Difference between revisions of "Team:Glasgow/Project/Overview/UVA"
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− | <li><i>P<sub>lsiR</sub></i> promoter from <i> | + | <li><i>P<sub>lsiR</sub></i> promoter from <i>Synechocystis</i> does not function as a promoter in <i>E. coli</i>. It may not be able to recruit the sigma-70 factor required for binding of <i>E. coli</i> RNA-polymerase to initiate transcription |
<li>The Phycocyanobillin synthesis biobrick used <a href="//parts.igem.org/wiki/index.php?title=Part:BBa_K322122">K322122</a> may be supplied with a mutated promoter, leading to lack of expression of PCB. We have documented this error in sequencing of its promoter on the experience page on the part K322122 | <li>The Phycocyanobillin synthesis biobrick used <a href="//parts.igem.org/wiki/index.php?title=Part:BBa_K322122">K322122</a> may be supplied with a mutated promoter, leading to lack of expression of PCB. We have documented this error in sequencing of its promoter on the experience page on the part K322122 | ||
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Revision as of 17:07, 17 October 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) • K1725411 (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 recognises unidirectional UV-A light and comes from the cyanobacterium synechocystis sp. PCC6803. The system has not yet been characterized by an iGEM team for the Parts Registry. 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) (Song et al., 2011). Expression of a chromophore molecule, phycocyanobillin (PCB), is also required for functional light sensing. Phycocyanobillin is synthesised in a two step pathway from Heme within cyanobacterium. Several biobricks encoding the two phycocyanobillin synthesis pathway enzymes already existed within the Registry of Parts due to utilisation of PCB in other previously characterised synechocystis sp. PCC6803 light sensors such as the ccaS green-light sensor system. We obtained uirS and uirR from synechocystis genomic DNA via PCR. Our primers were flanked with the BioBrick prefix as well as the medium strength ribosome-binding site B0032, and the biobrick suffix. For uirS we utilised the reverse primer to modify the stop codon from the (suboptimal in E. coli) TAG to TAA. A G-Block was ordered from IDT of the 535bp genomic region identified in Song et al. between the stop codon of uirR and start of lsiR, which was demonstrated to contain the uirR transcriptional activator binding region for the promoter of lsiR. The G-block was synthesised with the biobrick prefix and suffix attached, and a SpeI site within mutated away by one base (t58a). The uirR gene and <PlsiR promoter region were both biobrick compatible and were therefore ligated directly into the pSB1C3 plasmid; whereas uirS possessed three BioBrick incompatible restriction sites, preventing ligation into pSB1C3 and submission to the registry. In order to make uirS biobrick compatible we first had to clone it into a vector which would allow us to alter the incompatible restriction sites by PCR mutagenesis. We chose to use the TOPO® TA Cloning® Kit from Invitrogen (450641) and followed the protocol provided (See protocols). Through a diagnostic digest of 5 miniprepped transformants it was observed that uirS inserted into TOPO vector reversed in all 5 cases. TOPO cloning is a non-directional process, but it was hypothesised at this stage that the combination of the lac promoter and very high copy number resulting from the pUC origin of replication present in pCR 2.1 TOPO vector lead to selection against expression of uirS. Once successfully cloned into a vector we began the process of PCR mutagenizing the BioBrick incompatible restriction sites in a stepwise manner using the QuikChange II Site-Directed Mutagenesis Kit from Agilent (200523) (See protocols). The Agilent QuikChange Primer Design tool was used to design mutagenic primers to modify a single base in the three illegal restriction sites without altering the amino acid sequence of uirS and attempting to match codon frequency. Although we were modifying uirS in its reversed conformation within TOPO vector, the following sequence labels were numbered in the forward direction from the start codon. • XbaI site (1): 571-576 o TCTAGA to TCTcGA = a573c o CTA (Leucine) to CTC (Leucine) • EcoRI site (2): 1638-1643 o GAATTC to GAATcC = t1641c o ATT (Isoleucine) to ATC (Isoleucine) • XbaI site (3): 1790-1795 o TCTAGA to TCTcGA = a1792c o AGA (Arginine) to CGA (Arginine)
Sensor
In synechocystis, the uirS two-component system is involved in a negative phototactic response to unidirectional UV-A light (Song et al., 2011). The proposed mechanism places uirS, a transmembrane protein, as the protein that photosenses UV light. It is suggested that a phosphotransfer from uirS to uirR occurs upon UVA-light excitation of Phycocyanobillin chromophore bound within uirS; uirR is released from the transmembrane protein and locates to a binding region upstream of the lsiR promoter. uirR bound upstream of lsiR is shown to act as a transcriptional activator of lsiR (Song et al., 2011). Figure 4 is the illustration of the uirS mechanism taken from Song et al.
Figure 5 is taken from Schmid et al and shows their optimised green light sensor assembly.
As our chassis for UV-A testing we chose the E. coli strain DS941, which exhibited increased survivability under UV illumination when compared to both TOP10 and DH5α in our UVA illumination survival study. DS941 cells carrying K1725430.pSB1C3 plasmid were made chemically competent (Protocols) and transformed with the K1725445.pSB3K3 plasmid. Resulting transformants were cultured, miniprepped, and checked with a diagnostic digest to check presence of both plasmids. Three of the transformants checked appeared correct under diagnostic restriction digest. We then designed an experiment to determine whether sunlight UVA illumination would result in expression of GFP from our assembled uirS two plasmid system.
Six E. coli strains were tested:
- 3 different DS941 transformants expressing both sensor and response plasmids
- DS941 with K1725430 Response plasmid alone
- DS941 with K1725445 Sensor plasmid alone
- DS941 cells only
Cells were cultured overnight then 1 ml of o/n was added to 20 ml of fresh broth in a 100 ml conical flask, and incubated with shaking @ 37C for 2 hours. Then 10 ml of each cell culture was added to two empty Petri Dishes, one for sunlight illumination and one to be kept in darkness. Sunlight plates were placed on a tray by a window, and darkness plates were wrapped in tinfoil. After 5 hours 1ml of cells from each plate was pippetted into fresh eppendorf tubes, spun down to a pellet in a microfuge, and then resuspended in Phosphate binding solution (PBS: see interlab study protocol for full methodology). 200 l of each cell type was placed in a microwell plate along with blank PBS as a control, and scanned with a Typhoon fluorescence reader (see interlab study protocol for full methodology).
No fluorescence above that exhibited by the cells-only control wells was observed, indicating that our assembly of the uirS two component system did not function. At this point there was not sufficient time remaining prior to the jamboree to do further testing to discern the reason for the failure of the system, however the two reasons we believe to be the most likely cause of failure are:
- PlsiR promoter from Synechocystis does not function as a promoter in E. coli. It may not be able to recruit the sigma-70 factor required for binding of E. coli RNA-polymerase to initiate transcription
- The Phycocyanobillin synthesis biobrick used K322122 may be supplied with a mutated promoter, leading to lack of expression of PCB. We have documented this error in sequencing of its promoter on the experience page on the part K322122
Survivability
Introduction
Initial aims
Method
Results
Conclusion
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