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.
Step 1
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Vector
digestion: EcoRI + PstI
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Insert
digestion: EcoRI + PstI
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BBa-J52017
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_CMV-promotor
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Step
2
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Vector
digestion: AgeI+SpeI
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Insert
digestion: NgoMIV+SpeI
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pMA-BBFR
_ SPLIT-Linker
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C-YFP
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C-CFP
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Step
3
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Vector
digestion: AgeI+SpeI
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Insert
digestion: NgoMIV+SpeI
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pMA-BBFR
_egfR-Tm
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_ N-β-Lactamase
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_ C-β-Lactamase
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_ SPLIT-Linker_ C-YFP
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_ N-YFP
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_ SPLIT-Linker_ C-CFP
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_ N-CFP
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_ BB058 (Luciferase)
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_ BB057 (Luciferase)
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Step
4
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Vector
digestion: AgeI+SpeI
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Insert
digestion: NgoMIV+SpeI
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pMA-BBFR
_SP
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_scFv-anti-NIP
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_ Lipocalin
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Step
5
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Vector
digestion: AgeI+SpeI
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Insert
digestion: NgoMIV+SpeI
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pMA-BBFR
_SP_ scFv-anti-NIP
and
pMA-BBFR-+SP_ Lipocalin
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_GGGS-linker (produced by Klenow fill in)
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Step
6
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Vector
digestion: AgeI+SpeI
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Insert
digestion: NgoMIV+SpeI
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pMA-BBFR
_SP_ scFv-anti-NIP _ GGGS-Li
and
pMA-BBFR
_ SP_ Lipocalin _
GGGS-Li
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_
egfR-Tm _ N-β-Lactamase
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_
egfR-Tm _ C-β-Lactamase
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_
egfR-Tm _ SPLIT-Linker_ C-YFP
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_
egfR-Tm _ N-YFP
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_
egfR-Tm _ SPLIT-Linker_ C-CFP
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_
egfR-Tm _ N-CFP
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_
egfR-Tm _ BB058 (Luciferase)
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_
egfR-Tm _ BB057 (Luciferase)
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Step
7
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Vector
digestion:
SpeI + PstI
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Insert
digestion: XbaI + PstI
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BBa-J52017_CMV
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_SP_ scFv-anti-NIP_GGGS-Li_egfR-Tm_N-β-Lactamase
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_ SP_ scFv-anti-NI _GGGS-Li_ egfR-Tm_C-β-Lactamase
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_ SP_ scFv-anti-NIP_GGGS-Li_
egfR-Tm_SPLIT-Linker_C-YFP
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_ SP_ scFv-anti-NIP_GGGS-Li_ egfR-Tm_N-YFP
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_ SP_ scFv-anti-NIP_GGGS-Li_
egfR-Tm_SPLIT-Linker_C-CFP
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_ SP_ scFv-anti-NIP_GGGS-Li_ egfR-Tm_N-CFP
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_ SP_ scFv-anti-NIP_GGGS-Li _ egfR-Tm_BB058 (Luciferase)
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_ SP_ scFv-anti-NIP_GGGS-Li _ egfR-Tm_BB057 (Luciferase)
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_ SP_ Lipocalin _GGGS-Li_ egfR-Tm_N-β-Lactamase
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_ SP_ Lipocalin _GGGS-Li_ egfR-Tm_C-β-Lactamase
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_ SP_ Lipocalin _GGGS-Li_
egfR-Tm_SPLIT-Linker_ C-YFP
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_ SP_ Lipocalin _GGGS-Li_
egfR-Tm_N-YFP
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_ SP_ Lipocalin _GGGS-Li_
egfR-Tm_SPLIT-Linker_ C-CFP
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_ SP_ Lipocalin _GGGS-Li_
egfR-Tm_N-CFP
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_ SP_ Lipocalin _GGGS-Li__ egfR-Tm _ BB058 (Luciferase)
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_ SP_ Lipocalin _GGGS-Li__ egfR-Tm _ BB057 (Luciferase)
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