Difference between revisions of "Team:HZAU-China/Results"

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  <div class="HZAU_2017_menu">

      <li id="HZAU_menu_1">

         <a href="#" id="bianse_1">Results</a>

      <li id="HZAU_menu_2">

         <a href="#item2_1" id="bianse_2">Notes</a>

      <a class="fubiaoti">The function of dCas9 and gRNA</a>

      <a class="zhengwen">The function of dCas9 and gRNA

        We first construct the gRNA targeting at OriC and test if it could work as we expected. Through OD measurement we observed an inhibition of growth when dCas9 and gRNA are all expressed.</a>

         <img src= "https://static.igem.org/mediawiki/2017/c/ce/T--HZAU-China--Results_Figure1.gif" width = "60%">

         <br/>For further description of this synchronization method, we quantifying the number of oriC versus terC by using qPCR. The results confirm that the initiation of chromosome replication is inhibited.

         <img src= "https://static.igem.org/mediawiki/2017/2/2d/T--HZAU-China--Results_Figure2.gif" width = "60%">

         <br/>The flow cytometric is also used to conduct the run-out experiment to verify the synchronization.

         <img src=" " width="60%">

         <br/>According to our results, we can conclude that the dCas9 and gRNA(oriC) can be used to synchronize the cell cycle of <i>E.coli</i>

      </a>

      <a class="fubiaoti">The light induced CRISPR/dCas9 system at transcription level</a>

      <a class="zhengwen">An optimized CcaS-CcaR system is constructed under the design of our advisor, the performance of optimized system is as following.

      <img src="" width="60%">

      <br/>We next insert the sequence of gRNA(OirC) after the Pcpcg2, and measure the OD performance under the green light or red light separately.

      <img src="" width="60%">

      <br/>The result shows a difference in growth rate under green light and red light. Similarly, next we performed the qPCR to further demonstrate the synchronization.

      <img src="" width="60%">

      <br/>At last, we test if this system can make reverse regulate, which is essential for the concept of computer control, please view <a href="https://2017.igem.org/Team:HZAU-China/Demonstrate" >DEMONSTRATION</a>.

      </a>

      <a class="fubiaoti">The light induced CRISPR/dCas9 system at protein level</a>

      <a class="zhengwen">After getting DNA from IDT, we first constructed and tested the function of pMag and nMag through Luciferase assay.

      <br/>The result verifies the function of pMag and nMag. We next test the expression of split dCas9 to check if it is hydrolysis by SDS-PAGE.

      <img src="" width="60%">

      <br/>After inserting it into pET plasmid, the results turnout that protein is not hydrolysis.  

      <br/>The last reason we doubt is that if it is because the split method that makes the split dCas9 can’t complement. We replaced the pMag and nMag with a more reliable chemical induced dimerization protein, FKBP & FRB. The result shows that no inhibition of growth is observed after adding rapamycin, which induces the dimerization of FKBP and FRB.

      <img src="" width="60%">

      In summary, in this project we achieved controlling cell in the level of DNA replication, proved the feasibility of using CRISPR to regulate cell cycle, and further regulate it with light. A reverse regulation of our system is demonstrated by OD measurement and qPCR. At the same time, a corresponding software and hardware are developed to achieve the computer-controlled cell cycle. The software is used to predict the internal replication procession and control the hardware to regulate cell by light.

      For more information, please view <a href="https://2017.igem.org/Team:HZAU-China/Demonstrate">Demonstrate</a>

      </a>

<a class ="biaoti"> Notes</a>

<a class ="zhengwen"><li>When using the CcaS-CcaR system please note that the atc concentration is different from the former concentration 200ng/ml. After transformation of two plasmids related to CcaS-CcaR system into bacteria, it becomes more sensitive to aTc. A final concentration of 200ng/ml will be toxic to the bacteria, and a working concentration as 0.1~1ng/ml is recommended.</li>

<li>In a light-control system, the exist of light sensing molecule is very important, but it is also very neglectable.</li>

<li> The aTc may lose its inducing function if added into a relatively high concentration culture (OD~0.6) when you use CcaS-CcaR system.</li>

</a>

<a class ="biaoti"> Future plan</a>

<a class ="zhengwen">The future plan including two aspects. One is further developing the system. First we plan to replace the inducible promoter with a constitutive promoter J23115. We plan to developing CcaS-CcaR CRISPRi system by knocking it into genome to make it more significant. At the same time, we hope that we can make the pMag-nMag system work because this system is smaller and less effect on bacterial metabolism. The other aspect is using this system for several certain applications, like characterize the stability of genome gene expression after synchronizer, and so on. We plan to knock the sfGFP into the genome and measure the fluorescence per cell to determine the noise between each cell and characterize whether synchronization can make the gene on genome more stable.

</a>