Difference between revisions of "Team:NAIT Edmonton/Results"

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  <div class="main_content">
 
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<center>
 
<h2> This page is under construction! Please check back as we are continually updating our Team Wiki </h2>
 
 
 
<h2> pSB1C3 Backbone </h2>
 
 
<p> All parts for iGEM are required to submitted in the pSB1C3 backbone. As such, all of our custom sequences were ligated with this particular backbone. </p><br><br>
 
 
  <input id="tab1" type="radio" name="tabs" checked>
 
  <label for="tab1">General Info</label>
 
   
 
  <input id="tab2" type="radio" name="tabs">
 
  <label for="tab2">Design</label>
 
   
 
  <input id="tab3" type="radio" name="tabs">
 
  <label for="tab3">Experience</label>
 
 
   
 
  <section id="content1">
 
    <p> pSB1C3 is a high copy number plasmid (RFC [10]) carrying chloramphenicol resistance. </p> <br>
 
 
    <p> The replication origin is a pUC19-derived pMB1 (copy number of 100-300 per cell). </p> <br>
 
 
    <p> pSB1C3 has terminators bracketing its MCS which are designed to prevent transcription from *inside* the MCS from reading             
 
        out into the vector. The efficiency of these terminators is known to be < 100%. Ideally we would construct a future set
 
        of terminators for bracketing a MCS that were 100% efficient in terminating both into and out of the MCS region.</p> <br>
 
  </section>
 
   
 
  <section id="content2">
 
 
<h2>Original Sequence</h2>
 
 
<p>In Spring 2011, pSB1C3 was sequenced using several primers. The current sequence reflects the most recent sequencing of pSB1C3 (w/ BBa_J04450, located in SP 4000 Well 2A). However for posterity, we have included the old sequence that was originally specified in the Registry (PSB1C3-Text-Archival-5-4-11.txt) as well as images of the original sequence with markers pointing out the changes made:</p><br>
 
 
<img src="https://static.igem.org/mediawiki/parts/thumb/5/54/PSB1C3-Seq-Archival-5-4-11.png/300px-PSB1C3-Seq-Archival-5-4-11.png"> <br>
 
 
<h2>Design Notes</h2>
 
 
<p>Eliminated ampicillin resistance.</p><br>
 
  
<h2>Subversions</h2>
 
  
<p><b>Freiburg's pSB1C3 varient of 2010</b></p><br>
+
<center><img src="https://static.igem.org/mediawiki/2015/a/a5/NAIT_P1.png"></center>
  
<p>The iGEM team Freiburg created a modified version of the pSB1C3 in which the two restriction sites SspI and PvuII were removed via site directed mutagenesis. These restriction sites and two others that are not present in the pSB1C3 (BamHI and SalI) were used as single cutting restriction sites to replace the loop coding sequences of the Adeno-associated Virus. For this purpose scar-less cloning is necessary, because of the unpredictable consequences on the viral vector performance arising from mutations or insertions. The final capsid gene adheres fully to the RFC_10 standard.</p><br>
+
<p>The sequences that were ordered had a design flaw on them. The restriction sites were not on the correct place and were incompatible with pSB1C3. In order to fix them, we decided to create primers that would insert a point mutation in the restriction sites and, at the same time, add the correct iGEM prefix and suffix to the sequences.</p><br>
  
<p>The sequence and a more detailled description can be found under the BioBrick ID <a style="color:blue;" href="http://parts.igem.org/Part:BBa_K404200">BBa_K404200</a>.</p><br>
+
<p><img src="https://static.igem.org/mediawiki/2015/e/e7/NAIT_p3.png">A gradient PCR was conducted in order to determine the best annealing temperature (Ta) for the primers. It was observed that Ta=61ºC was optimum. A new PCR comprising all our sequences was done and, after using a PCR Purification kit, an agarose gel showed that out of 23 sequences, we were able to purify 18 (see Figure 2). Nonetheless, one of the sequences contained an illegal restriction site within itself and it was discarded.</p><br>
  
<h2>Source</h2>
+
<p>The sequences, now containing an iGEM compatible prefix and suffix, needed a vector and a host organism so as to be expressed. T7 expression systems can produce a high copy of a Protein of Interest (POI), provided that the DNA sequence that encodes for the polypeptide is next to a T7 promoter. With regards to the vector, it was noted that BioBrick K1321338 (BBa_ K1321338), found on the iGEM 2015 Kit Plate #5, contained a T7 promoter and a Ribosome Binding Site. And pertaining the host organism, BL21 (DE3), a T7 E.coli expression strain was chosen as the system to synthesize our POIs</p><br>  
  
<p>This part was derived from pSB1AC3-P1010.</p>
+
<img src="https://static.igem.org/mediawiki/2015/4/43/NAIT_p4.png">
  
 +
<p>After transforming cells with BBa_K1321338, obtaining the plasmid (i.e., pSB1C3 with the BioBrick. Note: pSB1C3 contains a chloramphenicol resistant gene) via a MiniPrep Kit, and confirming its presence by running a sample in an agarose gel, a digestion with SpeI and PstI, and subsequent dephosphorylation was conducted so as to linearize the plasmid and prepare it for ligation to the sequences. Simultaneously, the sequences were digested with XbaI and PstI (see Figure 3).</p>
  
  
  </section>
 
   
 
  <section id="content3">
 
    <p>The pSB1C3 backbone has been made more versatile by turning it into a shuttle vector. By cloning a <i>Staphylococcal</i> selective marker (erythromycin resistance gene) and origin of replication, this part has been improved to be used in both <i>E. coli</i> and <i>Staphylococcal</i> organisms. The <i>Staphylococcal</i> parts have been incorporated into the backbone between the VR and the pMB1 replication origin in pSB1C3. The newly integrated parts have been sequence confirmed and a restriction digest of this part isolated from <i>E. coli</i> shows expected bands:</p><br>
 
  
<img src="https://static.igem.org/mediawiki/parts/8/8d/Shuttle_vector_restriction_digest.png"><br>
+
<img src="https://static.igem.org/mediawiki/2015/6/61/NAIT_p5.png">
  
<p>The shuttle vector was successfully electroporated and maintained in <i>Staphylococcus epidermidis</i> (ATCC 12228) and the newly transformed cell displayed erythromycin resistance. Whether or not the shuttle plasmid confers chloramphenicol resistance due to the <i>E. coli</i> gene is still inconclusive due to the fact that <i>S. epidermidis</i> was shown to have some resistance to chloramphenicol already.</p>
 
  </section>
 
  
 
+
<p>Ligation was performed using T4 DNA Ligase; subsequently, E. coli BL21 (DE3) was transformed with the ligation products and plated in LB + chloramphenicol agar. 34 plates (two per sequence of interest) were left 24 hours at 37ºC to ensure optimum growth of transformed cells. Grown colonies were accounted for and numbered (see Figure 4).</p><br>
</div>
+
  
<!----- SAMPLE PARTS TAB TABLE -----
+
<p>pSB1C3 Forward and Reverse Primers were used to confirm that the colonies actually contained the sequence. A gradient PCR showed that the optimum Ta was 57ºC, so a colony PCR was made following such parameter and an agarose gel was done to verify outcome of the PCR.</p><br>
  
 +
<p>Data showed that, out of three hundred and two colonies, only five contained an insert (see Figure 5). Other colonies contained the plasmid without an insertion. This was concluded because the Forward and Reverse Primers amplify a fragment 339 bp long. The divergent colonies amplified longer fragments and, out of those six, only two had the size that was expected. These were sequences ‘Cys-Thr’ and ‘MLAB’ (see Figure 6, this figure only shows significant gels).</p><br>
  
<input id="tab1" type="radio" name="tabs" checked>
 
  <label for="tab1">General Info</label>
 
   
 
  <input id="tab2" type="radio" name="tabs">
 
  <label for="tab2">Design</label>
 
   
 
  <input id="tab3" type="radio" name="tabs">
 
  <label for="tab3">Experience</label>
 
  
   
+
<p>hese five positive colonies were cultured in 200mL of LB media with chloramphenicol and induced with IPTG to increase protein expression. The cells were pelleted and proteins were isolated using a NiNTA Kit.  
  <section id="content1">
+
The samples were ran in a SDS-PAGE (see Figure 6). Only the sample containing the protein encoded by sequence ‘Cys-Thr’ showed bands. Additionally, the bands were ~19kDa in size, the expected size for this particular protein.
    <p>
+
</p><br>
      Bacon ipsum dolor sit amet beef venison beef ribs kielbasa. Sausage pig leberkas, t-bone sirloin shoulder bresaola. Frankfurter rump porchetta ham. Pork belly prosciutto brisket meatloaf short ribs.
+
    </p> <br>
+
    <p>
+
      Brisket meatball turkey short loin boudin leberkas meatloaf chuck andouille pork loin pastrami spare ribs pancetta rump. Frankfurter corned beef beef tenderloin short loin meatloaf swine ground round venison.
+
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+
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+
   
+
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+
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+
      Bacon ipsum dolor sit amet landjaeger sausage brisket, jerky drumstick fatback boudin ball tip turducken. Pork belly meatball t-bone bresaola tail filet mignon kevin turkey ribeye shank flank doner cow kielbasa shankle. Pig swine chicken hamburger, tenderloin turkey rump ball tip sirloin frankfurter meatloaf boudin brisket ham hock. Hamburger venison brisket tri-tip andouille pork belly ball tip short ribs biltong meatball chuck. Pork chop ribeye tail short ribs, beef hamburger meatball kielbasa rump corned beef porchetta landjaeger flank. Doner rump frankfurter meatball meatloaf, cow kevin pork pork loin venison fatback spare ribs salami beef ribs.
+
    </p> <br>
+
    <p>
+
      Jerky jowl pork chop tongue, kielbasa shank venison. Capicola shank pig ribeye leberkas filet mignon brisket beef kevin tenderloin porchetta. Capicola fatback venison shank kielbasa, drumstick ribeye landjaeger beef kevin tail meatball pastrami prosciutto pancetta. Tail kevin spare ribs ground round ham ham hock brisket shoulder. Corned beef tri-tip leberkas flank sausage ham hock filet mignon beef ribs pancetta turkey.
+
    </p>
+
  </section>
+
   
+
  <section id="content3">
+
    <p>
+
      Bacon ipsum dolor sit amet beef venison beef ribs kielbasa. Sausage pig leberkas, t-bone sirloin shoulder bresaola. Frankfurter rump porchetta ham. Pork belly prosciutto brisket meatloaf short ribs.
+
    </p> <br>
+
    <p>
+
      Brisket meatball turkey short loin boudin leberkas meatloaf chuck andouille pork loin pastrami spare ribs pancetta rump. Frankfurter corned beef beef tenderloin short loin meatloaf swine ground round venison.
+
    </p>
+
  </section>
+
  
  
 +
<p>Preliminary data shows that this engineered protein is able to show a different colouration after silver staining (see Figure 8)</p>
  
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Revision as of 03:34, 19 September 2015

Team NAIT 2015

Parts and Results

The sequences that were ordered had a design flaw on them. The restriction sites were not on the correct place and were incompatible with pSB1C3. In order to fix them, we decided to create primers that would insert a point mutation in the restriction sites and, at the same time, add the correct iGEM prefix and suffix to the sequences.


A gradient PCR was conducted in order to determine the best annealing temperature (Ta) for the primers. It was observed that Ta=61ºC was optimum. A new PCR comprising all our sequences was done and, after using a PCR Purification kit, an agarose gel showed that out of 23 sequences, we were able to purify 18 (see Figure 2). Nonetheless, one of the sequences contained an illegal restriction site within itself and it was discarded.


The sequences, now containing an iGEM compatible prefix and suffix, needed a vector and a host organism so as to be expressed. T7 expression systems can produce a high copy of a Protein of Interest (POI), provided that the DNA sequence that encodes for the polypeptide is next to a T7 promoter. With regards to the vector, it was noted that BioBrick K1321338 (BBa_ K1321338), found on the iGEM 2015 Kit Plate #5, contained a T7 promoter and a Ribosome Binding Site. And pertaining the host organism, BL21 (DE3), a T7 E.coli expression strain was chosen as the system to synthesize our POIs


After transforming cells with BBa_K1321338, obtaining the plasmid (i.e., pSB1C3 with the BioBrick. Note: pSB1C3 contains a chloramphenicol resistant gene) via a MiniPrep Kit, and confirming its presence by running a sample in an agarose gel, a digestion with SpeI and PstI, and subsequent dephosphorylation was conducted so as to linearize the plasmid and prepare it for ligation to the sequences. Simultaneously, the sequences were digested with XbaI and PstI (see Figure 3).

Ligation was performed using T4 DNA Ligase; subsequently, E. coli BL21 (DE3) was transformed with the ligation products and plated in LB + chloramphenicol agar. 34 plates (two per sequence of interest) were left 24 hours at 37ºC to ensure optimum growth of transformed cells. Grown colonies were accounted for and numbered (see Figure 4).


pSB1C3 Forward and Reverse Primers were used to confirm that the colonies actually contained the sequence. A gradient PCR showed that the optimum Ta was 57ºC, so a colony PCR was made following such parameter and an agarose gel was done to verify outcome of the PCR.


Data showed that, out of three hundred and two colonies, only five contained an insert (see Figure 5). Other colonies contained the plasmid without an insertion. This was concluded because the Forward and Reverse Primers amplify a fragment 339 bp long. The divergent colonies amplified longer fragments and, out of those six, only two had the size that was expected. These were sequences ‘Cys-Thr’ and ‘MLAB’ (see Figure 6, this figure only shows significant gels).


hese five positive colonies were cultured in 200mL of LB media with chloramphenicol and induced with IPTG to increase protein expression. The cells were pelleted and proteins were isolated using a NiNTA Kit. The samples were ran in a SDS-PAGE (see Figure 6). Only the sample containing the protein encoded by sequence ‘Cys-Thr’ showed bands. Additionally, the bands were ~19kDa in size, the expected size for this particular protein.


Preliminary data shows that this engineered protein is able to show a different colouration after silver staining (see Figure 8)