Team:Paris/Modeling/Protocol Of Characterization
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{{Paris/Toggle2|'''III-B-Accessory plasmid'''|Team:Paris/Modeling/More_Accessory_Plasmid}} | {{Paris/Toggle2|'''III-B-Accessory plasmid'''|Team:Paris/Modeling/More_Accessory_Plasmid}} | ||
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==IV-Promoter and Transcription Factors insertion== | ==IV-Promoter and Transcription Factors insertion== |
Revision as of 02:29, 30 October 2008
Protocol of Characterization
I-Principles of the ExperimentsTo evaluate quantitativly the activity of a promoter in function of its transcription factors, we need data in which the different values of the activities are correlated with various known and controlled values of the transcription factors concentrations. II-Plasmid for promoter characterizationII-A-For study with one Transcription FactorII-B-For study with two Transcription FactorIII-Molecular design for Promoter Characterization PlasmidOur aim is to make this plasmid useful not only for our project but for the whole iGEM comunity. This is why we decided to keep the Biobrick spirit as much as we could, making the plasmid compatible with the parts, so the teams using it needs only the four traditional enzymes: EcoRI, XbaI, SpeI and PstI.We wanted also to make optional the introduction of a second tested transcription factor. The strategy is then based in two plasmids.
IV-Promoter and Transcription Factors insertionThe strategy to introduce the tested promoter and the tested transcription factor(s) is very simple. The only difficulty is that the order of insertion that we describe has to be respected to avoid unwanted restriction enzyme cuts:
-Cut Promoter with EcoRI and SpeI -Cut Principal plasmid with EcoRI and XbaI
-Cut Gene with XbaI and SpeI -Cut Principal plasmid+Promoter with SpeI -Check the right orientation of the 1st gene by PCR with appropiated primers If wanted…
-Cut Gene with XbaI and SpeI -Cut Accessory Plasmid with XbaI and SpeI -Check the right orientation of the 2nd gene by PCR with appropiated primers4
-Cut Accessory Plasmid+2nd gene with PstI -Cut Principal plasmid+Promoter+1st gene with SpeI -Check the right orientation of the 2nd gene expression system by PCR with appropiated primers V-Resulting plasmidsV-A-For one transcription factor effect
V-B-For two transcription factors effectVI-Protocole for plasmid constructionWe show here our plan to make these plasmids at the experimental level. VI-A-Principal Plasmid constructionWe devided the Principal Plasmid in two main blocks to go faster: VI-A-1-BlocksVI-A-2-Block 1 constructionthe result... VI-A-3-Block 2 constructionBiobrick assembly steps:
VI-A-4-Two-block assemblyVI-B-Accessory plasmid constructionAddition of restriction sites to B0015 by PCR: Addition of restriction sites to pBAD-AraC by PCR: Assembly: Specific Assumptions to the ExperimentsThe previous experiment is used to find parameters regarding to our modelization. However, the experiments themselves must be described in the same way to interprete these parameters consistently. In this order, the two inductible promoters will be described exactly as the others (those in the system), with similar rules of complexation and transcription. Otherwise, as we control the quantity of transcription factor by the introduction of small molecules, we must model the diffusion/complexation/induction phenomena, which lead from the latter to the former. By putting the cell culture in a chemostat, we will be able to control precisely the concentration of the input small molecules. At quasi steady-state, and assuming a simple, passive and quick diffusion, we consider the inner concentration, the outer medium concentration, and the input concentration beeing all equal. Thus, if we consider these "rules" it gives at quasi steady-state resulting in the following analytical expression of [Compl] and [Prot] : ...that we can introduce in the expression of the activity of pTet and pBad in function of their transcription factor. Thanks to these considerations, we can have access to these characterizations : ↓ Prior characterizations ↑
and then ↓ System characterizations ↑
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