Team:ETH Zurich/modeling/qs

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(Difference between revisions)
(Retrieving degradation rates)
(Retrieving degradation rates)
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$$\text{with} K_{mAHL}=\frac{K_{mLux}^2 k_{-RLux}}{k_{RLux}(K_{mLux}^2+\alpha_{LuxR}^2/d_{LuxR})}$$
$$\text{with} K_{mAHL}=\frac{K_{mLux}^2 k_{-RLux}}{k_{RLux}(K_{mLux}^2+\alpha_{LuxR}^2/d_{LuxR})}$$
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We have dynamic curves for different initial AHL concentrations. We can see in the equation above that for initial AHL concentrations much higher than K<sub>mAHL</sub>, GFP is only produced and degraded and thus :
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We have dynamic curves for different initial AHL concentrations.  
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We can see in the equation above that for initial AHL concentrations much higher than K<sub>mAHL</sub>=0.3 nM, GFP is only produced and degraded and thus :
$$\frac{d[GFP]}{dt}=LeakyLux+\frac{k_{mRNAGFP} k_{GFP} \alpha_{LuxR}^2}{d_{LuxR}^2(Km_{Lux}^2+\alpha_{LuxR})}-d_{GFP}[GFP]$$
$$\frac{d[GFP]}{dt}=LeakyLux+\frac{k_{mRNAGFP} k_{GFP} \alpha_{LuxR}^2}{d_{LuxR}^2(Km_{Lux}^2+\alpha_{LuxR})}-d_{GFP}[GFP]$$
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Therefore at steady state,
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so by taking $$t_{1/2}=\frac{ln(2)}{d_{GFP}}$$ from experimental curves, we find $$d_{GFP} = 4.9 . 10^{-3} min^{-1}$$.
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For initial AHL concentrations much lower than K<sub>mAHL</sub>=0.3 nM, we find
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$$\frac{d[GFP]}{dt}=LeakyLux+\frac{k_{mRNAGFP} k_{GFP} \alpha_{LuxR}^2}{d_{LuxR}^2(Km_{Lux}^2+\alpha_{LuxR})} \frac{[AHL]^2}{K_{mAHL}^2}-d_{GFP}[GFP]$$
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and thus a steady state
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$$[GFP]=Constant*\frac(d_{GFP}-2d_{AHL})}(e^{-2d_{AHL}t}-e^{-d_{GFP}t})$$
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$$[GFP]=Constant*(e^{-2d_{AHL}t}-e^{-d_{GFP}t})$$
 
  This curve has a maximum at  
  This curve has a maximum at  
$$t_{max}=\frac{1}{d_{GFP}-2d_{AHL}}ln\big(\frac{d_{GFP}}{2d_{AHL}}\big)$$
$$t_{max}=\frac{1}{d_{GFP}-2d_{AHL}}ln\big(\frac{d_{GFP}}{2d_{AHL}}\big)$$
   
   
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This way we can find from experimental curves (exploiting here only the GFP data points) \[d_{AHL}=4,0.10^{-3} min^{-1}\]
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This way we can find from experimental curves (exploiting here only the GFP data points)  
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$$d_{AHL}=4,0.10^{-3} min^{-1}$$
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Revision as of 03:00, 17 October 2014

iGEM ETH Zurich 2014