Team:BostonU/FusionProteins

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<pageheader>Notebook: Fusion Proteins</pageheader>
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<pageheader>Fusion Proteins</pageheader>
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    <br>
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            <th scope="col"> Notebook Overview </th> </tr>
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<tr>
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<br>
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<td colspan="2" scope="col">
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<th colspan="2" scope="col"><br><h2>June</h2></th>
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<center><img src="https://static.igem.org/mediawiki/2014/6/62/BU14_new_fusion_proteins.png" width="70%"></center><br>
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<h3>Why Fusion Proteins? </h3>
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<th colspan="2" scope="col"><h3>Week of June 23</h3></th>
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As described <a href="https://2014.igem.org/Team:BostonU/Chimera"> here</a>, our main goal this summer was to come up with an efficient workflow to design, build and test large genetic devices. To demonstrate the efficacy of our <a href="https://2014.igem.org/Team:BostonU/Workflow"> workflow</a>, we started designed and started building a <a href="https://2014.igem.org/Team:BostonU/Encoder"> priority encoder</a>. To facilitate measurement of each component, we added the fluorescent fusion proteins to the priority encoder design. Since we lacked a lot of the internal repressor genes that we needed, we decided to test well known proteins available in our lab (<i>tetR</i>, <i>lacI</i>, and <i>araC</i>) with a GFP fusion protein before using this linker sequence for all fusions.<br><br>
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<center><img src="https://static.igem.org/mediawiki/2014/b/be/BU14_PE_Updated_fromPP.png" width="65%"></center>
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        <th colspan="2" scope="col">Decided to make the following Level 0 Coding Sequences:<br> &nbsp;&nbsp; C0040_CI <br>  
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<capt><br><center>Priority encoder with fusion GFP shown linked to repressor proteins (CDS1-5)</center></capt>
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&nbsp;&nbsp; C0080_CI <br> &nbsp;&nbsp; E0040_ID <br> &nbsp;&nbsp; E0030_ID
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&nbsp;&nbsp;&nbsp; <ul><li>Used Phusion PCR to make the parts listed above and then, performed PCR cleanup to purify the DNA fragments. 
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<br><br>In order to test the individual transcriptional units and the regulatory arcs associated with them, we needed the output for the individual parts of the device to be fluorescent. One way to do this is by using the bicistronic design shown below that mimics operons seen in natural bacterial systems.  
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<li> Upon quantifying all clean-ups, I found that the concentration for the E0040_ID (4.4 ng/uL) cleanup was lower than that of the negative control (6.1 ng/uL). So, I repeated the Phusion PCR for that part and ended up with a concentration of 31.9 ng/uL.
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<center><img src="https://static.igem.org/mediawiki/2014/2/25/YAFP4BUWiki.png"  width = "700" alt="FP" ></center>
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<li> Performed MoClo Level 0 reaction to insert the purified constructs into backbones with a Cam resistant gene.
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<capt><br><center>Bicistronic design that could be used as an alternative to fusion proteins</center></capt>
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<li> Transformed the MoClo plasmids on Cam plates to perform Blue-White screening and pick colonies that had successful digestion-ligation
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<br><br>
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<li> Transformation didn't work because I used faulty Bioline cells. So, I repeated transformations using DH5a cells.
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A peculiar effect for these types of designs has been reported in the literature. Specifically, when ribosomes bind to the genes sequentially, the ribosome that binds at the 5' end of gene 1 can interrupt the attachment of a ribosome at the 5' end of gene 2, thus blocking the next ribosome from binding to the mRNA and translating the gene. So, the genes further down a transcript are expressed less than the genes upstream [1]. <br><br>
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<li> Screened colonies further by performing Colony PCRs and running a gel.
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</ul>
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<center><img src="https://static.igem.org/mediawiki/2014/9/9a/BU2014_Fig_4.jpg" width="40%"</center>
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<th colspan="2" scope="col"><br><h3>Week of June 30</h3></th>
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<capt><br><br><center>The image above is Figure 4 from Lim et al., 2011 [1]. Excerpt from Lim N H et al. (2011): "We found that CFP and YFP expression at the first position in the operons was higher than at the third position for each time point. The protein concentration at each time point was normalized by the final concentration to determine their relative expression (R). R is independent of protein production and depends only on the protein degradation rate and any delay in the induction (SI Materials and Methods). When R was calculated, it was the same for positions 1 and 3 at each time point (Fig. 4 D and E). Therefore, protein degradation and any delay after induction are the same at both positions, indicating the differences in expression must be due to greater protein production in the more proximal position of the operons."</center></capt></center>
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<tr>
 
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<th colspan="2" scope="col">This week was about sequence verifying the genes made earlier and laying down the plan for final testing of the fusion protein.
 
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&nbsp;&nbsp;&nbsp; <ul>
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<br><br>In summary, when genes are placed in this operon strategy in synthetic systems, the first gene always expresses higher amounts of protein than the second or third genes [1]. Since these constructs are designed to measure protein degradation rate directly, these types of designs are inefficient. This problem can be solved by fusing the regulator protein with the fluorescent protein, as only one ribosome will then be required to translate the entire sequence, eliminating this problem.  
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<li>Miniprepped the overnight cultures for the colonies with plasmids that contain the required insert and sent them in for sequencing. All the sequences were as expected.
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<br><br>
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<li>The following transcriptional units will be next assembled so that the fusion proteins can be tested efficiently:<ol type= "I">
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<li>J23100_AB - BCD2_BC - C0012_CD - B0015_DE
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<li>R0010_EB - BCD2_BC - C0040_CI - E0040_ID - B0015_DF
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<li>R0010_EB - BCD2_BC - C0040_CI - E0030_ID - B0015_DF
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<li>R0010_EB - BCD2_BC - C0080_CI - E0040_ID - B0015_DF
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<li>R0010_EB - BCD2_BC - C0080_CI - E0030_ID - B0015_DF
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<li>R0010_EB - BCD2_BC - C0080_CD - B0015_DF
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<li>R0010_EB - BCD2_BC - C0040_CD - B0015_DF
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<li>R0010_EB - BCD2_BC - E0040_CD - B0015_DF
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<li>R0010_EB - BCD2_BC - E0030_CD - B0015_DF
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<li>R0040_FB-BCD2_BC-E1010_CD-B0015_DG
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<li>I13453_FB-BCD2_BC-E1010_CD-B0015_DG</ol>
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<li>Didn't have miniprep stocks for R0040_FB, B0015_DG and I13453_FB. So, streaked them out.
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<li>Picked colonies and grew overnight cultures.
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<li>Made minipreps and quantified for the three parts that were streaked</ul> </tr>
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Another way to measure function by fluorescence, using consecutive transcriptional units
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<center><img src="https://static.igem.org/mediawiki/2014/5/55/YABUFP2Wiki.png" width = "700" alt="FP" ></center>
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<br><br>
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Because it takes a minimum of 3 days to build these types of devices using MoClo these types of designs result in the expenditure of more time and resources as compared to building single transcriptional units with fusion proteins. Any design involving just one transcriptional unit instead of the above construct will making cloning faster and more cost-effective. <br><br>
 +
 +
Fusion Proteins are fused to regulator proteins to allow us to measure degradation rate directly. They reduce order effect seen with the bicistronic design and are cheaper to build, compared to cloning multiple TUs.<br>
 +
<center><img src="https://static.igem.org/mediawiki/2014/1/10/FP3YABUWiki.png" width = "500" alt="FP" ></center>
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<br><br><br>
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<h3>Design and Assembly</h3>
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<tr>
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<center><img src="https://static.igem.org/mediawiki/2014/2/2e/YABUFPOverview.png" alt="Gel_8-31" style="float:center"></center>
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<th colspan="2" scope="col"><br><h2>July</h2></th>
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<capt><center>Design strategy for building the fusion proteins. Two PCR products (top lines) with C and I or I and D fusion sites flanking the 5' and 3' ends are cloned into a destination vector to form a cohesive fusion protein containing the repressor protein fused with a green fluorescent protein.</center></capt>
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</tr>
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<tr><th colspan="2" scope="col"><h3>Week of July 7</h3></th></tr>
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<br><br>
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<tr><th colspan="2" scope="col"> This week I ran into problems with Kan plates, due to which I lost a lot of time.
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To make fusion proteins, we used the <a href="https://2014.igem.org/Team:BostonU/MoClo"> Modular Cloning </a>method .
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I then redid the transformations on new plates and could hence see blue and white colonies.
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<br><br>
 +
First, we added a new MoClo fusion site (I - TCTA) to the genes (at the end of repressors and before the reporter proteins). The designed primer sequences can be accessed on the<a href="https://2014.igem.org/Team:BostonU/Data"> Data Collected</a> page.
 +
<br><br>
 +
Then, we used Phusion Polymerase Chain reaction on the basic MoClo Level 0 parts using primers designed based on the fusion sites. We ended up with repressors with TCTAGA sequence at their ends and reporter proteins with the same sequence at the start. These can be treated as standard Level 0 parts which can then be assembled and tested using MoClo.
 +
<br><br>
 +
As discussed above, the end goal of building fusion proteins is to use them in the Priority Encoders with the new <a href="https://2014.igem.org/Team:BostonU/Repressors"> repressors proteins</a> we designed. However, we wanted to test the effect of fusing proteins on regulatory proteins using this amino acid linker. Thus, we proceed to design primers for the regulators <i> tetR, araC </i> and for the reporters, GFP and YFP.
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<br><br><br>
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<h3>Testing </h3>
<br>
<br>
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The following Level 2 constructs were assembled using MoClo -
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<br>* All transcriptional units have BCD2 as the 5' UTR and B0015 as the terminator<br>
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<center><img src="https://static.igem.org/mediawiki/2014/d/da/YAFP6BUWiki.png" width="700" style="float:center"></center>
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<br><br>
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It is important that the fusion proteins made aren’t drastically inferior to the individual function of the repressor or the fusion proteins. All constructs made were to compare with those above. Simply put, all 6 Level 2s below were used a controls.
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<br><br>
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<center><img src="https://static.igem.org/mediawiki/2014/2/23/YAFP7BUWiki.png" width="700" style="float:center"></center>
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<br><br>
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&nbsp;&nbsp;&nbsp; <ul><li>Ran gel for colony PCR reactions
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Experimental Results can be found in the <a href="https://2014.igem.org/Team:BostonU/Data"> Data Collected </a>page.
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<li>Setup the MoClo reactions for all the Transcriptional Units
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Detailed progress on the construction of fusion proteins can be found in the <a href="https://2014.igem.org/Team:BostonU/FusionProteinsNotebook">Fusion Proteins notebook</a>.<br><br>
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<li> Transformed all reactions on Kan plates
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<h3><br>References</h3>
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<li> Plates did not have any growth. So, I repeated transformations another time and when that didn't work, repeated the MoClo reactions <ol type= "I">  
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[1] Lim N H, Lee Y, Hussein R (2011) "Fundamental relationship between operon organization and gene expression" , PNAS Vol. 108 No. 26, doi: 10.1073/pnas.1105692108
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<li> Finally, the transformations yielded blue and white colonies as expected. </ol>  
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</ul>
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</td> </tr>
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<br>
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Poured LB, LB+Amp, and LB+Kan plates
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  </tr>
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<br>
 
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<tr><th colspan="2" scope="col"><h3>Week of July 14</h3></th></tr>
 
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<tr><th colspan="2" scope="col">In addition to my wetlab work this week I cleaned the lab, refilled stocks, and autoclaved backup supplies. I also talked to female high school students about iGEM and my experience with science and research to encourage them to pursue a science related field in university.
 
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<br>
 
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pBad, pTet, pA1LacO
 
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<ul><li>Created stab plate and picked two colonies from each transformation plate <li>Miniprepped overnight cultures and sent level 0 tandem promoter MoClo parts in for sequencing <li> Analyzed sequences <ol type= "I"> <li>Only the pTet-pBad tandem promoter turned out correctly <li>Noticed that the pA1LacO promoter has a large repeating sequence <ol type="A"><li> PCR temperature that I used was too high (too specific causing reverse primer to bind to the wrong part)</ol> </ol> <li>Redid PCR for pBad (AK) and pA1LacO (AK, KB) </ul>
 
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<br>
 
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R0051
 
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<ul><li>Received and diluted R0051_Rev_B primer </ul>
 
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<br>
 
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L3S2P21, SrpR
 
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<ul><li>Made frozen stocks from the confirmed colonies</ul> </tr>
 
</table>
</table>

Latest revision as of 21:57, 17 October 2014



Fusion Proteins

Why Fusion Proteins?

As described here, our main goal this summer was to come up with an efficient workflow to design, build and test large genetic devices. To demonstrate the efficacy of our workflow, we started designed and started building a priority encoder. To facilitate measurement of each component, we added the fluorescent fusion proteins to the priority encoder design. Since we lacked a lot of the internal repressor genes that we needed, we decided to test well known proteins available in our lab (tetR, lacI, and araC) with a GFP fusion protein before using this linker sequence for all fusions.


Priority encoder with fusion GFP shown linked to repressor proteins (CDS1-5)


In order to test the individual transcriptional units and the regulatory arcs associated with them, we needed the output for the individual parts of the device to be fluorescent. One way to do this is by using the bicistronic design shown below that mimics operons seen in natural bacterial systems.
FP

Bicistronic design that could be used as an alternative to fusion proteins


A peculiar effect for these types of designs has been reported in the literature. Specifically, when ribosomes bind to the genes sequentially, the ribosome that binds at the 5' end of gene 1 can interrupt the attachment of a ribosome at the 5' end of gene 2, thus blocking the next ribosome from binding to the mRNA and translating the gene. So, the genes further down a transcript are expressed less than the genes upstream [1].



The image above is Figure 4 from Lim et al., 2011 [1]. Excerpt from Lim N H et al. (2011): "We found that CFP and YFP expression at the first position in the operons was higher than at the third position for each time point. The protein concentration at each time point was normalized by the final concentration to determine their relative expression (R). R is independent of protein production and depends only on the protein degradation rate and any delay in the induction (SI Materials and Methods). When R was calculated, it was the same for positions 1 and 3 at each time point (Fig. 4 D and E). Therefore, protein degradation and any delay after induction are the same at both positions, indicating the differences in expression must be due to greater protein production in the more proximal position of the operons."


In summary, when genes are placed in this operon strategy in synthetic systems, the first gene always expresses higher amounts of protein than the second or third genes [1]. Since these constructs are designed to measure protein degradation rate directly, these types of designs are inefficient. This problem can be solved by fusing the regulator protein with the fluorescent protein, as only one ribosome will then be required to translate the entire sequence, eliminating this problem.

Another way to measure function by fluorescence, using consecutive transcriptional units
FP


Because it takes a minimum of 3 days to build these types of devices using MoClo these types of designs result in the expenditure of more time and resources as compared to building single transcriptional units with fusion proteins. Any design involving just one transcriptional unit instead of the above construct will making cloning faster and more cost-effective.

Fusion Proteins are fused to regulator proteins to allow us to measure degradation rate directly. They reduce order effect seen with the bicistronic design and are cheaper to build, compared to cloning multiple TUs.
FP



Design and Assembly


Gel_8-31
Design strategy for building the fusion proteins. Two PCR products (top lines) with C and I or I and D fusion sites flanking the 5' and 3' ends are cloned into a destination vector to form a cohesive fusion protein containing the repressor protein fused with a green fluorescent protein.


To make fusion proteins, we used the Modular Cloning method .

First, we added a new MoClo fusion site (I - TCTA) to the genes (at the end of repressors and before the reporter proteins). The designed primer sequences can be accessed on the Data Collected page.

Then, we used Phusion Polymerase Chain reaction on the basic MoClo Level 0 parts using primers designed based on the fusion sites. We ended up with repressors with TCTAGA sequence at their ends and reporter proteins with the same sequence at the start. These can be treated as standard Level 0 parts which can then be assembled and tested using MoClo.

As discussed above, the end goal of building fusion proteins is to use them in the Priority Encoders with the new repressors proteins we designed. However, we wanted to test the effect of fusing proteins on regulatory proteins using this amino acid linker. Thus, we proceed to design primers for the regulators tetR, araC and for the reporters, GFP and YFP.


Testing


The following Level 2 constructs were assembled using MoClo -
* All transcriptional units have BCD2 as the 5' UTR and B0015 as the terminator


It is important that the fusion proteins made aren’t drastically inferior to the individual function of the repressor or the fusion proteins. All constructs made were to compare with those above. Simply put, all 6 Level 2s below were used a controls.



Experimental Results can be found in the Data Collected page. Detailed progress on the construction of fusion proteins can be found in the Fusion Proteins notebook.


References

[1] Lim N H, Lee Y, Hussein R (2011) "Fundamental relationship between operon organization and gene expression" , PNAS Vol. 108 No. 26, doi: 10.1073/pnas.1105692108







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