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Revision as of 00:16, 20 October 2016

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Threshold device
In the threshold device, we need to prove that the in-promoter will have different responses corresponding to different plasmid numbers. In our project, we use the inhibitor protein as the signal. We combined the wet experiment results and the mathematical model to prove our system can work in order. We divided it into two main goals:
(1) To prove that inhibitor’s concentration can regulate the expression of the killer gene by affecting its in-promoter.
(2) To prove that plasmid numbers will influence the inhibitor concentration
Results:
1. Simulated the production of inhibitors with different concentrations by adding different concentrations of arabinose
2. Found out the concentrations of inhibitor under different concentrations of arabinose and used the results to derive the threshold of plasmids number in the constitutive circuit.
3. Employed plasmids with different copy numbers and simulated the concentrations of plasmids losing on different levels
4. Employed different RBS and promoters with different strengths to change the inhibitor concentration

Killer device
Since the lethal efficiency of killer genes will decide the capacity of general circuit, so we have to:
1. Prove that the toxin protein we selected can successfully express and the lethal effect is obvious
2. Adjust the translation efficiency of toxin proteins through replace ribosome binding site (RBS), thus to adjust the threshold
3. Construct gene circuits connecting killer device and inhibitor device
4. Find another possible way to produce the lethal effect
Results:
1. Successfully constructed the testing circuits of toxin proteins [Part: BBa_K2120002 and Part: BBa_K2120003]
2. After transformation, we measured the OD600 to draw the growth curve and observed the function of toxin protein.
3. In addition to B0032, we selected a stronger RBS B0034 and a weaker one B0031. Through measuring OD600, we demonstrated that we can adjust the lethal efficiency through replacing RBS.
4. Successfully constructed the testing circuit of toxin proteins according to two kinds of inhibitors. [For example, Part: BBa_K2120400]
5. Tested the lethal effect of producing DSB through coupling sgRNA and Cas9

Recombination
Aim
Considering the factor of the potential deficiency of executor killer due to the completely lost of plasmids and the number of "in-promoters" will affect our system, we decide to integrate the killer device into the genome. This group mainly provided a tool for genome integration. The insertion fragment is our testing device, including the expression cassette of rfp and killer gene. With this recombination system, we can get the upgraded type of our P-SLACKiller.
Results
1. Coupled CRISPR/Cas9 system with λ-Red recombineering to integrate the donor fragments, but we haven’t finished the second plasmid construction
2. Tried the traditional lambda Red recombination and successfully inserted four testing devices into the genome, locus of LacI.

Site-directed promoter mutation
We have two combinations of inhibitor and "in-promoter": TetR-PTet, CI-PR. The strength of "in-promoter" will decide the expression level of killer gene. Directly applied these two combinations, we got the initial threshold. In order to adjust the threshold, we planned to mutate the "in-promoter" and got mutants with various strengths. We chose PTet as our target promoter. Through literature research, we chose the -35 region as our mutation region. We mainly used RFP to indicate the promoter strength in our wet experiment.
Results
1. Tried to use one-step mutation, but because of the secondary structure of promoters, we didn’t get positive results
2. Built a library of mutated PTet promoters and characterized the promoter activity through measuring the red fluorescence intensity
3. Selected 4 mutants and got the successful sequencing results