Team:EPF-Lausanne/Our Project

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Transcription is the first step of gene expression that can be regulated. Key elements of this regulation are proteins recognising and binding specific DNA sequences that either recruit the full  transcription machinery or prevent it from assembling on the DNA. It is this class of proteins, called transcription factors (TFs), that we intend to engineer.
Transcription is the first step of gene expression that can be regulated. Key elements of this regulation are proteins recognising and binding specific DNA sequences that either recruit the full  transcription machinery or prevent it from assembling on the DNA. It is this class of proteins, called transcription factors (TFs), that we intend to engineer.
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Existing DNA binding proteins can be a starting point for developing these new TFs. By changing their residues it is possible to modify the affinity of these proteins to a specific binding site and interact with the activation or repression mechanisms of the downstream gene transcription. Investigating these effects can improve our understanding of how the residue composition affects the TF's ability to recognise a given DNA consensus sequence.  
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Existing DNA binding proteins can be a starting point for developing these new TFs. By changing their residues it is possible to modify the affinity of these proteins for a specific binding site and alter how they interact with the activation or repression mechanisms of the downstream gene transcription. Investigating these effects can improve our understanding of how the residue composition affects the TF's ability to recognise a given DNA consensus sequence.  
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Engineering new transcription factors will not only give us a better idea of how they work but also extend the tool kit of the synthetic biologist. Within synthetic biology, TFs are used to design biological circuits where they act as building blocks for reporters, inverters, logic functions and switches . Extending the tool kit with new TFs will allow combinations of the devices that today share the same regulatory elements and thus cannot be used in the same system.
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Engineering new transcription factors will not only give us a better idea of how they work but also extend the tool kit of the synthetic biologist. Within synthetic biology, TFs are used to design biological circuits where they act as building blocks for reporters, inverters, logic functions and switches. Extending the tool kit with new TFs will enable combinations of devices that currently share the same regulatory elements and thus cannot be used in the same system.
== Goal ==
== Goal ==
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We want to enhance the diversity of the repressor-TF class by engineering new transcription factors that can bind unique promoter sequences different from the wild-type DNA binding site normally associated with TetR. Our proposed research plan for this summer is as follows:  
We want to enhance the diversity of the repressor-TF class by engineering new transcription factors that can bind unique promoter sequences different from the wild-type DNA binding site normally associated with TetR. Our proposed research plan for this summer is as follows:  
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'''1) introduce mutations in the TetR sequence and its binding site
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'''1) Introduce mutations in the TetR sequence and its binding site
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'''2) identify promising TF-binding site pairs (using in vivo and in vitro techniques)
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'''2) Identify promising TF-binding site pairs (using ''in vivo'' and ''in vitro'' techniques)
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'''3) conduct multiple rounds of selection to improve affinity and specificity to optimize new pairs of repressor-TFs.
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'''3) Conduct multiple rounds of selection to improve affinity and specificity to optimize new pairs of repressor-TFs.
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We are also developing a new negative-selection method: lysing the cells with interesting TF-binding site pairs, in order to recover their DNA. Coupled to a microfluidics device such as a chemostat chamber, our method would allow high-throughput ''in vivo'' selection.
== Strategy ==
== Strategy ==
During the summer, we worked on 3 main sections needed to complete the whole project:
During the summer, we worked on 3 main sections needed to complete the whole project:
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'''1) TetR mutants:''' Building mutations of TetR, both random ones and defined, already characterized in the litterature, ones. This part also comprised ''in vitro'' characterization, using MITOMI setup.
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'''2) Reporter plasmids:''' Assembling different plasmids allowing an ''in vivo'' characterization of TetR binding. Here we focused on RFP as a readout.
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'''1) TetR mutants:''' Building mutations of TetR, either random or defined (i.e. already characterized in the litterature). This part also comprised ''in vitro'' characterization, using MITOMI setup.
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'''3) T7 promoter variants:''' Coupling T7 promoters of different strength with a lysis cassette. This part includes both T7 characterization with RFP and a proof-of-concept that we can efficiently lyse cells and recover their DNA.
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'''2) Reporter plasmids:''' Assembling different plasmids allowing an ''in vivo'' characterization of TetR binding to its recognition sequence. We used RFP and a lysis cassette as a readout - either for characterization or for recovering DNA
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'''3) T7 promoter variants:''' Coupling T7 promoters of different strength with our 2 reporter genes, to have a better regulation of our Reporter plasmids system. This part includes both T7 characterization with RFP and a proof-of-concept that we can efficiently lyse cells and recover their DNA.
Section 1 presents the different TetR mutants and characterizes them ''in vitro''; sections 2 and 3 demonstrate '' in vivo'' TetR-Ptet interaction as well as recovery of DNA from the successful interactions.
Section 1 presents the different TetR mutants and characterizes them ''in vitro''; sections 2 and 3 demonstrate '' in vivo'' TetR-Ptet interaction as well as recovery of DNA from the successful interactions.

Latest revision as of 09:57, 21 September 2011