Team:ETH Zurich/labblog/20140824mod

From 2014.igem.org

(Difference between revisions)
(Monday, August 24th)
(Fitting quorum sensing dynamic curves)
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$$ \frac{d[GFP]}{dt}=\frac{k_{45}[P_{tot}][AHLi]^2e^{-2d_{AHL}t}}{K_{d4}K_{d3}}-d_{GFP}[GFP]$$
$$ \frac{d[GFP]}{dt}=\frac{k_{45}[P_{tot}][AHLi]^2e^{-2d_{AHL}t}}{K_{d4}K_{d3}}-d_{GFP}[GFP]$$
   
   
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  We find $$[GFP]=\frac{k_{45}[P_{tot}][AHLi]^2}{K_{d4}K_{d3}(d_{GFP}-2d_{AHL})}(e^{-2d_{AHL}t}-e^{-d_{GFP}t})$$.
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  We find  
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$$ [GFP]=\frac{k_{45}[P_{tot}][AHLi]^2}{K_{d4}K_{d3}(d_{GFP}-2d_{AHL})}(e^{-2d_{AHL}t}-e^{-d_{GFP}t})$$ .
  This curve has a maximum at  
  This curve has a maximum at  
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$$t_{max}=\frac{1}{d_{GFP}-2d_{AHL}}ln\big(\frac{d_{GFP}}{2d_{AHL}}\big)$$
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$$ t_{max}=\frac{1}{d_{GFP}-2d_{AHL}}ln\big(\frac{d_{GFP}}{2d_{AHL}}\big)$$
   
   
  This way we can find from experimental curves $$d_{AHL}=4,0.10^{-3} min^{-1}$$
  This way we can find from experimental curves $$d_{AHL}=4,0.10^{-3} min^{-1}$$
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This AHL degradation rate is alumped parameter between internal and external degradation rates, equivalent to $$d_{AHLext}+\alpha d_{AHLint}$$ where $$\alpha$$ is the fraction of the volume occupied by cells in the whole culture. From that on we could find reasonable values for internal and external AHL degradation rates.  
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This AHL degradation rate is alumped parameter between internal and external degradation rates, equivalent to $$d_{AHLext}+\alpha d_{AHLint}$$ where &alpha is the fraction of the volume occupied by cells in the whole culture. From that on we could find reasonable values for internal and external AHL degradation rates.  
Finally the curves simulated by our model with these parameters fit the experiments quite well:
Finally the curves simulated by our model with these parameters fit the experiments quite well:

Revision as of 19:57, 11 October 2014