Team:UT Dallas/pop3 o design

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For our three population signal propagation mechanism, we created three different strains using E.coli bacteria. These strains used three different quorum sensing molecules acyl homoserine-lactone (AHL), (autoinducer-1) Ai-1, and (autoinducer-2) Ai-2 coupled with yellow, red, and cyan fluorescent proteins to create a visual oscillating effect.<br><br>
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Population 1:<br>
Population 1:<br>
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·      Positive Feedback: The oscillation sequence begins with the synthesis of LsrK. When LsrK binds with AI-2 produced by the third population, it creates a phosphorylated dimer, referred to as “AI-2 +P”, that binds to the PLsrA promoter. This promotes the transcription of both Luxl and the yellow fluorescence protein, YFP. Also, LuxI, when bound with S-adenosylmethionine (SAM), produces AHL.
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The sequence begins with the synthesis of LsrK. When LsrK binds with Ai-2 produced by the third population, it creates a phosphorylated dimer, referred to as “Ai-2 +P”, that binds to the PLsrA promoter. This promotes the transcription of both Luxl and the yellow fluorescence protein, YFP. Also, LuxI, when bound with S-adenosylmethionine (SAM), produces AHL. <br><br>
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·      Negative Feedback: In population 1, LasR is constitutively promoted. When it binds with AI-1, it creates a dimer that, in turn, binds with PLasR and promotes the transcription of araC. AraA then binds with PBad to repress the production of LsrK, AHL and YFP.<br><br>
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Population 2:<br>
Population 2:<br>
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·      Positive Feedback: The second population in the sequence is induced by the AHL produced by Population 1. When AHL is in the presence of the bacteria, it creates a dimer with LuxR that binds to PLuxR. PLuxR then promotes LasI which when bound with SAM produces AI-1. RFP is attached to the end of the LasI gene, so that when LasI is produced, the bacterium also fluoresces red.<br>
 
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·      Negative Feedback: In population 2, LsrK is constitutively promoted. When it binds with AI-2, it creates a dimer, binds with PLsrA and promotes LacI. LacI then binds with PLac to repress the production of LuxR, AI-1 and RFP. This inhibits the red fluorescence with the populations<br><br>
 
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The second population in the sequence is induced by the AHL produced by Population 1. When AHL is in the presence of the bacteria, it creates a dimer with LuxR that binds to PLuxR. PLuxR then promotes LasI which when bound with SAM produces Ai-1. RFP is attached to the end of the LasI gene, so that when LasI is produced, the bacterium also fluoresces red.
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<br><br>
Population 3:<br>
Population 3:<br>
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·      Positive Feedback: The third population in the sequence is induced by the AI-1 molecules produced by Population 2. When AI-1 is in the presence of the bacteria, it creates a dimer with LasR and binds to PLasR. PLasR then promotes LuxS which when bound with SAM produces AI-2. CFP is attached to the end of the LuxS gene, so that when LuxS is produced, the bacterium fluoresces cyan.<br>
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·      Negative Feedback: In Population 3, LuxR is constitutively promoted. When it binds with AHL, it creates a dimer which binds with PLuxR and promotes TetR. TetR then binds with PTetR to repress the production of LasR, LuxS, and CFP.
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The third population in the sequence is induced by the Ai-1 molecules produced by Population 2. When Ai-1 is in the presence of the bacteria, it creates a dimer with LasR and binds to PLasR. PLasR then promotes LuxS which when bound with SAM produces Ai-2. CFP is attached to the end of the LuxS gene, so that when LuxS is produced, the bacterium fluoresces cyan.
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The Perfect Model<br><br>
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Pseudo-population 3<br>
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    This population consists of only a Constitutive promoter and LuxS. LuxS is the gene in Population 2 that produces the quorum sensing molecule Ai-2. This pseudo-population is used in testing whether the output of Population 3 will successfully promoter the production of Ai-2 and the yellow flourescence protein expression level in Population 1.
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Planning and Production<br>
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Biobricks we used to construct our three population system:<br><br>
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BBa_C0080: araC <br> 
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BBa_J23119: Constitutive Promoter <br>
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BBa_C0012: LacI<br>
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BBa_C0078: LasI <br>
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BBa_C0079: LasR  <br>
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BBa_K091002: LsrK  <br>
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BBa_C0061: LuxI  <br>
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BBa_C0062: LuxR <br> 
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BBa_K091109: LuxS<br>
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BBa_I13453: pBad<br>
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BBa_K091159: Pbad-LsrK<br>
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BBa_R0010: pLac<br>
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BBa_R0079: pLasR<br>
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BBa_K117002: pLsrA<br>
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BBa_R0062: pLuxR<br>
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BBa_R0040: pTet <br>
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BBa_B0034: RBS<br>
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BBa_E0422: RBS-CFP-Term-Term<br>
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BBa_K093005: RBS-RFP<br>
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BBa_E0432: RBS-YFP-Term-Term<br>
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BBa_B0015: Term-Term<br> 
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BBa_C0040: TetR<br>
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BBa_I14015: pLasR-TetO<br><br>
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In planning the production of our three population system we decided to take a two phase approach.<br>
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Phase 1: Promotion<br><br>
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        Construct a basic set of populations that each promote the expression of the next. For example, Population 1 promotes Population 2. Populations 2 promotes Population 3.<br>
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        Construct pseudo-populations that only produce the quorum sensing molecules of their respective population counterparts.<br>
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            Pseudo-population 1: Constitutive promoter-LuxI<br>
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            Pseudo-population 2: Constitutive promoter-LasI<br>
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            Pseudo-population 3: Constitutive promoter-LuxS<br><br>
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        Test each population individually using the pseudo-population that produces the quorum sensing molecules to promote their expression.<br>
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            Basic Population 1 with pseudo-population 3<br>
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            Basic Population 2 with pseudo-population 1<br>
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            Basic Population 3 with pseudo-population 2<br><br>
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        Test the effects of each population with its neighboring populations and pseudo-populations to see if one basic population can successfully promote another population instead of its respective pseudo-population.<br>
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            Basic Population 1 and Basic Population 2 with pseudo-population 3<br>
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            Basic Population 2 and Basic Population 3 with pseudo-population 1<br>
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            Basic Population 3 and Basic Population 1 with pseudo-population 2<br>
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        Test the effect of all three basic populations interacting with each other without any pseudo-populations.<br><br>
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Phase 2: Promotion and Repression<br><br>
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        Reconstruct the three populations from step one, but add the necessary parts that will cause each system to be repressed by the proper quorum sensing molecule.<br>
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        Test each population again using the pseudo-population that produces the quorum sensing molecules to promote its fluorescent protein expression and another time with the molecules that will repress its fluorescent protein expression.<br><br>
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            Population 1 with pseudo-population 3<br>
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            Population 1 with pseudo-population 2<br>
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            Population 2 with pseudo-population 1<br>
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            Population 2 with pseudo-population 3<br>
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            Population 3 with pseudo-population 1<br>
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            Population 3 with pseudo-population 2<br><br>
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        Test the effects of each population with its neighboring populations and pseudo-populations to see if one basic population can successfully promote another population instead of its respective pseudo-population.<br>
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            Population 1 and Population 2 with pseudo-population 3<br>
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            Population 1 and Population 3 with pseudo-population 3<br>
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            Population 2 and Population 1 with pseudo-population 1<br>
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            Population 2 and Population 3 with pseudo-population 1<br>
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            Population 3 and Population 1 with pseudo-population 2<br>
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            Population 3 and Population 2 with pseudo-population 2<br><br>
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        Finally test the effect of all three populations interacting with each other without any pseudo-populations and watch the magic happen.
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Latest revision as of 02:41, 4 October 2012

Three Population Cascade Design



<img width="750" src="Cascade.png">



For our three population signal propagation mechanism, we created three different strains using E.coli bacteria. These strains used three different quorum sensing molecules acyl homoserine-lactone (AHL), (autoinducer-1) Ai-1, and (autoinducer-2) Ai-2 coupled with yellow, red, and cyan fluorescent proteins to create a visual oscillating effect.

Population 1:
The sequence begins with the synthesis of LsrK. When LsrK binds with Ai-2 produced by the third population, it creates a phosphorylated dimer, referred to as “Ai-2 +P”, that binds to the PLsrA promoter. This promotes the transcription of both Luxl and the yellow fluorescence protein, YFP. Also, LuxI, when bound with S-adenosylmethionine (SAM), produces AHL.

Population 2:

The second population in the sequence is induced by the AHL produced by Population 1. When AHL is in the presence of the bacteria, it creates a dimer with LuxR that binds to PLuxR. PLuxR then promotes LasI which when bound with SAM produces Ai-1. RFP is attached to the end of the LasI gene, so that when LasI is produced, the bacterium also fluoresces red.

Population 3:

The third population in the sequence is induced by the Ai-1 molecules produced by Population 2. When Ai-1 is in the presence of the bacteria, it creates a dimer with LasR and binds to PLasR. PLasR then promotes LuxS which when bound with SAM produces Ai-2. CFP is attached to the end of the LuxS gene, so that when LuxS is produced, the bacterium fluoresces cyan.

Pseudo-population 3

   This population consists of only a Constitutive promoter and LuxS. LuxS is the gene in Population 2 that produces the quorum sensing molecule Ai-2. This pseudo-population is used in testing whether the output of Population 3 will successfully promoter the production of Ai-2 and the yellow flourescence protein expression level in Population 1.
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