Difference between revisions of "Team:Calgary/Description"

 
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     <title>Team:Calgary - 2018.igem.org/Description</title>
 
     <title>Team:Calgary - 2018.igem.org/Description</title>
 
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     <div class="container maincontent">
 
     <div class="container maincontent">
 
         <h1>OUR PROJECT</h1>
 
         <h1>OUR PROJECT</h1>
      <hr>
+
        <hr>
 +
        <p>
 +
            This year, iGEM Calgary 2018 sought to address some of the key issues affecting targeted gene
 +
            integration: accuracy of desired insertions, maximum size of recombinant DNA, and expression of
 +
            integrated DNA after integration with the host genome. To this extent, Calgary developed three main systems
 +
            in order to construct a cell line which could facilitate large, precise gene insertions which are
 +
            protected from transcriptional silencing and methylation. These three systems were:
 +
        </p>
 +
   
 +
        <ul>
 +
            <li> A CRISPR/Cas9 system, to introduce a recombination target site into the host genome </li>
 +
            <li> A FlpO/Beta resolvase system, to swap desired sequences into the genome at the recombination target
 +
                site and lock them in </li>
 +
            <li> A Chromatin Modifying Elements system, to stop transcriptional silencing and promoter methylation, as
 +
                well as reduce gene crosstalk </li>
 +
        </ul>
 +
        <br>
 +
      <a href="https://2018.igem.org/Team:Calgary/Gene_Integration_Diagram"><p><center> Click here for the full gene integration diagram </center></p></a>
 +
      <br> 
 
       <p>
 
       <p>
                    This year, iGEM uCalgary 2018 sought to address some of the key dilemmas affecting targeted gene integration: accuracy of desired insertions, the maximum size of recombinant DNA, and the expression of integrated DNA once it is within a host chromosome. To this extent, uCalgary developed three main systems in order to construct a cell line which could facilitate large, precise gene insertions which were then protected from transcriptional silencing and methylation upon insertion. These three systems were:
+
            Keep reading below for a breakdown of each of our three project segments!
                </p>
+
        </p>
<br>
+
     
<ul>
+
          
<li> A CRISPR/Cas9 system, to introduce a recombination target site into the host genome </li>
+
<li> A FlpO/Beta resolvase system, to swap desired sequences into the genome at the recombination target site and lock them in </li>
+
<li> A Chromatin Modifying Elements system, to stop transcriptional silencing and promoter methylation, as well as reduce gene crosstalk </li>
+
</ul>
+
<br>
+
  <p>
+
                    Keep reading below for a breakdown of each of our three project segments!
+
                </p>
+
         <img class="info-img" src="https://static.igem.org/mediawiki/2018/7/7f/T--Calgary--SampleImage.png">
+
 
+
      <hr>
+
  
 
         <br>
 
         <br>
 
         <div class="row">
 
         <div class="row">
 
             <div class="col-lg-5 info">
 
             <div class="col-lg-5 info">
                 <img style="width: 100%" src="https://static.igem.org/mediawiki/2018/7/7f/T--Calgary--SampleImage.png">
+
                 <img style="width: 100%" src="https://static.igem.org/mediawiki/2018/3/31/T--Calgary--CRISPR_Description_Image.png">
 
             </div>
 
             </div>
 
             <div class="col-lg-7 info">
 
             <div class="col-lg-7 info">
 +
             
 
                 <h3>
 
                 <h3>
 
                     CRISPR
 
                     CRISPR
                 </h3>
+
                 </h3>  
 
                 <h5>
 
                 <h5>
                  Inserting a landing pad into the genome to enable recombination
+
                    Inserting a landing pad into the genome to enable recombination
 
                 </h5>
 
                 </h5>
                 <p> CRISPR/Cas9 is a mechanism which induces targeted breaks into DNA, allowing the insertion of foreign DNA sequences into the break site. This method was selected for its targeted insertion properties to knock-in a Flp recognition target (FRT) site into the genome, opening the door to recombination in later steps. The FRT site can be thought of as a target, marking out a site in the genome for precision targeting by recombinase in the following stage. While the maximum knock-in size of CRISPR/Cas9 insertion is limited, the small size of our FRT was not predicted to cause any errors.
+
                 <p> CRISPR/Cas9 induces targeted breaks into DNA, allowing for the insertion of
 +
                    foreign DNA sequences into the break site. This method was selected for its targeted insertion
 +
                    ability to knock-in a Flp recognition target (FRT) site into the genome, opening the door to
 +
                    recombination in later steps. Our target insert is called Six/FRT. The Six/FRT site can be thought of as a target, marking out a site in the
 +
                    genome for precision targeting by recombinase in the following stage. While the maximum knock-in
 +
                    size of CRISPR/Cas9 insertion is limited, the small size of our Six/FRT site is not predicted to cause any
 +
                    errors.
 
                 </p>
 
                 </p>
                 <a href="https://2018.igem.org/Team:Calgary/CRISPR"><button type="button" class="btn btn-outline-dark">Read more</button></a>
+
                 <a href="https://2018.igem.org/Team:Calgary/CRISPR"><button type="button" class="btn btn-outline-dark">Read
 +
                        more</button></a>
 
             </div>
 
             </div>
 
         </div>
 
         </div>
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                     Integrating our desired genes at the landing pad
 
                     Integrating our desired genes at the landing pad
 
                 </h5>
 
                 </h5>
                 <p>
+
                 <p>  
                     After CRISPR has placed the FRT site into the genome, recombination can begin. FlpO recombinase is an enzyme which causes the exchange of two pieces of DNA, as long as both contain the same FRT site. Thus, by providing recombinant DNA containing the same FRT sequence as that which was inserted into the genome using CRISPR, FlpO will integrate the recombinant DNA into the genome. Our FlpO recombination system also involves a second recombination protein known as Beta resolvase. Following the initial recombination mediated by FlpO, Beta performs a second recombination which removes many of the junk sequences contained on the recombinant plasmid, as well as its FRT site. Not only does this clean up the final insert, but it prevents the insert from being removed by FlpO down the road. If the CRISPR stage of the project is thought of as placing a target in the genome, the recombinase stage is firing DNA at the target to be integrated in.
+
                     After CRISPR places the FRT site into the genome, recombination can begin. Recombination is the component of our project which physically inserts desired genes into the genome. While CRISPR can only reliably insert genes of a few kilobases, recombination can insert genes of hundreds of kilobases without issue. FlpO recombinase is
 +
                    an enzyme that causes the exchange of two pieces of DNA that both contain the same FRT
 +
                    site. Recombinant DNA containing the same FRT site as the one inserted into the genome, using CRISPR, will allow
 +
                  FlpO to
 +
                  integrate the recombinant DNA into the genome. A second recombination protein known as Beta resolvase is also used.
 +
                    Following the initial FlpO mediated recombination, Beta performs a second recombination event that
 +
                    removes undesirable sequences on the recombinant plasmid, as well as its FRT site.
 +
                    This clean up of the final insert prevents the insert from being removed by FlpO.
 +
 
 
                 </p>
 
                 </p>
                 <a href="https://2018.igem.org/Team:Calgary/FLP-Beta"><button type="button" class="btn btn-outline-dark">Read more</button></a>
+
                 <a href="https://2018.igem.org/Team:Calgary/FLP-Beta"><button type="button" class="btn btn-outline-dark">Read
 +
                        more</button></a>
 
             </div>
 
             </div>
 
             <div class="col-lg-5 info">
 
             <div class="col-lg-5 info">
                 <img style="transform: scaleX(-1); width: 100%" src="https://static.igem.org/mediawiki/2018/7/7f/T--Calgary--SampleImage.png">
+
                 <img style="width: 100%" src="https://static.igem.org/mediawiki/2018/3/32/T--Calgary--FLP-Beta_Description_Image.png">
 
             </div>
 
             </div>
 
         </div>
 
         </div>
      <hr>
+
        <hr>
      <div class="row">
+
        <div class="row">
 
             <div class="col-lg-5 info">
 
             <div class="col-lg-5 info">
 
                 <img style="width: 100%" src="https://static.igem.org/mediawiki/2018/9/94/T--Calgary--CMELandingPage.png">
 
                 <img style="width: 100%" src="https://static.igem.org/mediawiki/2018/9/94/T--Calgary--CMELandingPage.png">
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             <div class="col-lg-7 info">
 
             <div class="col-lg-7 info">
 
                 <h3>
 
                 <h3>
                     Chromatin Modifying Elements
+
                     Chromatin-Modifying Elements
 
                 </h3>
 
                 </h3>
 
                 <h5>
 
                 <h5>
 
                     Maintenance of integrated genes via minimization of gene silencing and neighbourhood effects
 
                     Maintenance of integrated genes via minimization of gene silencing and neighbourhood effects
 
                 </h5>
 
                 </h5>
                 <p>Gene inserts are at risk of being rendered ineffective even after successful integration into the genome, as the spread of heterochromatin and DNA methylation can cause gene silencing. Furthermore, regulatory elements within both the insert and genome near the locus of integration may interact bidirectionally, leading to changes in gene expression known as neighbourhood effects. Chromatin modifying elements (CMEs) can help to generate an isolated, protected pocket within the genome, thereby assuring stable and sustained expression of integrated genes within eukaryotic systems.
+
                 <p>Gene inserts are at risk of being rendered ineffective even after successful integration into the
                 
+
                    genome, as the spread of heterochromatin and DNA methylation can cause gene silencing. Furthermore,
 +
                    regulatory elements within both the insert and genome near the locus of integration may interact
 +
                    bidirectionally, leading to changes in gene expression known as neighbourhood effects.  
 +
                    Chromatin-modifying elements (CMEs) can help to generate an isolated, protected pocket within the genome,
 +
                    thereby assuring stable and sustained expression of integrated genes within eukaryotic systems.
 +
 
 
                 </p>
 
                 </p>
                 <a href="https://2018.igem.org/Team:Calgary/Chromatin_Modifying_Elements"><button type="button" class="btn btn-outline-dark">Read more</button></a>
+
                 <a href="https://2018.igem.org/Team:Calgary/Chromatin_Modifying_Elements"><button type="button" class="btn btn-outline-dark">Read
 +
                        more</button></a>
 
             </div>
 
             </div>
 
         </div>
 
         </div>
 
         <hr>
 
         <hr>
 
         <div class="row">
 
         <div class="row">
             <div class="col-lg-6 info">
+
          <div class="col-lg-4 info">
 +
                <h3>
 +
                  Parts
 +
                </h3>
 +
                <p>
 +
                    We designed a toolkit for targeted gene integration and expression maintenance in eukaryotic chassis.
 +
                  Parts include chromatin-modifying elements as well as the mCherry-BGH reporter gene with our improved CMV promoter.
 +
                  The parts have restriction sites for directional cloning into a Multiple Cloning Site (MCS) flanked by distinct FRT (FLP recombinase recognition target) sites.
 +
           
 +
                </p>
 +
                <a href="https://2018.igem.org/Team:Calgary/Parts"><button type="button" class="btn btn-outline-dark">Read
 +
                        more</button></a>
 +
            </div>
 +
             <div class="col-lg-4 info">
 
                 <h3>
 
                 <h3>
 
                     Microfluidics
 
                     Microfluidics
 
                 </h3>
 
                 </h3>
 
                 <p>
 
                 <p>
                     Lorem ipsum dolor sit amet consectetur adipisicing elit. Assumenda nihil recusandae ea suscipit blanditiis! Ut adipisci rem,
+
                     Another major hurdle that gene therapies have to overcome is the complexities of scaled-out
                    quisquam sed fugit libero voluptatum! Ratione vitae ipsum magnam nobis molestias, omnis hic.
+
                  production. To approach this problem, we worked towards developing components of a
 +
                microfluidic system that could enable large scale, end-to-end manufacture of autologous
 +
                  gene-therapies. Our Droplet Formation Module is designed for high throughput cell
 +
                  encapsulation, and the production of isogenic cell cultures.
 +
 
 
                 </p>
 
                 </p>
              <a href="https://2018.igem.org/Team:Calgary/Microfluidics"><button type="button" class="btn btn-outline-dark">Read more</button></a>
+
                <a href="https://2018.igem.org/Team:Calgary/Applied_Design"><button type="button" class="btn btn-outline-dark">Read
 +
                        more</button></a>
 
             </div>
 
             </div>
             <div class="col-lg-6 info">
+
             <div class="col-lg-4 info">
 
                 <h3>
 
                 <h3>
 
                     Software
 
                     Software
 
                 </h3>
 
                 </h3>
                 <p>Each year, iGEM teams develop software in conjunction with their research.  
+
                 <p>Each year, iGEM teams develop software in conjunction with their research.
However, it is difficult to efficiently access these tools due to the sheer volume of wiki content.
+
                    However, it is difficult to efficiently access these tools due to the sheer volume of wiki content.
Thus, we created an online database called SARA, the Software Aggregating Research Assistant,  
+
                    Thus, we created an online database called SARA, the Software Aggregating Research Assistant,
which organizes software tools created by iGEM teams and allows for the simplified searching.
+
                    which organizes software tools created by iGEM teams and allows for the simplified searching.
SARA also provides the opportunity for old software to be updated to stay current,
+
                   
and decreases the likelihood that teams will create redundant software.
+
 
                 </p>
 
                 </p>
              <a href="https://2018.igem.org/Team:Calgary/Software"><button type="button" class="btn btn-outline-dark">Read more</button></a>
+
                <a href="https://2018.igem.org/Team:Calgary/Software"><button type="button" class="btn btn-outline-dark">Read
 +
                        more</button></a>
 
             </div>
 
             </div>
 
         </div>
 
         </div>
 
     </div>
 
     </div>
 
</body>
 
</body>
 +
 
</html>
 
</html>

Latest revision as of 01:38, 18 October 2018

Team:Calgary - 2018.igem.org/Description

OUR PROJECT

This year, iGEM Calgary 2018 sought to address some of the key issues affecting targeted gene integration: accuracy of desired insertions, maximum size of recombinant DNA, and expression of integrated DNA after integration with the host genome. To this extent, Calgary developed three main systems in order to construct a cell line which could facilitate large, precise gene insertions which are protected from transcriptional silencing and methylation. These three systems were:

  • A CRISPR/Cas9 system, to introduce a recombination target site into the host genome
  • A FlpO/Beta resolvase system, to swap desired sequences into the genome at the recombination target site and lock them in
  • A Chromatin Modifying Elements system, to stop transcriptional silencing and promoter methylation, as well as reduce gene crosstalk

Click here for the full gene integration diagram


Keep reading below for a breakdown of each of our three project segments!


CRISPR

Inserting a landing pad into the genome to enable recombination

CRISPR/Cas9 induces targeted breaks into DNA, allowing for the insertion of foreign DNA sequences into the break site. This method was selected for its targeted insertion ability to knock-in a Flp recognition target (FRT) site into the genome, opening the door to recombination in later steps. Our target insert is called Six/FRT. The Six/FRT site can be thought of as a target, marking out a site in the genome for precision targeting by recombinase in the following stage. While the maximum knock-in size of CRISPR/Cas9 insertion is limited, the small size of our Six/FRT site is not predicted to cause any errors.

FLP Recombinase-Beta Resolvase

Integrating our desired genes at the landing pad

After CRISPR places the FRT site into the genome, recombination can begin. Recombination is the component of our project which physically inserts desired genes into the genome. While CRISPR can only reliably insert genes of a few kilobases, recombination can insert genes of hundreds of kilobases without issue. FlpO recombinase is an enzyme that causes the exchange of two pieces of DNA that both contain the same FRT site. Recombinant DNA containing the same FRT site as the one inserted into the genome, using CRISPR, will allow FlpO to integrate the recombinant DNA into the genome. A second recombination protein known as Beta resolvase is also used. Following the initial FlpO mediated recombination, Beta performs a second recombination event that removes undesirable sequences on the recombinant plasmid, as well as its FRT site. This clean up of the final insert prevents the insert from being removed by FlpO.

Chromatin-Modifying Elements

Maintenance of integrated genes via minimization of gene silencing and neighbourhood effects

Gene inserts are at risk of being rendered ineffective even after successful integration into the genome, as the spread of heterochromatin and DNA methylation can cause gene silencing. Furthermore, regulatory elements within both the insert and genome near the locus of integration may interact bidirectionally, leading to changes in gene expression known as neighbourhood effects. Chromatin-modifying elements (CMEs) can help to generate an isolated, protected pocket within the genome, thereby assuring stable and sustained expression of integrated genes within eukaryotic systems.

Parts

We designed a toolkit for targeted gene integration and expression maintenance in eukaryotic chassis. Parts include chromatin-modifying elements as well as the mCherry-BGH reporter gene with our improved CMV promoter. The parts have restriction sites for directional cloning into a Multiple Cloning Site (MCS) flanked by distinct FRT (FLP recombinase recognition target) sites.

Microfluidics

Another major hurdle that gene therapies have to overcome is the complexities of scaled-out production. To approach this problem, we worked towards developing components of a microfluidic system that could enable large scale, end-to-end manufacture of autologous gene-therapies. Our Droplet Formation Module is designed for high throughput cell encapsulation, and the production of isogenic cell cultures.

Software

Each year, iGEM teams develop software in conjunction with their research. However, it is difficult to efficiently access these tools due to the sheer volume of wiki content. Thus, we created an online database called SARA, the Software Aggregating Research Assistant, which organizes software tools created by iGEM teams and allows for the simplified searching.