Team:Freiburg/Modelling

From 2011.igem.org

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(Modelling: Rational protein design)
(Modelling: Rational protein design)
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The second milestone in the generation of the idea came up in a lecture of Prof. Martin, about Nickel allergy. He found a mutation in the TLR-4 receptor that indroduces Histidines in the LRR motif of the protein, which are capable of binding nickel and thus forming complexes of receptors on the cell surface of immune cells, triggering the inflammatory reaction.  
The second milestone in the generation of the idea came up in a lecture of Prof. Martin, about Nickel allergy. He found a mutation in the TLR-4 receptor that indroduces Histidines in the LRR motif of the protein, which are capable of binding nickel and thus forming complexes of receptors on the cell surface of immune cells, triggering the inflammatory reaction.  
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[[File:Freiburg11Modelling1.png|thumb|right|750px|caption]]
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[[File:Freiburg11Modelling1.png|thumb|750px|caption]]
This was the necessary clue that gave answer to the question.
This was the necessary clue that gave answer to the question.
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The Construction of a new protein
The Construction of a new protein
After a long and detailed search, we found out that it is most reasonable to use bacterial LRR motifs, since they seemed very well conserved in sequence, and they are the shortest – with only 21 aminoacids per LRR repeat. (Wei 2008, Kajava 1998). We wanted to have the protein as simple and as predictable in behavior and structure as possible.
After a long and detailed search, we found out that it is most reasonable to use bacterial LRR motifs, since they seemed very well conserved in sequence, and they are the shortest – with only 21 aminoacids per LRR repeat. (Wei 2008, Kajava 1998). We wanted to have the protein as simple and as predictable in behavior and structure as possible.
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Several search inquiries led to the most conserved and shortest of all bacterial LRR (PDB: NO), unluckily this protein is a toxin derived from Yersinia pestis. We of course did not want to mess around with toxins,[[File:Freiburg11_Seq1.png|thumb|250px]] especially not with one of the black plague. We also did not know what amino acid pattern on the LRR motif would cause the toxic effect. There probably would have been no harm from this protein alone, even if we did clone and express it, but why should we do that when we have a huge choice for free at hand anyway. Finally we settled on the bacterial ligase PDB:3CVR. A ligase would be definitively harmless, especially since we planned to restructure it completely.
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Several search inquiries led to the most conserved and shortest of all bacterial LRR (PDB: NO), unluckily this protein is a toxin derived from Yersinia pestis. We of course did not want to mess around with toxins,[[File:Freiburg11_Seq1.png|thumb|left|250px]] especially not with one of the black plague. We also did not know what amino acid pattern on the LRR motif would cause the toxic effect. There probably would have been no harm from this protein alone, even if we did clone and express it, but why should we do that when we have a huge choice for free at hand anyway. Finally we settled on the bacterial ligase PDB:3CVR. A ligase would be definitively harmless, especially since we planned to restructure it completely.
To do this we needed to understand how the structure of the Ligase was made.
To do this we needed to understand how the structure of the Ligase was made.

Revision as of 15:58, 20 September 2011


This is the wiki page
of the Freiburger student
team competing for iGEM 2011.
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