Team:EPF Lausanne/Results summary

From 2013.igem.org

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[[Image: Team-EPFL-Lausanne 1.3_MS_WATER-MOPS-HEPES.jpg|thumb|700px|center|Figure 11 :FRAC_image, exposure: 400ms, Multiplier 1, from left to right: pH: 7, pH: 6.5, pH: 8.5 ]]
[[Image: Team-EPFL-Lausanne 1.3_MS_WATER-MOPS-HEPES.jpg|thumb|700px|center|Figure 11 :FRAC_image, exposure: 400ms, Multiplier 1, from left to right: pH: 7, pH: 6.5, pH: 8.5 ]]
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==Effector:==
==Effector:==

Revision as of 00:53, 5 October 2013

Taxi.Coli: Smart Drug Delivery iGEM EPFL

Header

This section provides a short summary of our main experimental achievements.



Contents

Nanoparticles:

We successfully synthesized different batches of nanoparticles, whose mean diameter is in a range between 200 nm and 300 nm. We ended up with seven different collections of samples: simple naked gelatin nanoparticles, simple biotinylated nanoparticles, CY5-labeled biotinylated nanoparticles, rGFP loaded nanoparticles (naked and biotinylated) and FITC-Dextran loaded nanoparticles (naked and biotinylated). All of them were characterized by DLS. These experiments show that two cargo transport strategies are possible: an external labeling (the one we used with CY5) or an internal loading (with FITC-Dextran and rGFP).

Figure 1: DLS experiment results of the first nanoparticles we obtained: their mean diameter is a bit below 200 nm.
Figure 2: ELISA-like assay. The high absorbance in wells B and H (containing biotinylated nanoparticles) was quantitatively detected using a plate reader. It showed that the nanoparticles were well biotinylated.
Figure 3: Confocal microscopy image showing outer CY5 labeling of the nanoparticles. The size of those nanoparticles is around 200 nm, which corresponds to the previous DLS characterization.
Figure 4: Fluorescent microscopy of the FITC-Dextran loaded nanoparticles. In contrast to the rGFP-loaded ones, their cargo stay inside. Those nanoparticles have been successfully characterized and biotinylated.
Figure 5: Fluorescent microscopy of GFP-expressing E.coli and nanoparticles. The bacteria were chemically labeled with streptavidin as a surrogate of the cell-surface display strategy. We then mixed them with biotinylated CY5-labeled nanoparticles. This merge image shows that the coupling is successful and that the nanoparticles are attached to the E.coli.




































Cell surface expression:

Characterization of an existing part: The part BBa_K523013 (INP-YFP construct to export YFP at the membrane) had been characterized only by a comparison of pellet and supernatant fluorescence after centrifugation. We wanted to characterize it better to be sure that it was expressed on the outer membrane. We successfully showed that the YFP-INP was expressed at the membrane.

This fluorescence microscopy image shows that YFP direct excitation signal colocalizes with YFP-antibodysignal, meaning that the protein is not only at the membrane, but at the outer one.

Figure 6: INP-YFP expressing cells A)detection by WFP excitation (514nm); B) detection by biotinylated anti-YFP antibody and avidin daylight (650nm); C) Merged images show colocalization, proving that the fusion protein is expressed at the outer membrane.













Expression of streptavidin at the cell surface: Gibson assemblies of the three different streptavidin constructs worked. and sequencing results matched with what expected. The growth curve of transformed E.Coli showed delayed growth, but bacteria still divide with an acceptable rate. The assay with a fluorescent biotin supposed to bind streptavidin gave some positive results (some bacteria appeared flurescent when excited at the corresponding wavelenght) but since the negative control also showed fluorescence, nothing could be proved. However, a Western blot against streptavidin showed bands at the expected size (53 kDa) of streptavidin, proving that it was expressed.

Figure 7: INP-streptavidin expressing cells from INP-strepta alive construct. Detection was made using fluorescently labeled biotin (green). Note that some cells were also positive on the negative control (competent cells), though they were less numerous.
Figure 8: Western blot made from total protein of INP-strepta (from all three constructs) transformed cells. Though there is much unspecific noise, there are bands at the right size.





















Sensing:

We inserted two pH-dependent and one constitutive promoter in front of a superfolded GFP sequence ( [http://parts.igem.org/Part:BBa_I746908 Biobrick BBa_I746916, Main page] ). All three promoters as well as the respective backbones were successfully isolated and amplified by PCR. The Gibson assemblies also worked and the sequencing results showed a 100% match between the inserted promoters and the refererence sequence.
Fluorescence measurements with the PlateReader were not conclusive since a lot of cells died in acidic pH, supposed to activate the promoter. However, even if we were not able to prove that acidic pH triggers expression of GFP, fluorescence could be seen under the microscope. This indicated that the promoters are functional. The constitutive promoter worked as expected, inducing the expression of superfolded GFP strongly. We used the fact that those cells' fluorescence could be seen by the naked eye and put the plasmid in our human practice kit (Our Kit ).

Figure 9: 0.8% Gel, PCRs of the three backbones
Figure 10: Plate used for the PlateReader experiment. The cell marked in a black rectangle are the ones containing the constitutive promoter.



















Figure 11 :FRAC_image, exposure: 400ms, Multiplier 1, from left to right: pH: 7, pH: 6.5, pH: 8.5







Effector:

With the exception of MMP9, the Gibson Assemblies worked for both Gelatinase GelE and MMP2. The primers that were designed had introduced a stop codon upstream of GFP. But since we had planned to do constructs with and without GFP attached to the gelatinase, we continued our experiments. The Western Blot with an anti-His tag antibody did not work. The His-Tag it may be hidden in the protein, contain a mutaion or could simply not bind to the nickel columns as they were stored improperly.

Overall:

We can say that except minor problems, cloning succedeed well. The Gibson assemblies globally worked out and we had no trouble growing the resulting transformed bacteria. The most delicate part was the characterization of our parts with functionnal assays. However, a lot of parts showed encouraging results but would maybe need to be studied in more detail. The naoparticles is the part that worked out well, nanoparticles could be synthetized and loaded. This project was ambitious and was almost achieved, and we are really proud of sharing our results with the iGEM community!