3xCre3xAP1-miniCMV-miRFP670

Usage and Biology

When ß-lactams bind to the PASTA domain of PknB, its kinase domain phosphorylates ATF2, which then binds to our promoter. The promoter was identified by (Miller et al., 2010) as cyclic AMP responsive element (Cre)-sequence. ATF2-binding site is a consensus: 5-GTGACGT[AC][AG]-3) cAMP response element (CRE) (Hai et al., 1989). Based on observations made by Miller and colleagues (2010) showing similar kinase mechanisms between the prokaryotic PknB and eukaryotic MAPK towards ATF2, we generated a synthetic ATF2-responsive promoter construct with three Cre and three AP1 binding sites as well as a miniCMV promoter sequence. ATF2 was identified as the best PknB interaction partner. As with all our constructs, our promoter is followed by a fluorescent marker gene miRFP670 to detect specific activation

Cloning

Theoretical Part Design

We placed the miRFP670 fluorescent marker (K5317002) downstream behind this synthetic promotor (K5317017).

Sequence and Features

Cloning

This plasmid was engineered with NEBBuilder HIFI assembly method. First the backbone eGFP-C2neo was lineraized with AseI and BamHI, creating matching overhangs to the synthesized ATF2-3xCre3xAP1-Promoter_miniCMV sequence and the miRFP670 gene in the backbone ensured seamless cloning with predetermined order. We have designed this sequence containing triplicates of the Cre binding site as well as the AP1 binding site to increase the signal intensity. To ensure an optimal gene expression of miRFP670 we clonded behind the recognition sequenz of ATF1 a mini-CMV-Promotor. The promoter insert was synthesized with the correct overhangs already. The miRFP670 reporter gene was amplifyied by PCR using the primers in table 1.

Table 1: Primers used to amplify miRFP670 with matching 3' and 5' overhangs.

Figure 1: Assembled vector map with ATF2-3xCre3xAP1-Promoter_miniCMV_miRFP670 integrated into the pEGFP-C2 backbone.

Characterisation

Transfection experiments in mammalian HEK293T cells assessed the promoter functionality, sensitivity and specifity. The fully assembled cell-based beta-lactam-sensor requires the successful triple-transduction with the detecting unit, CMV-EGFP-PknB, the signal transmitting unit, CMV-ATF2-mRuby2, and the receiving and signal translating into a fluorescence signal unit, the promoter ATF2-3xCre3xAP1-miniCMV_miRFP670. However, before all three are introduced into the cell and tested with antibiotic stimulation, its neccessary to test them alone and control any sensor-unrelated responses of the promoter.

Single-transfection experiments

The composite part carrying plasmid was introduced via transfection to establish a baseline of endogenous promoter activity before performing co-transfection experiments with the CMV-ATF2-mRuby2 (composite part K5317016) and CMV-EGFP-PknB carrying plasmid (composite part K5317013) for ampicillin stimulation. The EGFP, mRuby and miRFP650 fluorescence signal was analyzed for presence and localization by microscopy.

Figure 2: Representative microscopic images of HEK293T cells expressing ATF2-3xCre3xAP1-Promoter_miniCMV_miRFP670. Shown are fluorescence channel for eGFP, mRuby and miRFP670. The basal activity of the promote is presented in the upper row. The promoter activity after induction with 100 µg/mL ampicillin for four hours is demostrated in the lower row.

The single-transfection experiment with the promoter and with or without the presence of beta-lactams demonstrated no unspecific signals from the miRFP670 in the green or lower red channels. The specific miRFP670 signal did not increase after incubation with ampicillin es expected since the signal detecting and transmitting units are not present in the cell. Rather less cells demonstrated a miRFP670 signal with ampicillin incubation. But its important that this could ba a result of different transfection efficiencies in the representative wells.

Triple-transfection experiments

To actually test the functionality of the cell-based beta-lactam-sensor, HEK293T cells were triple-transfected with all neccessary parts for signal detection (EGFP-PknB), signal transmission (ATF2-mRuby2) and signal emittance (ATF2-3xCre3xAP1-miniCMV_miRFP670) and the fluorescence signals analysed via microscopy and later on FACS analysis.

Figure 3: Representative microscopy image of HEK293T cells expressing EGFP-PknB, ATF2-mRuby2 and ATF2-3xCre3xAP1-Promoter_miniCMV_miRFP670. Shown are the fluorescence channels for EGFP, mRuby2 and miRFP670 (first three images from the left) and an overlay of the three channels (right). In a) is shown the basal activity of the promoter. In b) is shown the promoter activity after induction with 100 µg/mL ampicillin after four hours of incubation.

The representative images in figure 3 show nicely the correct localizations of all three sensor components with EGFP-PknB beeing mostly localized in the membrane regions, the mRuby2-ATF2 singal beeing emitted from the nucleus and the miRFP670 from the nucleocytoplasm. The detectable miRFFP670 signal even without the presence of ampicillin could be explained by possible binding of ATF2 to the 3xCre3xAP1-sites after its activation via other mammalian mechanisms, since ATF2 is a mmamalian transcription factor and possibly andogenously expressed and active.

FACS Analysis

Figure 4: Quantitive validation of reporter activity by flow cytometry analysis. The percentage of cells expressing the fluorophore under the control of the tested ATF2-3xCre3xAP1-Promoter is displayed as a function of various concentrations of ampicillin.

The results in Figure 4 are presented in the bar chart displayed in figure 10. Here, the percentage of cells expressing the fluorophore under the control of the tested ATF2-3xCre3xAP1-Promoter is displayed as a function of various concentrations of ampicillin.

References

Hai, T. W., Liu, F., Coukos, W. J., & Green, M. R. (1989). Transcription factor ATF cDNA clones: An extensive family of leucine zipper proteins able to selectively form DNA-binding heterodimers. Genes & Development, 3(12b), 2083–2090. https://doi.org/10.1101/gad.3.12b.2083

Miller, M., Donat, S., Rakette, S., Stehle, T., Kouwen, T. R. H. M., Diks, S. H., Dreisbach, A., Reilman, E., Gronau, K., Becher, D., Peppelenbosch, M. P., Van Dijl, J. M., & Ohlsen, K. (2010). Staphylococcal PknB as the First Prokaryotic Representative of the Proline-Directed Kinases. PLoS ONE, 5(2), e9057. https://doi.org/10.1371/journal.pone.0009057