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[[Media:Protein_domain_biobricks_presentation,_june_19_2006.ppt|Protein domain BioBricks presentation]]
<div class="tabs">
<ul>
<li id="current">[[IGEM:Harvard/2006/Fusion proteins|1. Main Page]]</li>
<li>[[IGEM:Harvard/2006/Fusion proteins/Notebook|2. Lab Notebook]]</li>
<li>[[IGEM:Harvard/2006/Fusion proteins/Literature|3. Literature]]</li>
<li>[[IGEM:Harvard/2006/Fusion proteins/Oligos|4. Oligos]]</li>
</ul>
</div>
<br style="clear:both">
<div class="tabcontent">
=Project Overview=
*The cell surface streptavidin project approaches targeting from a different direction, that is, from the cell. While the adaptamer project uses nucleic acids to target any two substrates to each other, the cell surface streptavidin project seeks to target any substrate(s) to the cell surface.
*The method of targeting would be implemented through the '''expression of streptavidin protein on the cell surface'''. Streptavidin is a protein which binds strongly to the biotin molecule, thus there is a common practice of biotinylating (adding biotin to) nucleic acids or peptides for streptavidin affinity purification or antibody conjugation. We would be utilizing this strong streptavidin-biotin binding to target <u>any</u> biotinylated nucleic acid or peptide to the outside of a cell expressing streptavidin on the surface. Here are some potentially useful applications.
**bringing a biotinylated protein to the cell surface for facilitated interaction with some other surface element.
**linking a cell with another protein/cell via a biotinylated aptamer.
**delivering a DNA nanobox to the cell surface through a biotinylated oligonucleotide.


[[Media:Targeting.ppt|Cell surface targeting]]
*Streptavidin would be expressed on the cell surface through the '''Lpp-OmpA surface display vehicle''' (Earhart, 2000). The complete vehicle consists of three fused protein domains.
**Signal peptide of lipoprotein (Lpp). This targets the protein to the outer membrane.
** Transmembrane domains of outer membrane protein A (OmpA). This spans the protein across the outer membrane to the cell surface.
**The surface protein.


==General Fusion==
*Assembly of the fusion protein would be carried out through a '''modified BioBricks assembly for protein domains''' (Phillips and Silver, 2006). Standard BioBricks parts separated from the flanking XbaI and SpeI sites by a single spacer nucleotide, in order to prevent Dam methylation. If you leave out these spacer nucleotides, the mixed site formed between assembled parts is six base pairs long, and so reading frame can be maintained between assembled protein domains.


<biblio>
<gallery>
#fusion1 pmid=1367360
Image:Lpp ompa.JPG|Lpp-OmpA surface display vehicle (Francisco et al., 1993)
# fusion1ab We have expressed a chimeric protein, comprising the LamB secretion signal sequence fused to mature bovine somatotropin (bST), in Escherichia coli. Plasmid constructs with the recA promoter showed significant protein accumulation prior to induction and cell lysis occurred after induction. In contrast, the lacUV5 promoter was tightly regulated. With the lacUV5 promoter, temperature and inducer concentration had significant effects on the total amount of recombinant protein produced and the fraction processed to mature bST. Quantitation of bST from shake flask cultures showed that 1-2 micrograms/ml/OD550 could be released from the periplasm by osmotic shock. N-terminal sequence analysis of the purified protein indicated that the majority of the secreted bST was correctly processed. The bST present in the osmotic shock fraction was judged to be correctly folded by comigration with oxidized methionyl-bST standard on a non-reducing polyacrylamide gel and activity in a bovine liver radioreceptor assay. These results provide a rapid method to produce bST for use in structure-function studies.
Image:Protein domain biobrick.JPG|Modified BioBricks assembly for protein domains
#fusion2 pmid=2476847
</gallery>
#fusion3 pmid=2548185
#fusion4 pmid=3079747
#fusion5 pmid=7691170
#fusion6 pmid=15695809
#fusion6ab Bradyrhizobium japonicum is an important nitrogenfixing symbiotic bacterium, which can form root nodules on soybeans. These bacteria have a gene encoding a putative avidin- and streptavidin-like protein, which bears an amino acid sequence identity of only about 30% over the core regions with both of them. We produced this protein in Escherichia coli both as the full-length wild type and as a C-terminally truncated core form and showed that it is indeed a high affinity biotin-binding protein that resembles (strept)avidin structurally and functionally. Because of the considerable dissimilarity in the amino acid sequence, however, it is immunologically very different, and polyclonal rabbit and human antibodies toward (strept)avidin did not show significant cross-reactivity with it. Therefore this new avidin, named bradavidin, facilitates medical treatments such as targeted drug delivery, gene therapy, and imaging by offering an alternative tool for use if (strept)avidin cannot be used, because of a deleterious patient immune response for example. In addition to its medical value, bradavidin can be used both in other applications of avidin-biotin technology and as a source of new ideas when creating engineered (strept)avidin forms by changing or combining the desired parts, interface patterns, or specific residues within the avidin protein family. Moreover, the unexpected discovery of bradavidin indicates that the group of new and undiscovered bacterial avidin-like proteins may be both more diverse and more common than hitherto thought.
</biblio>
<br>


==E. coli cell surface display==
=Results=
<biblio>
*We completed assembly of constructs using the following BioBrick parts.
#display1 pmid=16369779
**J04500. a composite part of a lac promoter (R0010) and a strong ribosome binding site (B0031)
#display2 pmid=11024362
**J36835. Lpp, the lipoprotein signal peptide.
#display3 pmid=9624691
**J36837 or J36838. OmpA, one (O1) or five (O5) transmembrane domains, respectively. Both have been shown to work (Earhart, 2000).
</biblio>
**J36841 or J36843. Streptavidin, either wild-type "SW" (Howarth, 2006), or single-chain dimeric "SD" (Aslan, 2005).
<br>
***Note: Streptavidin exists naturally as a soluble tetramer, but restriction to the surface might allow only monomeric/dimeric forms. What is interesting is that there has been research done to engineer such forms, in order to render biotin binding less strong but more easily reversible (Wu, 2005).
*Western blots were performed with transformed and induced cells, probing with anti-his6 antibody (each streptavidin had a His6 tag) and with anti-streptavidin antibody. Distinct bands were observed at the expected sizes in anti-his6 probing, and bands were observed at the same places with the anti-streptavidin probing. These results suggest the following.
**The promoter and ribosome binding site are functioning correctly for expression of these fusion protein construct.
**The BioBricks assembly of the fusion protein was successful in that reading frame was maintained, since the coding sequence for the His6 tag is found at the end of the construct.
**The streptavidin part of the fusion protein is still folding in such a way that anti-streptavidin antibody can recognize it.


===Notes on Autodisplay review (display1) ===
<gallery>
This is a review about the Autodisplay system used to express proteins on the E. coli cell surface. Some of the important features of this system are:
Image:Cell surface streptavidin construct.JPG|Diagram of cell surface streptavidin construct
*Utilizes E.coli-native AIDA-I as scaffold
Image:Cell surface streptavidin westerns.JPG|Western blots of cell surface streptavidin constructs
*Detection: monoclonal antibodies and protease cleavage sites created
</gallery>
*Protein unfolded during transport to cell surface.
*Variety of proteins have been displayed (p.610)
*Possibly to display catalytically active enzymes.
*Dimerization of proteins has been observed! (unique to this system); work on tetramers in progress. Protein anchor floats around membrane.
*Many proteins displayed: ~10^5 without loss of cell viability


The writer claims that the system is superior compared to all other display systems, but he might be biased since he created it.
=Future Plans=
 
*Now that we know that the construct is being expressed, we need to determine whether or not the construct is being localized to the outer membrane. We can separate the cell lysate by centrifugation, isolate the outer membrane proteins, and then perform Western blots, probing with anti-his6 and anti-streptavidin antibody.
===Notes on expressing genes in different compartments review (display2) ===
*If the construct is indeed being localized to the outer membrane, we then need to determine if the streptavidin is being displayed functionally on the cell surface. We can probe whole cells with anti-streptavidin antibodies or even fluorescently tagged streptavidin aptamers for in-cell westerns, or we can visualize surface binding of biotinylated, fluorescently tagged oligonucleotides under a microscope.
This is a more general review which is actually mostly about cell-surface display techniques. It offers a wider range of options, but came out in 2000, so new options probably have become available.
*If streptavidin is being expressed on the cell surface, we can switch in other engineered streptavidin clones and compare biotin binding. We can also try adding a length of amino acids between OmpA and streptavidin, which might give spatial flexibility to allow formation of tetramers on the cell surface or to allow the streptavidin to extend outside of any extracellular complexes.
 
*5 options; a good summary is found on page 3.
**Porins- Insert protein <= 60 residues
**Fimbriae- Insert protein <= 15 residues
**Lipoproteins
**GPI anchor
**Beta-autotransporter - same system as that used in display1
 
*The latter three were claimed to support large polypeptides. However, looking at a few of the articles seemed to suggest that they actually only tried them out with small polypeptides. The winners appear to be GPI anchors and beta autotransporters, although this might have changed in recent years. See display3 for the use of GPI anchors.
 
===GPI anchor(display3)===
I didn't read this one that thoroughly, but the point is that they forced E. coli to express functional levansucrase bound to a GPI anchor, Inp. Using these cells, they successfully converted sucrose to levan, which seems neat. Levansucrase, is about 400 a.a. residues long.
 
==Aptamers==
<biblio>
</biblio>
<br>
 
==Streptavidin==
<biblio>
#sa1 pmid=2201874
#sa2 pmid=2404273
#sa3 pmid=2406253
#sa4 pmid=2025272
#sa5 pmid=7499314
#sa6 pmid=9113646
#sa7 pmid=9037005
#sa8 pmid=9177186
#sa9 pmid=10796996
#sa10 pmid=11036649
#sa11 pmid=11959132
#sa12 pmid=10356256
#sa13 pmid=11959132
#sa14 pmid=15695809
#sa15 pmid=12000850
#sa16 pmid=16554826
#sa17 pmid=15840576
#sa18 pmid=16554831
#sa19 pmid=12182820
#sa20 pmid=11584006
#sa21 pmid=11345441
#sa22 pmid=15939877
#sa23 pmid=15845380
</biblio>
<br>
 
===Display of Tetrameric streptavidin on B. subtilis spore surfaces (sa23)===
 
As the title sugggests, a group was actually able to express _tetrameric_ streptavidin on the B. subtilis cell surface. This was a lot easier than doing it in other types of bacteria since they didn't have to worry about getting across the cell membrane or cell wall: when B. subtilis forms spores, a bunch of proteins form in the cytosol which then become the coats of spores... Additionally, spores form approximately when cells stop dividing, which somehow defeats the biotin sequestration problem. Actually, they never do a specific experiment to show this, but we are probably supposed to infer that it was enough to just see the streptavidin on the surface(?) Regardless, this organism is pretty different from E. coli, so it probably isn't terribly important.
 
==Related articles==
 
<biblio>
#other1 pmid=9893944
</biblio>
<br>
 
===Cd2+ binding ===
other1 is an old review article I came across talking about expressing metallothioneins on the cell surface of E. coli; these things bind Cd2+, so those interested in pollution cleanup might want to take a look.

Latest revision as of 09:12, 30 October 2006


Project Overview

  • The cell surface streptavidin project approaches targeting from a different direction, that is, from the cell. While the adaptamer project uses nucleic acids to target any two substrates to each other, the cell surface streptavidin project seeks to target any substrate(s) to the cell surface.
  • The method of targeting would be implemented through the expression of streptavidin protein on the cell surface. Streptavidin is a protein which binds strongly to the biotin molecule, thus there is a common practice of biotinylating (adding biotin to) nucleic acids or peptides for streptavidin affinity purification or antibody conjugation. We would be utilizing this strong streptavidin-biotin binding to target any biotinylated nucleic acid or peptide to the outside of a cell expressing streptavidin on the surface. Here are some potentially useful applications.
    • bringing a biotinylated protein to the cell surface for facilitated interaction with some other surface element.
    • linking a cell with another protein/cell via a biotinylated aptamer.
    • delivering a DNA nanobox to the cell surface through a biotinylated oligonucleotide.
  • Streptavidin would be expressed on the cell surface through the Lpp-OmpA surface display vehicle (Earhart, 2000). The complete vehicle consists of three fused protein domains.
    • Signal peptide of lipoprotein (Lpp). This targets the protein to the outer membrane.
    • Transmembrane domains of outer membrane protein A (OmpA). This spans the protein across the outer membrane to the cell surface.
    • The surface protein.
  • Assembly of the fusion protein would be carried out through a modified BioBricks assembly for protein domains (Phillips and Silver, 2006). Standard BioBricks parts separated from the flanking XbaI and SpeI sites by a single spacer nucleotide, in order to prevent Dam methylation. If you leave out these spacer nucleotides, the mixed site formed between assembled parts is six base pairs long, and so reading frame can be maintained between assembled protein domains.
  • Lpp-OmpA surface display vehicle (Francisco et al., 1993)

    Lpp-OmpA surface display vehicle (Francisco et al., 1993)

  • Modified BioBricks assembly for protein domains

    Modified BioBricks assembly for protein domains

Results

  • We completed assembly of constructs using the following BioBrick parts.
    • J04500. a composite part of a lac promoter (R0010) and a strong ribosome binding site (B0031)
    • J36835. Lpp, the lipoprotein signal peptide.
    • J36837 or J36838. OmpA, one (O1) or five (O5) transmembrane domains, respectively. Both have been shown to work (Earhart, 2000).
    • J36841 or J36843. Streptavidin, either wild-type "SW" (Howarth, 2006), or single-chain dimeric "SD" (Aslan, 2005).
      • Note: Streptavidin exists naturally as a soluble tetramer, but restriction to the surface might allow only monomeric/dimeric forms. What is interesting is that there has been research done to engineer such forms, in order to render biotin binding less strong but more easily reversible (Wu, 2005).
  • Western blots were performed with transformed and induced cells, probing with anti-his6 antibody (each streptavidin had a His6 tag) and with anti-streptavidin antibody. Distinct bands were observed at the expected sizes in anti-his6 probing, and bands were observed at the same places with the anti-streptavidin probing. These results suggest the following.
    • The promoter and ribosome binding site are functioning correctly for expression of these fusion protein construct.
    • The BioBricks assembly of the fusion protein was successful in that reading frame was maintained, since the coding sequence for the His6 tag is found at the end of the construct.
    • The streptavidin part of the fusion protein is still folding in such a way that anti-streptavidin antibody can recognize it.
  • Diagram of cell surface streptavidin construct

    Diagram of cell surface streptavidin construct

  • Western blots of cell surface streptavidin constructs

    Western blots of cell surface streptavidin constructs

Future Plans

  • Now that we know that the construct is being expressed, we need to determine whether or not the construct is being localized to the outer membrane. We can separate the cell lysate by centrifugation, isolate the outer membrane proteins, and then perform Western blots, probing with anti-his6 and anti-streptavidin antibody.
  • If the construct is indeed being localized to the outer membrane, we then need to determine if the streptavidin is being displayed functionally on the cell surface. We can probe whole cells with anti-streptavidin antibodies or even fluorescently tagged streptavidin aptamers for in-cell westerns, or we can visualize surface binding of biotinylated, fluorescently tagged oligonucleotides under a microscope.
  • If streptavidin is being expressed on the cell surface, we can switch in other engineered streptavidin clones and compare biotin binding. We can also try adding a length of amino acids between OmpA and streptavidin, which might give spatial flexibility to allow formation of tetramers on the cell surface or to allow the streptavidin to extend outside of any extracellular complexes.
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