Team:Freiburg/Project

From 2008.igem.org

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<font face="Arial Rounded MT Bold" style="color:#010369">_project</font></div>
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<font face="Arial Rounded MT Bold" style="color:#010369">_project report</font></div>
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<h2>[[Modular Synthetic Receptor System|Modular Synthetic  Receptor System]]</h2>
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<br>
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[[Image:Freiburg08_MSRS_Schema.png|thumb|200px|left|Schematical overview of the system]]
 
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'''Abstract:'''<br>
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<h2>'''Introduction:'''</h2>
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This year´s main project is the attempt to create an "artificial receptor-system", featuring extra- and intracellular modules as well as suitable transmembrane regions.
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Signaling through membranes is a characteristic of life. Transmembrane proteins control proliferation, differentiation, and cellular response and are key for the formation of multicellular organisms. Controlling such proteins enables modifying cellular behavior and ultimately programming cells at will. The complex rules for transmembrane signaling often require engagement of several proteins in a fine-tuned spatial and temporal manner.
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The intracellular domaine of our receptor-device is build by halves of split reporter-proteins that can reassemble and will then produce readable output, e. g. fluorescence.
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Each one of these protein-halves is connected to its extracellular domaine by a single-span transmembrane-helix.  
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To tap possibilities of transmembrane programming, the Freiburg 2008 iGEM team provides an extensible system comprising an external framework with spatial resolution, a concept for modifying natural receptors, and a modular set of fusion-Biobricks for the construction of synthetic receptors. Spatial resolution in the nanometer scale is provided by DNA-Origami modified with distinct patterns and combinations of ligands. Receptors are decoupled from their natural ligands by fusion with artificial binding domains. The Biobrick collection contains signal sequences, binding domains, transmembrane domains, and effector domains featuring split enzymes and split fluorescent proteins for immediate readout.
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The extracellular or detecting domaine consists of a protein or peptide with the ability to bind a certain molecule.<br>
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[[Modular Synthetic  Receptor System|Project Report]]
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Now, if a system with two matching receptors is presented these molecules in a strict, pairwise spatial arrangement, the receptor-devices are brought together,
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<br><br>
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the split reporter-protein reassembles inside the cell and the output can be detected.
-
 
+
We employ so-called "Origami-DNA" to create the exactly defined molecule-patterns that are needed to activate our receptors.
 +
<br>
 +
One of the main inspirations that lead to the idea of creating a synthetic receptor-like fusion protein is based on an immunologic study on the signaling pathway of the T-Cell-Receptor (TCR) that has been performed by Wolfgang Schamel at the Max-Planck-Institute for immunology, Freiburg[1].
 +
In this study he used modified TCRs with Fab-Fragment-singlechains of Anti-NIP –Antibodies fused to their ß-domaines by a flexible linker that would present them on the cell´s surface.
 +
This modification would allow to investigate the influence of receptor-clustering on the intensity of the cell-signaling. It could been shown that there is a relation between the clustering of the antigen and, thus, of the receptors by presenting various peptides with certain amounts and arrangements of NIP-molecules as stimulus.<br>
 +
Anyway, this experiment was restricted by the one-dimensionality of the antigen-fused peptides; at this point, the Origami-DNA comes into play:
 +
Paul Rothemund had discovered that it is possible to shape M13-Phage single-strand-DNA simply adding oligonucleotides that would work as „brackets“ when complementing the long single-strand. In this way, one can generate DNA-squares of a certain size with „nods“ at certain distances.<br>
 +
One member of our team, Daniel Hautzinger, has recently finished his diploma-thesis on Origami-DNA and the possibilities of generating patterns on these square surfaces by modifying the  Oligo-nucleotides that build up the nod-points.
 +
As the antigen NIP can as well be fused to these oligos, it was now possible to present strictly defined two-dimensional antigen-patterns to T-Cells carrying the modified receptors mentioned above.<br>
 +
This, again, made us come up with the idea of a transmembrane-fusion-protein that could be spatially arranged from outside the cell by the pattern on the Origami-DNA-surface.<br>
 +
Of course, the first extracellular domaine we had in mind was the anti-NIP-singlechain Schamel had used with his receptors. The first intracellular domaines should consist of the split-lactamase-halfes we designed as parts for last year´s iGEM, as this enzyme´s activity can be regained by complementation of the halves and detected by a fluorescent substrate.
 +
Now, we were looking for a single-span-transmembrane-protein; as the domaines of the Epidermal-Growth-Factor Receptor are well known, we chose to employ it´s transmembrane-helix and the signal-peptide mediating the construct´s insertion into the membrane.<br>
 +
Further modules we had in mind were an Anti-Fluorescein-singlechain and a fluorescein-binding variety of Lipocalin by Arne Skerra as extracellular „detectors“ as well as the complementing halves of each one of the split-fluorophores „Cerulean“ (cyan) and „Venus“ (yellow) as intracellular „reporters“. These split-fluorophores feature cross-compatibility  between the N- and C-terminal halves (green fluorescence), enabling us to generate three different „outputs“ (yellow, blue, green) with only two molecules (NIP, FluA) building up the „input-pattern“ on the Origami-DNA-surface. <br><br>
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<h2>'''Material and Methods:'''</h2>
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[[DNA-Origami|DNA-Origami]]<br>
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[[Team:Freiburg_Cloning Strategy|Cloning Strategy]]<br>
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[[Team:Freiburg_Cell Culture|Cell Culture]]<br>
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[[Team:Freiburg_Transfection|Transfection]]<br>
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[[Team:Freiburg_Calcium Imaging|Calcium Imaging]]
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<h2>'''Results:'''</h2>
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<h2>'''Discussion:'''</h2>
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<h2>'''Literature:'''</h2>
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'''Split-fluorophores:'''<br>
 +
-Chang-Deng Hu, Yurii Chinenov, Tom K. Kerppola: ”Visualization of Interactions among bZIP and Rel Family Proteins in Living Cells Using Bimolecular Fluorescence Complementation”, Molecular Cell, Vol. 9, 789–798, April, 2002<br>
 +
-Chang Deng Hu, Tom K. Kerppola: “Simultaneous visualization of multiple protein interactions in living cells using multicolor fluorescence complementation analysis”, Nat Biotechnol. 2003 May; 21(5):539-545 (doi:10. 1038/nbt816)<br>
 +
-Tom K. Kerppola: “Design and implementation of bimolecular fluorescence complementation (BiFC) assays for the visualization of protein interactions in living cells”, Nat Protoc. 2006;1(3):1278-1286 (doi:10.1038/nprot.2006.201)<br>
 +
-Nagai, T. et al. “A variant of yellow fluorescent protein with fast and efficient maturation for cell-biological applications” J. Biol. Chem. 276, 29188-29194, 2001<br>
 +
-Roger Y. Tsien et al. „Creating new fluorescent probes for cell biology“, Nature Biotechnology Reviews, Vol. 3, 906-918, 2002<br><br>
}}
}}

Revision as of 18:54, 28 October 2008


Freiburg2008 small header.gif



Home

The Team

Project Report

Parts

Modeling

Notebook

Safety

CoLABoration
_project report



Contents

Introduction:

This year´s main project is the attempt to create an "artificial receptor-system", featuring extra- and intracellular modules as well as suitable transmembrane regions. The intracellular domaine of our receptor-device is build by halves of split reporter-proteins that can reassemble and will then produce readable output, e. g. fluorescence. Each one of these protein-halves is connected to its extracellular domaine by a single-span transmembrane-helix. The extracellular or detecting domaine consists of a protein or peptide with the ability to bind a certain molecule.
Now, if a system with two matching receptors is presented these molecules in a strict, pairwise spatial arrangement, the receptor-devices are brought together, the split reporter-protein reassembles inside the cell and the output can be detected. We employ so-called "Origami-DNA" to create the exactly defined molecule-patterns that are needed to activate our receptors.
One of the main inspirations that lead to the idea of creating a synthetic receptor-like fusion protein is based on an immunologic study on the signaling pathway of the T-Cell-Receptor (TCR) that has been performed by Wolfgang Schamel at the Max-Planck-Institute for immunology, Freiburg[1]. In this study he used modified TCRs with Fab-Fragment-singlechains of Anti-NIP –Antibodies fused to their ß-domaines by a flexible linker that would present them on the cell´s surface. This modification would allow to investigate the influence of receptor-clustering on the intensity of the cell-signaling. It could been shown that there is a relation between the clustering of the antigen and, thus, of the receptors by presenting various peptides with certain amounts and arrangements of NIP-molecules as stimulus.
Anyway, this experiment was restricted by the one-dimensionality of the antigen-fused peptides; at this point, the Origami-DNA comes into play: Paul Rothemund had discovered that it is possible to shape M13-Phage single-strand-DNA simply adding oligonucleotides that would work as „brackets“ when complementing the long single-strand. In this way, one can generate DNA-squares of a certain size with „nods“ at certain distances.
One member of our team, Daniel Hautzinger, has recently finished his diploma-thesis on Origami-DNA and the possibilities of generating patterns on these square surfaces by modifying the Oligo-nucleotides that build up the nod-points. As the antigen NIP can as well be fused to these oligos, it was now possible to present strictly defined two-dimensional antigen-patterns to T-Cells carrying the modified receptors mentioned above.
This, again, made us come up with the idea of a transmembrane-fusion-protein that could be spatially arranged from outside the cell by the pattern on the Origami-DNA-surface.
Of course, the first extracellular domaine we had in mind was the anti-NIP-singlechain Schamel had used with his receptors. The first intracellular domaines should consist of the split-lactamase-halfes we designed as parts for last year´s iGEM, as this enzyme´s activity can be regained by complementation of the halves and detected by a fluorescent substrate. Now, we were looking for a single-span-transmembrane-protein; as the domaines of the Epidermal-Growth-Factor Receptor are well known, we chose to employ it´s transmembrane-helix and the signal-peptide mediating the construct´s insertion into the membrane.
Further modules we had in mind were an Anti-Fluorescein-singlechain and a fluorescein-binding variety of Lipocalin by Arne Skerra as extracellular „detectors“ as well as the complementing halves of each one of the split-fluorophores „Cerulean“ (cyan) and „Venus“ (yellow) as intracellular „reporters“. These split-fluorophores feature cross-compatibility between the N- and C-terminal halves (green fluorescence), enabling us to generate three different „outputs“ (yellow, blue, green) with only two molecules (NIP, FluA) building up the „input-pattern“ on the Origami-DNA-surface.

Material and Methods:

DNA-Origami
Cloning Strategy
Cell Culture
Transfection
Calcium Imaging

Results:

Discussion:

Literature:

Split-fluorophores:
-Chang-Deng Hu, Yurii Chinenov, Tom K. Kerppola: ”Visualization of Interactions among bZIP and Rel Family Proteins in Living Cells Using Bimolecular Fluorescence Complementation”, Molecular Cell, Vol. 9, 789–798, April, 2002
-Chang Deng Hu, Tom K. Kerppola: “Simultaneous visualization of multiple protein interactions in living cells using multicolor fluorescence complementation analysis”, Nat Biotechnol. 2003 May; 21(5):539-545 (doi:10. 1038/nbt816)
-Tom K. Kerppola: “Design and implementation of bimolecular fluorescence complementation (BiFC) assays for the visualization of protein interactions in living cells”, Nat Protoc. 2006;1(3):1278-1286 (doi:10.1038/nprot.2006.201)
-Nagai, T. et al. “A variant of yellow fluorescent protein with fast and efficient maturation for cell-biological applications” J. Biol. Chem. 276, 29188-29194, 2001
-Roger Y. Tsien et al. „Creating new fluorescent probes for cell biology“, Nature Biotechnology Reviews, Vol. 3, 906-918, 2002

Freiburg08 FT3.png

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