Berkeley

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=== Berkeley iGEM Team ===
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==Berkeley iGEM Team==
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<h3>Professors:</h3>
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<h3>Members:</h3>
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Adam Arkin<br>
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{| width=600
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Jay Keasling
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|Michael Chen
 +
|Vlad Goldenberg
 +
|Stephen Handley
 +
|-
 +
|Melissa Li
 +
|Jonathan Sternberg
 +
|Jay Su
 +
|-
 +
|Eddie Wang
 +
|Gabriel Wu
 +
|-
 +
|}
 +
 
 +
<h3>Advisors:</h3>
 +
{| width=300
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|Professor Adam Arkin
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|Professor Jay Keasling
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|}
<h3>GSIs:</h3>
<h3>GSIs:</h3>
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Jonathan Goler<br>
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{| width=300
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Justyn Jaworski  
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|Jonathan Goler
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|Justyn Jaworski
 +
|}
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<h3>Members:</h3>
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<hr>
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Michael Chen<br>
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=Parts=
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Vlad Goldenberg<br>
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[http://parts2.mit.edu/r/parts/partsdb/pgroup.cgi?pgroup=iGEM&group=iGEM_Berkeley Parts]
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Stephen Handley<br>
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Melissa Li<br>
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Jonathan Sternberg<br>
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Jay Su<br>
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Eddie Wang<br>
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Gabriel Wu
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<h1>Addressable Bacterial Communication</h1>
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=Protocols=
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We are working on building addressable bacterial communication via conjugation. A message, in the form of a gene locked by the Isaacs et al. riboregulator, is transferred within a packet plasmid mobilized by F-plasmid conjugation.  This mobilized plasmid is sent to cells in the vicinity upon induction of the pBadAraC-controlled TraJF conjugation regulator, expression of which triggers a cascade that constructs and uses F-plasmid conjugation machinery to transmit the packet plasmid. Addressing is achieved because the message can only be unlocked by cells containing a trans activating key which unlocks the hairpin formed over the RBS by the cis-repressed lock, where addressability is achieved by varying a 5 nucleotide region shared by the locks and keys. Upon receipt of the packet plasmid, the recipient cell turns on its own RP2-based conjugation machinery to send a similar acknowledgement packet back to the original cell, containing a genetic message locked and opened by a second addressed lock/key pair.
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[[Berkeley Protocols]]
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 +
 
 +
=Work Schedule and Progress=
 +
[[Berkeley Work Schedule and Progress]]
 +
 
 +
 
 +
=The Project: Addressable Bacterial Communication=
 +
We are working on building addressable bacterial communication via conjugation. Our construct consists of four different synthetic plasmids placed within communicating cells. 
 +
 
 +
<h3>Background:</h3>
 +
<b>Conjugation</b> is a process through which cells can exchange genetic material on plasmids.  Conjugal plasmids (in our case incF and incP plasmids) carry the machinery necessary to transfer themselves in the form of mating pair formation (mpf) and DNA transfer (dtr) genes.  Conjugation is under the control of the TraJ regulatory protein, which when expressed induces a cascade that results in the formation of a pore by mpf genes and then subsequent nicking, rolling circle replication and transfer of one strand of the plasmid by the relaxosome complex and other dtr proteins.  The relaxosome nicks the plasmid at the OriT region and then covalently attaches one of its subunits to the 5' end of the plasmid DNA, and by doing so it is able to drag the plasmid across the pore formed by the mpf machinery by means of a coupling protein. Upon reaching its destination, the single strand of plasmid DNA is recircularized and a complement strand is synthesized by transferred primases.
 +
 
 +
The <b>riboregulator</b> we are using is a biobricked version of the Isaacs riboregulator <5>, where we have added biobricks sites and designated an addressing region in the cis-repressed locks and the trans-activating keys. 
 +
 
 +
<h3>Implementation</h3>
 +
A message, in the form of a gene locked by the Isaacs et al. riboregulator, is transferred within a packet plasmid mobilized by F-plasmid conjugation.   
 +
A chemical signal (the binding of the ligand ara to the pBad promoter) begins the cascade for the mobilizable plasmid.  This plasmid consists of a controlled TraJf conjugation regulator, expression of which triggers a cascade that constructs and uses F-plasmid conjugation machinery to transmit the packet plasmid. Addressing is achieved because the message can only be unlocked by cells containing a trans activating key which unlocks the hairpin formed over the RBS by the cis-repressed lock, where addressability is achieved by varying a 5 nucleotide region shared by the locks and keys. Upon receipt of the packet plasmid, the recipient cell turns on its own RP2-based conjugation machinery to send a similar acknowledgement packet back to the original cell, containing a genetic message locked and opened by a second addressed lock/key pair.
We have used the lambda-red protocol to knock out the TraJ gene on the F plasmid so as to have total control over transfer via the pBadAraC promoter. Additionally, by knocking out the OriT nick region, we have marooned the F plasmid and its transfer machinery in the original cell so as to ensure only the packet is being sent.
We have used the lambda-red protocol to knock out the TraJ gene on the F plasmid so as to have total control over transfer via the pBadAraC promoter. Additionally, by knocking out the OriT nick region, we have marooned the F plasmid and its transfer machinery in the original cell so as to ensure only the packet is being sent.
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<h1> Protocols </h1>
 
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Restrictions
 
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    * 35 microliters of your favourite plasmid (make sure to record the concentrationShould be above around 80 ng/microliter)
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'''Genetic Construct'''
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    * 5 microliters of 10X BSA
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----------
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    * 5 microliters of NEB buffer (check the chart).
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The following is an outline of our genetic construct.  The construct exists as 3 separate plasmids (designated A,B,C for convenience) for 2 different types of cells ("F type" and "R type" respectively).
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    * 1.3-1.5 microliters of each delicious restriction enzyme
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 +
'''''Cell #1 (F type cell)''''':<br>
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*1-A Non-mobile synthetic F plasmid: Begins the conjugation signal, which it sends to plasmid BAlso contains the CFP tag which identifies the host cell as "F-type", and always produces mRNA 'key 2' which unlocks RNA lock 2<br>
 +
https://webfiles.berkeley.edu/carnive/public_html/fPicture1.png<br>
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 +
*1-B - Non-mobile almost-wild F plasmid: Contains all F-plasmid genes EXCEPT OriTf, TraJf.  Plasmid receives and propagates the conjugation signal from TraJf in plasmid 1-A and sends the signal to OriTf in 1-C<br>
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 +
*1-C - Mobile F plasmid: Contains the OriTf site which receives signal from plasmid 1-B.  This plasmid then leaves the host cell and enters the conjugating recipient cell.  Holds encrypted message (produce cI --> turn on GFP to signify "message 1 received") secured by RNA lock 1.<br>
 +
https://webfiles.berkeley.edu/carnive/public_html/fPicture2.png<br>
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 +
 
 +
'''''Cell #2 (R type cell)''''' <br>
 +
*2-A Non-mobile synthetic R plasmid: Always produces mRNA 'key1'. Thus when it receives 'lock1' (sent by mobile plasmid 1-C) it can open the latter and produce cI, which will activate plasmid 1-C (turn on GFP, "message 1 received") and simultaneously activate TraJr (start R conjugation cascade) <br>
 +
https://webfiles.berkeley.edu/carnive/public_html/rPicture1.png<br>
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Lamda-Red Protocol (from Datsenko and Wanner)
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*2-B Non-mobile almost-wild R plasmid: Just like 1-B, contains all of the wild type R-plasmid EXCEPT OriTr and TraJr.  Propagates TraJr signal from 2-A and sends it to OriTr<br>
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    * PCR TraJ? and OriT? from pKD3 purified plasmid with primers TJFlamF?/TJFlamR? and ORFlamF?/ORFlamR?
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*2-C Mobile R plasmid: Contains the OriTr site, which receives signal from plasmid 2-B. This plasmid then leaves the host cell and submits its message back into cell #1<br>
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    * Run on 2microliters on gel and look for 1000bp fragments
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https://webfiles.berkeley.edu/carnive/public_html/rPicture2.png<br>
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    * PCR purify, elute in 40microliters of EB, digest overnight with Dpn I
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    * Gel purify and elute in 30microliters of EB
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    * Grow pox38 x pKD46 conjugate overnight in Amp Kan at 30C
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    * Prepare appropriate number of 5mL LB tubes with Amp Kan + 2 for OD testing
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    * Using 20% w/v arabinose at JAG's bench add 37.5microliters to each 5mL tube for 10mM
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    * (If using larger culture flask add 7.5microliters of 20% w/v arabinose for every 1mL of culture)
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    * Innoculate 50microliters of overnight culture per 5mL tube
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    * Incubate in 30C shaker
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    * Last time took about 2.5 hours to reach OD of approximately .45 so probably good to check at 1 and 2 hours
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    * Ideal to stop at OD 0.4, be sure to have an ice bath ready before then and precool microcentrifuge to 4C
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    * Rest of steps must be at 4C
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    * At OD 0.4 place all cultures on ice
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    * Spin down in 2mL eppendorfs at top speed 5min per spin removing supernatant
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    * After spinning down all 5mL, wash with 10% ice cold glycerol. (50mL falcon tube in JAG's fridge)
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    * Once with 1.5mL of glycerol, then twice with 750microliters. Spin 2 min each time, pouring out supernatant
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    * The last time you pour out the supernatant there should be enough liquid and cells left to electroporate with (about 40-50 microliters)
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    * Add 2 microliters of gel purified PCR product that has been restricted with Dpn? I to electrocompetent cells and transform
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    * Place tubes in 37C <--I guess 37 is okay - for one hour and plate 150microliters on prewarmed Kan Chlor plates at 30C
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<h3>Relevant Papers</h3>
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=Relevant Papers=
1. Balbás et al. "A pBRINT family of plasmids for integration of cloned DNA into the Escherichia coli chromosome"<br>
1. Balbás et al. "A pBRINT family of plasmids for integration of cloned DNA into the Escherichia coli chromosome"<br>
2. Datsenko, Wanner, "One-step inactivation of chromosomal genes in escherichia coli k-12 using PCR products"<br>
2. Datsenko, Wanner, "One-step inactivation of chromosomal genes in escherichia coli k-12 using PCR products"<br>
3. Haldimann, Wanner, "Conditional-Replication, Integration, Excision, and Retrieval Plasmid-Host Systems for Gene Structure-Function Studies of Bacteria"<br>
3. Haldimann, Wanner, "Conditional-Replication, Integration, Excision, and Retrieval Plasmid-Host Systems for Gene Structure-Function Studies of Bacteria"<br>
-
4. Isaacs et al., "Engineered riboregulators enable post-transcriptional control of gene expression"
+
4. Isaacs et al., "Engineered riboregulators enable post-transcriptional control of gene expression" <br>
5. Jaenecke et al., "A stringently controlled expression system for analyzing lateral gene transfer between bacteria"<br>
5. Jaenecke et al., "A stringently controlled expression system for analyzing lateral gene transfer between bacteria"<br>
6. Knight, "Idempotent Vector Design for Standard Assembly of Biobricks"<br>
6. Knight, "Idempotent Vector Design for Standard Assembly of Biobricks"<br>

Latest revision as of 20:59, 15 April 2006

Contents

Berkeley iGEM Team

Members:

Michael Chen Vlad Goldenberg Stephen Handley
Melissa Li Jonathan Sternberg Jay Su
Eddie Wang Gabriel Wu

Advisors:

Professor Adam Arkin Professor Jay Keasling

GSIs:

Jonathan Goler Justyn Jaworski

Parts

[http://parts2.mit.edu/r/parts/partsdb/pgroup.cgi?pgroup=iGEM&group=iGEM_Berkeley Parts]

Protocols

Berkeley Protocols


Work Schedule and Progress

Berkeley Work Schedule and Progress


The Project: Addressable Bacterial Communication

We are working on building addressable bacterial communication via conjugation. Our construct consists of four different synthetic plasmids placed within communicating cells.

Background:

Conjugation is a process through which cells can exchange genetic material on plasmids. Conjugal plasmids (in our case incF and incP plasmids) carry the machinery necessary to transfer themselves in the form of mating pair formation (mpf) and DNA transfer (dtr) genes. Conjugation is under the control of the TraJ regulatory protein, which when expressed induces a cascade that results in the formation of a pore by mpf genes and then subsequent nicking, rolling circle replication and transfer of one strand of the plasmid by the relaxosome complex and other dtr proteins. The relaxosome nicks the plasmid at the OriT region and then covalently attaches one of its subunits to the 5' end of the plasmid DNA, and by doing so it is able to drag the plasmid across the pore formed by the mpf machinery by means of a coupling protein. Upon reaching its destination, the single strand of plasmid DNA is recircularized and a complement strand is synthesized by transferred primases.

The riboregulator we are using is a biobricked version of the Isaacs riboregulator <5>, where we have added biobricks sites and designated an addressing region in the cis-repressed locks and the trans-activating keys.

Implementation

A message, in the form of a gene locked by the Isaacs et al. riboregulator, is transferred within a packet plasmid mobilized by F-plasmid conjugation. A chemical signal (the binding of the ligand ara to the pBad promoter) begins the cascade for the mobilizable plasmid. This plasmid consists of a controlled TraJf conjugation regulator, expression of which triggers a cascade that constructs and uses F-plasmid conjugation machinery to transmit the packet plasmid. Addressing is achieved because the message can only be unlocked by cells containing a trans activating key which unlocks the hairpin formed over the RBS by the cis-repressed lock, where addressability is achieved by varying a 5 nucleotide region shared by the locks and keys. Upon receipt of the packet plasmid, the recipient cell turns on its own RP2-based conjugation machinery to send a similar acknowledgement packet back to the original cell, containing a genetic message locked and opened by a second addressed lock/key pair.

We have used the lambda-red protocol to knock out the TraJ gene on the F plasmid so as to have total control over transfer via the pBadAraC promoter. Additionally, by knocking out the OriT nick region, we have marooned the F plasmid and its transfer machinery in the original cell so as to ensure only the packet is being sent.


Genetic Construct


The following is an outline of our genetic construct. The construct exists as 3 separate plasmids (designated A,B,C for convenience) for 2 different types of cells ("F type" and "R type" respectively).

Cell #1 (F type cell):

  • 1-A Non-mobile synthetic F plasmid: Begins the conjugation signal, which it sends to plasmid B. Also contains the CFP tag which identifies the host cell as "F-type", and always produces mRNA 'key 2' which unlocks RNA lock 2

https://webfiles.berkeley.edu/carnive/public_html/fPicture1.png

  • 1-B - Non-mobile almost-wild F plasmid: Contains all F-plasmid genes EXCEPT OriTf, TraJf. Plasmid receives and propagates the conjugation signal from TraJf in plasmid 1-A and sends the signal to OriTf in 1-C
  • 1-C - Mobile F plasmid: Contains the OriTf site which receives signal from plasmid 1-B. This plasmid then leaves the host cell and enters the conjugating recipient cell. Holds encrypted message (produce cI --> turn on GFP to signify "message 1 received") secured by RNA lock 1.

https://webfiles.berkeley.edu/carnive/public_html/fPicture2.png


Cell #2 (R type cell)

  • 2-A Non-mobile synthetic R plasmid: Always produces mRNA 'key1'. Thus when it receives 'lock1' (sent by mobile plasmid 1-C) it can open the latter and produce cI, which will activate plasmid 1-C (turn on GFP, "message 1 received") and simultaneously activate TraJr (start R conjugation cascade)

https://webfiles.berkeley.edu/carnive/public_html/rPicture1.png

  • 2-B Non-mobile almost-wild R plasmid: Just like 1-B, contains all of the wild type R-plasmid EXCEPT OriTr and TraJr. Propagates TraJr signal from 2-A and sends it to OriTr
  • 2-C Mobile R plasmid: Contains the OriTr site, which receives signal from plasmid 2-B. This plasmid then leaves the host cell and submits its message back into cell #1

https://webfiles.berkeley.edu/carnive/public_html/rPicture2.png


Relevant Papers

1. Balbás et al. "A pBRINT family of plasmids for integration of cloned DNA into the Escherichia coli chromosome"
2. Datsenko, Wanner, "One-step inactivation of chromosomal genes in escherichia coli k-12 using PCR products"
3. Haldimann, Wanner, "Conditional-Replication, Integration, Excision, and Retrieval Plasmid-Host Systems for Gene Structure-Function Studies of Bacteria"
4. Isaacs et al., "Engineered riboregulators enable post-transcriptional control of gene expression"
5. Jaenecke et al., "A stringently controlled expression system for analyzing lateral gene transfer between bacteria"
6. Knight, "Idempotent Vector Design for Standard Assembly of Biobricks"
7. Lawley et al., "F factor conjugation is a true type IV secretion system"
8. Lessl et al., "The Mating Pair Formation System of Plasmid RP4"
9. Miller et al., "F Factor Inhibition of Conjugal Transfer of broad host range plasmid RP4"
10. Martinez-Morales et al., "Chromosomal Integration of Heterologous DNA in Escherichia coli"
11. Wilkins, "Plasmid promiscuity - meeting the challenge of DNA immigration control"

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