Team:uOttawa/project

From 2014.igem.org

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                 <h2>Our designs</h2>
                 <h2>Our designs</h2>
                 <p>In order to implement this network, A and B appear to have to work as both an activator (to activate themselves) and a repressor (of the other state). Thus, we had to design a system where A and B can function as both. In brief, activator binding sites were placed 10bp away from the TATA box, causing steric hindrance of the TATA binding protein. This is explained in more depth, along with accompanied data in the <b>Promoters</b> section.</p>
                 <p>In order to implement this network, A and B appear to have to work as both an activator (to activate themselves) and a repressor (of the other state). Thus, we had to design a system where A and B can function as both. In brief, activator binding sites were placed 10bp away from the TATA box, causing steric hindrance of the TATA binding protein. This is explained in more depth, along with accompanied data in the <b>Promoters</b> section.</p>
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                 <p>For our system to work, two controllable transcription activators were selected, GEV and rTTA. GEV is a fusion protein of the gal4 DNA binding domain (G), a human estrogen receptor subunit (E), and VP16 (V), a viral trans-activator. To function, two GEV molecules must dimerize with a beta-estradiol molecule, localizing the GEV to the nucleus and allowing for activation. As such, how much GEV is active can be controlled via estradiol concentration. Similarly, rTTA is the tetR binding domain with a VP16 trans-activator, which requires anhydrotetracycline (aTc) in order to function. Thus, we can control how much of each trans-activator is active at any given time by varying the concentration of these small molecules. This is important for our design, as it allows us to test the functionality of our promoters, and examine our system from various 'start points' or states.</p>
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                 <p>For our system to work, two controllable transcription activators were selected, GEV and rtTA. GEV is a fusion protein of the gal4 DNA binding domain (G), a human estrogen receptor subunit (E), and VP16 (V), a viral trans-activator. To function, two GEV molecules must dimerize with a beta-estradiol molecule, localizing the GEV to the nucleus and allowing for activation. As such, how much GEV is active can be controlled via estradiol concentration. Similarly, rtTA is the tetR binding domain with a VP16 trans-activator, which requires anhydrotetracycline (aTc) in order to function. Thus, we can control how much of each trans-activator is active at any given time by varying the concentration of these small molecules. This is important for our design, as it allows us to test the functionality of our promoters, and examine our system from various 'start points' or states.</p>
                 <p>To create this system, we engineered two designs, both of which are based upon this core interaction:</p>
                 <p>To create this system, we engineered two designs, both of which are based upon this core interaction:</p>
                 <figure>
                 <figure>
                     <img src="https://static.igem.org/mediawiki/2014/1/10/Uo2014-wet6.png" alt="">
                     <img src="https://static.igem.org/mediawiki/2014/1/10/Uo2014-wet6.png" alt="">
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                     <p>Tri-stable involved portion of our network. Activation arrows are shown in green, and repression arrows in red. GEV and rTTA are transcriptional activators. pGALtx is a promoter activated by GEV and repressed by rTTA. pTREgx is a promoter activated by rTTA and repressed by GEV. tPGK1 is a transcriptional terminator.</p>
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                     <p>Tri-stable involved portion of our network. Activation arrows are shown in green, and repression arrows in red. GEV and rtTA are transcriptional activators. pGALtx is a promoter activated by GEV and repressed by rtTA. pTREgx is a promoter activated by rTTA and repressed by GEV. tPGK1 is a transcriptional terminator.</p>
                 </figure>
                 </figure>
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                 <p>Thus, in order to create this system, we had to design novel promoters to drive GEVE and rTTA, along with promoters to drive reports with similar expression levels. Their design, construction, and testing are described in the Promoters section</p>
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                 <p>Thus, in order to create this system, we had to design novel promoters to drive GEVE and rtTA, along with promoters to drive reports with similar expression levels. Their design, construction, and testing are described in the Promoters section</p>
                 <p>We then created two designs with this core.</p>
                 <p>We then created two designs with this core.</p>
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   <figure>
   <figure>
                     <img src="https://static.igem.org/mediawiki/2014/d/d3/PTRE_4_sites.png"">
                     <img src="https://static.igem.org/mediawiki/2014/d/d3/PTRE_4_sites.png"">
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                     <p>Characterization of pTRE via dual drug induction. pTRE has 4 activating tetO sites and not repressing sites, so increasing aTC increases activation. Estradiol has no effect beyond auto-fluorescence.  </p>
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                     <p>Characterization of pTRE via dual drug induction. pTRE has 4 activating tetO sites and not repressing sites, so increasing aTc increases activation. Estradiol has no effect beyond auto-fluorescence.  </p>
                 </figure>
                 </figure>
</figure>
</figure>
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   <figure>
   <figure>
                     <img src="https://static.igem.org/mediawiki/2014/3/3e/Ptre%282%29.png"">
                     <img src="https://static.igem.org/mediawiki/2014/3/3e/Ptre%282%29.png"">
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                     <p>(LEFT) The pTre promoter shows no activation upon addition of aTc (anhydrotetracycline)in cells expressing the activator, rtTA (reverse tetracycline-controlled transactivator), with the weak constitutive promoter, pMRP7. (RIGHT) In cells expressing rtTA with the strong constitutive promoter, pADH1, there is weak activation with increasing aTC concentration. Increasing concentrations of estradiol was added to compare its effects on activation with the other cognate promoters made. No increase in activation is seen with increasing estradiol due to the absence of GAL4 UAS's in this promoter. </p>
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                     <p>(LEFT) The pTre promoter shows no activation upon addition of aTc (anhydrotetracycline)in cells expressing the activator, rtTA (reverse tetracycline-controlled transactivator), with the weak constitutive promoter, pMRP7. (RIGHT) In cells expressing rtTA with the strong constitutive promoter, pADH1, there is weak activation with increasing aTc concentration. Increasing concentrations of estradiol was added to compare its effects on activation with the other cognate promoters made. No increase in activation is seen with increasing estradiol due to the absence of GAL4 UAS's in this promoter. </p>
                 </figure>
                 </figure>
             </div>
             </div>

Revision as of 02:57, 18 October 2014

The Project

Engineering Fate: Cellular decision making and the Tri-Stable switch

Throughout our lives, individual cells make vital decisions that directly affect us. From deciding how to develop, when stem cells differentiation into various cell types, to when to die, as mutated or erroneous cells undergo apoptosis.

We decided to examine how cells make those decisions.

It was hypothesized that a unique tri-stable switch controlled stem cell differentiation, with the three states being an arbitrary state A, B and AB, where both states coexists stably (AB).

Design adapted from Sui Huang, 2009.

For instance, if state A produced blue marbles and B red marbles, the three states would look like this:

Now instead of marbles, lets image A and B as cell types like liver cells and heart cells, and the AB state the undifferentiated state! This of course is a massive over simplification, as A and B in nature are likely transcription factors. Yet, it helps to visualize this switch as such.

(TOP) Human Blastocyst from early development. (LEFT) Human liver cells. (RIGHT) Human heart cells.

This is a primary example of cellular decision making. The 2014 uOttwa iGEM team chose to build this decision making pathway. To do so we created a novel form of gene regulation using activators as repressors.

Potential Applications

Why build such a system? Understanding how this genetic network works and being able to model its behaviour may shed light on how exactly stem cells differentiate. More importantly, it will allow us to engineer cells that implement this synthetic decision-making pathway, and use it in an application such as logic gates.

Alternatively, we may use this system as a unique cellular detector. If A and B are reporters driven by promoters that are sensitive to small molecules such as phosphorous and nitrogen, these cells can monitor the balance between those two. The balance between those two is an important indicator of human pollution, which is indicated by high levels of phosphorous. If one spikes higher than the other, the cell will enter either the A or B state, which would be indicated by their respective reporters. If both spike, it will remain in the AB and indicate an equilibrium.