Team:UCSF/Project/Circuit/Design

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<font face="arial" size = "5"><b><center>Decision-Making Circuit</font></b> </center> <br>
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<font face="calibri" size = "5"><b><center>CRISPR Decision-Making Circuit</font></b> </center> <br> </div>
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<FONT COLOR="#008000">GOAL: To design a CRISPRi system with tiered responses that can be easily scaled to deploy multiple circuits within the same cell </FONT COLOR="#008000"></font></center>
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Building upon our CRISPR conjugation project, we began to think about what types of alterations we could confer to cells using the CRISPRi system. The unique capabilities of the CRISPR system allow for the design of a circuit that can achieve decision-making ability. Many synthetic circuits have been created using multiple repressors as their switch. In our circuit design <FONT COLOR="#008000"><b>we utilize guideRNAs (gRNAs) in lieu of repressors, which will allow for a highly scalable design. </b></FONT COLOR="#008000"><br>
Building upon our CRISPR conjugation project, we began to think about what types of alterations we could confer to cells using the CRISPRi system. The unique capabilities of the CRISPR system allow for the design of a circuit that can achieve decision-making ability. Many synthetic circuits have been created using multiple repressors as their switch. In our circuit design <FONT COLOR="#008000"><b>we utilize guideRNAs (gRNAs) in lieu of repressors, which will allow for a highly scalable design. </b></FONT COLOR="#008000"><br>
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<br>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 whether a high or low amount of chemical signal (inducer) is present, the cells would produce either RFP or GFP. The graph below shows our desired output based on inducer concentration. </div>
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<br>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 whether a high or low amount of chemical signal (inducer) is present, the cells would produce either RFP or GFP. The graph below is a model we created that shows our desired output based on inducer concentration. </div>
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<FONT COLOR="#008000">Promoter Sensitivity:</font> To specify our outputs we want a promoter that responds to a low amount of inducer and a promoter that responds to a high amount of inducer. </font>
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So why would we want a circuit to be transferred to a specific organism? Well our digestive trait is home to almost 1000 different species that have shown to directly affect our health and well-being. To improve and maintain healthy living it would be useful to have the ability to change the microbial community. For example, if a large of amount of a certain sugar was present in your gut ("signal #1") you might want to slow the growth of a certain bacteria to prevent a harmful outcome. In another scenario ("signal #2") it might be useful to increase the growth of other specific bacteria in your gut. </font>
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In our synthetic circuit, a chemical signal will start the production of a fluorescent protein and a gRNA. The gRNA will then form a complex with dCAS9, which is on a separate plasmid, and block the production of the opposite fluorescent protein. Only one fluorescent protein should be produced as our output. There are two scenarios that our circuit is capable of producing.</font>
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<FONT COLOR="#008000">CRISPRi Circuit Design:</font> In our synthetic circuit, a chemical signal will start the production of a fluorescent protein and a gRNA. The gRNA will then form a complex with dCAS9, which is on a separate plasmid, and block the production of the opposite fluorescent protein. Only one fluorescent protein should be produced as our output. There are two scenarios that our circuit is capable of producing.</font>
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  In scenario 1, 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-gRNA complex will then repress the RFP (left panel).  In scenario 2 the inverse follows the same principle. If suddenly the chemical signal increases to a high amount, RFP and gRNA to GFP will be produced. The gRNA-dCas9 complex will then repress GFP expression (right panel).</font>
  In scenario 1, 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-gRNA complex will then repress the RFP (left panel).  In scenario 2 the inverse follows the same principle. If suddenly the chemical signal increases to a high amount, RFP and gRNA to GFP will be produced. The gRNA-dCas9 complex will then repress GFP expression (right panel).</font>
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<br><FONT COLOR="#008000"><u>Design Requirements: </FONT COLOR="#008000"></u><br>
<br><FONT COLOR="#008000"><u>Design Requirements: </FONT COLOR="#008000"></u><br>
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<br><FONT COLOR="#008000"><u>Using CRISPR to Create Scalable Circuits: </u></FONT COLOR="#008000"></b>
<br><FONT COLOR="#008000"><u>Using CRISPR to Create Scalable Circuits: </u></FONT COLOR="#008000"></b>
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Latest revision as of 00:11, 28 October 2013

CRISPR Decision-Making Circuit


GOAL: To design a CRISPRi system with tiered responses that can be easily scaled to deploy multiple circuits within the same cell

Building upon our CRISPR conjugation project, we began to think about what types of alterations we could confer to cells using the CRISPRi system. The unique capabilities of the CRISPR system allow for the design of a circuit that can achieve decision-making ability. 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 whether a high or low amount of chemical signal (inducer) is present, the cells would produce either RFP or GFP. The graph below is a model we created that shows our desired output based on inducer concentration.

Promoter Sensitivity: To specify our outputs we want a promoter that responds to a low amount of inducer and a promoter that responds to a high amount of inducer.
So why would we want a circuit to be transferred to a specific organism? Well our digestive trait is home to almost 1000 different species that have shown to directly affect our health and well-being. To improve and maintain healthy living it would be useful to have the ability to change the microbial community. For example, if a large of amount of a certain sugar was present in your gut ("signal #1") you might want to slow the growth of a certain bacteria to prevent a harmful outcome. In another scenario ("signal #2") it might be useful to increase the growth of other specific bacteria in your gut.
CRISPRi Circuit Design: In our synthetic circuit, a chemical signal will start the production of a fluorescent protein and a gRNA. The gRNA will then form a complex with dCAS9, which is on a separate plasmid, and block the production of the opposite fluorescent protein. Only one fluorescent protein should be produced as our output. There are two scenarios that our circuit is capable of producing.


In scenario 1, 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-gRNA complex will then repress the RFP (left panel). In scenario 2 the inverse follows the same principle. If suddenly the chemical signal increases to a high amount, RFP and gRNA to GFP will be produced. The gRNA-dCas9 complex will then repress GFP expression (right panel).


Design Requirements:

In order for this circuit to properly function, we had to address two main challenges:

1) identifying or constructing promoters that were differentially responsive to both high and low levels of an inducer

2) ensuring that the fluorescent proteins and gRNAs were produced in the same amount under the same promoter.

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. We created these promoters by altering the location and number of repressor binding sites in the promoter region.

To address the second issue, we made strategic design choices and utilized an RNA-cutting enzyme called Csy4 in order to equivalently express both the fluorescent protein and guideRNA for each part of the circuit. Both the protein and gRNA are behind the same promoter and linked together with a sequence coding a Csy4 cut site. After transcription, the RNA product is cleaved to make both mRNA for the fluorescent protein and the gRNA. To see more of our design strategies for the guideRNAs and using Csy4, please refer to our parts submitted to the registry.

Using CRISPR to Create Scalable Circuits:

A novel feature of our synthetic circuit are the infinite designs that stem from using gRNA’s rather than repressors. These gRNA’s allow for high specificity to DNA sequences, are easily manufactured, and allow for numerous decision making circuits. We can create multiple plasmids featuring these gRNA’s and insert these plasmids, as well as a plasmid with dCAS9, into an organism. From there these gRNA’s will combine with dCAS9 only when the appropriate chemical signal starts transcription of these gRNA’s. In addition to Plasmid A, we have started constructing Plasmid B which will feature pigments rather than fluorescent proteins.