Difference between revisions of "Team:Glasgow/Project/Overview/UVA"
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<h5>Introduction</h5> | <h5>Introduction</h5> | ||
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| − | As our genetic circuit contain a UV-A sensor, we decided to test how Uv-A exposure affected different strain of <i>E. coli</i> in order to decide on a chassis. It is well known that UVB can be lethal to <i>E. coli</i>, but some strains might be able to withstand the dose of UV-A required to activate out UVA sensor ( | + | As our genetic circuit contain a UV-A sensor, we decided to test how Uv-A exposure affected different strain of <i>E. coli</i> in order to decide on a chassis. It is well known that UVB can be lethal to <i>E. coli</i>, but some strains might be able to withstand the dose of UV-A required to activate out UVA sensor (50µM/m<sup>2</sup>/sec).</div> |
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1ml 10x serial dilutions were made up to 10-6 from a 5ml overnight of each strain. 10µl spots of each dilution were then spotted onto LB agar plates. | 1ml 10x serial dilutions were made up to 10-6 from a 5ml overnight of each strain. 10µl spots of each dilution were then spotted onto LB agar plates. | ||
| − | These plates were then exposed to | + | These plates were then exposed to 50µM/m<sup>2</sup>/sec of UVA at room temperature in illumination cabinets. Time points were then taken by removing plates from the illumination cabinet. |
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After illumination, plates were incubated at 37°C, under the assumption that every single viable cell will form a colony. The length of incubation is irrelevant, provided that every cell is given enough time to form a visible colony. This also forms the basis of our counting system, where a colony is assumed to have come from a single cell. We also make the assumption that cell division at the temperature and time we were running the experiment was negligible/nonexistent. | After illumination, plates were incubated at 37°C, under the assumption that every single viable cell will form a colony. The length of incubation is irrelevant, provided that every cell is given enough time to form a visible colony. This also forms the basis of our counting system, where a colony is assumed to have come from a single cell. We also make the assumption that cell division at the temperature and time we were running the experiment was negligible/nonexistent. | ||
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| − | + | As shown in Figure 7, TOP10 and DH5α cell counts drop dramatically after 20 minutes. DS941 and MG1655 show some variation, but do not appear to be as adversely affected as the <i>recA-</i> mutants. Therefore DS941 was chosen as our chasis. | |
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<img src="https://static.igem.org/mediawiki/2015/1/19/2015-Glasgow-sur3.png" height="70%" width="70%"/> | <img src="https://static.igem.org/mediawiki/2015/1/19/2015-Glasgow-sur3.png" height="70%" width="70%"/> | ||
| − | <figcaption>Figure | + | <figcaption>Figure 7: Estimated cell count per 10ul of a 5ml overnight in lb broth over time of exposure to 50µM/m<sup>2</sup>/sec to UVA</figcaption> |
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Revision as of 03:29, 19 September 2015
Summary
Aims:
- To characterise the three components of a UV-A sensor system: UirS, UirR, PlsiR.
- To investigate E. coli survival rates in UV-A and sunlight.
- Essential: • K1725400 (PlsiR) • K1725410 (UirS) • K172541#(UirS with RBS) • K1725420 (UirR) • K1725421 (UirR with RBS)
- Others: • K1725401 (PlsiR.I13500) • K1725402 (PlsiR.E5501) • K1725422 (J23101.B0032.UirR) • K1725423 (J23110.B0032.UirR) • K1725424 (J23114.B0032.UirR) • K1725425 (J23116.B0032.UirR) • K1725426 (J23101.B0032.UirR.B0015) • K1725427 (J23110.B0032.UirR.B0015) • K1725428 (J23114.B0032.UirR.B0015) • K1725429 (J23116.B0032.UirR.B0015) • K1725430 (J23101.B0032.UirR.B0015.PlsiR.I13500) • K1725431 (J23110.B0032.UirR.B0015.PlsiR.I13500) • K1725432 (J23114.B0032.UirR.B0015.PlsiR.I13500) • K1725433 (J23116.B0032.UirR.B0015.PlsiR.I13500)
Overview
In order to prevent cells permanently shifting their metabolism towards one that favours light production, we decided to repress the bioluminescence genes (our optimised lux operon) in the presence of sunlight. The chosen system recognizes the presence of unidirectional UV-A light and comes from the cyanobacterium Synechocystis sp. PCC6803. The system has not been previously characterized before in iGEM. Three components are required to produce a response to UV-A: UirS (UV intensity response Sensor), UirR (UV intensity response Regulator), and PlsiR (promoter of the light and stress integrating response Regulator). For the system to be fully online K322122 is required. This BioBrick is responsible for the synthesis of phycocyanobillin, a chromophore normally found in cyanobacteria that is necessary for the functioning of nearly all light-sensing proteins. We obtained UirS and UirR from genomic Synechocystis DNA via PCR. Our primers included the BioBrick prefix and suffix as well as a ribosome-binding site (B0032). Due to non-BioBrick compatible restriction sites in the UirS gene PCR mutagenesis was carried out with the use of the TOPO TA plasmid vector. The UirR gene contained no such sites and was therefore inserted directly into the pSB1C3 plasmid. PlsiR also lacked such restriction sites and was therefore inserted into pSB1C3. Due to possible toxicity of the UirS gene, our proposed construct contains UirR and PlsiR with an appropriate coding gene in the high copy number pSB1C3, while UirS, alongside with the phycocyanobillin synthesis operon, was put in the low copy number plasmid pSB3K3. We have decided not to put a terminator between UirS and K322122 because the promoter of K322122 is stronger than that of UirS.
Sensor
Originally, the system containing UirS, UirR, and PlsiR accounts for a negative phototactic response to unidirectional UV-A light. The proposed mechanism puts UirS, a transmembrane protein of the CBCR family, as the molecule that perceives UV light. It is suggested that through a physical interaction between UirS and UirR and possibly a phosphotransfer from UirS to UirR, UirR is released from the transmembrane protein. The released UirR can now bind to DNA and UirR, which is similar to other activators of stress responses, was found to be a transcriptional activator of lsiR after binding to its promoter PlsiR . We suggest a system where UV-light triggers the expression of a repressor that acts on the production of bioluminescence genes to alleviate the burden they may cause on the cells’ metabolism if constantly expressed. During the night, the bioluminescence genes are expressed, and produce a green-blue light. As it becomes day, UV-A causes the release and activation of UirR. UirR binds to PlsiR to turn expression of the repressor PhlF. PhlF binds to PPhlF to turn off expression of LuxCDABE, so there is no bioluminescence. As it becomes night again, UirR is no longer bound to PlsiR so expression of PhlF is turned off. As PPhlF is no longer repressed, expression of LuxCDABE is turned and bioluminescence is produced again.
Survivability
Introduction
Initial aims
Method
Results
Conclusion
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