Difference between revisions of "Team:BostonU/Design"

 
(74 intermediate revisions by 4 users not shown)
Line 2: Line 2:
 
<html>
 
<html>
 
<style>
 
<style>
 +
 +
body {
 +
min-width:1000px;}
  
 
#button {
 
#button {
Line 9: Line 12:
 
top:53vh;
 
top:53vh;
 
right:6vw;
 
right:6vw;
background-color:#0071A7;
 
 
border-color:#0071A7;
 
border-color:#0071A7;
 
border-radius:50%;
 
border-radius:50%;
 
border-style:solid;
 
border-style:solid;
font-size:125%;
+
font-size:150%;
 
color:white;
 
color:white;
 
text-align:center;
 
text-align:center;
Line 26: Line 28:
 
color:#0071A7;
 
color:#0071A7;
 
text-align:center;
 
text-align:center;
font-size:175%;
+
font-size:150%;
 
}
 
}
  
Line 35: Line 37:
 
top:53vh;
 
top:53vh;
 
left:4vw;
 
left:4vw;
background-color:#0071A7;
 
 
border-color:#0071A7;
 
border-color:#0071A7;
 
border-radius:50%;
 
border-radius:50%;
 
border-style:solid;
 
border-style:solid;
 
font-size:150%;
 
font-size:150%;
color:white;
+
background-color:white;
 
text-align:center;
 
text-align:center;
 
}
 
}
Line 53: Line 54:
 
text-align:center;
 
text-align:center;
 
font-size:175%;
 
font-size:175%;
 +
}
 +
 +
#button:hover, #buttonback:hover {
 +
transform:scale(1.2);
 +
}
 +
 +
 +
.thebuttons {
 +
display:inline-block;
 +
border:none;
 +
height:50px;
 +
width:12.4vw;
 +
background-color:white;
 +
color:#0071A7;
 +
border:solid #0071A7;
 +
border-radius:35px;
 +
}
 +
 +
.thebuttons:hover {
 +
background-color:#0071A7;
 +
color:white;
 +
border-color:#0071A7;
 +
transform:scale(1.3)
 +
}
 +
 +
#container {
 +
width:80%;
 +
background-color:white;
 +
z-index:50;
 +
padding:2vw 0vw 1vw 0vw;
 +
}
 +
 +
.cont {
 +
position:absolute;
 +
width:80%;
 +
}
 +
 +
#contthree, #conttwo {
 +
display:none;
 
}
 
}
  
 
</style>
 
</style>
  
</body>
+
<body>
 +
<div id = "buttonback">
 +
<a href="https://2016.igem.org/Team:BostonU/Abstract_and_Motivation"><img style = "width:5vw" src = "https://static.igem.org/mediawiki/2016/a/a8/T--BostonU--blueback.png"></a>
 +
</div>
  
<div id = "buttonone">
+
<div id = "buttononeback">
 
<br>
 
<br>
Experimental Results
+
Motivation
 
</div>
 
</div>
 +
 +
<div id = "buttonone" style = "font-size:175%;">
 +
<br>
 +
Proof of Concept
 +
</div>
 +
  
 
<div id = "button">
 
<div id = "button">
<div style = "margin:3.75vh 0vh 0vh 0vh;">
+
<a href="https://2016.igem.org/Team:BostonU/Proof"><img style = "width:5vw" src = "https://static.igem.org/mediawiki/2016/f/ff/T--BostonU--bluefor.png"></a>
<a href="https://2016.igem.org/Team:BostonU/Proof" style = "text-align:center; font-size:200%; color:white;">>></a>
+
 
</div>
 
</div>
 +
 +
 +
<div style = "width:80%; margin:0 auto;">
 +
 +
<div id = "design" style = "font-size:300%; padding:75px 50px 3px 50px; text-align:center; color:#0071A7;">Design</div>
 +
<br><center><hr style= "width:60%; height: 3px; background-color:#0071A7"></center><br>
 +
 +
<p style = "font-size:150%; padding:5px 150px 5px 150px; color:#0071A7;">Seeing that the problem we wanted to address had a natural duality to it (digital and analog), we decided to develop Gemini. This system's name refers to the twins Castor and Pollux in Greek mythology. What attracted us most to this name was the fact that while each of the twins was a hero in their own regard, they were far more powerful together. While digital and analog promoter networks are individually impressive, the ability to control both networks through one system is the ultimate goal. To obtain our system of well characterized mammalian digital and analog promoters, we divided our research into three technical aims:</p>
 +
 +
<div style = "width:60%; position:relative; left:20%;">
 +
<ul>
 +
<li style = "font-size:150%; color:#0071A7; padding: 10px 0px;">Development of a digital promoter library</li>
 +
<li style = "font-size:150%; color:#0071A7; padding: 10px 0px;">Expansion into an analog promoter library</li>
 +
<li style = "font-size:150%; color:#0071A7; padding: 10px 0px;">Integration of our parts into genetic circuit contexts</li>
 +
</ul>
 
</div>
 
</div>
  
<div id = "buttononeback">
+
<p style = "font-size:150%; padding:5px 150px 20px 150px; color:#0071A7;"> To complete these goals we made use of three classes of plasmids: a constitutive guide RNA expressing vector, a guide RNA operator reporter vector driven by a minimal CMV, and a constitutive dCas9-VPR complex. dCas9, like its sister system Cas9, works by using CRISPR’s targeting system and a guide RNA to find a specific sequence. Where they differ is in how the proteins interact with the genome. While Cas9 has a nuclease that can cleave the DNA, dCas9’s nuclease is catalytically inhibited. This results in a protein that can be localized to a region of DNA but cannot physically modify it. When fused, however, to the VPR, a strong activating complex of transcription regulators, the dCas9 becomes an activating complex that can drive the production of a gene of interest. </p>
 +
 
 +
<center><img src = "https://static.igem.org/mediawiki/2016/3/37/T--BostonU--ProjectDescription_dCas9_explanation.png" style = "padding:0px 0px 50px 0px; width:50%;"></center>
 +
 
 +
<p style = "font-size:150%; padding:5px 150px 20px 150px; color:#0071A7;"> In our work, those genes of interest were fluorescent proteins. The benefit of using fluorescent proteins is that they are easily assayable. The two assaying techniques used throughout our research were flow cytometry and fluorescent microscopy (the latter courtesy of Worcester Polytechnic Institute’s iGEM Team).
 +
</p>
 +
 
 +
<br><center><hr style= "width:60%; height: 3px; background-color:#0071A7"></center><br>
 
<br>
 
<br>
Description
 
</div>
 
  
<div id = "buttonback">
+
<center>
<div style = "margin:3.75vh 0vh 0vh 0vh;">
+
<div id = "container">
<a href="https://2016.igem.org/Team:BostonU/Description" style = "text-align:center; font-size:200%; color:white;"><<</a>
+
<center>
 +
<div class = "thebuttons" id = "parentone">
 +
<p style = "text-align:center; font-size:200%; padding:0px 0px 0px 0px;">Digital</p>
 
</div>
 
</div>
 +
<div class = "thebuttons" id = "parenttwo" style="margin:0vw 12vw 0vw 12vw;">
 +
<p style = "text-align:center; font-size:200%; padding:0px 0px 0px 0px;">Analog</p>
 
</div>
 
</div>
 +
<div class = "thebuttons" id = "parentthree">
 +
<p style = "text-align:center; font-size:200%; padding:0px 0px 0px 0px;">Circuits</p>
 +
</div>
 +
</div>
 +
</center>
 +
<br>
 +
<center><div style= "color:#bd162a; font-size:150%; width:100%;">Click on each button to read how we designed our system to meet each aim.</div></center><br>
  
 +
<div>
 +
<div id = "contone" class = "cont">
 +
<br><br><center style = "font-size:225%; color:#0071A7;">Aim 1:</center><br>
 +
<center style = "font-size:200%; color:#0071A7;">Developing a Digital Library</center>
  
<div style = "width:80%; margin:0 auto;">
+
<p style = "font-size:150%; padding:25px 150px 20px 150px; color:#0071A7;">We began our work by developing the digital promoter library. Before moving into experimentation, we made several design considerations. First, our system had to be orthogonal to the human genome. We did not want to activate off target genes in the human genome. Although not immediate, we envision our work having long reaching applications in therapeutics and immunotherapy, and thus we wanted to begin optimizing our system accordingly. </p>
  
<div id = "design" style = "font-size:300%; padding:75px 50px 25px 50px; text-align:center; color:#0071A7;">Design</div>
 
  
<br><center><hr style= "width:60%; height: 3px; background-color:#0071A7"></center><br>
+
<p style = "font-size:150%; padding:5px 150px 20px 150px; color:#0071A7;">Our next design goal was to demonstrate low basal activity when necessary components were absent, and high expression activity when all components were present. This behavior needed to be maintained across multiple genes of interest.</p>
  
<br><br><center style = "font-size:225%; color:#0071A7;">Phase 1:</center><br>
+
<p style = "font-size:150%; padding:5px 150px 20px 150px; color:#0071A7;">Finally, we needed to motivate that components of our system were mutually orthogonal. We wanted to make sure that there was no cross talk that would generate undesired outputs under the wrong conditions.</p>
<center style = "font-size:200%; color:#0071A7;">Gene Activation Component</center>
+
  
<p style = "font-size:150%; padding:25px 150px 20px 150px; color:#0071A7;">In order to make genes activate in response to certain signals, our system first needed a method to activate genes in general. We chose CRISPR/dCAS9-VPR as an activator. We chose  dCAS9 due to its ease of use and its ability to target specific DNA sequences. dCAS9-VPR targets specific sequences by binding to specialized RNA. Part of this RNA (gRNA) contains 20 base pairs that will act as a guide, guiding the dCAS9 to the complimentary 20 base pairs found upstream of a gene one wishes target. This can be seen in the info-graphic below:</p>
 
  
 +
<center><img src = "https://static.igem.org/mediawiki/2016/3/38/T--BostonU--SingleOp-DesignPage.png" style = "padding:0px 0px 50px 0px;; width:50%;"></center>
 +
</div>
 +
</div>
  
<center><img src = "https://static.igem.org/mediawiki/2016/3/37/T--BostonU--ProjectDescription_dCas9_explanation.png" style = "padding:0px 0px 50px 0px; width:80%;"></center>
+
<div>
 +
<div id = "conttwo" class = "cont">
 +
<br><br><br><center style = "font-size:225%; color:#0071A7;">Aim 2:</center><br>
 +
<center style = "font-size:200%; color:#0071A7;">Expanding to an Analog Library</center>
  
<br><br><br><center style = "font-size:225%; color:#0071A7;">Phase 2:</center><br>
+
<p style = "font-size:150%; padding:25px 150px 20px 150px; color:#0071A7;">After establishing the digital library, we moved to expand into our full analog library. We did this using two main hypotheses: the multimerization of binding sites would increase expression and the mutation of binding sites would decrease expression. In the case of the former, the multimerization would recruit a greater number of dCas9-VPR’s upstream of the minimal promoter. In the case of the former, mutations should decrease the binding affinity of the dCas9-VPR. In addition to those parameters, we also increased the distance between binding sites on the multimerized plasmids in another attempt to increase expression.
<center style = "font-size:200%; color:#0071A7;">Analog Expression System</center>
+
Once the library was expanded out into the analog domain, we begun integrating our library into genetic logic circuits. The motivation behind doing this was is once again two fold (catching a theme here… wink… wink...Gemini). First, genetic circuits represent one of synthetic biology’s most powerful tools. Circuits have become integral in our search for better immunotherapy procedures. Also, genetic circuits grant a scientist a greater capacity to mimic naturally cellular behavior for synthetic operations. </p>
  
<p style = "font-size:150%; padding:25px 150px 20px 150px; color:#0071A7;">Once we were able to activate genes, we then expanded our system to activate genes to different levels, thereby achieving the graded analog expression level that we desired from our system. To accomplish this, we multermerized the 20 base pair target sequence, placing multiple copies
+
</p>
of the target sequence upstream of the gene. By varying the number of copies, we were able to create a gradient of expression. The more target sequences we added, the more the gene was activated. This is illustrated in the image below:</p>
+
  
 
<center><img src = "https://static.igem.org/mediawiki/2016/d/d9/T--BostonU--multimerization.png" style = "padding:0px 0px 50px 0px;; width:80%;"></center>
 
<center><img src = "https://static.igem.org/mediawiki/2016/d/d9/T--BostonU--multimerization.png" style = "padding:0px 0px 50px 0px;; width:80%;"></center>
 +
</div>
 +
</div>
  
<br><br><br><center style = "font-size:225%; color:#0071A7;">Phase 3:</center><br>
+
<div>
<center style = "font-size:200%; color:#0071A7;">Signal Integration Components</center>
+
<div id = "contthree" class = "cont">
 +
<br><br><br><center style = "font-size:225%; color:#0071A7;">Aim 3:</center><br>
 +
<center style = "font-size:200%; color:#0071A7;">Integrating our Library into Genetic Circuit Contexts</center>
  
<p style = "font-size:150%; padding:25px 150px 20px 150px; color:#0071A7;">Finally, once we completed phase one and two, we expanded our system once again. Using recombinase based circuits, we were able to control which gRNA was produced. gRNA 1 corresponded to a reporter with one target sequence, and gRNA 2 corresponded to the same gene but with two of the target sequence. Releasing gRNA 1 turned the gene on to a small degree, and gRNA two turned it on to a large degree. We then incorporated two more gRNA's flanked by two more recombinase recognition sites, allowing the system to have a smoother, four point analog expression level increase. Since the recombinase circuits that release the different gRNA is completely digital, (the recombinases are activated by the digital prescience or absence of a signal such as a hormone and once activated, are extremely efficient) the system was a merger of digital signals giving rise to different levels of analog gene expression, as stated in our goal. A diagram of these circuits can be found below:</p>
+
<p style = "font-size:150%; padding:25px 150px 20px 150px; color:#0071A7;">There were two distinct class of circuits we aimed to develop. The first is a combinatorial digital logic circuit. These circuits are defined by their binary outputs as well as their ignorance towards input order. In a biological context, a binary output would be the expression or absence of expression of a gene of interest. The second type of circuit is the combinatorial analog logic circuit. These circuit are defined by their analog output of a single gene as well as their ignorance towards input order. In a biological context, this behavior can be modelled by increasing the expression of gene as one shifts from a given logical state to another logical state.
 +
</p>
 +
 
 +
<p style = "font-size:150%; padding:5px 150px 20px 150px; color:#0071A7;">Each design parameter mentioned above required its own distinct set of experiments to prove our system could achieve them. Ultimately, we were able to prove that Gemini could fulfill all design parameters. The evidence of this can be seen under our Proof of Concept.
 +
</p>
  
 
<center><img src = "https://static.igem.org/mediawiki/2016/0/06/T--BostonU--RealRecombinase.png" style = "padding:0px 0px 50px 0px;; width:80%;"></center>
 
<center><img src = "https://static.igem.org/mediawiki/2016/0/06/T--BostonU--RealRecombinase.png" style = "padding:0px 0px 50px 0px;; width:80%;"></center>
 
</div>
 
</div>
 
+
</div>
 +
</div>
 +
<div style = "width:100%; height:900px;" id = "spacer"></div>
  
 
</body>
 
</body>
 +
 +
<script type="text/javascript">
 +
$(document).ready(
 +
    function(){
 +
  $("#parentone").click(function () {
 +
            $("#spacer").animate({'height':'900px'}, 0);
 +
            $("#contone").show(200);
 +
            $('#conttwo').hide(200);
 +
            $('#contthree').hide(200);
 +
        });
 +
 +
    });
 +
</script>
 +
 +
  <script type="text/javascript">
 +
$(document).ready(
 +
    function(){
 +
  $("#parenttwo").click(function () {
 +
            $("#spacer").animate({'height':'1300px'}, 0);
 +
            $("#conttwo").show(200);
 +
            $('#contthree').hide(200);
 +
            $('#contone').hide(200);
 +
        });
 +
 +
    });
 +
</script>
 +
 +
  <script type="text/javascript">
 +
$(document).ready(
 +
    function(){
 +
  $("#parentthree").click(function () {
 +
            $("#spacer").animate({'height':'1600px'}, 0);
 +
            $("#contthree").show(200);
 +
            $('#conttwo').hide(200);
 +
            $('#contone').hide(200);
 +
        });
 +
 +
    });
 +
</script>
 +
 
</html>
 
</html>

Latest revision as of 21:53, 19 October 2016


Motivation

Proof of Concept
Design



Seeing that the problem we wanted to address had a natural duality to it (digital and analog), we decided to develop Gemini. This system's name refers to the twins Castor and Pollux in Greek mythology. What attracted us most to this name was the fact that while each of the twins was a hero in their own regard, they were far more powerful together. While digital and analog promoter networks are individually impressive, the ability to control both networks through one system is the ultimate goal. To obtain our system of well characterized mammalian digital and analog promoters, we divided our research into three technical aims:

  • Development of a digital promoter library
  • Expansion into an analog promoter library
  • Integration of our parts into genetic circuit contexts

To complete these goals we made use of three classes of plasmids: a constitutive guide RNA expressing vector, a guide RNA operator reporter vector driven by a minimal CMV, and a constitutive dCas9-VPR complex. dCas9, like its sister system Cas9, works by using CRISPR’s targeting system and a guide RNA to find a specific sequence. Where they differ is in how the proteins interact with the genome. While Cas9 has a nuclease that can cleave the DNA, dCas9’s nuclease is catalytically inhibited. This results in a protein that can be localized to a region of DNA but cannot physically modify it. When fused, however, to the VPR, a strong activating complex of transcription regulators, the dCas9 becomes an activating complex that can drive the production of a gene of interest.

In our work, those genes of interest were fluorescent proteins. The benefit of using fluorescent proteins is that they are easily assayable. The two assaying techniques used throughout our research were flow cytometry and fluorescent microscopy (the latter courtesy of Worcester Polytechnic Institute’s iGEM Team).





Digital

Analog

Circuits


Click on each button to read how we designed our system to meet each aim.



Aim 1:

Developing a Digital Library

We began our work by developing the digital promoter library. Before moving into experimentation, we made several design considerations. First, our system had to be orthogonal to the human genome. We did not want to activate off target genes in the human genome. Although not immediate, we envision our work having long reaching applications in therapeutics and immunotherapy, and thus we wanted to begin optimizing our system accordingly.

Our next design goal was to demonstrate low basal activity when necessary components were absent, and high expression activity when all components were present. This behavior needed to be maintained across multiple genes of interest.

Finally, we needed to motivate that components of our system were mutually orthogonal. We wanted to make sure that there was no cross talk that would generate undesired outputs under the wrong conditions.




Aim 2:

Expanding to an Analog Library

After establishing the digital library, we moved to expand into our full analog library. We did this using two main hypotheses: the multimerization of binding sites would increase expression and the mutation of binding sites would decrease expression. In the case of the former, the multimerization would recruit a greater number of dCas9-VPR’s upstream of the minimal promoter. In the case of the former, mutations should decrease the binding affinity of the dCas9-VPR. In addition to those parameters, we also increased the distance between binding sites on the multimerized plasmids in another attempt to increase expression. Once the library was expanded out into the analog domain, we begun integrating our library into genetic logic circuits. The motivation behind doing this was is once again two fold (catching a theme here… wink… wink...Gemini). First, genetic circuits represent one of synthetic biology’s most powerful tools. Circuits have become integral in our search for better immunotherapy procedures. Also, genetic circuits grant a scientist a greater capacity to mimic naturally cellular behavior for synthetic operations.




Aim 3:

Integrating our Library into Genetic Circuit Contexts

There were two distinct class of circuits we aimed to develop. The first is a combinatorial digital logic circuit. These circuits are defined by their binary outputs as well as their ignorance towards input order. In a biological context, a binary output would be the expression or absence of expression of a gene of interest. The second type of circuit is the combinatorial analog logic circuit. These circuit are defined by their analog output of a single gene as well as their ignorance towards input order. In a biological context, this behavior can be modelled by increasing the expression of gene as one shifts from a given logical state to another logical state.

Each design parameter mentioned above required its own distinct set of experiments to prove our system could achieve them. Ultimately, we were able to prove that Gemini could fulfill all design parameters. The evidence of this can be seen under our Proof of Concept.