Difference between revisions of "Team:Glasgow/Project/Overview/Repressors"
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<figcaption>Figure 4 Characterising Promoters. All constructs with pSB3K3 plasmid backbone, in DH5α cells. Replicates of constructs and controls from three colonies, under the same conditions. Mean and standard deviation of replicates were calculated to give value and error bars. Values were normalised against a cells only control (not shown) so cells only = 0, therefore any negative values where the error bars overlapping 0, are essentially 0 (as a negative number of molecules is not possible).</figcaption> | <figcaption>Figure 4 Characterising Promoters. All constructs with pSB3K3 plasmid backbone, in DH5α cells. Replicates of constructs and controls from three colonies, under the same conditions. Mean and standard deviation of replicates were calculated to give value and error bars. Values were normalised against a cells only control (not shown) so cells only = 0, therefore any negative values where the error bars overlapping 0, are essentially 0 (as a negative number of molecules is not possible).</figcaption> |
Revision as of 16:31, 17 October 2015
Home > Project > Repressors
Summary
Aim: To characterise PhlF and SrpR repressors and their respective repressible promoters for submission to the iGEM registry. Results Overview: • K1725000 (PhlF repressible promoter) and K1725020 (SrpR repressible promoter) successfully drive expression of GFP in E. coli. • K1725042 (phlF expression driven by a lac regulated promoter) represses K1725001 (GFP expression driven by PhlF repressible promoter) GFP expression 83-fold. • K1725042 (phlF expression driven by a lac regulated promoter) is orthongonal. Basic Parts submitted: • BBa_K1725000 – PhlF repressible promoter • BBa_K1725020 – SrpR repressible promoter • BBa_K1725040 – phlF encoding PhlF repressor • BBa_K1725060 – srpR encoding SrpR repressor • BBa_K1725080 – Promoter (lacI regulated, lambda pL hybrid) with extra NheI site
Introduction
Our genetic circuit needed an inverter, as our UVA sensor turns on transcription, but our circuit needed to turn off transcription when UVA was present. There are suitable several repressor protein/repressible promoter pairs in the iGEM registry such as TetR or LacI, however, they usually come from experimental studies based on existing systems. Recently, Stanton et al. (2014) have identified sixteen prokaryotic TetR-like repressors by genomic mining and designed synthetic repressible promoters (Figure 1A), as with more independently functioning parts, it will be possible to build increasingly complex genetic circuits . By characterising and submitting two new repressors to the registry, based on Stanton et al. (2014) designs, we aimed to demonstrate that this approach could yield efficient parts, thus widening the access to this synthetic technique, which has the potential to create a much larger range of functions for genetic circuits. To understand how they were able to design synthetic repressible promoters, it is important to understand how promoters and repressors work.Transcription is the process where RNA polymerase binds to DNA to make mRNA; a promoter tells RNA polymerase where to bind to the DNA, so a promoter is found upstream of a gene. Promoters have -10 and -35 sites that the sigma transcription facter binds to and attracts RNA polymerase, as shown in Figure 1B, transcription starts at +1. If one or both of these sites are bound by another protein, sigma factor cannot recognise the promoter, and transcription does not take place. Transcriptional repressors are proteins that bind to DNA at a specific sequence called the operator sequence. Stanton et al. (2014) overlapped the operator sequence for each repressor over the -10 and/or -35 sites of BBa_J23119, a strong, constitutive Anderson family promoter, meaning when the repressor binds to its operator sequence sigma factor cannot recognise the promoter and transcription cannot start, as shown in Figure 1B.
Methods
E. coli strains used: TOP10, DH5α, and DS941. Plasmids in Table 1 constructed by BioBrick Standard Assembly, and checked by restriction digest before confirming by sequencing.
Results
GFP fluorescence driven by PphlF, PsrpR, and PtetR each with a weak and strong ribosome binding site (RBS) (B0032 and B0034, respectively) with plasmid backbone pSB3K3 was measured to compare the relative strengths of promoters K1725000 (PphlF) and K1725020 (PsrpR) to a promoter already well documented in the registry, R0040 (PtetR). Figure 4 shows the fluorescence scan image and a graph of approximate molecules of GFP per cell. These results indicated that PphlF is a significantly stronger promoter than PtetR or PsrpR. It also confirms that B0034 is a stronger ribosome binding site that B0032. Due to this, promoters driving expression of GFP with B0034 ribosome binding site were used for characterisation of the repressors.
Conclusion
New Basic Parts, BBa_K1725000 (PhlF repressible promoter), BBa_K1725020 (SrpR repressible promoter), and BBa_K1725040 (phlF encoding PhlF repressor) were successfully characterised, and submitted to the iGEM registry. BBa_K1725060 – (srpR encoding SrpR repressor) was characterised on our Bistable Switch page. K1725000 drives expression of GFP in the BioBricks K1725001 and K1725002, and is significantly stronger than our control promoter, R0040. K1725020 drives expression of GFP in the BioBricks K1725021 and K1725022, and is of equivalent strength to our control promoter, R0040, when both were coupled with the strong Ribosome Binding Site, B0034. K1725040 successfully represses K1725000 driven GFP expression 83-fold, and does not repress promoters K1725020 or R0040. The next steps in characterisation of our repressor BioBricks would be to construct the BioBrick K1725062 (by insertion of the lacI regulated promoter, K1725080, upstream of K1725061, in order to express the repressor protein) then to repeat our fluorescence experiments to characterise K1725060 further. Additionally, GFP purifed from E. coli would be used in place of iLOV fluorescent protein to calibrate the Typhoon FLA 9000, so the molecules of GFP per cell calculations would give a value closer to an absolute value for fluorescence.
References
Abbas, A., Morrissey, J.P., Marquez, P.C., Sheehan, M.M., Delany, I.R., and O’Gara, F. (2002). Characterization of Interactions between the Transcriptional Repressor PhlF and Its Binding Site at the phlA Promoter in Pseudomonas fluorescens F113. J. Bacteriol. 184, 3008–3016. Alberts et al (2008). Molecular Biology of the Cell (Garland Science, Taylor and Francis Group). Chapter 7, p337-434 Buckley, A. Petersen, J. Roe, A. Douce, G. Christie, J. (2015). LOV-based reporters for fluorescence imaging. Current Opinion in Chemical Biology. 27 (1), p39–45. Sheehan, M.M., Delany, I., Fenton, A., Bardin, S., O’Gara, F., and Aarons, S. (2000). Regulation of production of the antifungal metabolite 2,4-diacetylphloroglucinol in Pseudomonas fluorescens F113: genetic analysis of phlF as a transcriptional repressor. Microbiology 146, 537–546. Stanton, B.C., Nielsen, A.A.K., Tamsir, A., Clancy, K., Peterson, T., and Voigt, C.A. (2014). Genomic mining of prokaryotic repressors for orthogonal logic gates. Nat. Chem. Biol. 10, 99–105. Sun, X., Zahir, Z., Lynch, K.H., and Dennis, J.J. (2011). An Antirepressor, SrpR, Is Involved in Transcriptional Regulation of the SrpABC Solvent Tolerance Efflux Pump of Pseudomonas putida S12. J. Bacteriol. 193, 2717–2725. Wery, J., Hidayat, B., Kieboom, J., and Bont, J.A.M. de (2001). An Insertion Sequence Prepares Pseudomonas putida S12 for Severe Solvent Stress. J. Biol. Chem. 276, 5700–5706.
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