Difference between revisions of "Team:Bielefeld-CeBiTec/Results/PRIA"
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<h2>Successful detection of an analyte <i>in vitro</i> </h2> | <h2>Successful detection of an analyte <i>in vitro</i> </h2> | ||
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| − | + | <div> <p>The main achievement in this subproject was the establishment of a protocol for the <b>P</b>lasmid <b>R</b>epressor <b>I</b>nteraction <b>A</b>ssay (PRIA). We demonstrated that the detection of analytes in drinking water is feasible in a biological system without transcription or translation of reporter proteins, but just by detecting the disruption of the bond between plasmid DNA and a repressor protein. We optimized the system for the LacI-<i>lacO</i> model system and are confidential to apply it to all sorts of analytes in the near future. | |
| − | + | ||
</br> | </br> | ||
The procedure performed for the PRIA was based on histagged repressor proteins immobilized on a Ni-NTA agarose column. Plasmid DNA containing the operator site for specific binding of the repressor was added to the column, unbound plasmid was washed away and the restant plasmid could be eluted by addition of the analyte to the washing buffer. We analyzed this with simple gel electrophoresis. On a future test strip the immobilized DNA-protein complex would be provided.</br> | The procedure performed for the PRIA was based on histagged repressor proteins immobilized on a Ni-NTA agarose column. Plasmid DNA containing the operator site for specific binding of the repressor was added to the column, unbound plasmid was washed away and the restant plasmid could be eluted by addition of the analyte to the washing buffer. We analyzed this with simple gel electrophoresis. On a future test strip the immobilized DNA-protein complex would be provided.</br> | ||
| − | We worked out optimal conditions for the elution of the highest amount of DNA possible in the first elution step, since this would correspond to a high signal on the test strip. The concentration of salt turned out to be essential for the process and the optimal concentration was determined to be 500 mM potassium chloride in a slightly buffered solution. At this concentration most DNA was eluted in the first step, which was not the case with lower concentrations. Furthermore the binding of the plasmid to the protein was not impaired, as observed for higher concentrations.</br> <figure style="float:right; margin-left: 20px; width: | + | We worked out optimal conditions for the elution of the highest amount of DNA possible in the first elution step, since this would correspond to a high signal on the test strip. The concentration of salt turned out to be essential for the process and the optimal concentration was determined to be 500 mM potassium chloride in a slightly buffered solution. At this concentration most DNA was eluted in the first step, which was not the case with lower concentrations. Furthermore the binding of the plasmid to the protein was not impaired, as observed for higher concentrations.</br> <figure style="float:right; margin-left: 20px; width:200px;"> |
| − | <a href="https://static.igem.org/mediawiki/2015/4/4f/Bielefeld-CeBiTec_PT_salts_big.png" data-lightbox="PRIAResults" data-title="Effect of different salt concentrations on amount of DNA in the first elution step | + | <a href="https://static.igem.org/mediawiki/2015/4/4f/Bielefeld-CeBiTec_PT_salts_big.png" data-lightbox="PRIAResults" data-title="Effect of different salt concentrations on amount of DNA in the first elution step. Agarose gels with samples from washes and elutions of each step of the PRIA after addition of the plasmid. Each PRIA was performed with a buffer containing different amounts of potassium chloride. The only difference between the washing and the elution buffer was the addition of the analyte (in this case IPTG). After the third elution step, the protein bound to the column was eluted with an imidazole buffer to confirm its presence. The Ni-NTA agarose column was also applied to the gel to check for restant plasmid bound to it. The negative control was plasmid applied to a column without protein and washed with 250 mM KCl buffer. "><img src="https://static.igem.org/mediawiki/2015/b/be/Bielefeld-CeBiTec_PT_salts_small.png" alt="Sorry, cannot show you these brilliant bands at the moment"></a> |
| − | + | <figcaption>Effect of different salt concentrations on amount of DNA in the first elution step</figcaption></figure></div> <div>Tap water with the analyte alone could not disrupt the binding of the plasmid to the protein. The user would thus be required to add a certain amount of salt to his sample. Common sodium chloride is suitable for that purpose, as we tested (See <a href="https://2015.igem.org/Team:Bielefeld-CeBiTec/Results/PRIA#salt">below</a>). Nevertheless, the solution should be slightly buffered with TRIS-HCl or sodium/potassium phosphate. <br>To further reduce the time for the assay we also tested whether the complex could be formed prior to addition of the complex to the column. In this case the bond between repressor and plasmid could not be disrupted at all. In the agarose gels DNA was visible after the elution of the protein that was performed to verify the presence of the protein at the end of the essay. This step was necessary to demonstrate that the appearance of DNA in the agarose gel was not due to the elution of the whole plasmid-repressor complex. | |
</p> | </p> | ||
<figure id="salt" style="float:left; margin-right: 20px; width:300px;"> | <figure id="salt" style="float:left; margin-right: 20px; width:300px;"> | ||
| − | <a href="https://static.igem.org/mediawiki/2015/9/9c/Bielefeld-CeBiTec_PT-150602_PRIA-500mMNaCl.png" data-lightbox="PRIAResults" data-title="Usage of 500 mM NaCl instead of KCl"><img src="https://static.igem.org/mediawiki/2015/2/2b/Bielefeld-CeBiTec_PT_NaCl_small.png" alt="Sorry, cannot show you these brilliant bands at the moment"></a> | + | <a href="https://static.igem.org/mediawiki/2015/9/9c/Bielefeld-CeBiTec_PT-150602_PRIA-500mMNaCl.png" data-lightbox="PRIAResults" data-title="Usage of 500 mM NaCl instead of KCl. Substitution of 500 mM KCl by 500 mM NaCl does not alter the result of PRIA. A first step to user-friendly application is made, since the addition of common salt to the sample should not be a big problem."><img src="https://static.igem.org/mediawiki/2015/2/2b/Bielefeld-CeBiTec_PT_NaCl_small.png" alt="Sorry, cannot show you these brilliant bands at the moment"></a> |
| − | <figcaption> | + | <figcaption>Usage of 500 mM NaCl instead of KCl</figcaption> |
</figure> | </figure> | ||
| − | + | </div> | |
</div> | </div> | ||
Revision as of 09:52, 12 September 2015
PRIA Results
A cell-free detection system based on two purified components
Successful detection of an analyte in vitro
The main achievement in this subproject was the establishment of a protocol for the Plasmid Repressor Interaction Assay (PRIA). We demonstrated that the detection of analytes in drinking water is feasible in a biological system without transcription or translation of reporter proteins, but just by detecting the disruption of the bond between plasmid DNA and a repressor protein. We optimized the system for the LacI-lacO model system and are confidential to apply it to all sorts of analytes in the near future.
The procedure performed for the PRIA was based on histagged repressor proteins immobilized on a Ni-NTA agarose column. Plasmid DNA containing the operator site for specific binding of the repressor was added to the column, unbound plasmid was washed away and the restant plasmid could be eluted by addition of the analyte to the washing buffer. We analyzed this with simple gel electrophoresis. On a future test strip the immobilized DNA-protein complex would be provided.
We worked out optimal conditions for the elution of the highest amount of DNA possible in the first elution step, since this would correspond to a high signal on the test strip. The concentration of salt turned out to be essential for the process and the optimal concentration was determined to be 500 mM potassium chloride in a slightly buffered solution. At this concentration most DNA was eluted in the first step, which was not the case with lower concentrations. Furthermore the binding of the plasmid to the protein was not impaired, as observed for higher concentrations. 
To further reduce the time for the assay we also tested whether the complex could be formed prior to addition of the complex to the column. In this case the bond between repressor and plasmid could not be disrupted at all. In the agarose gels DNA was visible after the elution of the protein that was performed to verify the presence of the protein at the end of the essay. This step was necessary to demonstrate that the appearance of DNA in the agarose gel was not due to the elution of the whole plasmid-repressor complex.
Immobilization of Protein on paper
We aimed at the development of a paper-based system and had optimized the procedure for immobilized protein. So we pursued the approach which was based on repressors fused to a cellulose binding domain (BBa_K1321340). We cloned and expressed fusion proteins for our LacI-lacO model system, the repressor ArsR for the detection of arsenic and for the protein BlcR, the repressor of the blc-operon, which we were working with in order to detect date rape drugs. When pipetted onto various types of paper, the presence of the proteins could be confirmed by staining and destaining of the paper with Coomassie brilliant blue and destaining solution used for SDS-PAGES. The binding was unspecific. Any protein could be pipetted onto paper and be detected with Coomassie brilliant blue after over night washing. Besides, most CBDs bind to microcristalline cellulose or cotton.(Lethiö et al.,2001) We were not able to find a hint about the binding of CBDs to common paper. That is why we focused on the second approach with immobilized DNA.
Successful immobilization of DNA on paper
Based on a method proposed by Araújo et al. (Araújo et al., 2012) DNA was immobilized on filter paper previously activated wth p-phenylene-diisothiocyanate (PDITC). To accomplish this, aminolabeled DNA is required. We made some adaptations to the original protocol in order to immobilize dsDNA instead of ssDNA. We omitted an 0.5 hs washing step with 4x SSC buffer, since this serves for the denaturing of DNA. Furthermore to be able to quantify the DNA immobilized on paper we hybridized the amino labeled operatorstrand with the complementary strand that was Cy3 labeled. This was performed via a simple annealing of two oligonucleotides. So by detecting the Cy3 label via the Typhoon Fluorescence scanner we could be sure, that the immobilized DNA was the correct dsDNA. We were not able to acquire molecular sieves at the start of our project, so we dissolved the PDITC in pure ethanol, which is easily available in any standard molecular biology laboratory. We compared the loss of the Cy3 fluorescence signal upon washing on paper that was activated with PDITC disolved in ethanol to the loss of signal upon washing on paper that was activated with PDITC disolved in dried DMSO. The immobilization works even better if ethanol is used as a solvent for the PDITC. The loss of signal can be mainly attributed to the washing out of DNA, since an control showed, that the decrease of fluorescence of the Cy3 dye due to repeated scanning is minimal. We applied three different liquids for washing: an antibody stripping buffer, that is normally used to disrupt all protein-protein interactions in an western blot, which resulted in strong blurring of the DNA spots; water and the binding buffer, that was normally used in PRIA. Compared to the restant fluorescence signal on the acitvated papers the signal on the not activated papers decreases strongly, indicating that the immobilization was successful.
Successful Expression and purification of functional sfGFP-tagged repressor proteins
For the approach to a paper-based test strip with immobilized DNA, super folding Green Fluorescent Protein (sfGFP)-tagged repressor proteins are required for the generation of a signal upon release. We tagged the repressors for the detection of arsenic, date rape drugs, as well as our model protein LacI with sfGFP C-terminally. Their specific binding to the operator DNA could be proven by EMSA. Upon increasing amounts of protein binding to the electrophorectic mobility of the DNA fragments decreases. This generates the EMSA shift.(See below.)
Successful simultaneous visualization of Protein and DNA on paper
The next step for us was to establish the DNA-protein complex on paper. In order to test if the complex formation was successful we required at first an method for the simultaneous visualization of both components. Since the repressorproteins we wanted to detect were tagged with sfGFP, they were detectable via fluorescence. DNA was labeled with Cy3 containing primers, therefore it was also detectable on paper. We visualized both components with an Ettan Dige Scanner normally used for 2D-SDS-Pages. The exposure time was optimized as was the paper that was used.
Tecan Measurements
Siddiki et al. immobilized biotinylated DNA in an 96-well plate and added cell lysated to each well. The cell lysates contained GFP-tagged repressor proteins. After washing the wells once they would add their sample to the wells, wait for 15-30 minutes and measure the flourescence in the supernatant. They report a concentration dependent increase of the fluorescence in response to cadmium and arsenic. This increase in fluorescence was due to the dissociation of the GFP tagged repressor proteins from the immobilized operator sites: the tagged proteins were eluted from the wells and became part of the supernatant. (Siddikiet al.) We tried to reproduce these finding with a 96 well plate coated with avicell microcrystalline cellulose. In the Tecan measurement you can see that DNA was immobillized, since the Cy3 signal is above the background signal generated by the paper. Nevertheless the measurement of the supernatant fluorescence showed no clear tendency, neither did the fluorescence that remained in the wells. We tested different conditions: the buffers used in our optimized PRIA protocol and the buffers described by Siddikiet al., to avoid unspecific binding of the protein to the cellulose we tested the effect of blocking with milk powder solution prior to addition of the cell lysate for both buffercombinations. (See below). None of the observed changes was significant.
References
Araújo, Ana Caterina; Song, Yajing; Lundeberg, Joakim; Stahl, Patrik L.; Brumer, Harry (2012): Activated Paper Surfaces for the Rapid Hybridization of DNA through Capillary Transport. In Anal. Chem. 2012, 84, pp. 3311-3317. DOI: 10.1021/ac300025v
Lehtiö, Janne; Wernerús, Henrik; Samuelson, Patrik; Teeri, Tuula T.; Stahl, Stefan (2001): Directed immobillization of recombinant staphylococci on cotton fibers by functional display of a fungal cellulose-binding domain. In FEMS Microbiol Lett. 2001, 195(2), pp. 197-204. DOI: 10.1111/j.1574-6968.2001.tb10521.x 197-204
Siddiki, Mohammad Shohel Rana; Kawakami, Yasunari; Ueda, Shunsaku; Maeda, Isamu (2011): Solid Phase Biosensors for Arsenic or Cadmium Composed of A trans Factor and cis Element Complex.In Sensors 2011, 11, pp. 10063-10073. 10.3390/s111110063