Difference between revisions of "Team:Toulouse-INSA-UPS/Description"

 
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         <h1 class="heavy">DESCRIPTION</h1>
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         <h1 class="heavy">DESCRIPTION</h1><hr/>
  
  
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             <a class="nav-link btn btn-secondary rounded-top corner-bottom mr-1" data-toggle="pill" href="#Desc_Part2" role="tab" style="color:white !important;">Our project</a>
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             <a class="nav-link btn btn-secondary rounded-top corner-bottom mr-1" data-toggle="pill" href="#Desc_Part2" role="tab" style="color:white !important;">Our Project</a>
 
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             <a class="nav-link btn btn-secondary rounded-top corner-bottom mr-1" data-toggle="pill" href="#Desc_Part3" role="tab" style="color:white !important;">CBM3a</a>
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             <a class="nav-link btn btn-secondary rounded-top corner-bottom mr-1" data-toggle="pill" href="#Desc_Part3" role="tab" style="color:white !important;">The CBM3a Head</a>
 
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             <a class="nav-link btn btn-secondary rounded-top corner-bottom mr-1" data-toggle="pill" href="#Desc_Part4" role="tab" style="color:white !important;">Streptavidin</a>
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             <a class="nav-link btn btn-secondary rounded-top corner-bottom mr-1" data-toggle="pill" href="#Desc_Part4" role="tab" style="color:white !important;">The Streptavidin Head</a>
 
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             <a class="nav-link btn btn-secondary rounded-top corner-bottom mr-1" data-toggle="pill" href="#Desc_Part5" role="tab" style="color:white !important;">4-L-azidophenylalanine</a>
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             <a class="nav-link btn btn-secondary rounded-top corner-bottom mr-1" data-toggle="pill" href="#Desc_Part5" role="tab" style="color:white !important;">The AzF Head</a>
 
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             <h2 class="heavy">Cellulose: a material with endless possibilities</h2><hr/>
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             <h2 class="heavy">Cellulose: a Material with Endless Possibilities</h2><hr/>
             <p>With approximatively fifty billion tonnes produced yearly, cellulose is one of the most abundant polymers on earth<SUP>1</SUP>. Cellulose is a polysaccharide made of D-glucose units linked together in a linear chain by β-(1-4) bonds. It is mainly produced by plants, but also by bacteria such as <i>Gluconacetobacter hansenii</i>. Nowadays, cellulose and its derivatives (nitrocellulose, cellulose acetate, methyl cellulose, carboxymethyl cellulose, etc.) are among the first materials that have been exploited in the industry (wood, cotton, textiles, paper, electronics and biomedical devices<SUP>2</SUP>), and they now represent significant economic issues.</p>
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             <p>However, today, we mostly use cellulose that is extracted from plants and their wastes. But because it branches with other compounds such as hemicellulose and lignin, it must go through harsh chemical treatments to finally be considered “pure”<SUP>3</SUP>. These purification processes cost a lot in terms of energy, money and time. One solution to this problem could lie in the use of bacterial cellulose. Some acetic acid bacteria naturally produce cellulose as biofilm to protect themselves. This cellulose is purer than the one produced by plants. It shows also interesting properties compared to the latter (unique nanostructure, high water holding capacity, high degree of polymerisation, high mechanical strength and high crystallinity<SUP>3</SUP>) which proves its potential as a promising material and alternative to plant cellulose for the future. Sadly, due to its high cost and low-yield production, bacterial cellulose is not yet widely spread in industries. </p>
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             <p>With approximatively fifty billion tonnes produced yearly, cellulose is the most abundant bio-polymer on earth. Cellulose is a linear polysaccharide of D-glucose residues linked to each other via &#946;-1,4 bonds. It is mainly synthetized in the plant cell wall, associated with other molecules in order to shape the plant body. However, cellulose is also secreted in the surroundings of aerobic bacteria such as <em>Gluconacetobacter hansenii </em>in order to form a biofilm enabling oxygen uptake. Nowadays, cellulose and its derivatives (nitrocellulose, cellulose acetate, methyl cellulose, carboxymethyl cellulose, etc…) are among the first materials that have been intensively used in industries (wood, cotton, textiles, paper, electronics and biomedical devices<sup>1</sup>), representing a market share evaluated at USD 20.61 billion in 2015.</p>
             <p>By functionalising cellulose, we aim to demonstrate how this widely used material can be more than a simple packaging or textile fibres. By combining it with Cerberus, cellulose can become a source of information and bring new opportunities for industrial applications. </p>
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<figure class="figure"  style="text-align:center;">
       
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                <img style="width : 70%; heigth = auto;" src="https://static.igem.org/mediawiki/2018/2/26/T--Toulouse-INSA-UPS--Desc--Youn--Cellulosemolecule.png" class="figure-img img-fluid rounded" alt="A generic square placeholder image with rounded corners in a figure.">
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                <figcaption class="figure-caption"><strong>Figure 1:</strong> <i>Cellulose molecular model</i></figcaption>
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<p>Bacterial cellulose has also been the target of the research and development in industries. As it is naturally purer than plant cellulose, it does not need to go through harsh purification processes that cost a lot of energy, time and money<sup>2</sup>. However, different types of cellulose with various properties and degrees of purity are used in industry, depending on the desired product or application.</p>
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<p>As it is now, cellulose is everywhere in our everyday lives. Now, imagine the endless possibilities if new functions could be added to cellulose. Cellulose with antibiotics for dressings, cellulose with color or fluorescence for new fashion trends, cellulose with conductivity properties for the electronic industry...But, this depends on the capacity to graft molecules to cellulose. This requires a new disruptive technology. This requires the iGEM Cerberus project.
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</p>
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             <h3>References</h3>
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            <i>    <ol>
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                <li>Keshk SM: Bacterial Cellulose Production and its Industrial Applications. Journal of Bioprocessing & Biotechniques 2014, 4;2. DOI: 10.4172/2155-9821.1000150.</li>
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                <li>Faezah Esa SMT, Norliza Abd Rahman: Overview of Bacterial Cellulose Production and Application. Agriculture and Agricultural Science Procedia 2 2104:113-119. DOI: 10.1016/j.aaspro.2014.11.017.</li>
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             <h2 class="heavy">Genesis of our project, Cerberus</h2><hr/>
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             <h2 class="heavy">Genesis of Our Project, Cerberus</h2><hr/>
             <p>When brainstorming about the project, we had these different ideas and they all revolved around functionalising several materials. We then realised it could be of great use to have one material that we could functionalise at our discretion. That is how we decided to work on cellulose, especially bacterial cellulose, in hope of developing its use by adding a whole range of exciting possibilities. From conductive paper to anti-infection tissues, applications domains are aplenty (medicine, textile, stationery, etc). The major bottleneck is the complexity to conjugate bioactive molecules to cellulose.</p>
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             <video style="width : 100%;
            <p>To circumvent this limitation and enable a wide range of chemicals to be fixated to cellulose, we designed a three headed linker protein named Cerberus (in reference to the mythological dog). Cerberus is based on the fusion of three fixating protein structures representing the three heads of the system. The first head is a protein domain of the type 3 Carbohydrate Binding Module (CBM3) family to bind cellulose. The second is one of the strongest linkage systems of the living realm, streptavidin, with its high affinity for biotinylated compounds. The last of the heads features a non-natural amino acid, 4-L-azidophenylalanine, catalysing covalent bonds by click chemistry. Therefore, the versatility of our thought-out linker will allow a large variety of organic and inorganic molecules to conjugate with cellulose.</p>
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                      <p>During our phase of brainstorming to pop up a project, we discussed around different subjects that would involve bio-functionalisation of a material. For example, we thought about a bandage made with cellulose fused with an antimicrobial peptide to accelerate skin wound healing. We also thought about producing dyes and grafting carbon nanotubes to cellulose for staining or adding conductivity properties. Each of these ideas would require a specific strategy. That is how we came up with the concept to generalise the functionalisation of cellulose and designed a generic and versatile platform protein named Cerberus.</p>
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                      <p>Our platform protein is composed of three heads as the Ancient Greek mythological three-headed dog, keeper of the gate of the Underworld. The main head is a Carbohydrate Binding Module of the family 3 (CBM3a) from <em>Clostridium thermocellum</em>, well described to specifically bind to crystalline cellulose<sup>1</sup> (in green in the video above). Linked at the <em>N</em>-terminus of the CBM3, the second module (in red) is a streptavidin from <em>Streptomyces avidinii</em> displaying one of the strongest known linkage systems in Nature to biotinylated molecules<sup>2</sup>. At the <em>C</em>-terminus of the CBM3a, we designed a linker incorporating an unnatural amino acid, 4-azido-L-phenylalanine (in blue in the video above), enabling the covalent bonds association of alkyne derivate molecule to Cerberus by click chemistry<sup>3</sup>. Therefore, our platform Cerberus will introduce versatility in cellulose functionalisation, with biological and/or with chemical components.</p>
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                      <h3>References</h3>
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            <i>    <ol>
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                <li>Morag E, Lapidot A, Govorko D, Lamed R, Wilchek M, Bayer EA, Shoham Y: Expression, purification, and characterization of the cellulose-binding domain of the scaffoldin subunit from the cellulosome of Clostridium thermocellum. Applied and Environmental Microbiology 1995, 61:1980-1986. </li>
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                <li>Nogueira ES, Schleier T, Durrenberger M, Ballmer-Hofer K, Ward TR, Jaussi R: High-level secretion of recombinant full-length streptavidin in Pichia pastoris and its application to enantioselective catalysis. Protein Expr Purif 2014, 93:54-62. DOI: 10.1016/j.pep.2013.10.015.</li>
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                <li>Pickens CJ, Johnson SN, Pressnall MM, Leon MA, Berkland CJ: Practical Considerations, Challenges, and Limitations of Bioconjugation via Azide-Alkyne Cycloaddition. Bioconjug Chem 2018, 29:686-701. DOI: 10.1021/acs.bioconjchem.7b00633.</li>
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             <h2 class="heavy">One head to bind to cellulose, the CBM3a</h2><hr/>
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             <h2 class="heavy">The Cellulose Binding Head</h2><hr/>
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            <p>The first function of our platform is to bind to cellulose. The family 3 Carbohydrate Binding Module of type a (CBM3a) from <em>Clostridium thermocellum</em><sup>1 </sup>is part of a scaffold protein attached to the outer membrane of the bacteria and decorated with nine catalytic enzymes dedicated to the deconstruction of plant cell wall.</p>
  
            <p>The first head is the core of our linker, Cerberus. We chose the Carbohydrate Binding Module type 3a (CBM3a) to bind to cellulose. This domain is found in the cellulosome of <i>Clostridium thermocellum</i><SUP>4</SUP> and its four aromatic amino acids make it the perfect candidate to bind to cellulose through a dipole-dipole interaction between the CBM3a’s aromatic amino acids and the cellulose’s glucose rings.</p>  
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<figure class="figure"  style="text-align:center;">
             <p>Our CBM3a features a long endogenous linker on each end, to which we can attach other structures to functionalise cellulose.</p>
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                <img style="width : 70%; heigth = auto;" src="https://static.igem.org/mediawiki/2018/e/e1/T--Toulouse-INSA-UPS--Desc--Youn--CBMmodel.png" class="figure-img img-fluid rounded" alt="A generic square placeholder image with rounded corners in a figure.">
         
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                <figcaption class="figure-caption"><strong>Figure 1:</strong> <i>Representation of </i>Ct<i>CBM3a associated with cellulose microfibrills. </i>Ct<i>CBM3a is colored in cyan and orange. Amino acids involved in stacking with glucose units of cellulose is in magenta (from pdb 1NBC). Cellulose is in green (from Perez and Samain, 2010 doi.org/10.1016/S0065-2318(10)64003-6).</i></figcaption>
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<p>This enzymatic machinery known as the cellulosome<sup>2</sup>, is one of the most effective degrading cellulose systems. Glucose sub-units of cellulose are recognised mainly by three aromatic amino acid side-chain displayed at the plan surface of the CBM3a (Figure 1). The CBM3a is composed of 159 amino acids. In our design, we also included the endogenous <em>N</em>- and <em>C</em>-terminus linkers (42 and 32 amino acids respectively) of the CBM3a in order to associate new domains to the CBM3a core part.</p>
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            <h3>References</h3>
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            <i>
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            <ol >
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            <li>Morag E, Lapidot A, Govorko D, Lamed R, Wilchek M, Bayer EA, Shoham Y: Expression, purification, and characterization of the cellulose-binding domain of the scaffoldin subunit from the cellulosome of Clostridium thermocellum. Applied and Environmental Microbiology 1995, 61:1980-1986. </li>
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             <li>Lamed R, Setter E, Bayer EA: Characterization of a cellulose-binding, cellulase-containing complex in Clostridium thermocellum. J Bacteriol 1983, 156:828-836. </li>
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             <h2 class="heavy">One head to bind biological macromolecules, streptavidin</h2><hr/>
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             <h2 class="heavy">The Streptavidin Head</h2><hr/>
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            <p>At the <em>N</em>-terminus of the cellulose binding head, we fused a streptavidin module. Streptavidin is a 60 kDa homotetrameric protein composed of 512 amino acids, isolated from <em>Streptomyces avidinii</em>, and it is well known for its interaction with biotin and biotinylated proteins. With a dissociation constant of 10<sup>-13</sup> M, the interaction between streptavidin and biotin is the strongest non-covalent one known in Nature<sup>1</sup>. </p>
  
            <p>The second head of Cerberus is streptavidin, which has been added to cellulose N-Terminus. Streptavidin is a 60 kDa homotetrameric protein, isolated from <i>Streptomyces avidinii</i>, and it is well known for its interaction with biotin and biotinylated proteins. With a dissociation constant of 10<sup>-13</sup> M, the interaction between streptavidin and biotin is the strongest non-covalent one known in Nature<SUP>5</SUP>.</p>  
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<figure class="figure"  style="text-align:center;">
            <p>The sequence of streptavidin wild type is used in fusion with the CBM3a. This streptavidin forms a complex with three other streptavidin monomers, hence the unmatched affinity for biotin since it can bind four molecules of biotin per tetramer. We decided to use two versions of streptavidin: the native form which is tetrameric because we have data on its interaction with biotin, and a monomeric version called mSA2<SUP>6</SUP> because we feared that the tetrameric streptavidin would cause agglutination of our  Cerberus protein. In case we needed to release the streptavidin linked to our function into the surrounding medium, we also included a TEV-protease site to cut off this section.</p>
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                <img style="width : 70%; heigth = auto;" src="https://static.igem.org/mediawiki/2018/7/7f/T--Toulouse-INSA-UPS--Desc--Youn--Streptabiotin_model.png" class="figure-img img-fluid rounded" alt="A generic square placeholder image with rounded corners in a figure.">
             <p>By adding a 15-residue AviTag, we managed to biotinylate our proteins with the help of BirA<SUP>7</SUP>. For this in-vivo biotinylation, we have transformed our chassis with a plasmid containing the protein BirA.</p>
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                <figcaption class="figure-caption"><strong>Figure 1:</strong> <i>Surface representation of the monomeric form of streptavidin mSA (in purple) in complex with biotin (colored in yellow). Amino acid residues involved in the complex are in mesh (colored in green). Dash lines represent hydrogen bond with surrounding amino acid sides chains (from pdb 4jnj).</i></figcaption>
             
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<p>This streptavidin-biotin association, shown in Figure 1, is a very convenient way to link organic molecules to Cerberus. Indeed, most proteins and even other molecules such as DNA can be biotinylated. This should ensure wide possibilities to functionalise cellulose (enzymes or non-catalytic proteins such as some fluorophores). </p>          
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             <h3>References</h3>
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<i>
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        <li>Nogueira ES, Schleier T, Durrenberger M, Ballmer-Hofer K, Ward TR, Jaussi R: High-level secretion of recombinant full-length streptavidin in Pichia pastoris and its application to enantioselective catalysis. Protein Expr Purif 2014, 93:54-62. DOI: 10.1016/j.pep.2013.10.015.</li>
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             <h2 class="heavy">One head to bind inorganic molecules, 4-L-azidophenylalanine</h2><hr/>
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             <h2 class="heavy">The Click Chemistry Head</h2><hr/>
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            <p>Some of the interesting new properties for cellulose are based on non-biological molecules which could not always be grafted on the streptavidin head. In order to expand the versatility of our platform to non-biological molecules, we introduced an unnatural amino acid at the end of the <em>C</em>-terminus linker of the CBM3a. The 4-azido-L-phenylalanine is a phenylalanine displaying an azide chemical function. This function reacts with an alkyne function, in a so called click chemistry reaction, in order to form a covalent bond (Figure 1).</p>  
  
            <p>To expand the versatility of our system, on the C-Terminus of the CBM3a, an unnatural amino acid called 4-L-azidophenylalanine was added. Its structure is like that of a phenylalanine, except that it presents an azide, or N-three, function on its tip, as the name would suggest. When presented with an alkyne function, and in particular dibenzocyclooctyne (DBCO), a reaction called click chemistry allows us to covalently bond these functions to our Cerberus protein in a spontaneous and irreversible way.</p>
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<figure class="figure"  style="text-align:center;">
             <p>The strategy used to incorporate this unnatural amino acid into our protein is to bring an orthogonal pair of tRNA and aminoacyl-tRNA synthetase with our plasmid<SUP>8</SUP>. The tRNA will recognize the amber codon TAG and this codon will not stop the translation as it normally does. Instead, it will allow the incorporation of our unnatural amino acid, the 4-L-azidophenylalanine.</p>
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                <img style="width : 70%; heigth = auto;" src="https://static.igem.org/mediawiki/2018/6/63/T--Toulouse-INSA-UPS--Desc--Youn--AzFrecapClick.png" class="figure-img img-fluid rounded" alt="A generic square placeholder image with rounded corners in a figure.">
             <p>There are two types of click chemistry that can be done on 4-L-azidophenylalanine to functionalise our Cerberus. The first one is the copper-catalyzed azide-alkyne cycloaddition reaction (CuAAC). It takes place as its name suggests between the azide group of the unnatural amino acid and an alkyne group; the reaction is catalysed by Cu2+ ions. The main problem of this method is the cytotoxicity of copper on cells limits its use in assays that take place in the cellular environment. The second type of click is the strain-promoted azide-alkyne cycloaddition reaction (SPAAC) which proceeds without the need of a catalyst<SUP>9</SUP>.</p>
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                <figcaption class="figure-caption"><strong>Figure 1:</strong> <i>Click reaction detail on AzF and DBCO. a) 4-L-azidophenylalanine molecular structure, b) dibenzocyclooctyne molecular structure, c) DBCO-AzF click product  </i></figcaption>
             <p>For our experimental plan, we decided to use both types of click chemistry, but we managed to only use the SPAAC during our time in the lab.</p>
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            </figure>
             
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<p>In many cases, proteins are built within organisms by combining the 20 common amino acids. To genetically encode more amino acids, referred to as unnatural, opens the possibilities of controlling the chemical functions of proteins and thus expanding their chemical space. For example, proteins can be expressed with novel side chains. The strategy is to use the cellular machinery to introduce these unnatural amino acids (UnAAs). Today, more than 50 UnAAs have already been incorporated in different microorganisms and the mechanism is weel described<sup>1</sup>. This is done by using orthogonal amino acyl tRNA synthetase (aaRS)/tRNA pairs, and an unassigned or reassigned codon. The 20 common amino acids are encoded by 61 triplet codons, which leaves the three stop codons (TAG, amber; TAA, ochre; and TGA, opal) to serve to specify the UnAA. For the 4-azido-L-phenylalanine, the amber stop codon was used<sup>2</sup>.</p>
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             <p>Briefly, for our system, an amber stop codon TAG is introduced at the desired position in the DNA sequence. Then, a second plasmid containing an engineered tRNA and aminoacyl-tRNA synthase from <em>Methylococcus ianaschii </em>dedicated to our UnAA and our amber codon is transformed into <i>E. coli</i>. During the expression of our protein, the medium is supplemented with 4-azido-L-phenylalanine. The tRNA charged with the UnAA will recognise the amber codon and translate it with the corresponding 4-azido-L-phenylalanine. In absence of UnAA, the amber stop codon is recognised as a classical stop codon and the translation is stopped.</p>
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             <p>Two different kind of click chemistry reactions could be used to bond the azide group to the alkyne group of the 4-azido-L-phenylalanine. The first one is the copper-catalyzed azide-alkyne cycloaddition reaction (CuAAC). It takes place as its name suggests between the azide group of the unnatural amino acid and an alkyne group; the reaction is catalysed by Cu<sup>2+</sup> ions. The main problem of this approach is the cytotoxicity of copper for cells, limiting its use in assays <em>in vivo</em>. The second type of click chemistry is the strain-promoted azide-alkyne cycloaddition reaction (SPAAC) which proceeds without the need of a catalyst<sup>3</sup>. This second type of reaction allows to proceed quickly and to overcome the problem of the toxicity for the living cells.</p>
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             <h3>References</h3>
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            <i>
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            <ol >
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            <li>Young TS, Schultz PG: Beyond the canonical 20 amino acids: expanding the genetic lexicon. J Biol Chem 2010, 285:11039-11044. DOI: 10.1074/jbc.R109.091306.</li>
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<li>Yang ST, Lim SI, Kiessling V, Kwon I, Tamm LK: Site-specific fluorescent labeling to visualize membrane translocation of a myristoyl switch protein. Sci Rep 2016, 6:32866. DOI: 10.1038/srep32866.</li>
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            <li>Pickens CJ, Johnson SN, Pressnall MM, Leon MA, Berkland CJ: Practical Considerations, Challenges, and Limitations of Bioconjugation via Azide-Alkyne Cycloaddition. Bioconjug Chem 2018, 29:686-701. DOI: 10.1021/acs.bioconjchem.7b00633.</li>
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             <h2 class="heavy" >Our system</h2><hr/>
 
             <h2 class="heavy" >Our system</h2><hr/>
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<p>To summarise, we aim to functionalise cellulose thanks to a generic and versatile platform to easily graft a wide range of organic and inorganic molecules to it. This Cerberus platform is structured to enable us to use two or three heads at the same time to further increase the possibility of cellulose functionalisation.</p>
 
             <figure class="figure"  style="text-align:center;">
 
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                 <img style="width : 70%; heigth = auto;" src="https://static.igem.org/mediawiki/2018/3/3d/T--Toulouse-INSA-UPS--Desc--OurSystem.png" class="figure-img img-fluid rounded" alt="A schematic representation of our system">
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                 <img style="width : 100%; heigth = auto;" src="https://static.igem.org/mediawiki/2018/3/3d/T--Toulouse-INSA-UPS--Desc--OurSystem.png" class="figure-img img-fluid rounded" alt="A schematic representation of our system">
 
             </figure>
 
             </figure>
             <p>For further details about our system, please see our <a href="https://2018.igem.org/Team:Toulouse-INSA-UPS/Design" >Design page</a>.</p>
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             <p>To know how we set up our system, check our <a href="https://2018.igem.org/Team:Toulouse-INSA-UPS/Design" >Design page</a>!</p>
  
 
                
 
                
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         <h3>References</h3>
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        <li> Serge Perez, (2000), Structure et morphologie de la cellulose.</li>
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        <li> Keshk SMAS (2014) Bacterial Cellulose Production and its Industrial Applications. J Bioprocess Biotech 4: 150 doi: 10.4172/2155-9821.1000150
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        <li> « Overview of Bacterial Cellulose Production and Application », Agric. Agric. Sci. Procedia, vol. 2, p. 113-119, janv. 2014.
+
        <li> E. Morag et al., « Expression, purification, and characterization of the cellulose-binding domain of the scaffoldin subunit from the cellulosome of Clostridium thermocellum. », Appl. Environ. Microbiol., vol. 61, no 5, p. 1980-1986, mai 1995.
+
        <li> E.S. Nogueira et al. / Protein Expression and Purification 93 (2014) 54–62
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        <li> K. H. Lim, H. Huang, A. Pralle, et S. Park, « Stable, high-affinity streptavidin monomer for protein labeling and monovalent biotin detection », Biotechnol. Bioeng., vol. 110, no 1, p. 57-67, janv. 2013.
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        <li> REFMANQUANTE
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        <li> T. S. Young et P. G. Schultz, « Beyond the Canonical 20 Amino Acids: Expanding the Genetic Lexicon », J. Biol. Chem., vol. 285, no 15, p. 11039-11044, avr. 2010.
+
        <li> C. J. Pickens, S. N. Johnson, M. M. Pressnall, M. A. Leon, et C. J. Berkland, « Practical Considerations, Challenges, and Limitations of Bioconjugation via Azide–Alkyne Cycloaddition », Bioconjug. Chem., vol. 29, no 3, p. 686-701, mars 2018.
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Latest revision as of 22:21, 17 October 2018

DESCRIPTION

Cellulose: a Material with Endless Possibilities

With approximatively fifty billion tonnes produced yearly, cellulose is the most abundant bio-polymer on earth. Cellulose is a linear polysaccharide of D-glucose residues linked to each other via β-1,4 bonds. It is mainly synthetized in the plant cell wall, associated with other molecules in order to shape the plant body. However, cellulose is also secreted in the surroundings of aerobic bacteria such as Gluconacetobacter hansenii in order to form a biofilm enabling oxygen uptake. Nowadays, cellulose and its derivatives (nitrocellulose, cellulose acetate, methyl cellulose, carboxymethyl cellulose, etc…) are among the first materials that have been intensively used in industries (wood, cotton, textiles, paper, electronics and biomedical devices1), representing a market share evaluated at USD 20.61 billion in 2015.

A generic square placeholder image with rounded corners in a figure.
Figure 1: Cellulose molecular model

Bacterial cellulose has also been the target of the research and development in industries. As it is naturally purer than plant cellulose, it does not need to go through harsh purification processes that cost a lot of energy, time and money2. However, different types of cellulose with various properties and degrees of purity are used in industry, depending on the desired product or application.

As it is now, cellulose is everywhere in our everyday lives. Now, imagine the endless possibilities if new functions could be added to cellulose. Cellulose with antibiotics for dressings, cellulose with color or fluorescence for new fashion trends, cellulose with conductivity properties for the electronic industry...But, this depends on the capacity to graft molecules to cellulose. This requires a new disruptive technology. This requires the iGEM Cerberus project.

References

  1. Keshk SM: Bacterial Cellulose Production and its Industrial Applications. Journal of Bioprocessing & Biotechniques 2014, 4;2. DOI: 10.4172/2155-9821.1000150.
  2. Faezah Esa SMT, Norliza Abd Rahman: Overview of Bacterial Cellulose Production and Application. Agriculture and Agricultural Science Procedia 2 2104:113-119. DOI: 10.1016/j.aaspro.2014.11.017.

Genesis of Our Project, Cerberus

During our phase of brainstorming to pop up a project, we discussed around different subjects that would involve bio-functionalisation of a material. For example, we thought about a bandage made with cellulose fused with an antimicrobial peptide to accelerate skin wound healing. We also thought about producing dyes and grafting carbon nanotubes to cellulose for staining or adding conductivity properties. Each of these ideas would require a specific strategy. That is how we came up with the concept to generalise the functionalisation of cellulose and designed a generic and versatile platform protein named Cerberus.

Our platform protein is composed of three heads as the Ancient Greek mythological three-headed dog, keeper of the gate of the Underworld. The main head is a Carbohydrate Binding Module of the family 3 (CBM3a) from Clostridium thermocellum, well described to specifically bind to crystalline cellulose1 (in green in the video above). Linked at the N-terminus of the CBM3, the second module (in red) is a streptavidin from Streptomyces avidinii displaying one of the strongest known linkage systems in Nature to biotinylated molecules2. At the C-terminus of the CBM3a, we designed a linker incorporating an unnatural amino acid, 4-azido-L-phenylalanine (in blue in the video above), enabling the covalent bonds association of alkyne derivate molecule to Cerberus by click chemistry3. Therefore, our platform Cerberus will introduce versatility in cellulose functionalisation, with biological and/or with chemical components.

References

  1. Morag E, Lapidot A, Govorko D, Lamed R, Wilchek M, Bayer EA, Shoham Y: Expression, purification, and characterization of the cellulose-binding domain of the scaffoldin subunit from the cellulosome of Clostridium thermocellum. Applied and Environmental Microbiology 1995, 61:1980-1986.
  2. Nogueira ES, Schleier T, Durrenberger M, Ballmer-Hofer K, Ward TR, Jaussi R: High-level secretion of recombinant full-length streptavidin in Pichia pastoris and its application to enantioselective catalysis. Protein Expr Purif 2014, 93:54-62. DOI: 10.1016/j.pep.2013.10.015.
  3. Pickens CJ, Johnson SN, Pressnall MM, Leon MA, Berkland CJ: Practical Considerations, Challenges, and Limitations of Bioconjugation via Azide-Alkyne Cycloaddition. Bioconjug Chem 2018, 29:686-701. DOI: 10.1021/acs.bioconjchem.7b00633.

The Cellulose Binding Head

The first function of our platform is to bind to cellulose. The family 3 Carbohydrate Binding Module of type a (CBM3a) from Clostridium thermocellum1 is part of a scaffold protein attached to the outer membrane of the bacteria and decorated with nine catalytic enzymes dedicated to the deconstruction of plant cell wall.

A generic square placeholder image with rounded corners in a figure.
Figure 1: Representation of CtCBM3a associated with cellulose microfibrills. CtCBM3a is colored in cyan and orange. Amino acids involved in stacking with glucose units of cellulose is in magenta (from pdb 1NBC). Cellulose is in green (from Perez and Samain, 2010 doi.org/10.1016/S0065-2318(10)64003-6).

This enzymatic machinery known as the cellulosome2, is one of the most effective degrading cellulose systems. Glucose sub-units of cellulose are recognised mainly by three aromatic amino acid side-chain displayed at the plan surface of the CBM3a (Figure 1). The CBM3a is composed of 159 amino acids. In our design, we also included the endogenous N- and C-terminus linkers (42 and 32 amino acids respectively) of the CBM3a in order to associate new domains to the CBM3a core part.

References

  1. Morag E, Lapidot A, Govorko D, Lamed R, Wilchek M, Bayer EA, Shoham Y: Expression, purification, and characterization of the cellulose-binding domain of the scaffoldin subunit from the cellulosome of Clostridium thermocellum. Applied and Environmental Microbiology 1995, 61:1980-1986.
  2. Lamed R, Setter E, Bayer EA: Characterization of a cellulose-binding, cellulase-containing complex in Clostridium thermocellum. J Bacteriol 1983, 156:828-836.

The Streptavidin Head

At the N-terminus of the cellulose binding head, we fused a streptavidin module. Streptavidin is a 60 kDa homotetrameric protein composed of 512 amino acids, isolated from Streptomyces avidinii, and it is well known for its interaction with biotin and biotinylated proteins. With a dissociation constant of 10-13 M, the interaction between streptavidin and biotin is the strongest non-covalent one known in Nature1.

A generic square placeholder image with rounded corners in a figure.
Figure 1: Surface representation of the monomeric form of streptavidin mSA (in purple) in complex with biotin (colored in yellow). Amino acid residues involved in the complex are in mesh (colored in green). Dash lines represent hydrogen bond with surrounding amino acid sides chains (from pdb 4jnj).

This streptavidin-biotin association, shown in Figure 1, is a very convenient way to link organic molecules to Cerberus. Indeed, most proteins and even other molecules such as DNA can be biotinylated. This should ensure wide possibilities to functionalise cellulose (enzymes or non-catalytic proteins such as some fluorophores).

References

  1. Nogueira ES, Schleier T, Durrenberger M, Ballmer-Hofer K, Ward TR, Jaussi R: High-level secretion of recombinant full-length streptavidin in Pichia pastoris and its application to enantioselective catalysis. Protein Expr Purif 2014, 93:54-62. DOI: 10.1016/j.pep.2013.10.015.

The Click Chemistry Head

Some of the interesting new properties for cellulose are based on non-biological molecules which could not always be grafted on the streptavidin head. In order to expand the versatility of our platform to non-biological molecules, we introduced an unnatural amino acid at the end of the C-terminus linker of the CBM3a. The 4-azido-L-phenylalanine is a phenylalanine displaying an azide chemical function. This function reacts with an alkyne function, in a so called click chemistry reaction, in order to form a covalent bond (Figure 1).

A generic square placeholder image with rounded corners in a figure.
Figure 1: Click reaction detail on AzF and DBCO. a) 4-L-azidophenylalanine molecular structure, b) dibenzocyclooctyne molecular structure, c) DBCO-AzF click product

In many cases, proteins are built within organisms by combining the 20 common amino acids. To genetically encode more amino acids, referred to as unnatural, opens the possibilities of controlling the chemical functions of proteins and thus expanding their chemical space. For example, proteins can be expressed with novel side chains. The strategy is to use the cellular machinery to introduce these unnatural amino acids (UnAAs). Today, more than 50 UnAAs have already been incorporated in different microorganisms and the mechanism is weel described1. This is done by using orthogonal amino acyl tRNA synthetase (aaRS)/tRNA pairs, and an unassigned or reassigned codon. The 20 common amino acids are encoded by 61 triplet codons, which leaves the three stop codons (TAG, amber; TAA, ochre; and TGA, opal) to serve to specify the UnAA. For the 4-azido-L-phenylalanine, the amber stop codon was used2.

Briefly, for our system, an amber stop codon TAG is introduced at the desired position in the DNA sequence. Then, a second plasmid containing an engineered tRNA and aminoacyl-tRNA synthase from Methylococcus ianaschii dedicated to our UnAA and our amber codon is transformed into E. coli. During the expression of our protein, the medium is supplemented with 4-azido-L-phenylalanine. The tRNA charged with the UnAA will recognise the amber codon and translate it with the corresponding 4-azido-L-phenylalanine. In absence of UnAA, the amber stop codon is recognised as a classical stop codon and the translation is stopped.

Two different kind of click chemistry reactions could be used to bond the azide group to the alkyne group of the 4-azido-L-phenylalanine. The first one is the copper-catalyzed azide-alkyne cycloaddition reaction (CuAAC). It takes place as its name suggests between the azide group of the unnatural amino acid and an alkyne group; the reaction is catalysed by Cu2+ ions. The main problem of this approach is the cytotoxicity of copper for cells, limiting its use in assays in vivo. The second type of click chemistry is the strain-promoted azide-alkyne cycloaddition reaction (SPAAC) which proceeds without the need of a catalyst3. This second type of reaction allows to proceed quickly and to overcome the problem of the toxicity for the living cells.

References

  1. Young TS, Schultz PG: Beyond the canonical 20 amino acids: expanding the genetic lexicon. J Biol Chem 2010, 285:11039-11044. DOI: 10.1074/jbc.R109.091306.
  2. Yang ST, Lim SI, Kiessling V, Kwon I, Tamm LK: Site-specific fluorescent labeling to visualize membrane translocation of a myristoyl switch protein. Sci Rep 2016, 6:32866. DOI: 10.1038/srep32866.
  3. Pickens CJ, Johnson SN, Pressnall MM, Leon MA, Berkland CJ: Practical Considerations, Challenges, and Limitations of Bioconjugation via Azide-Alkyne Cycloaddition. Bioconjug Chem 2018, 29:686-701. DOI: 10.1021/acs.bioconjchem.7b00633.

Our system

To summarise, we aim to functionalise cellulose thanks to a generic and versatile platform to easily graft a wide range of organic and inorganic molecules to it. This Cerberus platform is structured to enable us to use two or three heads at the same time to further increase the possibility of cellulose functionalisation.

A schematic representation of our system

To know how we set up our system, check our Design page!

No dogs were harmed over the course of this iGEM project.

INSA Toulouse UPS LISBP TWB Defi Adisseo Foundation ESF Catalyses


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