Difference between revisions of "Gaucher Disease: Task 09 - Lab Journal"

From Bioinformatikpedia
(1. Choose a structure to work with)
(Preparation)
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Structure 2V3F seems to be a good choice because of the highest pH-value and the lowest R-value and R-free. However, there are some missing residues, 8 in chain A:
 
Structure 2V3F seems to be a good choice because of the highest pH-value and the lowest R-value and R-free. However, there are some missing residues, 8 in chain A:
   
  +
REMARK 465 MISSING RESIDUES <br/>
===2. Visualise the mutations you want to work with===
 
  +
REMARK 465 THE FOLLOWING RESIDUES WERE NOT LOCATED IN THE <br/>
  +
REMARK 465 EXPERIMENT. (M=MODEL NUMBER; RES=RESIDUE NAME; C=CHAIN <br/>
  +
REMARK 465 IDENTIFIER; SSSEQ=SEQUENCE NUMBER; I=INSERTION CODE.) <br/>
  +
REMARK 465 <br/>
  +
REMARK 465 M RES C SSSEQI <br/>
  +
REMARK 465 PRO A 29 <br/>
  +
REMARK 465 THR A 30 <br/>
  +
REMARK 465 PHE A 31 <br/>
  +
REMARK 465 LEU A 499 <br/>
  +
REMARK 465 VAL A 500 <br/>
  +
REMARK 465 ASP A 501 <br/>
  +
REMARK 465 THR A 502 <br/>
  +
REMARK 465 MET A 503 <br/>
  +
REMARK 465 GLU B -1 <br/>
  +
REMARK 465 PHE B 0 <br/>
  +
REMARK 465 ASP B 27 <br/>
  +
REMARK 465 PRO B 28 <br/>
  +
REMARK 465 PRO B 29 <br/>
  +
REMARK 465 THR B 30 <br/>
  +
REMARK 465 PHE B 31 <br/>
  +
REMARK 465 PRO B 32 <br/>
  +
REMARK 465 LEU B 498 <br/>
  +
REMARK 465 LEU B 499 <br/>
  +
REMARK 465 VAL B 500 <br/>
  +
REMARK 465 ASP B 501 <br/>
  +
REMARK 465 THR B 502 <br/>
  +
REMARK 465 MET B 503 <br/>
   
  +
===2. Visualise the mutations you want to work with===
===3. Create mutated structures===
 
   
  +
===3. Create mutated structures===
   
 
==Energy comparisons==
 
==Energy comparisons==

Revision as of 14:13, 28 August 2013

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This page is under construction.

Preparation

1. Choose a structure to work with

In the former tasks, we worked with the reference structure 1OGS, because it has no gaps - but an offset of 39 residues at the N terminus, as all structures for our protein P04062 referenced in UniProt - and has a pretty low resolution of 2.0 Å. However, there are four other structures with a lower resolution (all resolved using the X-ray diffraction method). We compare 1OGS and those four structures for the resolution, coverage and gaps, R-factor, R-free and pH-value at which the structure was resolved in the following table.

<figtable id="structure_choice">

PDB-ID Resolution (Å) Chain Covered residues Missing residues R-Value(obs.) R-Free pH Temperature (K)
2NT0 1.79 A/B/C/D 40-536 (92.7%) 1-39? 0.181 0.215 4.5 100
3GXI 1.84 A/B/C/D 40-536 (92.7%) 1-39? 0.193 0.231 5.5 ?
2V3F 1.95 A/B 40-536 (92.7%) 1-39? 0.154 0.196 6.5 100
2V3D 1.96 A/B 40-536 (92.7%) 1-39? 0.157 0.208 6.5 100
1OGS 2.0 A-/B 40-536 (92.7%) 1-39? 0.195 0.230 4.6 100
Comparison of the resolution top five PDB structures according to different other criteria.

</figtable>

Structure 2V3F seems to be a good choice because of the highest pH-value and the lowest R-value and R-free. However, there are some missing residues, 8 in chain A:

REMARK 465 MISSING RESIDUES
REMARK 465 THE FOLLOWING RESIDUES WERE NOT LOCATED IN THE
REMARK 465 EXPERIMENT. (M=MODEL NUMBER; RES=RESIDUE NAME; C=CHAIN
REMARK 465 IDENTIFIER; SSSEQ=SEQUENCE NUMBER; I=INSERTION CODE.)
REMARK 465
REMARK 465 M RES C SSSEQI
REMARK 465 PRO A 29
REMARK 465 THR A 30
REMARK 465 PHE A 31
REMARK 465 LEU A 499
REMARK 465 VAL A 500
REMARK 465 ASP A 501
REMARK 465 THR A 502
REMARK 465 MET A 503
REMARK 465 GLU B -1
REMARK 465 PHE B 0
REMARK 465 ASP B 27
REMARK 465 PRO B 28
REMARK 465 PRO B 29
REMARK 465 THR B 30
REMARK 465 PHE B 31
REMARK 465 PRO B 32
REMARK 465 LEU B 498
REMARK 465 LEU B 499
REMARK 465 VAL B 500
REMARK 465 ASP B 501
REMARK 465 THR B 502
REMARK 465 MET B 503

2. Visualise the mutations you want to work with

3. Create mutated structures

Energy comparisons

foldX

Minimise

Gromacs (optional task for those who love MD!)

Sources

PDB R-value and R-free