Coding

Part:BBa_K3034006

Designed by: Qiuyun Huang 、Zixin Wang   Group: iGEM19_UESTC-China   (2019-09-16)
Revision as of 07:50, 2 October 2019 by Estrella (Talk | contribs) (Results)


Ciprofloxacin resistance cassette

This part is a ciprofloxacin resistance cassette. It contains a strong promoter J23119(BBa_J23119), RBS(BBa_K1725309), ciprofloxacin resistance gene qnrS1 and a terminator(BBa_B1006)(fig.1).

Ciprofloxacin resistance gene qnrS1 is first found in Gram-negative strains. It's one of the plasmid-mediated quinolone resistance genes and it encodes pentapeptide duplicates of about 200 amino acids. These proteins can produce quinolone resistance through two different mechanisms of action. One is decreasing the number of quinolone target sites by reducing DNA binding to helicase or topoisomerase IV. The other one is to inhibit the binding of quinolone to enzymes by binding these proteins to helicase or topoisomerase.

fig.1 The Framework of BBa_K3034006.

Usage and Biology

In order to let the engineered E.coli DH5α grow and play a role normally under the exist of ciprofloxacin(CIP), we constructed this ciprofloxacin resistance cassette to enhance the resistance ability of our engineered E.coli DH5α.

MIC tests-Ciprofloxacin, E.coli DH5α carrying qnrS1 and wild-type E.coli DH5α

Experiment

In addition, we would like to increase the resistance effect, so we selected DH5α chemically competent cell to do transform. We shook the bacteria fluid overnight and adjusted them to the same Abs600. Then we added gradient concentrations of CIP and measured Abs600 per hour using 96 wells plate.

Results

Minimal Inhibitory Concentration (MIC) is the lowest concentration of antibiotic which prevents growth of bacteria. As for our E.coli DH5α carrying qnrS1, the MIC value was found to be between 10mg/L-50mg/L (30uM-150uM) (fig.2).

fig.2 Growth of E.coli DH5α(with qnrS1) in the Presence of Ciprofloxacin.

In the presence of different concentrations, we selected another wild-type E.coli DH5α which didn’t carry qnrS1 as the negative control group. And we tested its growth curve over time (fig.3).

fig.3 Growth of Wild-Type E.coli DH5α in the Presence of Ciprofloxacin.

We discovered that MIC value for negative group was between 0.3mg/L-1mg/L. iGEM16_Groningen(BBa_K1930004) tested the MIC value for wild-type E.coli Top10 and it was between 100nM-130nM (0.033mg/L-0.043mg/L). Comparing these two results, we found that wild-type DH5α has the higher resistance than Top10.

Besides, the MIC value for wild-type DH5α was much lower than our E.coli DH5α carrying qnrS1. Thereout it verified that our part was workable.

Inhibition ratio

Moreover, we defined the inhibition ratio to represent the resistance ability of our part(fig.4). The higher the inhibition ratio, the weaker the resistance.

T-UESTC-China-Inhibition ratio.jpeg

It could be seen intuitively from fig.4 that our E.coli DH5α carrying qnrS1 showed significant resistance under 0.15mg/L-1mg/L CIP in the first three hours. It even growth better than the negative group under 0.3mg/L CIP. As time went on, resistance effect of qnrS1 was gradually weakening.

fig.4 The Inhibition Rate of Ciprofloxacin on Wild-Type E.coli DH5α and E.coli DH5α(with qnrS1).

Conclusions

  1. The MIC value of E.coli DH5α carrying qnrS1 is between 10mg/L-50mg/L (30uM-150uM). And the MIC value of E.coli DH5α without qnrS1 is between 0.3mg/L-1mg/L (1uM-3uM). So this part can significantly improve the ciprofloxacin resistance of E.coli DH5α.
  2. The resistance of wild-type E.coli DH5α is stronger than wild-type E.coli Top10.

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal NheI site found at 7
    Illegal NheI site found at 30
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal BglII site found at 36
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


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