Team:Washington/Gram Negative/Design

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=Type Six Secretion System=
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=Designing the Transfer of the Type Six Secretion System into ''E. coli''=
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==Using a fosmid to transfer the T6SS genes into ''E. coli''==
+
==Using a Fosmid to Transfer the T6SS Genes into ''E. coli''==
-
Our three goals:
+
The T6SS is comprised of 23 genes across several operons.  Capturing and moving these genes via standard restriction digest cloning was determined to be impractical.  We discovered that the sequence of the ''P. aeruginosa'' strain (PAO1) we were using was solved using fosmids (essentially large plasmids).  We were able to locate these fosmids and were very excited to find that one of the fosmids contained all of the necessary T6SS genes organized nicely in two divergent operonsWe successfully transferred the fosmid into ''E. coli''It was not clear, however, whether or not the genes would be expressed in ''E. coli'', since the promoters that controlled the expression of the T6SS genes on the fosmid were from ''P. aeruginosa''.  In order to verify expression of the T6SS genes we performed a Western blot using antibodies against Fha1, a critical protein of the secretion system and a reporter for T6SS activity.
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    1. Figure out what genes are necessary for the T6SS to be functional
+
-
    2. Physically transfer the genes into E.Coli
+
-
    3. Optimize the regulation of the T6SS
+
-
 
+
-
The T6SS is comprised of 23 genes on several operons.  Capturing and moving these genes via standard restriction digest cloning was determined to be impractical.  We discovered that the sequence of the P. aeruginosa strain (pao1) we were using was solved using fosmids (essentially large plasmids).  We were able to locate these fosmids and were very excited to find that one of the fosmids contained all of the necessary T6SS genes.  The fosmid was put into E.Coli through a process called recombineeringAfter we did this however, it was not clear whether or not the genes would be expressed in E.coli.  In order to verify expression of the T6SS genes we performed a western blot using antibodies against Hcp1, a critical protein of the secretion system, and a reporter for its activity.
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<br>
<br>
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[[Image:Washington T6SS Fosmid.jpg|500px|center]]
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[[Image:Washington T6SS Fosmid.jpg|500px|center|thumb|'''Obtained Fosmid Contains T6SS Genes Organized into Two Divergent Operons''']]
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==Testing the native ''Pseudomonas aeriginosa'' promoter in ''E. coli''==
+
==Testing the Native ''Pseudomonas aeruginosa'' Promoter-regulated Type VI Secretion System in ''E. coli''==
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The fosmid was tranfered into ''E. coli'' by recombineering, and the cells were pelleted and then a western blot was preformed for Hcp, one of the proteins of the "shaft" of the T6SS. This was done in order to determine if the genes in the T6SS were being expressed from the native ''P. aeriginosa'' promoter. The western blot showed no bands (figure x), indicating that ''E. coli'' was not transcribing from the native ''P. aeriginosa'' promoter. It was decided that the promoter would need to be changed to a bidirectional promoter compatible with ''E. coli''. It was also determined that the native promoter would need to be switched to a bidirectional T7 promoter.  T7 promoters are well characterized, and known to be highly robust this makes them relatively easy to work with.
+
To determine whether the T6SS genes from the fosmid were being expressed from the native ''P. aeruginosa'' promoter, the fosmid was tranferred into ''E. coli'', and a Western blot was performed on cell extracts for Fha1, one of the proteins critical for T6SS activity. As expected, the Western blot showed a band for Fha1 in the ''P. aeruginosa'' cell extract sample, but no bands were seen in the ''E. coli'' cell extract samples (shown below), indicating that ''E. coli'' was probably not transcribing the T6SS genes from the native ''P. aeruginosa'' promoter.   
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[[Image:T6SS_no_exp.jpg|805px]]
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[[Image:T6SS_no_exp.jpg|450 px|center|thumb|'''Expression of T6SS Components from the Fosmid Occurs in ''P. aeruginosa'' but Not in ''E. coli'']]
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=Tse2/Tsi2 Toxin/ Antitoxin System=
+
==Strategy to Improve Type VI Secretion System Expression in ''E. coli''==
-
==Regulating the Toxin and Antitoxin==
+
To allow expression of these genes in ''E. coli'', we designed a promoter system that would allow the same ''E. coli'' - recognized promoter to drive expression of both divergent operons.  This promoter system would replace the native ''P. aeruginosa'' promoter system.  We chose a bidirectional T7 promoter, which would promote transcription in both the 5' and 3' direction.  T7 promoters are well characterized, and known to be highly robust for expression in ''E. coli''.
-
Our three goals:
+
=Designing Regulation of the Toxin/ Antitoxin System=
-
    1. Separate the Tse2 and Tsi2 for easy regulation
+
-
    2. Verify the Tse2 toxicity and characterize it
+
-
    3. Induce the Tse2 and Tsi2 upon exposure to a pathogen molecule
+
-
The  purpose of the Tse2/Tsi2, toxin/antitoxin, circuit is to regulate the probiotic in a way that allows it to be more effective at killing gram-negative bacteria. If our probiotic system were constantly producing Tse2 and killing gram-negative cells there would be an increased chance of the E.Coli evolving and developing resistance to the tse2. The helpful gut flora would also be adversely affected. It would therefore be preferential to be able to activate the T6SS/Tse2/Tsi2 system only when a pathogen is present. While it is possible to regulate this probiotic system by regulating the expression of the T6SS, the response time of such a system would be limited by the complex 23 protein nature of the T6SS. Consequentially it would be most effective to be able to activate our probiotic by inducing Tse2 expression only in the presence of a pathogen.
+
-
== Design of our Inducable Tse2/Tsi2 system==
+
==Separating the Regulation of the Toxin/Antitoxin from the Type VI Secretion System==
-
Activating Tse2 production when a pathogen is present would require a promoter inducable by some molecular stimulis unique to a specific pathogen. In addition, the expression of Tsi2 would need to be constituitve, or induced by the same stimulis that induces Tse2 expression.  As a proof-of-concept, this project uses the LuxR-pLux transcription factor- promoter system from ''Vibrio fischeri''  to regulate expression of the Tse2-Tsi2 locus. ''V. fischeri'' excretes 3OC6HSL, a small membrane permeable molecule( hereafter refered to as HSL). HSL binds to LuxR, changing the conformation of LuxR, which then induces the pLux promoter. Since ''V. fischeri'' also produces HSL, expression from the pLux promoter is linked to cell density. This is referred to as quorum sensing. Quorum sensing is found in many pathogenic species, making the use of the pLux-LuxR system a good proof-of concept. When our probiotic detects a gram-negative pathogen-specific molecule ( modeled by HSL), transcription is induced from an inducible promoter( modeled by pLux). This leads to expression of Tse2 ( a toxic protein) and Tsi2 ( its antitoxin). The Type VI Secretion System then attacks the pathogen, puncturing the cell wall. Tse2 is then secreted into the gram negative pathogen, killing the pathogen. This system could easily be changed to target a wide range of gram (-) pathogens by just changing the regulation of the Tse2/Tsi2 locus.
+
We chose to separate the regulation  of the toxin antitoxin system (Tse2.Tsi2) from the regulation of the T6SS, since the T6SS has too many proteins to be easily induced.  The purpose of generating novel Tse2/Tsi2 regulatory circuits is to activate the killing activity of our ''E. coli'' antibiotic only when necessary.  If our probiotic system were constitutively producing Tse2, this would adversely affect natural gut flora.  In addition, natural gut flora might develop resistance to Tse2 and pass this resistance to potential Gram-negative pathogens.  As a BioBrick, the Tse2.Tsi2 circuit is modular, and therefore promoters and other regulatory components can be swapped out.  For example, one could ingest the probiotic, have it exist in the gut, but only induce its killing behavior by ingesting some user-defined signal, such as arabinose, which would activate expression of the toxin, which would then travel through the already-present T6SS into Gram-negative targets.  In addition, one could envision a scenario in which it would be advantageous to separately regulate Tsi2, to kill the probiotic when it is no longer useful by preventing Tsi2 expression, causing cell suicide due to the production of Tse2.  For the purposes of  this project, we decided to make a probiotic that produced the Tse2 toxin only when the probiotic detected the presence of a pathogen, and to express Tsi2 on the same operon.
-
[[Image:Washington_Probiotic_overview.jpg|805px]]
+
 
-
===Diagram of the Tse2/Tsi2 HSL inducible circuit===
+
 
-
The Tse2/Tsi2 toxin/antitoxin system has a relativly simple circuit design. Tse2 and Tsi2 are present in one operon ( as in ''Pseudomonas aeruginosa'') regulated by the pLux promoter. The LuxR transcriptional factor is constituitively expressed, as no tetR is present to repress the production of LuxR. When HSl is present, it binds to LuxR, resulting the in the induction of Tse2 and Tsi2 production. The pTet, LuxR, and pLux region of the construct is present in part [http://partsregistry.org/Part:BBa_F2620 F2620], easing the contruction of the circuit.
+
[[Image:washington_Hypotheticalcircuit.jpg|450 px|center|thumb|'''Separating the toxin and the antitoxin allow us to make us to make a probiotic that can respond to a pathogen but that can also be killed off through repression of the antitoxin''']]
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<!-- [[Image:Washington_Diagram_F2620-Tse2-Tsi2.png|805px]] -->
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-
<html>
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==Inducing Toxin Expression Upon Detection of Pathogen: Proof of Concept==
-
<img src="https://static.igem.org/mediawiki/2010/8/8c/Washington_Diagram_F2620_Tse2_Tsi2.png" width="805" height="297" alt="Washington Diagram F2620 Tse2 Tsi2.png" usemap="#Washington Diagram F2620 Tse2 Tsi2.png" />
+
In order to activate Tse2 production in response to a pathogen, we needed a promoter that is inducible by some molecular stimulus unique to a specific pathogen. In addition, the expression of Tsi2 would need to be either constitutive or induced by the same stimulus that induces Tse2 expression.  As a proof-of-concept, this project uses the LuxR-pLux transcription factor - promoter system from ''Vibrio fischeri''  to regulate expression of the Tse2-Tsi2 locus. ''V. fischeri'' excretes 3OC6HSL, a small membrane permeable molecule (hereafter referred to as HSL). HSL binds to the transcription factor LuxR, thereby inducing its DNA transcriptional activity. Thus, expression from the pLux promoter is linked to cell density. This is referred to as quorum sensing. Quorum sensing is found in many bacterial species including pathogenic species, making the use of the pLux-LuxR system a good proof-of concept for induction of toxin production when the probiotic detects the presence of a pathogen. When our probiotic detects a Gram-negative pathogen-specific molecule (modeled by HSL), transcription is induced by an inducible promoter (modeled by pLux). This leads to expression of Tse2 (a toxic protein) and Tsi2 (its antitoxin). The T6SS then attacks the pathogen, puncturing the cell wall. Tse2 is then secreted into the Gram-negative pathogen, killing the pathogen. This system could easily be modified to target a wide range of Gram-negative pathogens by just changing the regulation of the Tse2 and Tsi2 locus.
-
<map name="Washington Diagram F2620 Tse2 Tsi2.png">
+
[[Image:Washington_Probiotic_overview.jpg|780px|center|thumb|'''In Response to Pathogen Detection, Probiotic Produces and Secretes Toxin into Pathogen Cytoplasm''']]
-
<area shape="rect" coords="249,203,319,252" alt="B0010" href="http://partsregistry.org/Part:BBa_B0010" />  
+
===Diagram of the Toxin and Antitoxin HSL Inducible Circuit===
-
<area shape="rect" coords="319,203,390,252" alt="B0012" href="http://partsregistry.org/Part:BBa_B0012" />  
+
<span id=diagram>
-
<area shape="rect" coords="79,233,136,252" alt="B0034" href="http://partsregistry.org/Part:BBa_B0034" />  
+
The Tse2 Tsi2 toxin antitoxin system has a relatively simple circuit design. Tse2 and Tsi2 are present in one operon (as in ''Pseudomonas aeruginosa'') and are regulated by the pLux promoter. For the pLux promoter, we used the well-characterized BioBrick [http://partsregistry.org/Part:BBa_F2620 F2620].  The LuxR transcription factor is constituitively expressed because no tetR is present to repress the production of LuxR. When HSL is present it binds to LuxR resulting in the induction of Tse2 and Tsi2 production. This BioBrick is part [http://partsregistry.org/Part:BBa_K314203 K314203].
-
<area shape="rect" coords="460,233,517,252" alt="BOO34" href="http://partsregistry.org/Part:BBa_B0034" />  
+
<!-- [[Image:Washington_Diagram_F2620-Tse2-Tsi2.png|805px|center|thumb|'''TinkerCell-Generated Schematic of F2620-Tse2-Tsi2 Composite BioBrick''']] -->
-
<area shape="rect" coords="136,233,249,252" alt="LuxR" href="http://partsregistry.org/Part:BBa_C0062" />  
+
<html><table><tr><center>
-
<area shape="rect" coords="517,233,629,252" alt="Tse2" href="http://partsregistry.org/Part:BBa_Something" />  
+
<img src="https://static.igem.org/mediawiki/2010/8/8c/Washington_Diagram_F2620_Tse2_Tsi2.png" width="750" height="269" alt="Washington_Diagram_F2620_Tse2_Tsi2.png" usemap="#Washington_Diagram_F2620_Tse2_Tsi2.png" />
-
<area shape="rect" coords="629,233,742,252" alt="Tsi2" href="http://partsregistry.org/Part:BBa_Something" />  
+
<map name="Washington_Diagram_F2620_Tse2_Tsi2.png">
-
<area shape="rect" coords="390,203,460,252" alt="pLux" href="http://partsregistry.org/Part:BBa_R0062" />  
+
<area shape="rect" coords="233,184,299,230" alt="B0010" title="Part:BBa_B0010" href="http://partsregistry.org/Part:BBa_B0010" />  
-
<area shape="rect" coords="9,203,79,252" alt="pTet" href="http://partsregistry.org/Part:BBa_R0040" />  
+
<area shape="rect" coords="299,184,365,230" alt="B0012" title="Part:BBa_B0012" href="http://partsregistry.org/Part:BBa_B0012" />  
-
</map>
+
<area shape="rect" coords="75,213,128,230" alt="B0034" title="Part:BBa_B0034" href="http://partsregistry.org/Part:BBa_B0034" />  
-
</html>
+
<area shape="rect" coords="431,213,484,230" alt="BOO34" title="Part:BBa_B0034" href="http://partsregistry.org/Part:BBa_B0034" />  
 +
<area shape="rect" coords="128,213,233,230" alt="luxR" title="Part:BBa_C0062" href="http://partsregistry.org/Part:BBa_C0062" />  
 +
<area shape="rect" coords="365,184,431,230" alt="pLux" title="Part:BBa_R0062" href="http://partsregistry.org/Part:BBa_R0062" />  
 +
<area shape="rect" coords="3729,3124,3791,3183" alt="pLux1" title="Part:BBa_R0062" href="http://partsregistry.org/Part:BBa_R0062" />  
 +
<area shape="rect" coords="9,184,75,230" alt="pTet" title="Part:BBa_R0040" href="http://partsregistry.org/Part:BBa_R0040" />  
 +
<area shape="rect" coords="484,213,589,230" alt="tse2" title="Part:BBa_K314200" href="http://partsregistry.org/Part:BBa_K314200" />
 +
<area shape="rect" coords="589,213,694,230" alt="tsi2" title="Part:BBa_K314201" href="http://partsregistry.org/Part:BBa_K314201" />  
 +
</map></center></tr>
 +
</table></html>
 +
</span>
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Latest revision as of 00:25, 28 October 2010

Designing the Transfer of the Type Six Secretion System into E. coli

Using a Fosmid to Transfer the T6SS Genes into E. coli

The T6SS is comprised of 23 genes across several operons. Capturing and moving these genes via standard restriction digest cloning was determined to be impractical. We discovered that the sequence of the P. aeruginosa strain (PAO1) we were using was solved using fosmids (essentially large plasmids). We were able to locate these fosmids and were very excited to find that one of the fosmids contained all of the necessary T6SS genes organized nicely in two divergent operons. We successfully transferred the fosmid into E. coli. It was not clear, however, whether or not the genes would be expressed in E. coli, since the promoters that controlled the expression of the T6SS genes on the fosmid were from P. aeruginosa. In order to verify expression of the T6SS genes we performed a Western blot using antibodies against Fha1, a critical protein of the secretion system and a reporter for T6SS activity.

Obtained Fosmid Contains T6SS Genes Organized into Two Divergent Operons

Testing the Native Pseudomonas aeruginosa Promoter-regulated Type VI Secretion System in E. coli

To determine whether the T6SS genes from the fosmid were being expressed from the native P. aeruginosa promoter, the fosmid was tranferred into E. coli, and a Western blot was performed on cell extracts for Fha1, one of the proteins critical for T6SS activity. As expected, the Western blot showed a band for Fha1 in the P. aeruginosa cell extract sample, but no bands were seen in the E. coli cell extract samples (shown below), indicating that E. coli was probably not transcribing the T6SS genes from the native P. aeruginosa promoter.

Expression of T6SS Components from the Fosmid Occurs in P. aeruginosa but Not in E. coli

Strategy to Improve Type VI Secretion System Expression in E. coli

To allow expression of these genes in E. coli, we designed a promoter system that would allow the same E. coli - recognized promoter to drive expression of both divergent operons. This promoter system would replace the native P. aeruginosa promoter system. We chose a bidirectional T7 promoter, which would promote transcription in both the 5' and 3' direction. T7 promoters are well characterized, and known to be highly robust for expression in E. coli.

Designing Regulation of the Toxin/ Antitoxin System

Separating the Regulation of the Toxin/Antitoxin from the Type VI Secretion System

We chose to separate the regulation of the toxin antitoxin system (Tse2.Tsi2) from the regulation of the T6SS, since the T6SS has too many proteins to be easily induced. The purpose of generating novel Tse2/Tsi2 regulatory circuits is to activate the killing activity of our E. coli antibiotic only when necessary. If our probiotic system were constitutively producing Tse2, this would adversely affect natural gut flora. In addition, natural gut flora might develop resistance to Tse2 and pass this resistance to potential Gram-negative pathogens. As a BioBrick, the Tse2.Tsi2 circuit is modular, and therefore promoters and other regulatory components can be swapped out. For example, one could ingest the probiotic, have it exist in the gut, but only induce its killing behavior by ingesting some user-defined signal, such as arabinose, which would activate expression of the toxin, which would then travel through the already-present T6SS into Gram-negative targets. In addition, one could envision a scenario in which it would be advantageous to separately regulate Tsi2, to kill the probiotic when it is no longer useful by preventing Tsi2 expression, causing cell suicide due to the production of Tse2. For the purposes of this project, we decided to make a probiotic that produced the Tse2 toxin only when the probiotic detected the presence of a pathogen, and to express Tsi2 on the same operon.


Separating the toxin and the antitoxin allow us to make us to make a probiotic that can respond to a pathogen but that can also be killed off through repression of the antitoxin

Inducing Toxin Expression Upon Detection of Pathogen: Proof of Concept

In order to activate Tse2 production in response to a pathogen, we needed a promoter that is inducible by some molecular stimulus unique to a specific pathogen. In addition, the expression of Tsi2 would need to be either constitutive or induced by the same stimulus that induces Tse2 expression. As a proof-of-concept, this project uses the LuxR-pLux transcription factor - promoter system from Vibrio fischeri to regulate expression of the Tse2-Tsi2 locus. V. fischeri excretes 3OC6HSL, a small membrane permeable molecule (hereafter referred to as HSL). HSL binds to the transcription factor LuxR, thereby inducing its DNA transcriptional activity. Thus, expression from the pLux promoter is linked to cell density. This is referred to as quorum sensing. Quorum sensing is found in many bacterial species including pathogenic species, making the use of the pLux-LuxR system a good proof-of concept for induction of toxin production when the probiotic detects the presence of a pathogen. When our probiotic detects a Gram-negative pathogen-specific molecule (modeled by HSL), transcription is induced by an inducible promoter (modeled by pLux). This leads to expression of Tse2 (a toxic protein) and Tsi2 (its antitoxin). The T6SS then attacks the pathogen, puncturing the cell wall. Tse2 is then secreted into the Gram-negative pathogen, killing the pathogen. This system could easily be modified to target a wide range of Gram-negative pathogens by just changing the regulation of the Tse2 and Tsi2 locus.

In Response to Pathogen Detection, Probiotic Produces and Secretes Toxin into Pathogen Cytoplasm

Diagram of the Toxin and Antitoxin HSL Inducible Circuit

The Tse2 Tsi2 toxin antitoxin system has a relatively simple circuit design. Tse2 and Tsi2 are present in one operon (as in Pseudomonas aeruginosa) and are regulated by the pLux promoter. For the pLux promoter, we used the well-characterized BioBrick [http://partsregistry.org/Part:BBa_F2620 F2620]. The LuxR transcription factor is constituitively expressed because no tetR is present to repress the production of LuxR. When HSL is present it binds to LuxR resulting in the induction of Tse2 and Tsi2 production. This BioBrick is part [http://partsregistry.org/Part:BBa_K314203 K314203].

Washington_Diagram_F2620_Tse2_Tsi2.png B0010 B0012 B0034 BOO34 luxR pLux pLux1 pTet tse2 tsi2

Overview of the Gram(-) Therapeutic       Building the Gram(-) Therapeutic