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Team:ETH Zurich/modeling/qs
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| - | == Characterization == | + | == Characterization: K<sub>mLas</sub> == |
=== Data === | === Data === | ||
| - | + | For the Las system we used the same rate of formation of RLas as for RLux (reference). Again for fitting the remaining parameters we used our data which was mainly a transfer function of normalized GFP concentration as a function of input Las-AHL concentrations. (link to data) | |
=== Assumptions === | === Assumptions === | ||
| + | From the original set of reactions, we reduce the rate of production of mRNA<sub>Bxb1</sub> as a Hill function of RLux instead of Mass action kinetics in terms of P<sub>LuxON</sub> and P<sub>LuxOFF</sub>. | ||
| + | |||
| + | |||
| + | Assumption A | ||
| + | |||
| + | We assumed that the dimerization of RLux to DRLux is quick. Quasi steady state approximation (QSSA) as follows | ||
| + | |||
| + | $$\frac{d[DRLux]}{dt} = k_{DRLux} [RLux]^2 - k_{-DRLux} [DRLux] - d_{DRLux} [DRLux] \approx 0\\$$ | ||
| + | |||
| + | Assumption B | ||
| + | |||
| + | Further, from literature, we found that DRLux is specific to DNA and the dissociation constant is low (k<sub>m</sub> = 0.1nM) {Reference}. Therefore, we using QSSA again, | ||
| + | |||
| + | $$\frac{d[P_{LuxON}]}{dt} = k_{P_{LuxON}} [P_{LuxOFF}][DRLux] - k_{-P_{LuxON}} [P_{LuxON}] \approx 0\\$$ | ||
| + | |||
| + | Solving, we get the rate of production of mRNA<sub>Bxb1</sub> as | ||
| + | $$\frac{d[mRNA_{Bxb1}]}{dt} = L_{P_{Lux}} + \frac{K_{mRNA_{Bxb1}}RLux^2}{K_{mLux} + RLux^2 }- d_{mRNA_{Bxb1}} [mRNA_{Bxb1}]\\$$ | ||
| + | |||
| + | where | ||
| + | |||
| + | $$K_{mLux} = \frac {k_{-P_{LuxON}}}{k_{P_{LuxON}}}.\frac {k_{-DRLux} + d_{DRLux}}{k_{DRLux}}$$ | ||
| + | |||
| + | is a lumped parameter which we fitted to our data. | ||
| + | |||
| + | |||
| + | <!--Further, | ||
| + | $$K_{mRNA_{Bxb1}} = k_{mRNA_{Bxb1}} P_{LuxTOT}$$ which we assumed. --> | ||
Revision as of 11:54, 12 October 2014
Quorum Sensing
Model
The Quorum sensing module is mainly involved in receiving signals from the sender cells. The sender cells secrete some signalling molecules (inducers) which bind to the regulator molecules in the receiver cells, thus activating the transcription of certain genes. The model for this module is presented below.
Chemical Species
| Name | Description |
|---|---|
| Lux-AHL | 30C6-HSL is an acyl homoserine lactone which mainly binds to LuxR. |
| LuxR | Constitutively expressed regulator protein that can bind Lux-AHL and stimulate transcription of Bxb1. |
| RLux | LuxR and Lux-AHL complex which can dimerize. |
| DRLux | Dimerized form of RLux. |
| mRNABxb1 | mRNA of the Bxb1 integrase being transcribed by the Lux promoter. |
| Bxb1 | Serine integrase that can fold into two conformations - Bxb1a and Bxb1b. We chose to use a common connotation for both conformations - Bxb1. |
| Las-AHL | 30C12-HSL is an acyl homoserine lactone which mainly binds to LasR. |
| LasR | Constitutively expressed regulator protein that can bind Las-AHL and stimulate transcription of ΦC31. |
| RLas | LasR and Las-AHL complex which can dimerize. |
| DRLas | Dimerized form of RLas. |
| mRNAΦC31 | mRNA of the ΦC31 integrase being transcribed by the Lux promoter. |
| ΦC31 | Serine integrase that can fold into two conformations - ΦC31a and ΦC31b. We chose to use a common connotation for both conformations - ΦC31. |
Reactions
- For the Lux system
$$ \begin{align} &\rightarrow LuxR \\ Lux-AHL+LuxR & \leftrightarrow RLux\\ RLux+RLux &\leftrightarrow DRLux\\ DRLux+P_{luxOFF} & \leftrightarrow P_{luxON}\\ P_{luxON}&\rightarrow P_{luxON}+mRNA_{Bxb1}\\ mRNA_{Bxb1}&\rightarrow Bxb1\\ AHL &\rightarrow \\ LuxR &\rightarrow \\ RLux &\rightarrow\\ DRLux &\rightarrow\\ mRNA_{Bxb1} &\rightarrow\\ Bxb1 &\rightarrow \end{align}$$
- For the Las system
\begin{align} &\rightarrow LasR \\ Las-AHL+LasR & \leftrightarrow RLas \\ RLas+RLas & \leftrightarrow DRLas\\ DRLas+P_{LasOFF} & \leftrightarrow P_{LasON}\\ P_{LasON}&\rightarrow P_{LasON}+mRNA_{\phi C31}\\ Las-AHL &\rightarrow \\ LasR &\rightarrow \\ RLas &\rightarrow\\ DRLas &\rightarrow\\ mRNA_{\phi C31} &\rightarrow \\ \phi C31 &\rightarrow \\ \end{align}
Differential Equations
Applying mass action kinetic laws, we obtain the following set of differential equations. $$\begin{align*} \frac{d[Lux-AHL]}{dt} &= k_{-RLux}[R_{Lux}]-k_{RLux}[Lux-AHL][LuxR]-d_{Lux-AHL}[Lux-AHL]\\ \frac{d[LuxR]}{dt} &= \alpha_{LuxR} -k_{RLux}[Lux-AHL][LuxR] + k_{-RLux}[RLux] - d_{LuxR}[LuxR] \\ \frac{d[RLux]}{dt} &= k_{RLux}[Lux-AHL][LuxR] - k_{-RLux}[RLux] - 2 k_{DRLux} [RLux]^2 + 2 k_{-DRLux} [DRLux] - d_{RLux} [RLux] \\ \frac{d[DRLux]}{dt} &= k_{DRLux} [RLux]^2 - k_{-DRLux} [DRLux] - d_{DRLux} [DRLux] \\ \frac{d[P_{LuxON}]}{dt} &= k_{P_{LuxON}} [P_{LuxOFF}][DRLux] - k_{-P_{LuxON}} [P_{LuxON}]\\ \frac{d[mRNA_{Bxb1}]}{dt} &= L_{P_{Lux}} + k_{mRNA_{Bxb1}} [P_{LuxON}] - d_{mRNA_{Bxb1}} [mRNA_{Bxb1}]\\ \frac{d[Bxb1]}{dt} &= k_{mRNA_{Bxb1}} [mRNA_{Bxb1}] - d_{Bxb1}[Bxb1]\\ \end{align*}$$
The same holds true for the Las system.
Characterization: KmLux
Data
For the Quorum sensing module we used established experimentally determined parameters for the rate of formation of RLux (reference). Since, in the literature the other parameters were estimated or fitted to their data, we decided to determine the parameters specific to our system. Hence, we used our data for the remaining parameters. Our data was mainly a transfer function of normalized GFP concentration as a function of input Lux-AHL concentrations. (link to data)
Assumptions
From the original set of reactions, we reduce the rate of production of mRNABxb1 as a Hill function of RLux instead of Mass action kinetics in terms of PLuxON and PLuxOFF.
Assumption A
We assumed that the dimerization of RLux to DRLux is quick. Quasi steady state approximation (QSSA) as follows
$$\frac{d[DRLux]}{dt} = k_{DRLux} [RLux]^2 - k_{-DRLux} [DRLux] - d_{DRLux} [DRLux] \approx 0\\$$
Assumption B
Further, from literature, we found that DRLux is specific to DNA and the dissociation constant is low (km = 0.1nM) {Reference}. Therefore, we using QSSA again,
$$\frac{d[P_{LuxON}]}{dt} = k_{P_{LuxON}} [P_{LuxOFF}][DRLux] - k_{-P_{LuxON}} [P_{LuxON}] \approx 0\\$$
Solving, we get the rate of production of mRNABxb1 as $$\frac{d[mRNA_{Bxb1}]}{dt} = L_{P_{Lux}} + \frac{K_{mRNA_{Bxb1}}RLux^2}{K_{mLux} + RLux^2 }- d_{mRNA_{Bxb1}} [mRNA_{Bxb1}]\\$$
where
$$K_{mLux} = \frac {k_{-P_{LuxON}}}{k_{P_{LuxON}}}.\frac {k_{-DRLux} + d_{DRLux}}{k_{DRLux}}$$
is a lumped parameter which we fitted to our data.
Parameter fitting
Range of validity of the assumptions
These assumptions hold true for all input Lux-AHL concentrations.
Characterization: KmLas
Data
For the Las system we used the same rate of formation of RLas as for RLux (reference). Again for fitting the remaining parameters we used our data which was mainly a transfer function of normalized GFP concentration as a function of input Las-AHL concentrations. (link to data)
Assumptions
From the original set of reactions, we reduce the rate of production of mRNABxb1 as a Hill function of RLux instead of Mass action kinetics in terms of PLuxON and PLuxOFF.
Assumption A
We assumed that the dimerization of RLux to DRLux is quick. Quasi steady state approximation (QSSA) as follows
$$\frac{d[DRLux]}{dt} = k_{DRLux} [RLux]^2 - k_{-DRLux} [DRLux] - d_{DRLux} [DRLux] \approx 0\\$$
Assumption B
Further, from literature, we found that DRLux is specific to DNA and the dissociation constant is low (km = 0.1nM) {Reference}. Therefore, we using QSSA again,
$$\frac{d[P_{LuxON}]}{dt} = k_{P_{LuxON}} [P_{LuxOFF}][DRLux] - k_{-P_{LuxON}} [P_{LuxON}] \approx 0\\$$
Solving, we get the rate of production of mRNABxb1 as $$\frac{d[mRNA_{Bxb1}]}{dt} = L_{P_{Lux}} + \frac{K_{mRNA_{Bxb1}}RLux^2}{K_{mLux} + RLux^2 }- d_{mRNA_{Bxb1}} [mRNA_{Bxb1}]\\$$
where
$$K_{mLux} = \frac {k_{-P_{LuxON}}}{k_{P_{LuxON}}}.\frac {k_{-DRLux} + d_{DRLux}}{k_{DRLux}}$$
is a lumped parameter which we fitted to our data.
Parameter fitting
Range of validity of the assumptions
