Difference between revisions of "Team:KU Leuven/Wetlab"

 
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We designed a circuit capable of forming patterns in a controlled way. Using a modified and temperature-sensitive lambda repressor (cI), we can trigger formation at desired points in time. This time-dependent controllability, together with the possibility to change many different parameters and output signals, leads to an enormous tunability in the creation of the patterns. Our mechanism will stimulate advancements in a variety of industrial processes like the creation of novel bio-materials. This fundamental project could also speed up medical research projects like tumor formation and tissue regeneration.  
 
We designed a circuit capable of forming patterns in a controlled way. Using a modified and temperature-sensitive lambda repressor (cI), we can trigger formation at desired points in time. This time-dependent controllability, together with the possibility to change many different parameters and output signals, leads to an enormous tunability in the creation of the patterns. Our mechanism will stimulate advancements in a variety of industrial processes like the creation of novel bio-materials. This fundamental project could also speed up medical research projects like tumor formation and tissue regeneration.  
 
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<h2>Basic components</h2>
 
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Two different cell types, called A and B will interact and create patterns. In order achieve the desired behavior, the cells used in our experiments will not be wildtype Escherichia Coli, but specific knockout strains. Celltype A has a deletion of tar and tsr, whereas in celltype B, both tar and cheZ are knocked out. Tar and Tsr are two major chemotactic receptors and cheZ is a key phosphatase that regulates cell-motility. In absence of both Tsr and Tar, the cell is rendered insenstive to leucine as a repellent and attractant. On the other hand, cells who have lost only Tar, are repelled by leucine. In cell B, the absence of cheZ causes incessant tumbling.
 
 
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Both cells are transfected with only one plasmid (figure 1). Each plasmid contains a temperature sensitive cI repressor protein, which is constitutively expressed. This repressor is only able to bind to the lambda promotor at temperatures below a certain threshold. At elevated temperatures, cI is unable to bind to the promotor region enabeling RNA polymerase to start transcription. From the lambda promotor in cell A, two essential protagonists for our system are expressed: The AHL- producing enzyme LuxI and the transcription activator LuxR. On the contrary, cell B only contains the lambda promotor coupled to the LuxR gene. Cell A fulfills a dual role by coupling the expression of an auto-aggregation factor Ag43-YFP and a leucine-producing enzyme IlvE to the AHL-LuxR regulated promotor. Ag43 causes cells A to stick together and form clumps. At the same time, IlvE produces the repellent leucine. The repellent has no impact on cell A, since it does not contain the necessairy receptors anymore.  Cell B on the other hand is repelled by leucine, and contains a Lux promotor coupled to CheZ-GFP and the transcription repressor PenI. This repressor binds to the PenI-promotor, which regulates the transcription of a RFP. In order to measure the concentration of the key proteins LuxI and LuxR, they were fused with a His-tag and an E-tag respectively. To ensure rapid degradation of proteins whose expression is AHL concentration dependent facilitating the readout, an LVA tag was fused to CheZ, GFP and RFP.
 
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  <h2>Background</h2>
 
  <h2>Background</h2>
  <p>We decided to work on the fundamental mechanisms behind pattern formation. We design two bacteria strains which interact with each other. To achieve our goal, the link between wet lab and modeling will be crucial to the successful design of our experiments.
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  <p> A detailed description about the interaction between our two cells and the genetic circuit can be found here.
 
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<a href="https://2015.igem.org/Team:KU_Leuven/Wetlab/Background">Read more</a>
 
<a href="https://2015.igem.org/Team:KU_Leuven/Wetlab/Background">Read more</a>
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  <h2>Parts</h2>
 
  <h2>Parts</h2>
  <p>Swift and smart in actions to design the plasmids, quantify the parameters and to create the patterns. Join us in our exciting journey.
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  <p>A list of all used biobricks, the modifications we performed on them and the new ones we designed.
 
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<a href="https://2015.igem.org/Team:KU_Leuven/Project/About">Read more</a>
 
<a href="https://2015.igem.org/Team:KU_Leuven/Project/About">Read more</a>
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  <h2>Methods</h2>
 
  <h2>Methods</h2>
  <p>The modeling team fit models to the data obtained by the wet lab. Continuous and hybrid models will be used. Hybrid models are models which have a discrete and continuous part. Synergically, simulations from the cyber lab will aid tuning the experimental conditions that lead to the desirable patterns.
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  <p>Here you can find the performed steps to create two different cell types and detailed quantification methods to determine interesting parameters
 
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<a href="https://2015.igem.org/Team:KU_Leuven/Project/About">Read more</a>
 
<a href="https://2015.igem.org/Team:KU_Leuven/Project/About">Read more</a>
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  <h2>Results</h2>
 
  <h2>Results</h2>
  <p>Diverse with respect to thoughts, perspectives, nationalities and languages, yet bound together by our enthusiasm for science and research. Would you like to know more about us?
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  <p>The results of our experiments will appear here.
 
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<a href="https://2015.igem.org/Team:KU_Leuven/Project/About">Read more</a>
 
<a href="https://2015.igem.org/Team:KU_Leuven/Project/About">Read more</a>

Latest revision as of 14:47, 31 July 2015

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We designed a circuit capable of forming patterns in a controlled way. Using a modified and temperature-sensitive lambda repressor (cI), we can trigger formation at desired points in time. This time-dependent controllability, together with the possibility to change many different parameters and output signals, leads to an enormous tunability in the creation of the patterns. Our mechanism will stimulate advancements in a variety of industrial processes like the creation of novel bio-materials. This fundamental project could also speed up medical research projects like tumor formation and tissue regeneration.


Background

A detailed description about the interaction between our two cells and the genetic circuit can be found here.
Read more

Parts

A list of all used biobricks, the modifications we performed on them and the new ones we designed.
Read more

Methods

Here you can find the performed steps to create two different cell types and detailed quantification methods to determine interesting parameters
Read more

Results

The results of our experiments will appear here.
Read more