Difference between revisions of "Part:BBa K3007036"

 
 
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<partinfo>BBa_K3007036 short</partinfo>
 
<partinfo>BBa_K3007036 short</partinfo>
  
The CDS of super folder GFP
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It is the CDS of dsRed, which is under the control of downstream promoter. In our design, we used this fluorescece protein to report if high concentration uric acid presents in the environment.
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===Contribution===
 +
<div>
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<b>Group: QHFZ-China iGEM 2019</b>
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<br>
 +
<b>Author: Cheng Li</b>
 +
<br>
 +
<b>Design:</b>
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<br>
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[[File:T--QHFZ-China--BBa K3007036 1.png|400px|thumb|left|Figure 1. Schematic cartoon of the DNA construct of BBa_K3007036]]
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<p><br><br><br><br><br><br><br><br><br><br><br><br><br><br>
 +
<b>Documentation:</b>
 +
<br>
 +
This year, QHFZ-China designed a UA monitor system in E. coli. The original version is shown in Fig. 1. Pc is a constitutive promoter, Pcp6 promoter, and it promotes the expression of HucR and YgfU. When uric acid is absent, HucR can bind to PhucR, which suppresses dsRed expression. If uric acid presents in high concentration, HucR will release from PhucR and the expression of dsRed will recover from the inhibition [2]. </p>
 +
[[File:T--QHFZ-China--BBa K3007001 2.png|400px|thumb|left|Figure 1. Working mechanism of the uric acid detection system in E. coli. ]]
 +
<p><br>
 +
Two clones with the UA detection system were tested. The original gene circuit was able to response to UA in a range of 0 to 200 μM (Fig. 2A). The clone 1 showed much better dynamics than the other (Fig. 2B). Time course experiments showed that the fluorescence intensity became quite strong at 4 to 6 hours after UA induction, and became stable at 10 to 12 hours (Fig. 2C). Even if we removed UA by replacing fresh LB medium, after 48 hours shaking, the fluorescence would be still notable (Fig. 2D) and there was not significant difference of dsRed fluorescence / OD600 between before and after UA removing (Fig. 2E). All the data meant our design could detect high UA concentration quickly and stably.</p>
 +
[[File:T--QHFZ-China--BBa K3007005 3.png|400px|thumb|left|Figure 2. Response of UA detection system after different concentration of UA induction. (A) A photo to visualize the fluorescence induced by UA under a blue light. (B) Responding curve about the dsRed fluorescence / OD600 to different UA concentration of two E. coli clones. Data were shown as mean ± SD. N = 3 technical repetitions. (C) Time course experiments about the dsRed fluorescence / OD600 of E. coli after 0, 20 or 100 μM UA addition. Data were shown as mean ± SD. N = 3 technical repetitions. (D) A photo to visualize the fluorescence after UA removal under a blue light. (E) Quantitative measurement of dsRed fluorescence / OD600 before and after UA removal.]]
 +
<p><br>
 +
However, through our human practices, we found the sensitivity and responding time of the original design are not good enough. In the next generation design, we introduced RinA_p80α - PrinA_p80a system to enhance the sensitivity. Meanwhile, we changed dsRed to sfGFP, whose maturation time is much shorter, to shorten the waiting time. The new version of the uric acid detector was shown in Fig. 3. If UA presented, RinA_p80α would express and active transcription of sfGFP which was under control of PrinA_p80α. We called this as Version 2.</p>
 +
[[File:T--QHFZ-China--BBa K3007005 4.png|400px|thumb|left|Figure 3. Working mechanism of new uric acid detection system in E. coli (Version 2). ]]
 +
<p><br>
 +
We tested the sfGFP production of Version 2 under different concentration of extracellular UA. The curve in Fig. 4A showed the fluorescence was saturated under only 15 μM UA induction, while the old version needed about 100 μM UA to get saturated (Fig. 2B). To test if sfGFP could shorten the reaction time, we used the same construct only except reporter genes, called PRinA_p80α – sfGFP and PRinA_p80α – dsRed, respectively. After adding 20 μM UA into the reaction system, the curve of PRinA_p80α – sfGFP climbed much faster than PRinA_p80α – dsRed, which suggested our new design had a great induction performance, and fitted our predictions very well (Fig. 4B). </p>
 +
[[File:T--QHFZ-China--BBa K3007005 5.png|400px|thumb|left|Figure 4. The induction performances of the Version 2. (A) Induction curve of Version 2 under 0 to 200 μM UA treatment by measuring the sfGFP fluorescence / OD600. Data were shown as mean ± SD. N = 3 technical repetitions. (B) Time course experiment of sfGFP Version 2 and dsRed Version 2. Data were normalized by taking the fluorescence / OD600 of two groups at 0 h as standard, respectively. Data were shown as mean ± SD. N = 3 technical repetitions.]]
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<p>At last, we took a photo to show the green fluorescence released by <i>E. coli</i> expressing sfGFP. </p>
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[[File: T--QHFZ-China--BBa K3007036 sfGFP.jpeg|400px|thumb|left| Figure 5. green fluorescence released by <i>E. coli</i> expressing sfGFP under a blue light]]
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 +
<p><br><br>
 +
<b>References:</b><br>
 +
[1] Wan, X., Volpetti, F., Petrova, E., French, C., Maerkl, S. J., & Wang, B. (2019). Cascaded amplifying circuits enable ultrasensitive cellular sensors for toxic metals. Nature chemical biology, 15(5), 540.<br>
 +
[2] Liang C., Xiong D., Zhang Y., Mu S. and Tang S. (2015). Development of a novel uric-acid-responsive regulatory system in Escherichia coli. Appl. Microbiol. Biotechnol. 99, 2267–2275.</p>
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<!-- Add more about the biology of this part here
 
<!-- Add more about the biology of this part here
 
===Usage and Biology===
 
===Usage and Biology===
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<!-- -->
 
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<span class='h3bb'>Sequence and Features</span>
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<b><span class='h3bb'><br><br><br>Sequence and Features</span></b>
 
<partinfo>BBa_K3007036 SequenceAndFeatures</partinfo>
 
<partinfo>BBa_K3007036 SequenceAndFeatures</partinfo>
  

Latest revision as of 12:18, 21 October 2019


sfGFP

It is the CDS of dsRed, which is under the control of downstream promoter. In our design, we used this fluorescece protein to report if high concentration uric acid presents in the environment.

Contribution

Group: QHFZ-China iGEM 2019
Author: Cheng Li
Design:

Figure 1. Schematic cartoon of the DNA construct of BBa_K3007036















Documentation:
This year, QHFZ-China designed a UA monitor system in E. coli. The original version is shown in Fig. 1. Pc is a constitutive promoter, Pcp6 promoter, and it promotes the expression of HucR and YgfU. When uric acid is absent, HucR can bind to PhucR, which suppresses dsRed expression. If uric acid presents in high concentration, HucR will release from PhucR and the expression of dsRed will recover from the inhibition [2].

Figure 1. Working mechanism of the uric acid detection system in E. coli.


Two clones with the UA detection system were tested. The original gene circuit was able to response to UA in a range of 0 to 200 μM (Fig. 2A). The clone 1 showed much better dynamics than the other (Fig. 2B). Time course experiments showed that the fluorescence intensity became quite strong at 4 to 6 hours after UA induction, and became stable at 10 to 12 hours (Fig. 2C). Even if we removed UA by replacing fresh LB medium, after 48 hours shaking, the fluorescence would be still notable (Fig. 2D) and there was not significant difference of dsRed fluorescence / OD600 between before and after UA removing (Fig. 2E). All the data meant our design could detect high UA concentration quickly and stably.

Figure 2. Response of UA detection system after different concentration of UA induction. (A) A photo to visualize the fluorescence induced by UA under a blue light. (B) Responding curve about the dsRed fluorescence / OD600 to different UA concentration of two E. coli clones. Data were shown as mean ± SD. N = 3 technical repetitions. (C) Time course experiments about the dsRed fluorescence / OD600 of E. coli after 0, 20 or 100 μM UA addition. Data were shown as mean ± SD. N = 3 technical repetitions. (D) A photo to visualize the fluorescence after UA removal under a blue light. (E) Quantitative measurement of dsRed fluorescence / OD600 before and after UA removal.


However, through our human practices, we found the sensitivity and responding time of the original design are not good enough. In the next generation design, we introduced RinA_p80α - PrinA_p80a system to enhance the sensitivity. Meanwhile, we changed dsRed to sfGFP, whose maturation time is much shorter, to shorten the waiting time. The new version of the uric acid detector was shown in Fig. 3. If UA presented, RinA_p80α would express and active transcription of sfGFP which was under control of PrinA_p80α. We called this as Version 2.

Figure 3. Working mechanism of new uric acid detection system in E. coli (Version 2).


We tested the sfGFP production of Version 2 under different concentration of extracellular UA. The curve in Fig. 4A showed the fluorescence was saturated under only 15 μM UA induction, while the old version needed about 100 μM UA to get saturated (Fig. 2B). To test if sfGFP could shorten the reaction time, we used the same construct only except reporter genes, called PRinA_p80α – sfGFP and PRinA_p80α – dsRed, respectively. After adding 20 μM UA into the reaction system, the curve of PRinA_p80α – sfGFP climbed much faster than PRinA_p80α – dsRed, which suggested our new design had a great induction performance, and fitted our predictions very well (Fig. 4B).

Figure 4. The induction performances of the Version 2. (A) Induction curve of Version 2 under 0 to 200 μM UA treatment by measuring the sfGFP fluorescence / OD600. Data were shown as mean ± SD. N = 3 technical repetitions. (B) Time course experiment of sfGFP Version 2 and dsRed Version 2. Data were normalized by taking the fluorescence / OD600 of two groups at 0 h as standard, respectively. Data were shown as mean ± SD. N = 3 technical repetitions.

At last, we took a photo to show the green fluorescence released by E. coli expressing sfGFP.

Figure 5. green fluorescence released by E. coli expressing sfGFP under a blue light



References:
[1] Wan, X., Volpetti, F., Petrova, E., French, C., Maerkl, S. J., & Wang, B. (2019). Cascaded amplifying circuits enable ultrasensitive cellular sensors for toxic metals. Nature chemical biology, 15(5), 540.
[2] Liang C., Xiong D., Zhang Y., Mu S. and Tang S. (2015). Development of a novel uric-acid-responsive regulatory system in Escherichia coli. Appl. Microbiol. Biotechnol. 99, 2267–2275.





Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    INCOMPATIBLE WITH RFC[1000]
    Illegal SapI.rc site found at 13