Team:Freiburg/Modelling

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To get a first impression how Histidines are positioned in a bacterial Ligase, we replaced all non conserved aminoacids by Histidines and sent the sequence for a 3D sequence prediction to I-TASSER, an online structure prediction software tool.
To get a first impression how Histidines are positioned in a bacterial Ligase, we replaced all non conserved aminoacids by Histidines and sent the sequence for a 3D sequence prediction to I-TASSER, an online structure prediction software tool.
[[File:Freiburg11_Seq7.png]]
[[File:Freiburg11_Seq7.png]]
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[[File:Freiburg11Modelling3.png|border|750px]]
[[File:Freiburg11Modelling3.png|border|750px]]
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1.Ambrish Roy, Alper Kucukural, Yang Zhang. I-TASSER: a unified platform for automated protein structure and function prediction. Nature Protocols, vol 5, 725-738 (2010).
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2.Yang Zhang. Template-based modeling and free modeling by I-TASSER in CASP7. Proteins, vol 69 (Suppl 8), 108-117 (2007).
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We received this pdb file with a C-score= 0.53. Obviously this was not a realistic model, since the folding would surely be impaired by so many Histidines everywhere. But is was useful to find several good locations, were the Nickel could fit in in respect to the requirements it has for binding ligands.
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[[File:Freiburg11Modelling4.png]]
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We manually fit in a Nickel ion, as it was crystallized in the mentioned PDB file, and measured the distances and evaluated the 3dimensional orientation of the Histidines towards the Nickel. Histidines can coordinate ligands with their free electron pair pointing planar away from the imidazole ring.
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[[File:Freiburg11Modelling5.png]]
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What we further realized from the structure file was, that the end of the LRR segments were “open”, that means, the hydrophobic core of the protein was exposed and as it is visible in the prediction, curled in on one end into a sort of helix. This means the protein folding is not reliable and the structure needs some caps on both ends to stabilize the LRR core motif. A solution to this was shown by Schmidt et al 2010, who crystallized the TLR-4 receptor.
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[[File:Freiburg11Modelling6.png|border|750px]]
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In this very nice piece of work he dissected the TLR4(PDB: 3FXI) into 3 parts, since it was to large and unhandy to be crystallized at once. To overcome this problem of an exposed hydrophobic core, he used the N- and C-terminal protein fragments of a LRR protein derived from hagfish. They tried a variety of different versions of how to glue together his fragments and these N- and C-terminal caps until he found a working one.
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We used this knowledge for our purpose and took the same sequences and attached them to our protein sequence. These caps partially still show the typical LRR consensus sequences (which luckily is highly conserved in all kingdoms of life!), which made it possible to fit them onto our stack of LRR loops in the right position.
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Revision as of 12:35, 20 September 2011


This is the wiki page
of the Freiburger student
team competing for iGEM 2011.
Thank you for your interest!