Team:UCSF/Project/Circuit/Design
From 2013.igem.org
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src="https://static.igem.org/mediawiki/2013/f/fe/Circuit.jpg"> </center><br></div> | src="https://static.igem.org/mediawiki/2013/f/fe/Circuit.jpg"> </center><br></div> | ||
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<br><b><FONT COLOR="#008000">Design Requirements: </FONT COLOR="#008000"></b>In order for this circuit to properly execute, we had to address two main challenges: <b><FONT COLOR="#008000"> 1) </font></b> ensuring that the fluorescent proteins and gRNAs were produced in the same amount under the same promoter, and | <br><b><FONT COLOR="#008000">Design Requirements: </FONT COLOR="#008000"></b>In order for this circuit to properly execute, we had to address two main challenges: <b><FONT COLOR="#008000"> 1) </font></b> ensuring that the fluorescent proteins and gRNAs were produced in the same amount under the same promoter, and | ||
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<br>A large portion of our project was extensively testing and modeling promoter activity for use in the circuit, as well as designing a new lactose-reponsive promoter to sense changing levels of inducer. | <br>A large portion of our project was extensively testing and modeling promoter activity for use in the circuit, as well as designing a new lactose-reponsive promoter to sense changing levels of inducer. | ||
- | <br>To address the second issue, we made strategic design choices and utilized an RNA-cutting enzyme called Csy4. {DESCRIPTION HERE} To see more of our design strategies for the guideRNAs and using Csy4, please refer to our parts submitted to the registry. | + | <br>To address the second issue, we made strategic design choices and utilized an RNA-cutting enzyme called Csy4. {DESCRIPTION HERE} To see more of our design strategies for the guideRNAs and using Csy4, please refer to our parts submitted to the registry. {LINK TO REGISTRY} |
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- | <br><b><FONT COLOR="#008000">ASSUMPTIONS: </FONT COLOR="#008000"></b>While creating the model for our system, we made a few assumptions about some of the aspects of the model that would be impossible for us to know within a few months. We made four assumptions: <b><FONT COLOR="#008000"> 1) </font></b> protein degradation is linear; | + | <br><b>THIS PART IS FROM MODELING////WILL BE ALTERED<FONT COLOR="#008000">ASSUMPTIONS: </FONT COLOR="#008000"></b>While creating the model for our system, we made a few assumptions about some of the aspects of the model that would be impossible for us to know within a few months. We made four assumptions: <b><FONT COLOR="#008000"> 1) </font></b> protein degradation is linear; |
<b><FONT COLOR="#008000">2) </font></b>protein production is based on a hill function and also depends on inducer concentration; | <b><FONT COLOR="#008000">2) </font></b>protein production is based on a hill function and also depends on inducer concentration; | ||
<b><FONT COLOR="#008000">3) </font></b> repression is governed by a hill function and depends on the concentration of dCas9 and gRNA complex; and | <b><FONT COLOR="#008000">3) </font></b> repression is governed by a hill function and depends on the concentration of dCas9 and gRNA complex; and |
Revision as of 18:40, 23 September 2013
Building upon our CRISPR conjugation project, we began to think about what types of alterations we could confer to cells using the CRISPRi system. One alteration we had in mind was a decision making ability that can be achieved with a circuit design. Many synthetic circuits have been created using multiple repressors as their switch. In our circuit design we utilize guideRNAs (gRNAs) in lieu of repressors which will allow for a highly scalable design.
Our synthetic circuit has been engineered to give cells a decision making ability between differential outputs and will utilize CRISPRi as a switching mechanism between these outputs. Depending on a high or low amount of chemical signal, our cells can produce either RFP or GFP. If there was a low amount of chemical signal, GFP and a gRNA to RFP will be produced. The gRNA will then combine with dCas9, which has been incorporated on a separate plasmid. The dCas9 will then repress the RFP. The inverse follows the same principle; if suddenly the chemical signal increases, RFP and gRNA to GFP will be produced. The gRNA will combine with dCas9 and repress GFP expression.
Design Requirements: In order for this circuit to properly execute, we had to address two main challenges: 1) ensuring that the fluorescent proteins and gRNAs were produced in the same amount under the same promoter, and 2) identifying (or constructing) promoters that were differentially responsive to both high and low levels of an inducer.
A large portion of our project was extensively testing and modeling promoter activity for use in the circuit, as well as designing a new lactose-reponsive promoter to sense changing levels of inducer.
To address the second issue, we made strategic design choices and utilized an RNA-cutting enzyme called Csy4. {DESCRIPTION HERE} To see more of our design strategies for the guideRNAs and using Csy4, please refer to our parts submitted to the registry. {LINK TO REGISTRY}
THIS PART IS FROM MODELING////WILL BE ALTEREDASSUMPTIONS: While creating the model for our system, we made a few assumptions about some of the aspects of the model that would be impossible for us to know within a few months. We made four assumptions: 1) protein degradation is linear; 2) protein production is based on a hill function and also depends on inducer concentration; 3) repression is governed by a hill function and depends on the concentration of dCas9 and gRNA complex; and 4) that the binding and unbinding of dCas9 and gRNA complex happens much faster than the production/degradation of gRNA and fluorescent proteins (the complex is at Quasi Steady State).