Team:Slovenia
From 2009.igem.org
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<li>We prepared polypeptide assemblies, based on gyrase B fragment, which can be <b>assembled and disassembled by the addition of different compounds</b>, which has particularly useful properties for drug delivery.</li><br> | <li>We prepared polypeptide assemblies, based on gyrase B fragment, which can be <b>assembled and disassembled by the addition of different compounds</b>, which has particularly useful properties for drug delivery.</li><br> | ||
- | <li>We proposed an approach for <b>biomaterial design</b> that could be crosslinked through coiled-coil interactions, which will allow introducing <b>additional functional polypeptides</b> that provide different functions to the cell-growth matrix, such as antimicrobial activity (LL-37 peptide), cell differentiation (NGF), growth factors etc. | + | <li>We proposed an approach for <b>biomaterial design</b> that could be crosslinked through coiled-coil interactions, which will allow introducing <b>additional functional polypeptides</b> that provide different functions to the cell-growth matrix, such as antimicrobial activity (LL-37 peptide), cell differentiation (NGF), growth factors, etc. with an almost unlimited number of potential combinations.</li><br> |
<li>We prepared polypeptide network based on self-assembly of a polypeptide that contains a p53 <b>tetramerization domain and a coiled coil domain</b>. <b>Real world application</b> such as <b>ultrafiltration</b> was demonstrated on self-assembled polypeptide membrane for the removal of viruses.</li><br> | <li>We prepared polypeptide network based on self-assembly of a polypeptide that contains a p53 <b>tetramerization domain and a coiled coil domain</b>. <b>Real world application</b> such as <b>ultrafiltration</b> was demonstrated on self-assembled polypeptide membrane for the removal of viruses.</li><br> |
Latest revision as of 02:26, 22 October 2009
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nanomaterials from nano to macro If you use Microsoft Explorer navigate from main menu
Imagine that you could manufacture complex devices that self-assemble from their components, imagine that those components measure a few nanometers, imagine that you could have a factory that produces those devices from simple sugars or even from solar light and carbon dioxide. This is exactly what is going on in cells as the ultimate factories and the devices that are produced are mainly made of polypeptides, such as enzymes, silk or hair. We set to prepare and test modular genetic elements we named nanoBricks, to create self-assembling material to form structures unseen in nature. In comparison to usual nanomaterials we can program the composition of polypeptide nanomaterials through DNA code. This allows us an unrivaled control of their composition at nanoscale, which determines the properties of those materials. We achieved this by combining small building blocks, called coiled-coils that twist around each other, forming rigid rods. Several of those rods are linked by flexible hinges into chains, which can assemble into complex polyhedra and into planar and three-dimensional networks. Those assemblies may contain pores of a defined size, which we can modify at will with respect to size or chemical properties. We used nanoBricks to prepare functional ultrafiltration membrane and material that can be assembled or disassembled by the addition of small molecules. The high level of control at the nanoscale, ease and sustainability of production has exciting potentials for manufacturing sophisticated scaffolds, biomineralization, drug delivery and many, many more applications. Modular nanoBricks were used to prepare polypeptide chain, composed of three designed coiled-coil -forming segments (shown as arrows), which guide the polypeptide chains into nanobox as well as into planar lattice (left), which we experimentally confirmed (right, transmission electron microscopic image).
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