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Team:ETH Zurich/modeling/parameters
From 2014.igem.org
(Difference between revisions)
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|k<sub>-DBxb1</sub>||10<sup>-4</sup> min<sup>-1</sup>||Dissociation rate of DBxb1||Fitted | |k<sub>-DBxb1</sub>||10<sup>-4</sup> min<sup>-1</sup>||Dissociation rate of DBxb1||Fitted | ||
|- | |- | ||
| - | |k<sub>SABxb1</sub>||1 nM<sup>-1</sup>min<sup>-1</sup>||Rate of formation of | + | |k<sub>SABxb1</sub>||1 nM<sup>-1</sup>min<sup>-1</sup>||Rate of formation of SA<sub>Bxb1</sub> from DBxb1 and SI<sub>Bxb1</sub>||Fitted |
|- | |- | ||
| - | |k<sub>-SABxb1</sub>||10<sup>-4</sup> min<sup>-1</sup>||Dissociation rate of | + | |k<sub>-SABxb1</sub>||10<sup>-4</sup> min<sup>-1</sup>||Dissociation rate of SA<sub>Bxb1</sub>||Fitted |
|- | |- | ||
|d<sub>DBxb1</sub>||0.02 min<sup>-1</sup>||Degradation rate of DBxb1||Assumed | |d<sub>DBxb1</sub>||0.02 min<sup>-1</sup>||Degradation rate of DBxb1||Assumed | ||
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|k<sub>-Dϕc31</sub>||10<sup>-4</sup> min<sup>-1</sup>||Rate of dissociation of Dϕc31||Fitted | |k<sub>-Dϕc31</sub>||10<sup>-4</sup> min<sup>-1</sup>||Rate of dissociation of Dϕc31||Fitted | ||
|- | |- | ||
| - | |k<sub>SAϕc31</sub>||1 nM<sup>-1</sup>min<sup>-1</sup>||Rate of formation of | + | |k<sub>SAϕc31</sub>||1 nM<sup>-1</sup>min<sup>-1</sup>||Rate of formation of SA<sub>ϕc31</sub> from Dϕc31 and SI<sub>ϕc31</sub>||Fitted |
|- | |- | ||
| - | |k<sub>-SAϕc31</sub>||10<sup>-4</sup> min<sup>-1</sup>||Rate of dissociation of | + | |k<sub>-SAϕc31</sub>||10<sup>-4</sup> min<sup>-1</sup>||Rate of dissociation of SA<sub>ϕc31</sub>||Fitted |
|- | |- | ||
|d<sub>Dϕc31</sub>||0.02 min<sup>-1</sup>||Degradation rate of Dϕc31||Assumed | |d<sub>Dϕc31</sub>||0.02 min<sup>-1</sup>||Degradation rate of Dϕc31||Assumed | ||
Revision as of 09:15, 12 October 2014
Parameters
No model is complete without parameters. Our exhaustive list of parameters are summarised in the table below.
| Parameter | Value | Description | Reference |
|---|---|---|---|
| αLuxR | 60 nMmin-1 | Production rate of LuxR | Estimated |
| kRLux | 0.1 nM-1min-1 | Rate of formation of RLux from Lux-AHL and LuxR | Weber |
| k-RLux | 10 min-1 | Dissociation rate of RLux | Weber |
| kDRLux | 0.05 nM-1min-1 | Dimerization rate of RLux | Weber |
| k-DRLux | 1 min-1 | Dissociation rate of DRLux | Weber |
| KdPLux | 0.007652 nM | Dissociation rate constant for DRLux-PLux | Fitted |
| dLux-AHL | 0.004 min-1 | Degradation rate of Lux-AHL (30C6HSL) | Estimated/Fitted |
| dLuxR | 0.0174 min-1 | Degradation rate of LuxR | Weber |
| dRLux | 0.0174 min-1 | Degradation rate of RLux | Weber |
| dDRLux | 0.0231 min-1 | Degradation rate of DRLux | Weber |
| dBxb1 | 0.01 min-1 | Degradation rate of Bxb1 | Assumed |
| LPLux | 0.04458 nM-1min-1 | Leakiness after using riboswitch for PLux | Fitted |
| αLasR | 60 nMmin-1 | Production rate of LasR | Estimated |
| kRLas | 0.1 nM-1min-1 | Rate of formation of RLas from Las-AHL and LasR | Weber |
| k-RLas | 10 min-1 | Dissociation rate of RLas | Weber |
| kDRLas | 0.05 nM-1min-1 | Dimerization rate of RLas | Weber |
| k-DRLas | 1 min-1 | Dissociation rate of DRLas | Weber |
| KdPLas | 1.3672 nM | Dissociation rate constant for DRLas-PLas | Fitted |
| dLas-AHL | 0.004 min-1 | Degradation rate of Las-AHL (30C12HSL) | Estimated/Fitted |
| dLasR | 0.0174 min-1 | Degradation rate of LasR | Weber |
| dRLas | 0.0174 min-1 | Degradation rate of RLas | Weber |
| dDRLas | 0.0231 min-1 | Degradation rate of DRLas | Weber |
| dϕc31 | 0.01 min-1 | Degradation rate of ϕC31 | Assumed |
| LPLux | 0.02461 nM-1min-1 | Leakiness after using riboswitch for PLas | Fitted |
| kDBxb1 | 1 nM-1min-1 | Dimerization rate of Bxb1 | Fitted |
| k-DBxb1 | 10-4 min-1 | Dissociation rate of DBxb1 | Fitted |
| kSABxb1 | 1 nM-1min-1 | Rate of formation of SABxb1 from DBxb1 and SIBxb1 | Fitted |
| k-SABxb1 | 10-4 min-1 | Dissociation rate of SABxb1 | Fitted |
| dDBxb1 | 0.02 min-1 | Degradation rate of DBxb1 | Assumed |
| kϕc31 | 1 nM-1min-1 | Dimerization rate of ϕc31 | Fitted |
| k-Dϕc31 | 10-4 min-1 | Rate of dissociation of Dϕc31 | Fitted |
| kSAϕc31 | 1 nM-1min-1 | Rate of formation of SAϕc31 from Dϕc31 and SIϕc31 | Fitted |
| k-SAϕc31 | 10-4 min-1 | Rate of dissociation of SAϕc31 | Fitted |
| dDϕc31 | 0.02 min-1 | Degradation rate of Dϕc31 | Assumed |
| kToffBxb1 | 100 nM-2min-1 | Rate of flipping of Ton,i to ToffBxb1 | Assumed |
| k-ToffBxb1 | 100 nM-2min-1 | Rate of flipping of ToffBxb1 to Ton,f | Assumed |
| kToffϕc31 | 100 nM-2min-1 | Rate of flipping of Ton,i to Toffϕc31 | Assumed |
| k-Toffϕc31 | 100 nM-2min-1 | Rate of flipping of Toffϕc31 to Ton,f | Assumed |
| kGFP | 10 min-1 | Production rate of GFP | Assumed |
| kLuxI | 10 min-1 | Production rate of LuxI | Assumed |
| kLasI | 10 min-1 | Production rate of LasI | Assumed |
| dGFP | 0.0049 min-1 | Degradation rate of GFP | Estimated |
| dLuxI | 0.0167 min-1 | Degradation rate of LuxI | Weber |
| dLasI | 0.0167 min-1 | Degradation rate of LasI | Weber |
| kLux-AHL | 0.04 min-1 | Production rate of Lux-AHL (30C6HSL) from the LuxI | Weber |
| kLas-AHL | 0.04 min-1 | Production rate of Las-AHL (30C12HSL) from the LasI | Weber |
