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c-di-AMP

Part:BBa_K1045002:Experience

Designed by: iGEM Team Göttingen 2013   Group: iGEM13_Goettingen   (2013-06-24)
Revision as of 10:09, 26 October 2013 by Kati (Talk | contribs) (→‎Platereader Data)


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Applications of BBa_K1045002

The Riboswitch Reporter System

Microscope Data

As described on our [http://2013.igem.org/Team:Goettingen/Project Wiki], we designed a c-di-AMP sensing in vivo screening system in E. coli. This system could be used to screen for future antibiotic substances targeting the signal molecule c-di-AMP.

In order to do so, we combined the ydaO riboswitch fom B. subtilis with a CFP reporter. E. coli cells transformed with this construct were characterized by fluorescence microscopy. We grew our cells under different conditions: without and with c-di-AMP and with c-di-AMP plus polyamines. Polyamines were supposed to allow the uptake of c-di-AMP (Fig. 1, Oppenheimer-Shaaman et al., 2011).

Experimental details: E. coli cells were grown in LB medium until log phase. A culture aliquot was prepared on slides covered with 1 % agarose (in water) and the cells observed under the fluorescence microscope. For all images, the same exposure time was used. Microscope: Axioskop 40 FL fluorescence microscope; Camera: digital camera AxioCam MRm; Software for image processing: AxioVision Rel version 4.8 (Carl Zeiss, Göttingen, Germany); Objective: Neofluar series objective (×100 primary magnification); Filter set: Filter set 47 (BP 436/20, FT 455, and LP 480/40; Carl Zeiss) for CFP detection.

Fig. 1. left: YdaO without c-di-AMP, center: Ydao + c-di-AMP, right: YdaO + c-di-AMP + polyamines. All pictures represent merges of a bright field image and a CFP fluorescence image. The exposure time used to record CFP fluorescence was in all cases 1 second.

Since we saw no difference between the conditions, we assumed the B. subtilis promoter as part of the riboswitch to be so strong, that the amount of c-di-AMP entering the cells was just not enough to shut down expression of the reporter.

In order to achieve termination of transcription (e.g. in order to use this biobrick as a "negative inductor"), we suggest our shorter version of the riboswitch (BBa_K1045005, the riboswitch without its native promoter) combined with a weaker promoter.

Platereader Data

We furthermore produced quantitative data characterizing the growth and the fluorescence over time of the BL21 E. colis we transformed with the riboswitch reporter system BBa_K1045002. As a control, we used the plasmid carrying only the cfp gene, but not control elements for CFP expression (BBa_E0020).

Plate reader experiments were performed to quantify the strength of the ydaO riboswitch construct. In this setup, a dilution series of c-di-AMP ranging from 0 to 10000 nmol was used to test how strong the affinity of the riboswitch is. In addition to the c-di-AMP, polyamines (1 ”l/ml, 1000x stock solution) were added to series of samples to test if the uptake of c-di-AMP into E. coli could be enhanced by this additive. Two biological with two technical replicates were done. The graphs show the mean values of the technical replicates of one of the biological replicates.

Fig. 2 shows the growth curves recorded via the OD at 600 nm. The CFP fluorescence was measured at 480 nm and normalized to the cell density (Fig. 3).

Experimental setup: total time 21 h; 15 min measurement interval; 37°C, medium shaking; 96-well titer plate; Synergy Mx Monochromator-Based Multi-Mode Microplate Reader; Gen5 V2.01

Fig. 2: The growth of the E. coli cells was measured in a plate reader via the OD at 600 nm. To facilitate the differentiation between the growth phases, the OD at 600 nm is depicted in log scale. Top: E. coli cells carrying the control plasmid BBa_E0020; Bottom: E. coli cells transformed with the riboswitch reporter system BBa_K1045002. The cells were cultured with c-di-AMP in different concentrations or without c-di-AMP. The dilution series was done with or without polyamines (1 ”l/ml, 1000x stock solution). Note that for Fig. 2 top, some error bars are only shown as positive error bars. Since the corresponding negative error bars reached into the negative number range, it was not possible to depict them in a log scale diagram. Please enlarge the pictures for better reading (click on them).Riboswitch 3.png
Fig. 3: The CFP fluorescence measured at 480 nm was normalized to the OD at 600 nm. Top: E. coli cells carrying the control plasmid BBa_E0020; Bottom: E. coli cells transformed with the riboswitch reporter system BBa_K1045002. The cells were cultured with c-di-AMP in different concentrations or without c-di-AMP. The dilution series was done with or without polyamines (1 ”l/ml, 1000x stock solution). Please enlarge the pictures for better reading (click on them).Riboswitch 1.png




It was observed that the polyamines did not influence the uptake of c-di-AMP into the cells in one way or the other. The used concentrations of c-di-AMP had no measurable effect on the riboswitch either. The single riboswitch replicate, that showed lower fluorescence (highest concentration) could not be replicated. We assume this to be an artifact or a pipetting mistake. It is believed that even higher amounts of c-di-AMP are necessary to change the the riboswitch secondary structure such that cfp is not expressed. Due to time and financial issues, those hypotheses were not tested.

In conlusion, we showed that the E. coli cells expressed the CFP reporter over exponential and stationary phase under a promoter from B. subtilis ydaO gene. We also showed, that E. coli was not harmed or hindered in its growth, even under high concentrations of c-di-AMP, allowing it to be used in our screening system without the danger of killing our host.

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