Team:EPF Lausanne/Cell surface display

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Taxi.Coli: Smart Drug Delivery iGEM EPFL

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Overview

We adressed the following question :
How can one bind Nanoparticles to bacteria?

EPF-Lausanne-Overview-Coupling.jpg

Once we knew we wanted to bind nanoparticles to bacteria we needed an idea how to connect those two components. We came up with the idea to use one of the strongest non covalent interactions existing in nature, the interaction between streptavidin and biotin with a Kd of 10-14 mol/l. Streptavidin is a tetrameric protein, each of the four subunits can bind one biotin. The streptavidin-biotin complex is resistant against different pHs, temperatures and detergents. Moreover streptavidin binding is highly specific. So, in order to achieve our device and couple nanoparticles to bacteria, these latters need to express streptavidin on its surface on one sied and the nanoparticles need to be biotynilated on the other side.





INP-Streptavidin

E.Coli are Gram-negative bacteria and they have two membranes, an inner one and an outer one, separated by a periplasmic space. Furthermore, the outer membrane is covered with a glycocalix, a layer of sugars.
Team-EPF-Lausanne gram-negative.jpg There are different strategies to express a heterologous protein on the outer membrane of E.coli. Peptides can be fused with outer membrane proteins, or on fimbriae, fused to beta-autotransporters or lipoproteins, as for example the (Lpp)-OmpA protein which was used by the igem team 2006 of Harvard and the igem team 2009 of Washington. But then there is also another promising display system that uses ice nucleation protein (INP) from Pseusomonas syringae, which is a glycosyl-phosphatidyliositol anchored outer membrane protein. The GPI anchor is normally used by eukaryotes, so to see this motif in prokaryotes is quite unique. Over 90% of INP is found in the outer membrane when it is expressed in E.coli (Wolber et al). It has successfully been used for cell surface display of enzymes, single-chain antibodies and antigens. Jung et al ([http://www.ncbi.nlm.nih.gov/pubmed/9624691 [1]]) successfully expressed functional levansucrase (47 KDa) on the surface of E.coli by fusing it to INP. Streptavidin is only 14 kDa, so we assumed that it should be even easier for the E.coli to export it.

Streptavidin originates from the bacterium Streptomyces avidinii ([http://www.ncbi.nlm.nih.gov/nuccore/A00743.1 link ncbi link]). It is a tetrameric protein, which means it has 4 subunits, each of them can bind a biotin molecule. For our Biobricks we used different kinds of streptavidin.
The Biobrick BBa_K1111014 contains streptavidin that was cloned out of the Biobrick BBa_K283010.
The Biobrick BBa_K1111012 has the coding sequence of a monomeric streptavidin, which means only one of the four subunits of streptavidin is able to bind to biotin. This decreases the dissociation rate. The plasmid containing the sequence was provided by the laboratory of Mark Howarth at Oxford university Dept. of Biochemistry (http://users.ox.ac.uk/~bioc0756/MyWebs/activesite/index.htm).
The Biobrick BBa_K1111013 was designed to serve as a negative control for our experiments, it contains a dead version of streptavidin, which means it doesn’t bind to biotin.

Our Biobricks

Team-EPF-Lausanne Biobrick.jpg

onmouseover="This is our biobrick()"

INP-YFP Characterization

There was already a Biobrick that contained INP in the registry (BBa_K523013), so we decided to use it. It was designed by the Edinburgh igem team of 2011 (https://2011.igem.org/Team:Edinburgh/Cell_Display). This Biobrick encodes a fusion protein of a truncated and codon optimized INP and yellow fluorescent protein (YFP) under control of the LacZ promoter. The INP is truncated, it only contains the first 211 and last 97 amino acids that are normally encoded by the inaK gene. This is enough to target it to the outer membrane.
We improved the Biobrick BBa_K523013 by extensively characterizing it.

We used confocal microscopy (Thanks to Thierry Laroche from the "plateforme technologique de bio-imagerie et imagerie otpique" for operating the microscope) to see if it was expressed and eventually show surface localization.

Team-EPF-Lausanne INP-YFP-confocal.jpg
EPFL-INP-YFP-zoom.png


Looking at E.Coli we noticed that fluorescence was localized in specific spots, that the team of Edinburgh didn’t describe. We continued characterizing this biobrick by first determing the percentage of bacteria that was fluorescent, approximatively 30% of E.coli expressed YFP. We also counted the percentage of fluorescent bacteria that showed these dots of very strong fluorescence, around XX%. We started looking for an explanation for this phenomena and found in the literature, that INP forms aggregates in the cell membrane [http://www.ncbi.nlm.nih.gov/pubmed/2203606 [2]], to have good ice nucleation abilities. So it suggests that this also happens if INP is fused to another protein, which seems to be the case.

The team of Edinburgh grew bacteria and lysed them. After centrifugation, they looked where the fluorescence seemed concentrated. On the transformed bacteria, it was mainly the pellet that appeared fluorescent, meaning that the fusion protein was embedded in the membrane. The negative control, in contrast, showed fluorescence in the pellet as well as in the supernatant with the same intensity. This method was used because their microscopy was not good enough.
Like this team, we didn't succed to proof surface localization with the intrinsic fluorescence of the YFP. There was a signal, which was a goo sign, but quite diffuse. So we came up with an alternative strategy an immunofluorescent assay with an anti GFP antibody (which also binds to YFP because of their close conformations) (Thanks to XXX for providing us with the antibody). Then we made images with the microscope first a bright field, then exiting the YFP, and finally exiting the Antibody (red) By superimposing the images we could show nicely the two different fluorescent signals are colocalized. This proofs conclude that the fusion protein between INP and YFP is exported to the outer membrane.

Merge image of the YFP signal and the anti-YFP-Antibody signal
Team-EPF-Lausanne INP-YFP%.jpg
Team-EPF-Lausanne INP-YFP-AB-R-G.jpg
Team-EPF-Lausanne INP-YFP-AB-R-Y.jpg











Team-EPF-Lausanne beads-1-biotin-BF-G.jpg
Team-EPF-Lausanne Merged CC IPTG biotin.tif
Team-EPF-Lausanne Merged ISA2 IPTG biotin5.jpg











Team-EPF-Lausanne Merged ISA2 IPTG biotin4.jpg
Team-EPF-Lausanne Merged ISA2 IPTG biotin2.jpg











Results

In the following section, you will find results concerning our cell surface display work. Before moving on it is important to define the nomenclature we will further use:
1)Initially used plasmid:
INP_EYFP Biobrick: BBa_523013
Streptavidin Alive: BBa_K1111010
Streptavidin Dead: BBa_K1111011
Streptavidin iGEM: BBa_K283010

2) PCR reactions products
INP_construct = BBa_K523013 after PCR without EYFP; SA = Streptavidin Alive; SD = Streptavidin Dead; SI = Streptavidin iGEM.

3) Gibson reaction product names:
ISA = INP_Streptavidin Alive gibson product BBa_K1111012
ISD = INP_Streptavidin Dead gibson productBBa_K1111013
ISI = INP_Streptavidin iGEM BBa_K283010 gibson productBBa_K1111014



Our first experimental steps were to perform Polymerase Chain Reactions (PCR) in order to isolate the different streptavidins.

Figure x: 0.8% Gel electrophoresis to verify PCR of Streptavidin Alive coding sequence
Figure y: 0.8% Gel electrophoresis to verify PCR of Streptavidin Dead coding sequence
Figure z: 0.8% Gel electrophoresis to verify PCR of Streptavidin iGEM coding sequence











Figure x: 0.8% Gel electrophoresis to verify INP_Streptavidin Alive Gibson Assembly product
Figure y: 0.8% Gel electrophoresis to verify INP_Streptavidin Dead Gibson Assembly product
Figure z: 0.8% Gel electrophoresis to verify INP_Streptavidin iGEM Gibson Assembly product

















The previous Gels show that our PCR reactions to amplify coding sequences went fine. The sizes were the expected ones (the band migrated approximately at the same height than the 400 kb marker for streptavidin. The Gibson Assembly reaction to obtain our biobricks worked as expected, with twe bands seen in the lane corresponding to Gibson product. The shift between these bands is the hangovers corresponding to streptavidin ends.
Then another way to verify that our Gibson assembly recation potentially worked was to tranform cells with this product. The transformed cells should be able to grow on an antibiotic medium thanks to the resistance provided by the plasmid. The on only problem with this second verification is that the Gibson product could still contain parental plasmid,which insertion in cells can also lead to cells resistance and survival. Here, you are not provided with the transformation plates and their controls because they worked as expected. You can only observe plates containing cells from the glycerol stocks we made of our gibson products .

Figure x: INP_Streptavidin Alive Gibson transformed cells plated from the glycerol stock
Figure y: INP_Streptavidin Dead Gibson transformed cells plated from the glycerol stock
Figure z: INP_Streptavidin iGEM Gibson transformed cells plated from the glycerol stock











As the other checks did not provide informations about possible mutations, we also sent our constructs for sequencing, using VR and VF2 iGEM primers but also another forward primer we designed on ourselves results_ISA ; results_ISD ;results_ISI . The sequencing results were also good. From these previous documents, we can simply conclude that our basic cloning strategy was working. Now we needed to test the localisation at the outer membrane and the functionnality of the expressed protein. In order to do so, we designed immunostaining assays to verify localisation at the outer membrane and biotin-staining assay for the protein functionnality (see protocols). Then we visualized the samples using a NIKON Eclipse TI inverted microscope and also a Confocal microscope.

References

[1] Surface display of Zymomonas mobilis levansucrase by using the ice-nucleation protein of Pseudomonas syringae, Jung HC, Lebeault JM, Pan JG. (1998) [2] Clustering of ice nucleation protein correlates with ice nucleation activity, Mueller GM, Wolber PK, Warren GJ. (1990)