AHL sfGFP+ASV reporter

This composite part produces sfGFP when a large enough concentration of lactone (AHL) is present in the medium. In this case, it constitutively produces LuxR, which binds to the lactone present in the medium and together, they form a complex that activates the pLux promoter, generating the sfGFP whose fluorescence can be measured. The schematics of this composite part can be seen in Figure 1.

Figure 1. Scheme of the interactions on the AHL sfGFP+ASV tag reporter sensor cell.

This system allows a fast report on the AHL concentrations in the medium, something important to know the amount of protein. The composite part is Biobrick compatible.

This composite part is composed by all the following parts:

BBa_B0015: A reliable double terminator that consists on BBa_B0010 and BBa_B0012.

BBa_B0033: A weak RBS. The RBS.4 (derivative of BBa_0030).

BBa_B0032: A medium RBS. The RBS.3 (medium) (derivative of BBa_0030

BBa_R0062: LuxR & HSL regulated promoter.

BBa_J72005: Ptet Promoter. Is activated by the AHL-LuxR complex

BBa_K3484006: sfGFP+ASV coding sequence

Model Characterization

A model to characterize the AHL sfGFP+ASV reporter was designed. It must be consider that the sfGFP production follows a Hill function, as it is activated by a complex. Moreover, LuxR is constitutively expressed and due to the law of mass action can be simplified (For more detail go to . The final ODE system can be seen below (Eq.1).

Equation 1. Final ODE system of the AHl sfGFP+ASV reporter model.

From the ODE system (Eq.1) a transfer function can be derived if LuxR and GFP are on a steady state (dy/dx=0). This transfer function (Eq.2) allows us to connect the concentration of lactone (AHL) in the media to the fluorescence that the sensor cells are emitting. The function has the shape of a Hill function with a low hill coefficient (n=1), thus meaning that the sensor will not be hypersensitive and it will have a long dynamic range where it can sense the AHL concentration[1][2].

Equation 2. Transfer function of the AHL sfGFP+ASV biosensor model

Figure 2. GFP fluorescence emission with respect to different AHL concentrations from experimental data.

The transfer function (Eq.2) was fitted with experimental data to see if our model could follow real data. This data was extracted from a Plate-Reader analysis on GFP fluorescence emission with concentrations of lactone going from 100 pM to 100 µM. From these results we can conclude that there is a high correlation between the experimental and the modelling results, thus indicating that the sensor cell model we have developed sensor cell model reflects the real phenomena that happen in a sensor cell.

[1] Ballestero, M. C., Duran-Nebreda, S., Monta, R., Solé, R., Macía, J., Rodríguez-Caso, C. A bottom-up characterization of transfer functions for synthetic biology designs: lessons from enzymology. Nucleic Acids Research, 2014, Vol. 42, No. 22.

[2] Garcia-Ojalvo, J., Elowitz, M.B., Strogatz, S.H. Modeling a synthetic multicellular clock: repressilators coupled by quorum sensing. Proc. Natl Acad. Sci. U.S.A., 101, 10955–10960.

Characterization experiments

For the characterization a Plate-Reader analysis was made. All the information on the experimental conditions and parameters used are described on the table below (Table 1).

Sequence and Features