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<a href="/Team:IIT_Delhi/Circuit_Design">Circuit design and construction</a> | <a href="/Team:IIT_Delhi/Circuit_Design">Circuit design and construction</a> | ||
− | <a href="/Team:IIT_Delhi/Microfluidics">Microfluidics and | + | <a href="/Team:IIT_Delhi/Microfluidics">Microfluidics and Fluorescence</a> |
<a href="/Team:IIT_Delhi/Photobleaching">Photobleaching</a> | <a href="/Team:IIT_Delhi/Photobleaching">Photobleaching</a> | ||
<a href="/Team:IIT_Delhi/Promoter">Promoter strength</a> | <a href="/Team:IIT_Delhi/Promoter">Promoter strength</a> | ||
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− | <h2 class="h2font"> | + | <h2 class="h2font">Project Overview</h2> |
<p> | <p> | ||
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− | <h2 id="pfont"><u id="pfont2">Digital Logic in Synthetic Biology</u><br> | + | <h2 id="pfont"><u id="pfont2">Digital Logic in Synthetic Biology</u><br><br> |
A large chunk of effort in synthetic biology has been aimed at attempting to view genes as parts of a circuit. Thus, a lot of focus has been directed toward creating biological analogues of digital logic gates, such as an AND or a NOT gate, which give a digital 1 or 0 response, depending on the truth table of the gate.<br><br> | A large chunk of effort in synthetic biology has been aimed at attempting to view genes as parts of a circuit. Thus, a lot of focus has been directed toward creating biological analogues of digital logic gates, such as an AND or a NOT gate, which give a digital 1 or 0 response, depending on the truth table of the gate.<br><br> | ||
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However, there is a serious issue in the scale up of these circuits. While that can be attributed to several reasons, one of the major reasons is this simplification under which the systems work. We can see that the output response from the gate is not close to the actual digital “1 or 0” kind that one would ideally want from a logic gate, and in the range that is neither in the ON nor the OFF regime, the response is really graded. <br><br> | However, there is a serious issue in the scale up of these circuits. While that can be attributed to several reasons, one of the major reasons is this simplification under which the systems work. We can see that the output response from the gate is not close to the actual digital “1 or 0” kind that one would ideally want from a logic gate, and in the range that is neither in the ON nor the OFF regime, the response is really graded. <br><br> | ||
− | + | Thus, when a combination of gates is used in conjunction, one could not expect them to remain digital. Just imagine using a 10 input AND gate as shown below, that could possibly be used as an environmental biosensor. If the concentration of a few inputs is in the ON range, while the others are in the middle range, should the device show an ON or an OFF state? It may show neither, as we have seen above, leaving the researcher confused as to how the results must be perceived. <br><br> | |
<img src = "https://static.igem.org/mediawiki/2017/3/39/T--IIT_Delhi--shreya2.png" width="600" height="200"><br> | <img src = "https://static.igem.org/mediawiki/2017/3/39/T--IIT_Delhi--shreya2.png" width="600" height="200"><br> | ||
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</h2> | </h2> | ||
− | <h2 id=" | + | <h2 id="pfont"><u id="pfont2">High Cooperativity Repressors – A Possible Solution</u><br> |
<br>The solution to the problem lies in the cooperativity of the parts that are used as actuators in these digital devices. These are mostly created using repressors or activators, which can repress or activate their respective promoters. Cooperativity is basically the phenomenon where the repressor (or activator) molecules do not act independently of each other, and two or more molecules of the same are needed to first bind to each other, before binding to the promoter that they are to repress. | <br>The solution to the problem lies in the cooperativity of the parts that are used as actuators in these digital devices. These are mostly created using repressors or activators, which can repress or activate their respective promoters. Cooperativity is basically the phenomenon where the repressor (or activator) molecules do not act independently of each other, and two or more molecules of the same are needed to first bind to each other, before binding to the promoter that they are to repress. | ||
<br> <br> | <br> <br> | ||
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<h6>Figure – Variation of output with repressor concentration. As can be seen, the response for n = 1 is the furthest away from a digital response, while as n increases, the output moves from 1 to 0 in a more digital fashion.</h6> | <h6>Figure – Variation of output with repressor concentration. As can be seen, the response for n = 1 is the furthest away from a digital response, while as n increases, the output moves from 1 to 0 in a more digital fashion.</h6> | ||
</h2> | </h2> | ||
− | <h2 id="pfont"><u>The Square Wave Generator</u><br> | + | <h2 id="pfont"><u id="pfont2">The Square Wave Generator</u><br> |
<br>With the goal of searching and employing high cooperativity repressors, we looked at a paper by Voigt et al (Nature Chem Biol. 2013), in which they reported 73 analogs of the TetR repressor, of which 16 of them were found to be perfectly orthogonal to each other. A few of these repressors had really high cooperativities, with the highest n value being 6.1 for the Orf2 repressor. | <br>With the goal of searching and employing high cooperativity repressors, we looked at a paper by Voigt et al (Nature Chem Biol. 2013), in which they reported 73 analogs of the TetR repressor, of which 16 of them were found to be perfectly orthogonal to each other. A few of these repressors had really high cooperativities, with the highest n value being 6.1 for the Orf2 repressor. | ||
<br><br> | <br><br> |
Latest revision as of 22:13, 1 November 2017
Project Overview