Team:Peking S/lab/notebook/qx

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<font size=6> <font color="#FFFFFF">Yiwei Chen's Notebook</font></FONT>
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== '''summary''' ==
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== '''Summary''' ==
I took the responsibility for constructing the sRNA-dependent competitor with my partner Qin Xiao. Furthermore, our work mainly focused on the characterization of the response curve of competitor in E. coli, and finally contributed to the rational design of the competitor.
I took the responsibility for constructing the sRNA-dependent competitor with my partner Qin Xiao. Furthermore, our work mainly focused on the characterization of the response curve of competitor in E. coli, and finally contributed to the rational design of the competitor.

Latest revision as of 05:19, 5 October 2011


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Xiao Qin's Notebook


Summary

I took the responsibility for constructing the sRNA-dependent competitor with my partner Qin Xiao. Furthermore, our work mainly focused on the characterization of the response curve of competitor in E. coli, and finally contributed to the rational design of the competitor.

Contents

July

7.1 - 7.7

We did four rounds of PCR to get the ptsG1+gfp. The gfp here refers to BBa_E0840 from the iGEM 2011 Parts Kit. In each step, we added around 30bp of the ptsG1’s 5’ untranslated region (5’ UTR) to the former product, and we finally got the construct for the fused protein. We sequenced the plasmids and it turned out to be correct.

7.8 - 7.14

We started to construct the SgrS(wt) module. To begin with, we managed to get the sequence from the k12 strain of E. coli. Then we added the constitutive promoter BBa_J23106 and the terminator BBa_B0015 to flank the SgrS. The product here was “Pc+SgrS(wt)+Terminator”. We also substituted the constitutive promoter with the arabinose-inducible promoter PBAD (BBa_I13453) and got “PBAD+SgrS(wt)+Terminator”.

7.15 - 7.21

According to the same protocol, we tried to construct the remaining ptsG mutants, i.e. ptsG1’, ptsG2, and ptsG2’. Since the primers were designed in the same manner as ptsG1, we expected to go through this part of molecular cloning smoothly. However, things got stuck here. The PCR always aborted half the way, and all we could do is to slightly change the reaction system and repeat the procedure over and over again. Finally, it seemed we had got all four candidates for further characterization. To our great surprise, the sequences proved to be all the same: they were all identical to ptsG1. Then we found out that the problem emerged from the design of the primers. We had four sequential forward primers, and the ignorance of the overlapping part of them led to the reverse mutation that compensated the adjustment we did to ptsG1’, 2, and 2’ from ptsG1.

7.22 - 8.7

These days we mainly focused on executing site mutation PCR to get the construction SgrS1 and SgrS2. We met another great problem here. Though we conducted our experiment exactly according to the protocol, the PCR always failed. All the products remained in the holes of the gel after electrophoresis, and further experiments thus couldn’t be done. Again we had to repeat the experiment to figure out what was the optimal condition to get things done. By troubleshooting, we thought problems lied in the specificity of our primers and the fidelity of the DNA polymerase. By changing our template as well as the enzyme we used, after days of tedious work, we made it. SgrS1&2 were done.

August

7.22 - 8.7

These days we mainly focused on executing site mutation PCR to get the construction SgrS1 and SgrS2. We met another great problem here. Though we conducted our experiment exactly according to the protocol, the PCR always failed. All the products remained in the holes of the gel after electrophoresis, and further experiments thus couldn’t be done. Again we had to repeat the experiment to figure out what was the optimal condition to get things done. By troubleshooting, we thought problems lied in the specificity of our primers and the fidelity of the DNA polymerase. By changing our template as well as the enzyme we used, after days of tedious work, we made it. SgrS1&2 were done.

8.8 - 8.15

We turned back to our ptsGs. Using ptsG1 as the template, we conducted another series of site mutation experiments to get ptsG1’, ptsG2, and ptsG2’. This time it went much more successfully. After the addition of Pc and PBAD upstream, we could finally undertake the task of characterization of our competitor.

8.16 - 8.24

Up to now, we had “Pc+ptsG+gfp” series (wt, 1, 1’, 2, 2’), “PBAD +ptsG+gfp” series (as above), “Pc+SgrS+Terminator” series (wt, 1, 2), and “PBAD+SgrS+Terminator” series (as above) in all. What remained to be done is to put them on appropriate-copy-numbered plasmids to get our competitor’s best performance. We first tried to put the “PBAD” class on the medium-to-low copy number plasmids pSB3T5, while let the “Pc” class untouched on their high-copy-number plasmids. After double transformation, we conducted the pre-experiments to qualitatively evaluate the competitor’s performance. The experimental protocol was as follows. We used 10-2 mol/L arabinose to induce the PBAD, and every 5 experimental groups are coupled with 2 controls, i.e. culture solution without any arabinose in it. The result was that whether ptsG or SgrS was under Pc, its property is dominant. That suggested Pc overweighed PBAD completely under such a configuration. A change in copy number was needed. What’s more, the ptsG1 and ptsG2 fused gfp performed badly in the experiments; their fluorescence was hardly discernible even under Pc. So we dropped them and chose ptsG1’ and ptsG2’ to go on.

8.25 - 9.5

By changing backbones, we got “Pc+ptsG+gfp+pSB4K5” series (1’, 2’, wt), and co-transformed them with “PBAD+SgrS+Terminator+pSB1A3” series (1, 2, wt). Then we got 3×3=9 constructs in total. A matrix was built up to test the repression capacity of the conjugated ptsG/SgrS systems and the orthogonality of the cross systems. The result was as expected and not bad. However, in one of our experiments, we discovered that 10-2 mol/L arabinose alone could repress the expression of GFP, probably by activated the function of endogenesis SgrS(wt) of the E. coli. To eliminate the interference of this, we decided to displace PBAD with salicylic acid inducible promoter PSal, since salicylic acid wouldn’t crosstalk with the ptsG/SgrS system. Besides, we also had “PBAD+ptsG+gfp+pSB3T5” series (1’, 2’, wt) co-transformed with “Pc+SgrS+Terminator+pSB1A3” series (1, 2, wt). Since the PBAD needed to be replaced, this part of experiments was abandoned.

September

8.25 - 9.5

By changing backbones, we got “Pc+ptsG+gfp+pSB4K5” series (1’, 2’, wt), and co-transformed them with “PBAD+SgrS+Terminator+pSB1A3” series (1, 2, wt). Then we got 3×3=9 constructs in total. A matrix was built up to test the repression capacity of the conjugated ptsG/SgrS systems and the orthogonality of the cross systems. The result was as expected and not bad. However, in one of our experiments, we discovered that 10-2 mol/L arabinose alone could repress the expression of GFP, probably by activated the function of endogenesis SgrS(wt) of the E. coli. To eliminate the interference of this, we decided to displace PBAD with salicylic acid inducible promoter PSal, since salicylic acid wouldn’t crosstalk with the ptsG/SgrS system. Besides, we also had “PBAD+ptsG+gfp+pSB3T5” series (1’, 2’, wt) co-transformed with “Pc+SgrS+Terminator+pSB1A3” series (1, 2, wt). Since the PBAD needed to be replaced, this part of experiments was abandoned.

9.6 - 9.14

These days, we mainly did molecular cloning to replace the PBAD in our system with PSal. Finally we finished “PSal+ptsG+gfp+pSB3T5” series (1’, 2’,wt), “PSal+SgrS+Terminator” series (1, 2, wt) and got their sequence correct. Again we will characterize their performance as what we had done with those “PBAD” constructs.

9.15 - 9.24

Using the newly constructed ptsG/SgrS systems, we started to prepare the titration curve of our competitor. We conducted the “Pc+ptsG+pSB4K5/PSal+sgrS+pSB1A3” system first. The salicylic acid concentration gradient was as follows. 10-7 M, 10-6 M, 5×10-6 M, 10-5 M, 2.5×10-5 M, 5×10-5 M, 7.5×10-5 M, 10-4 M, 2.5×10-4 M, 5×10-4 M, 7.5×10-4 M, 10-3 M, 12 in total. And the grouping of the experimental and control groups was the same as before, i.e. the 5+2 configuration. The data fitted into the logistic model. Further analysis was needed. As for the “PSal +ptsG+pSB3T5/Pc+sgrS+pSB1A3” system, still the Pc was too much stronger than PSal. Nearly all ptsGs were repressed. So once again we needed to change the copy number of the “PSal +ptsG” series constructs.

9.25 - 9.30

We are still working on the change of copy number. This time we need to put “Psal+PtsG+gfp” series (1’, 2’, wt) back to high copy number plasmids. When this is done, we will transform them with “Pc+sgrS1/2/wt+Terminator+pSB4K5”, respectively. Then we hope we can get the final data of our competitor.

October

10.1

10.3

10.4

10.5

10.7

10.8

10.9

10.10

10.11

10.12

10.13

10.15

10.16-10.21

10.21-10.25