGAGTCAACAGCGACGGGCCCAACATACCCGCCACCGTTAATCCGCC | 70.98°C |
RefA1-His-3k3-rev | GCTCTAGTATTAGTGGTGATGGTGATGATGGTACATGTGGTAATCGTAATAATTACGATCG | 66.41°C |
TorA-RefA1-Fwd | GCTGTTGACTCCTCGCAGAGCGACGGCAGCACAAGCCGCAatgggatccatgaaccgttacc | 67.89°C |
3k3-TorA-Rev | GAAAGCGACGCCGAGAAGCCTGAAATAAGTCGTTGTTCGCCATctagctactagagaaagaggagaaatactag | 60.483°C |
GFP imaging
We hoped to see a halo effect of GFP in the periplasm, demonstrating correct export of our TorA-Reflectin-GFP fusion. Unfortunately, our preliminary observations do not support this hope. If time allows we will refine our protocol to see if reflectins can be exported by this pathway.
Conclusion
Time did not allow us to achieve functional export of reflectin, so we cannot know whether reflectin self assembly will give structural colour in the periplasm.
[http://www.ncbi.nlm.nih.gov/pubmed/12711311 Barrett et al] suggests that our level of induction was too high to see any significant export. We aim to try altered growth conditions in the hope of improving export efficiency, but as of the time of writing we have not had a chance to attempt this.