Team:Oxford/biosensor construction
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Introduction: how we constructed our biosensor
In order to be able to use our model and to determine whether DcmR acts as a repressor or activator in the presence of DCM, we designed and constructed the following two-plasmid system. We primarily used Gibson assembly methods and sourced most of the necessary DNA from gblocks (synthesised oligonucleotides) we had designed based in the sequenced genome of Methylobacterium DM4. This system will also form the DCM biosensor and will be integrated with an electronic circuit to complement this genetic one:Production of the DCM-binding protein DcmR
Oxford iGEM 2014The binding site for DcmR with expression-reporting GFP
Unfortunately, we were unable to assemble the pSRKGm-pdcmA-sfGFP construct even after multiple attempts. Since we plan to prove that this system can work in E. coli, we re-designed this construct to use a different vector with an origin of replication that is compatible with our other construct pOXON-2 (containing dcmR).
We chose to use plasmid backbone pJ404 since it contains a pBR322 origin of replication which is compatible with p15A origin of replication present in pOXON-2.
Since DcmR is predicted to regulate expression of DcmA as well as auto-regulating its own expression, we decided to insert this promoter-containing intergenic region in both orientations upstream of sfGFP. This means we have two constructs:
- One with sfGFP in a position corresponding to the equivalent position of dcmA (labelled as ‘forward’ or PdcmA)which can express sfGFP under the PdcmA promoter.
- A second construct with sfGFP in the equivalent position of dcmR (labelled as ‘reverse' or PdcmR)that can express sfGFP under the promoter PdcmR.
These are shown below:
Building pOXON-1
Building pOXON-2 and pOXON-2-dcmR
Adding in mCherry
Building pSRK Gm construct
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