Fitting of the hybrid promoter

What experiment do we need to fit the activation behavior of the hybrid promoters?

The most simple way to check the response of an inducible promoter is to measure its activity (via a reporter gene like gfp) under different inducer concentrations. In our case, we are dealing with a hybrid promoter that should respond to two different inducers. Therefore, decided for an experiment covering the 2D space of the two inputs: lactate and AHL. However, we must not forget that AHL alone cannot induce the promoter, and needs to bind to the LuxR protein for that. This is why we also included the luxR gene, whose expression has been previously characterized, in our strain for this experiment.

Need for a better hybrid promoter activation model

We first tried to fit the parameters of the hybrid promoters relying on following model we had used until then:

\[\frac{\mathrm{d} [\text{luxI}]}{\mathrm{d} t} = a_{\text{LuxI}} (k_{\text{LuxI}} + (1 - k_{\text{LuxI}}) P_{\text{Lux-Lac}}) - d_{\text{LuxI}} [\text{luxI}]\]

where

\[\begin{aligned} P_{\text{Lux-Lac}} &= \frac{\left(\frac{[\text{LuxR-AHL}]}{K_{\text{LuxR}}} \right)^{n_{\text{LuxR}}}}{1 + \left(\frac{[\text{LuxR-AHL}]}{K_{\text{LuxR}}} \right)^{n_{\text{LuxR}}}} \times \frac{\left(\frac{[\text{Lac}]}{K_{\text{Lac}}} \right)^{n_{\text{Lac}}}}{1 + \left(\frac{[\text{Lac}]}{K_{\text{Lac}}} \right)^{n_{\text{Lac}}}} \\ \end{aligned}\]

However, given the experimental data we wanted to fit, it had become clear that this model had to be adapted. Indeed, it only takes into account a "global leakiness" k_luxI, which means that the promoter is considered to have the same leakiness in regard to LuxR-AHL and lactate. This is not at all what we observed on the activation pattern of the hybrid promoter: the leakiness towards lactate was far more pronounced than the leakiness towards LuxR-AHL.

This is why we changed our model of the hybrid promoter activation to take into account two separated leakinesses and fit better to reality:

\[\frac{\mathrm{d} [\text{luxI}]}{\mathrm{d} t} = a_{\text{LuxI}} \times P_{\text{Lux-Lac}} - d_{\text{LuxI}} [\text{luxI}]\]

where

\[\begin{aligned} P_{\text{Lux-Lac}} &= \Bigg[ k_{\text{Lux}} + (1-k_{\text{Lux}}) \cdot \frac{\left(\frac{[\text{LuxR-AHL}]}{K_{\text{LuxR}}} \right)^{n_{\text{LuxR}}}}{1 + \left(\frac{[\text{LuxR-AHL}]}{K_{\text{LuxR}}} \right)^{n_{\text{LuxR}}}} \Bigg] \Bigg[(k_{\text{Lac}} + (1-k_{\text{Lac}}) \cdot \frac{\left(\frac{[\text{Lac}]}{K_{\text{Lac}}} \right)^{n_{\text{Lac}}}}{1 + \left(\frac{[\text{Lac}]}{K_{\text{Lac}}} \right)^{n_{\text{Lac}}}} \Bigg] \\ \end{aligned}\]

Fit of the hybrid promoters responses

From the experimental data of the hybrid promoter response, we could fit four parameters of our model: both leakinesses of our hybrid promoters in regard to LuxR-AHL and lactate, and both half-activation concentrations of LuxR-AHL and lactate (expect for one hybrid promoter for the latter):