Team:Washington/Project/Display

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Background

Our system hinged on finding a protein which could bind other proteins to the outside of the cell, but whose interaction with these proteins was weak enough to be disrupted by another small molecule. streptavidin presented itself as a logical choice. Several protein tags (such as the Nano-Tag 1) have been developed such that they bind streptavidin at the biotin binding site, but can be released when biotin is added to the system and binds to streptavidin. The ability for peptides to bind streptavidin and be released upon the addition of biotin is a technology currently used on a daily basis world-wide by labs purifying proteins. The major difference between the traditional system and our system is that streptavidin is attached to beads which are used in a column format in the traditional protein purification method. Our system will have streptavidin attached to the surface of the cell. Combining the display system with our target and secretion vector our vision is complete. A single cell can then produce, secrete, bind, and release any protein of interest.

Strept-biotin.png The binding of the Nano-Tag by streptavidin has an affinity of 4nM and has been used to purify multiple proteins. The ability of biotin to compete off the Nano-Tag in biding assays indicates that the binding occurs at the same site of streptavidin. Of great importance for incorporating streptavidin into our display system is that streptavidin is a common protein used in bio-chemical assays. Its ability to bind biotin is one of the strongest non-covalent interactions known. This allows for the utilization of biotin and streptavidin to act as molecular connectors in protein systems. Furthermore the availability of biotinylated and streptavidin linked fluorophores allows for an easy assay of their presence, using fluorescence microscopy2.

Next we needed a way to anchor the streptavidin to the outer membrane. The obvious choice was to use the LPP signal peptide and Outer Membrane Protein A (ompA) because this system has been extensively characterized as an expression system to display proteins on the cell surface. This LPP-ompA system has been used to display a diverse group of proteins, including:

  1. Green Fluorescent Protein (GFP) 3
  2. Organophosphorus Hydrolase (OPH) 4
  3. Cyclodextrin Glucanotransferase (CGTase) 5
  4. Methyl Parathion Hydrolase (MPH) 6
  5. Enhanced Green Fluorescent Protein (EGFP) 6


Thus, an appropriate display construct for our system would be Lpp-OmpA display construct fused to streptavidin, which would be anchored in the outer membrane and display streptavidin on the surface of the cell - which would bind a nanotag on our target protein in an interaction that could be disrupted upon the addition of biotin. When we checked the Parts Registry to see if someone had already built this or sometime similar that we could use as a starting part for our Idealized Protein Purification Display System, we found this Lpp-OmpA-streptavidin construct, submitted by Harvard iGEM team as part of their project in 2006 7. In fact, Harvard had submitted four biobrick parts which were all variations on the same theme. All four are fusion proteins which have a LPP signal peptide, either one or five trans-membrane ompA, and either monomeric or dimeric streptavidin. All the variations and the resulting biobricks are shown below:


Bio Brick OmpA trans-membrane domains Type of Streptavidin
J36848 1 monomeric
J36849 1 dimeric
J36850 5 monomeric
J36851 5 dimeric


A basic graphic (that we made) of the structure of this display system is shown below:

Display image.jpg


Harvard 2006 Surface Display System: Documented Data

Data regarding the activity of the Harvard iGEM 2006 Lpp-OmpA-Streptavidin construct has been published in IET Synthetic Biology in 2007 7. The author showed, by Western blot against the His tag fused to this construct, that their protein was being expressed within the cell. In order to demonstrate binding of their cell-surface-anchored streptavidin to biotin, the author incubated cells expressing Lpp-OmpA-streptavidin with an aptamer that linked biotin to a fluorophore using an oligonucleotide linker (see figure below). Any cells that express streptavidin on the surface of the cell should fluoresce in their assay - concordantly, when cells were incubated with this biotin-oligo-fluorescein aptamer, the author saw fluorescence on cells expressing Lpp-OmpA-Streptavidin, but not on Lpp-OmpA negative control. However, cells that expressed streptavidin on the surface also bound to the negative aptamer control (oligo-fluorescein) that lacked biotin, indicating that the oligo aptamer itself (and not biotin) may have been responsible for the association of the fluorophore to the cell surface. Thus, the Harvard 2006 iGEM team was never able to definitively show specific affinity of their Lpp-OmpA-Streptavidin construct.

HarvardIETSYNTH.jpg
L01W, Lpp-OmpA-Streptavidin monomer, no His Tag. L01H, Lpp-OmpA-Streptavidin monomer with His tag. L01S, Lpp-OmpA-Streptavidin dimer. L01, Lpp-OmpA alone). A, no aptamer added. B, With only ‘F’ 50 -fluorescently-tagged oligonucleotide. C, With fluorescently tagged streptavidin aptamer. D, With ‘B-F’ hybrid of 50 -biotinylated oligonucleotide annealed with 50-fluorescently-tagged oligonucleotide7.


Based on these experiments, we decided to try using this display system for our purpose. But first, since binding of the system to streptavidin had not be definitively shown, we had to verify binding of the Lpp-OmpA-Streptavidin construct to biotin for ourselves, and characterize this interaction.

Experiments

Harvard's Legacy 2006 Cell Surface Display Parts: Do They Work As Predicted?

In order to determine whether the Harvard 2006 iGEM streptavidin cell surface display parts were 1. expressed properly, and 2. bound biotin on the surface of the cell, we decided to do the following set of tests.

  1. Western to verify expression of Harvard 2006 surface display parts
  2. Assessment of biotin binding to cell surface by visualization in fluorescence microscope
  3. Assessment of biotin binding to cell surface by visualization in flow cytometer


Western Blot Demonstrates that Harvard 2006 iGEM Parts Are Expressed

The goal of this experiment was to make sure that the proteins were being expressed in our cell lines, and also to make sure that they were the correct length. This was crucial to ascertain before we moved on and began to test the parts. Even though we had the individual parts sequenced confirmed we needed to make sure that the proteins were being expressed correctly in the cell. Since all our the Harvard parts are conveniently his tagged, we used a Western blot reagent (horseradish peroxidase) that was conjugated to nickel-NTA (binds His tags)8.


Data

File:Western.jpg

The expected sizes of each of these proteins are shown in the table below:

Bio Brick Length (in kD)
J36848 21478.7
J36849 34600.9
J36850 31215.4
J36851 44972.3


Based on the above table, we were able to verify expression of the Harvard 2006 iGEM surface display parts. The varying intensity of the bands does not indicate the strength of expression because the protein amount was not normalized before it was inserted into the gel. Next we wanted to determine whether functional, biotin-binding streptavidin was displayed on the cell surface in cells expressing these parts. To test this, we used two different methods: visualization by fluorescence microscopy and by flow cytometer.

Streptavidin-Biotin Binding Is Not Visualized By Fluorescence Microscopy

The goal of this experiment was to confirm the display of streptavidin on the surface of the cell. To do this, we incubated cells expressing the Harvard 2006 iGEM streptavidin surface display parts with a fluorophore conjugated to biotin. If cells are expressing functional streptavidin on the surface of the cell, they should bind the biotinylated fluorophore, and this binding should be detectable in our florescence microscope as a halo of fluorescence surrounding each individual cell. As a positive control for streptavidin-biotin binding we incubated the biotinylated fluorophore with streptavidin-coated beads that were roughly the same size (with respect to volume) as our cells (except spherical) (see Notebook page for protocols).


Data

Positive Control

Negative Control

M beads1.png
M beads2.png

Induced Cells

Uninduced Cells

M cells1.png
M cells2.png


These images were analyzed using imageJ 9. The image on the left shows an image of the beads with flourophore added to them. These beads were diluted and spun diluted and spun down until the background level of florescence was low enough to get an accurate reading. We then used imageJ to analyze the intensity of a line going through the bead, which is demonstrated by the above schematic. On the positive control the edges of the streptavidin-coated beads show spikes in florescence, indicating binding of the biotinylated fluorophore to the beads. The negative control (beads without fluorophore) showed no such increase. This meant that our biotinylated flouophore binds to streptavidin in a detectable manner. When our cells were examined in the same manner, no difference could be seen in biotinylated fluorophore binding between cells that had induced expression of surface streptavidin (left) and uninduced cells which should not express the surface display protein (right). This was evidence that the streptavidin surface display part binding to biotin was very low / nonexistent. In order to verify this, we measured the binding of the biotinylated fluorophore to entire populations of streptavidin-expressing cells by flow cytomtery.

Streptavidin-Biotin Binding Is Not Visualized By Flow Cytometry

The goal of this experiment was to visualize biotin binding to streptavidin over a whole population of cells. Whereas the Microscope experiment looked at a few localized cells, we set the cytometer to look 50,000 streptavidin-expressing cells after incubation (and washing) with the biotinylated fluorophore and read the resulting florescence (see Notebook page for protocols). Like in the microscopy assay, we used streptavidin-coated beads as a positive control. The cytometer reads the flouresence of each individual particle (cell or bead) passing through it, which allows for accurate readings, and monitoring of a much larger sample size than we visualized under the microscope. The results of this experiment are described below.


Data

Beads cytometer.png


Cells cytometer.png


In the flow cytometer, our positive control, streptavidin-coated beads, showed a clear distinction between beads pre-incubated with biotinylated flourophore and the beads without flourophore, indicating that this assay is capable of visualizing streptavidin binding to the biotinylated fluorophore. Like in the microscopy assay, we did not observe appreciable binding occurring with any of the ompA-streptavidin parts to biotin at the population level. All streptavidin-expressing cells demonstrated low levels of florescence comparable to those of beads not pre-incubated with fluorophore.

Conclusion

In conclusion, we demonstrated expression of the Harvard 2006 streptavidin surface display parts via Western Blot. We were unable, however, to visualize binding between a biotinylated flourophore and the cells expressing these proteins. This indicates that the streptavidin display system is likely not binding biotin correctly. We hypothesize that streptavidin might not having enough room on the cell surface to form tetramers (which is its native state), and thus may not be binding to biotin with high efficiency. In order to generate a construct that demonstrates tight binding to to biotin, we propose to design a generalized cell surface display system, and to computationally design a biotin-binding streptavidin monomer using software developed at the University of Washington. These solutions are described below and in the future directions section.


References

    The Nano-tag, a streptavidin-binding peptide for the purification and detection of recombinant proteins doi:10.1016/j.physletb.2003.10.071
    Structural origins of high-affinity biotin binding to streptavidin. PC Weber, DH Ohlendorf, JJ Wendoloski, and FR Salemme (6 January 1989). Science 243 (4887), 85. [DOI: 10.1126/science.2911722]
    Display of green fluorescent protein on Escherichia coli cell surface. Shi H, Wen Su W. Department of Biological & Agricultural Engineering, University of Missouri-Columbia, 65211, Columbia, MO, USAEnzyme Microb Technol. 2001 Jan 2;28(1):25-34.
  1. Cell surface display of organophosphorus hydrolase using ice nucleation protein. Shimazu M, Mulchandani A, Chen W. Biotechnol Prog. 2001 Jan-Feb;17(1):76-80. Department of Chemical and Environmental Engineering, and Environmental Toxicology Program, University of California, Riverside, CA 92521, USA.
  2. Anchorage of cyclodextrin glucanotransferase on the outer membrane of Escherichia coli. Wan HM, Chang BY, Lin SC. Biotechnol Bioeng. 2002 Aug 20;79(4):457-64. Department of Chemical Engineering, National Chung Hsing University, Taichung, 402, Taiwan.
  3. Cell surface display of functional macromolecule fusions on Escherichia coli for development of an autofluorescent whole-cell biocatalyst. Yang C, Zhao Q, Liu Z, Li Q, Qiao C, Mulchandani A, Chen W. Environ Sci Technol. 2008 Aug 15;42(16):6105-10. State Key Laboratory of Integrated Management of Pest Insects and Rodents, Institute of Zoology, Chinese Academy of Sciences, Beijing 100101, China.
  4. Cell surface streptavidin. Tsai P. IET Synthetic Biol. 2007;1(1.2):32.
  5. http://www.kpl.com/catalog/productdetail.cfm?catalog_ID=17&Category_ID=448&Product_ID=1085
  6. http://rsbweb.nih.gov/ij/docs/index.html