Difference between revisions of "Part:BBa K2969047"
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This part combines the composite part pCI434-doc BBa_K2969046 with the transcriptional factor CI434ts-TEVsite BBa_K2969020. | This part combines the composite part pCI434-doc BBa_K2969046 with the transcriptional factor CI434ts-TEVsite BBa_K2969020. | ||
+ | |||
+ | |||
+ | <h2>Characterization | ||
+ | </h2> | ||
+ | |||
+ | <h3><center>Cold-inducible On-switch + Toxin</center></h3> | ||
+ | |||
+ | <p> One way to address the biosafety issue is using toxin-antitoxin pairs. Toxin is a kind of protein which is the output of the genetic circuit. Under certain condition such as temperature, toxin begins to be expressed by the engineered bacteria and eventually kill those bacteria. </p><br>. | ||
+ | <p> In our engineering bacteria, we used Doc, a toxin interferes with basic metabolism at the level of translation, to associate with our cold-inducible on-switch, so that under low temperature, the switch is turned on to express Doc protein. | ||
+ | </p> | ||
+ | |||
+ | <br><p>To explore the possibility of escape for evaluating the performance of our kill switch, we measured the growth of the bacteria with DOC gene in LB solid medium at different temperatures and dilutions. The results showed that the strain cultured at 25β grew much worse compared with the strain grown at 37β, and the 20h average solid escape frequency is 2.318Γ10-2 , the lowest escape rate can be limited to 10-3 level.</p><br> | ||
+ | |||
+ | |||
+ | <div>[[File:T--UCAS-China--biosafety3.jpeg|700px|thumb|center|]]</div> | ||
+ | <div>[[File:T--UCAS-China--biosafety4.jpeg|700px|thumb|center|]]</div> | ||
+ | <div>[[File:T--UCAS-China--biosafety5.jpeg|700px|thumb|center|]]</div> | ||
+ | |||
+ | <h5>Figure 1. The escape rate of bacteria on solid LB plate after 20h. The escape rate is calculated using the formula πππ π¬πππππ πππππππππ =(πͺπππππππ ππ πππππππππππππ πππππ Γ π
πππππππ)/(πͺπππππππ ππ ππππππππππ πππππ Γ π
πππππππ) , the escape rate of 3 groups are (1Γ10^7)/(2Γ10^8 )=5Γ10^(-2) , (11Γ10^7)/(6Γ10^10 )=1.83Γ10^(-2) and (2Γ10^7)/(16Γ10^9 )=1.25Γ10^(-3) respectively(from above to below). And the π¬πππππ πππππππππ = π¨ππππππ π¬πππππ πππππππππ Β± πππππ
πππ
π
ππππππππ =2.318 Γ10^(β2) Β± 0.122. </h5> | ||
+ | |||
+ | <p> Moreover, we measured the growth curve of the strains with DOC gene at different temperatures to characterize their growth in liquid medium, and took the strains without doc gene as the control to verify the effectiveness of the toxin system. The results showed that the growth of the two strains was almost the same at 37β, indicating relatively low leakage of the system and low while the growth of the strains with doc gene was worse at 25β, indicating that the system with DOC as toxin was effective. | ||
+ | </p> | ||
+ | |||
+ | <div>[[File:T--UCAS-China--biosafety6.png|700px|thumb|center|<b>Figure 2:</b>The growth curve of bacteria on liquid LB. Incubated in 4 mL volume in 24-deep-well plate.]]</div> | ||
+ | |||
+ | |||
+ | <p> Based on the design of our cold-inducible switch and integrating toxin Doc, we developed a βkill switchβ which sensitively and accurately responds to the natural signal of human body and the environment β temperature. We successfully limit the escape rate to 10-2 to 10-3. Considering the improvement of the robustness and performance of the whole system, also to ensure the ability of our ark to adapt to various situation with as little risk for both human and nature as possible, we design another strategy as follow.</p><br> | ||
<!-- Add more about the biology of this part here | <!-- Add more about the biology of this part here |
Latest revision as of 19:15, 19 October 2019
pCI434-doc-J23119-CI434ts-TEVsite
This part combines the composite part pCI434-doc BBa_K2969046 with the transcriptional factor CI434ts-TEVsite BBa_K2969020.
Characterization
Cold-inducible On-switch + Toxin
One way to address the biosafety issue is using toxin-antitoxin pairs. Toxin is a kind of protein which is the output of the genetic circuit. Under certain condition such as temperature, toxin begins to be expressed by the engineered bacteria and eventually kill those bacteria.
.
In our engineering bacteria, we used Doc, a toxin interferes with basic metabolism at the level of translation, to associate with our cold-inducible on-switch, so that under low temperature, the switch is turned on to express Doc protein.
To explore the possibility of escape for evaluating the performance of our kill switch, we measured the growth of the bacteria with DOC gene in LB solid medium at different temperatures and dilutions. The results showed that the strain cultured at 25β grew much worse compared with the strain grown at 37β, and the 20h average solid escape frequency is 2.318Γ10-2 , the lowest escape rate can be limited to 10-3 level.
Figure 1. The escape rate of bacteria on solid LB plate after 20h. The escape rate is calculated using the formula πππ π¬πππππ πππππππππ =(πͺπππππππ ππ πππππππππππππ πππππ Γ π πππππππ)/(πͺπππππππ ππ ππππππππππ πππππ Γ π πππππππ) , the escape rate of 3 groups are (1Γ10^7)/(2Γ10^8 )=5Γ10^(-2) , (11Γ10^7)/(6Γ10^10 )=1.83Γ10^(-2) and (2Γ10^7)/(16Γ10^9 )=1.25Γ10^(-3) respectively(from above to below). And the π¬πππππ πππππππππ = π¨ππππππ π¬πππππ πππππππππ Β± πππππ πππ π ππππππππ =2.318 Γ10^(β2) Β± 0.122.
Moreover, we measured the growth curve of the strains with DOC gene at different temperatures to characterize their growth in liquid medium, and took the strains without doc gene as the control to verify the effectiveness of the toxin system. The results showed that the growth of the two strains was almost the same at 37β, indicating relatively low leakage of the system and low while the growth of the strains with doc gene was worse at 25β, indicating that the system with DOC as toxin was effective.
Based on the design of our cold-inducible switch and integrating toxin Doc, we developed a βkill switchβ which sensitively and accurately responds to the natural signal of human body and the environment β temperature. We successfully limit the escape rate to 10-2 to 10-3. Considering the improvement of the robustness and performance of the whole system, also to ensure the ability of our ark to adapt to various situation with as little risk for both human and nature as possible, we design another strategy as follow.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12INCOMPATIBLE WITH RFC[12]Illegal NheI site found at 644
Illegal NheI site found at 667 - 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]