Team:ETHZ Basel/Biology/Implementation

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(Difference between revisions)
(Plasmid copy number)
(Modeller's input)
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Due to the high amount of fusion proteins that were in planing (81 constructs), priorities had to be distributed to the different genes. This was possible due to the various models the dry-lab team implemented.
Due to the high amount of fusion proteins that were in planing (81 constructs), priorities had to be distributed to the different genes. This was possible due to the various models the dry-lab team implemented.
* [[Team:ETHZ_Basel/Modeling/Collaboration|'''Chemotactic protein''']]: CheY was chosen as first target.
* [[Team:ETHZ_Basel/Modeling/Collaboration|'''Chemotactic protein''']]: CheY was chosen as first target.
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* '''Anchor''': TetR was the first choice due to its wide application in synthetic biology and extensive characterization.
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* [[Team:ETH_Basel/Biology/Molecular_Mechanism&action|'''Anchor''']]: TetR was the first choice due to its wide application in synthetic biology and extensive characterization.
* [[Team:ETHZ_Basel/Modeling/Collaboration|'''Pif3 linked to Che-Protein''']]: Although PhyB seemed to be the more robust choice, Pif3 was chosen to be linked to the Che-Protein due to the tendency of PhyB to sequester.
* [[Team:ETHZ_Basel/Modeling/Collaboration|'''Pif3 linked to Che-Protein''']]: Although PhyB seemed to be the more robust choice, Pif3 was chosen to be linked to the Che-Protein due to the tendency of PhyB to sequester.
* [[Team:ETHZ_Basel/Modeling/Collaboration|'''Ratio anchor to binding partner''']]: The simulations favoured a ratio of 50 µM anchor to 40 µM anchor binding partner.
* [[Team:ETHZ_Basel/Modeling/Collaboration|'''Ratio anchor to binding partner''']]: The simulations favoured a ratio of 50 µM anchor to 40 µM anchor binding partner.

Revision as of 20:17, 18 October 2010

Implementation

Generation of fusion proteins

Schematical overview of the planned constructs. In the planning phase, 81 constructs were considered.

The image shows all the fusion proteins that were planned. The BioBricks for all these constructs were generated via PCR or synthesized at GeneArt and ligated into the storage vector for sequencing. Easy cutting and pasting into working vectors should be possible with the cloning strategy BBF RFC28 (http://dspace.mit.edu/handle/1721.1/46721).

Modeller's input

Due to the high amount of fusion proteins that were in planing (81 constructs), priorities had to be distributed to the different genes. This was possible due to the various models the dry-lab team implemented.

  • Chemotactic protein: CheY was chosen as first target.
  • Anchor: TetR was the first choice due to its wide application in synthetic biology and extensive characterization.
  • Pif3 linked to Che-Protein: Although PhyB seemed to be the more robust choice, Pif3 was chosen to be linked to the Che-Protein due to the tendency of PhyB to sequester.
  • Ratio anchor to binding partner: The simulations favoured a ratio of 50 µM anchor to 40 µM anchor binding partner.

Plasmid copy number

Plasmid copy number estimation.

As the ratio between the amount of anchor and its binding partner has been shown to be essential (Team:ETHZ_Basel/Modeling/Collaboration), the plasmid copy number was determined by normalization of cell number via optical density measurement followed by plasmid concentration measurements using a commercial Miniprep kit.

From a modeling perspective, working vector 1 (BBR1 ori) should have a higher copy number than working vector 2 (RK2 ori). The results show that working vector 1 has a 1.1x higher frequency in the cell that working vector 2. This is acceptable, as molecular modeling suggest an optimal ratio of 1.5x.

In view of fraction anchor to anchor binding protein, the aim of tetO7 = 50 µM in one cell can not even be achieved by ligation into a high copy number plasmid such as pUC19. The measured amount of 266 vectors in one cell gives approximately 5 µM tetO binding sites. Therefore, the decision of integrating a second anchor binding protein also fused to the light sensitive protein PhyB in one operon was made.

Functionality assays

The constructs will have to be tested for the following properties:

  • Che protein fusion: Using the chemotactic assay described by Mazumder et al., the functionality of Che protein fusions can be tested.
  • Localizer fusion: Spatial localization of the anchor protein to either the plasmid (tetR-tetO), the cell membrane (mreB) or the ribosome (trigA) can be investigated by fusing the anchor binding protein to a fluorescent protein.
  • PhyB-Pif3 system: Fusing a second fluorescent protein to Pif3 would enable the visualization of the light activated dimerization.