Team:Alberta/Protocols
From 2013.igem.org
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<p class="content-title">Protocols</p> | <p class="content-title">Protocols</p> | ||
+ | </div> | ||
+ | <a class="anchor" id="Parts"></a> | ||
+ | <div class="block"> | ||
+ | <h2>The Parts</h2> | ||
+ | <p>The 6 genes that were required to assemble various routes were obtained by PCR from plasmids kindly provided by Genomikon Inc. Each gene (AmpR, KanR, ClrR, GFP, RFP and aCP) exist as self contained cassettes that are flanked by BsaI sites. Parts were then generated according to the schematic shown below:</p> | ||
+ | <img src="/wiki/images/c/c5/Making_parts_678x586.png" align="middle" style="width:100%;"> | ||
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<a class="anchor" id="Build"></a> | <a class="anchor" id="Build"></a> | ||
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<p>Our plasmid assembly system relies upon the achievements of previous Team Alberta iGEM entries, 2009’s BioBytes and 2010’s Genomikon assembly methods. This process begins with origins of replication anchored at one end to magnetic beads in a suspension within a reaction microfuge tube. The anchored strands have a single, free-floating sticky end, onto which successive genes are ligated. Once the new gene has been ligated on, we use a magnet to hold the beads (along with the anchored DNA) inside the reaction tube, while washing away the rest of the reaction, including the enzyme, buffers, and any non-ligated DNA that remains. The beads are then resuspended in a new reaction mixture, containing the next ligation step.</p> | <p>Our plasmid assembly system relies upon the achievements of previous Team Alberta iGEM entries, 2009’s BioBytes and 2010’s Genomikon assembly methods. This process begins with origins of replication anchored at one end to magnetic beads in a suspension within a reaction microfuge tube. The anchored strands have a single, free-floating sticky end, onto which successive genes are ligated. Once the new gene has been ligated on, we use a magnet to hold the beads (along with the anchored DNA) inside the reaction tube, while washing away the rest of the reaction, including the enzyme, buffers, and any non-ligated DNA that remains. The beads are then resuspended in a new reaction mixture, containing the next ligation step.</p> | ||
<img src="/wiki/images/b/b4/2013Alberta-Poster2.jpg" align="middle" style="width:100%;"> | <img src="/wiki/images/b/b4/2013Alberta-Poster2.jpg" align="middle" style="width:100%;"> | ||
+ | <p>Once all of the genes have been ligated, a tail-piece that complements the original bead-anchor DNA sequence is added, so that the finished product can be unbound from the beads and will close upon itself to form the circular plasmid. In this fashion, a four-gene, roughly 5000-base-pair plasmid is assembled in as little as an afternoon, cheaply and easily.</p> | ||
</div> | </div> | ||
</div> | </div> |
Revision as of 02:11, 29 October 2013
Protocols
The Parts
The 6 genes that were required to assemble various routes were obtained by PCR from plasmids kindly provided by Genomikon Inc. Each gene (AmpR, KanR, ClrR, GFP, RFP and aCP) exist as self contained cassettes that are flanked by BsaI sites. Parts were then generated according to the schematic shown below:
Building the Plasmids
Our plasmid assembly system relies upon the achievements of previous Team Alberta iGEM entries, 2009’s BioBytes and 2010’s Genomikon assembly methods. This process begins with origins of replication anchored at one end to magnetic beads in a suspension within a reaction microfuge tube. The anchored strands have a single, free-floating sticky end, onto which successive genes are ligated. Once the new gene has been ligated on, we use a magnet to hold the beads (along with the anchored DNA) inside the reaction tube, while washing away the rest of the reaction, including the enzyme, buffers, and any non-ligated DNA that remains. The beads are then resuspended in a new reaction mixture, containing the next ligation step.
Once all of the genes have been ligated, a tail-piece that complements the original bead-anchor DNA sequence is added, so that the finished product can be unbound from the beads and will close upon itself to form the circular plasmid. In this fashion, a four-gene, roughly 5000-base-pair plasmid is assembled in as little as an afternoon, cheaply and easily.