Difference between revisions of "Team:BostonU/Proof"

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<p style = "font-size:260%; color:#0071A7; text-align:center;">Phase 1 Results</p>
 
<p style = "font-size:260%; color:#0071A7; text-align:center;">Phase 1 Results</p>
 
<center><hr style= "width:550px; height: 4px; background-color:#0071A7"></center><br>
 
<center><hr style= "width:550px; height: 4px; background-color:#0071A7"></center><br>
<p style = "text-indent:70px; font-size:150%; padding:25px 150px 50px 150px; color:#0071A7;">The goal of phase 1 to establish a consistent method of gene activation through dCAS9-VPR. Using MIT's CRISPR  optimization tool, we generated 20 sequences to be used as our gRNA and target site. The dCAS9-VPR complex, the target sequence and reporter gene, and the gRNA expression vectors were constructed and transfected into HEK293 cells. Another set of transfections took place simultaneously with the same materials minus the gRNA expression vector as a negative control. The fold increase between the basal level of expression from the control and the activated level of expression was then recorded. The results can be found below.</p>
+
<p style = "text-indent:70px; font-size:150%; padding:25px 150px 50px 150px; color:#0071A7;">The goal of phase 1 to establish a consistent method of gene activation through dCAS9-VPR and well characterize the components of our system. Using MIT's CRISPR  optimization tool, we generated 20 sequences to be used as our gRNA and target site. The dCAS9-VPR complex, the target sequence and reporter gene, and the gRNA expression vectors were constructed and transfected into HEK293 cells. Another set of transfections took place simultaneously with the same materials minus the gRNA expression vector as a negative control. The fold increase between the basal level of expression from the control and the activated level of expression was then recorded. The results can be found below.</p>
  
 
<center><img src = "https://static.igem.org/mediawiki/2016/a/aa/T--BostonU--InitialData.jpg" style = "width:80%"></center>
 
<center><img src = "https://static.igem.org/mediawiki/2016/a/aa/T--BostonU--InitialData.jpg" style = "width:80%"></center>
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<p style = "font-size:260%; color:#0071A7; text-align:center;">Phase 2 Results</p>
 
<p style = "font-size:260%; color:#0071A7; text-align:center;">Phase 2 Results</p>
 
<center><hr style= "width:550px; height: 4px; background-color:#0071A7"></center><br>
 
<center><hr style= "width:550px; height: 4px; background-color:#0071A7"></center><br>
<p style = "text-indent:70px; font-size:150%; padding:25px 150px 50px 150px; color:#0071A7;">Words will go here that explain all the experiments we conducted to achieve aim one. I don't know what those words will be yet, but hey, I'm just the html guy not the writer guy. I mean, I do enjoy writing, but right now I have other things to work on. I just have to remember to come back and change this part. If I forget, that would bad, but I don't think I will. Here are some extra words to make it seem like this is a different pargraph than the rest when really, it's not. It's just the same thing. But I want to make it look different, so there you go. Let's just add a few more words, and there we go. That should do it. Shoot, this still isn't  enough words. Hold on, here a few more, and a few more. Okay, now I'm out of ideas.</p>
+
<p style = "text-indent:70px; font-size:150%; padding:25px 150px 50px 150px; color:#0071A7;">With our parts of our project well characterized, we began experimenting with achieving a variety of consistent expression levels with our dCAS9-VPR activator. Our first strategy was to attempt multimerizing the target operators, placing two and then three operators up stream of the gene of interest using two of our operators. During this experiment, we also tested the effect of spacing the target operators with a different number of intervening base pairs. We tested with 0, 3, 6, 12, and 24 intervening base pairs. The results of these experiments yielded a predictable, linear correlation between the number of operators and the expression level and the number of base pairs in the intervening sequences. The results can be found below: </p>
 +
 
 +
<center><img src = "https://static.igem.org/mediawiki/2016/2/27/T--BostonU--multi.png" style = "width:80%"></center>
 +
 
 +
 
 +
 
 +
<br>
 +
<p style = "text-indent:70px; font-size:150%; padding:25px 150px 50px 150px; color:#0071A7;">There were some anomalies within this data set. The target operators with 0 and 12 base pair spacing had lower expression than expected. One explanation is that when the operators are at 0 and 12 base pairs apart, they are on the same side of the DNA helix and crowd each other out. Once we eliminated these results, were able to create a smooth progression in expression level across several levels of expression, as seen below.</p>
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 +
<center><img style = "width:80%;" src = "https://static.igem.org/mediawiki/2016/f/fb/T--BostonU--chosen.png"></center>
 +
<br>
 +
<p style = "text-indent:70px; font-size:150%; padding:25px 150px 50px 150px; color:#0071A7;">Finally, we realized that while we could achieve a wide range of high expression levels, it is sometimes favorable to lower expression levels below the standard single operator expression level. In order to accomplish this, we mutated our operators, replacing a base pair at a time. We tested 20 versions of 2 of our operator plasmids. Each version had one of the twenty base pairs in the twenty base pair operator mutated, so that there was a single mismatch between the operator and the guide RNA attached to the dCAS9-VPR system. By changing the location of the single mismatch, we were able to create another smooth curve of changing expression levels, this time lowering expression levels. The expression levels can be found in the graph below.</p>
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<center><img src = "" style = "width:400px; height:400px;"></center>
 
 
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<p style = "font-size:260%; color:#0071A7; text-align:center;">Phase 3 Results</p>
 
<p style = "font-size:260%; color:#0071A7; text-align:center;">Phase 3 Results</p>
 
<center><hr style= "width:550px; height: 4px; background-color:#0071A7"></center><br>
 
<center><hr style= "width:550px; height: 4px; background-color:#0071A7"></center><br>
<p style = "text-indent:70px; font-size:150%; padding:25px 150px 50px 150px; color:#0071A7;">These words have to be a little different, just to show that the words are changing. Everything else from here on in will be identical to phase  though. So without further ado, here's phase 2 again. Words will go here that explain all the experiments we conducted to achieve aim one. I don't know what those words will be yet, but hey, I'm just the html guy not the writer guy. I mean, I do enjoy writing, but right now I have other things to work on. I just have to remember to come back and change this part. If I forget, that would bad, but I don't think I will. Here are some extra words to make it seem like this is a different pargraph than the rest when really, it's not. It's just the same thing. But I want to make it look different, so there you go.</p>
+
<p style = "text-indent:70px; font-size:150%; padding:25px 150px 50px 150px; color:#0071A7;">Now that we could achieve a variety of expression levels, we began integrating our system into recombination based circuitry. The circuit we used could release a different gRNA for every combination of drugs introduced. Before integrating our multimerized plasmids, we first tested the circuit by making each gRNA correspond to a different fluorescent reporter. The data for this experiment can be found below. There were four possible combinations of two drugs, and each combination yielded a relatively high expression of its corresponding fluorescent gene.</p>
 +
 
 +
<center><img src = "https://static.igem.org/mediawiki/2016/2/21/T--BostonU--initialcirc.png" style = "width:80%"></center>
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 +
 
 +
 
 +
<br>
 +
<p style = "text-indent:70px; font-size:150%; padding:25px 150px 50px 150px; color:#0071A7;">Results</p>
 +
 
 +
<center><img style = "width:80%;" src = ""></center>
 +
<br>
 +
<p style = "text-indent:70px; font-size:150%; padding:25px 150px 50px 150px; color:#0071A7;">Results</p>
 +
 
 +
<center><img src = "" style = "width:50%;"></center>
  
<center><img src = "" style = "width:400px; height:400px;"></center>
 
 
</div>
 
</div>
 
<br><br><br><br><br><br><br><br>
 
<br><br><br><br><br><br><br><br>

Revision as of 22:27, 10 September 2016


Project Design
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Phase 1

Phase 2

Phase 3


Phase 1 Results


The goal of phase 1 to establish a consistent method of gene activation through dCAS9-VPR and well characterize the components of our system. Using MIT's CRISPR optimization tool, we generated 20 sequences to be used as our gRNA and target site. The dCAS9-VPR complex, the target sequence and reporter gene, and the gRNA expression vectors were constructed and transfected into HEK293 cells. Another set of transfections took place simultaneously with the same materials minus the gRNA expression vector as a negative control. The fold increase between the basal level of expression from the control and the activated level of expression was then recorded. The results can be found below.


The goal of phase 1 to establish a consistent method of gene activation through dCAS9-VPR. Using MIT's CRISPR optimization tool, we generated 20 sequences to be used as our gRNA and target site. The dCAS9-VPR complex, the target sequence and reporter gene, and the gRNA expression vectors were constructed and transfected into HEK293 cells. Another set of transfections took place simultaneously with the same materials minus the gRNA expression vector as a negative control. The fold increase between the basal level of expression from the control and the activated level of expression was then recorded. The results can be found below. Here are some extra words to make it seem like this is a different paragraph than the rest when really, it's not. It's just the same thing. But I want to make it look different, so there you go. Let's just add a few more words, and there we go. That should do it.


The goal of phase 1 to establish a consistent method of gene activation through dCAS9-VPR. Using MIT's CRISPR optimization tool, we generated 20 sequences to be used as our gRNA and target site. The dCAS9-VPR complex, the target sequence and reporter gene, and the gRNA expression vectors were constructed and transfected into HEK293 cells. Another set of transfections took place simultaneously with the same materials minus the gRNA expression vector as a negative control. The fold increase between the basal level of expression from the control and the activated level of expression was then recorded. The results can be found below.


Phase 2 Results


With our parts of our project well characterized, we began experimenting with achieving a variety of consistent expression levels with our dCAS9-VPR activator. Our first strategy was to attempt multimerizing the target operators, placing two and then three operators up stream of the gene of interest using two of our operators. During this experiment, we also tested the effect of spacing the target operators with a different number of intervening base pairs. We tested with 0, 3, 6, 12, and 24 intervening base pairs. The results of these experiments yielded a predictable, linear correlation between the number of operators and the expression level and the number of base pairs in the intervening sequences. The results can be found below:


There were some anomalies within this data set. The target operators with 0 and 12 base pair spacing had lower expression than expected. One explanation is that when the operators are at 0 and 12 base pairs apart, they are on the same side of the DNA helix and crowd each other out. Once we eliminated these results, were able to create a smooth progression in expression level across several levels of expression, as seen below.


Finally, we realized that while we could achieve a wide range of high expression levels, it is sometimes favorable to lower expression levels below the standard single operator expression level. In order to accomplish this, we mutated our operators, replacing a base pair at a time. We tested 20 versions of 2 of our operator plasmids. Each version had one of the twenty base pairs in the twenty base pair operator mutated, so that there was a single mismatch between the operator and the guide RNA attached to the dCAS9-VPR system. By changing the location of the single mismatch, we were able to create another smooth curve of changing expression levels, this time lowering expression levels. The expression levels can be found in the graph below.


Phase 3 Results


Now that we could achieve a variety of expression levels, we began integrating our system into recombination based circuitry. The circuit we used could release a different gRNA for every combination of drugs introduced. Before integrating our multimerized plasmids, we first tested the circuit by making each gRNA correspond to a different fluorescent reporter. The data for this experiment can be found below. There were four possible combinations of two drugs, and each combination yielded a relatively high expression of its corresponding fluorescent gene.


Results


Results