Difference between revisions of "Structure-based mutation analysis BCKDHA"

From Bioinformatikpedia
(3. SCWRL)
(5.MDP)
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<!-- pdb2gmx -f bckdha_mod.pdb -o bckdha.gro -p topol.top -water tip3p -ff amber03-->
 
<!-- pdb2gmx -f bckdha_mod.pdb -o bckdha.gro -p topol.top -water tip3p -ff amber03-->
   
===5.MDP===
+
===5. MDP===
  +
<!--
  +
<code>
  +
title = PBSA minimization in vacuum
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cpp = /usr/bin/cpp
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define = -DFLEXIBLE -DPOSRES
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implicit_solvent = GBSA
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integrator = steep
  +
emtol = 1.0
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nsteps = 500
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nstenergy = 1
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energygrps = System
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ns_type = grid
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coulombtype = cut-off
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rcoulomb = 1.0
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rvdw = 1.0
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constraints = none
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pbc = no
  +
</code
  +
-->
   
 
===6.grompp===
 
===6.grompp===

Revision as of 20:39, 29 June 2011

Structure selection

The following table presents the PDB structures for BCKDHA to date:

PDB id resolution [Å] R-factor coverage ph-value
1DTW 2.70 0.224 7.5*
1OLS 1.85 0.172 5.5
1OLU 1.90 0.161 5.5
1OLX 2.25 0.161 5.5
1U5B 1.83 0.156 5.8
1V11 1.95 0.139* 5.5
1V16 1.90 0.132* 5.5
1V1M 2.00 0.130* 5.5
1V1R 1.80 0.158 5.5
1WCI 1.84 0.149 5.5
1X7W 1.73 0.148 5.8
1X7X 2.10 0.149 5.8
1X7Y 1.57 0.150 5.8
1X7Z 1.72 0.154 5.8
1X80 2.00 0.161 5.8
2BEU 1.89 0.171 5.5
2BEV 1.80 0.139 5.5
2BEW 1.79 0.147 5.5
2BFB 1.77 0.145 5.5
2BFC 1.64 0.144 5.5
2BFD 1.39* 0.150 5.5
2BFE 1.69 0.150 5.5
2BFF 1.46 0.150 5.5
2J9F 1.88 0.171 5.5

The following PDB Structure was chosen because of its good experimental resolution: <bold></bold>

  • resultion:
  • R-factor
  • ph-value

Comparison energies

Mapping of the mutations on the crystal structure

SCWRL

Before we could use SCWRL we first had to get the sequence of our model: repairPDB bckdha.pdb -seq >> bckdha.seq

When we have the sequence we have to make one file for each mutation. In these files we copied the bckdha.seq and changed the sequence to lower case letters. Then we add the mutation in an upper case letter.

To run SCWRL we used the command: scwrl -i bckdha.pdb -s mutation1.seq -o mutation1Model.pdb


Total minimal energy of the graph

Position Energy
M82L 642.213
Q125E 616.85
Y166N 616.293
G249S 633.378
C264W 805.257
R265W 710.647
I326T 619.424
F409C 617.305
Y438N 615.951

foldX

To use foldX we first had to build a runscript. We create two different scripts one for the wildtype and one for the mutations.

Additionally we had to create one file with the PDB-ID (foldx_protein.txt). And for the mutation-script a file where the mutation is declared (mutant_file.txt).

wildtype

<TITLE>FOLDX_runscript;
<JOBSTART>#;
<PDBS>#;
<BATCH>foldx_protein.txt;
<COMMANDS>FOLDX_commandfile;
<Stability>wildtype.txt;
<END>#;
<OPTIONS>FOLDX_optionfile;
//<Temperature>298;
<R>#;
<pH>5.5;
<IonStrength>0.050;
<water>-CRYSTAL;
<metal>-CRYSTAL;
<VdWDesign>2;
<OutPDB>false;
<pdb_hydrogens>false;
<END>#;
<JOBEND>#;
<ENDFILE>#;


mutation

<TITLE>FOLDX_runscript;
<JOBSTART>#;
<PDBS>#;
<BATCH>foldx_protein.txt;
<COMMANDS>FOLDX_commandfile;
<BuildModel>#,mutant_file.txt;
<END>#;
<OPTIONS>FOLDX_optionfile;
<Temperature>298;
<R>#;
<pH>7;
<IonStrength>0.050;
<water>-CRYSTAL;
<metal>-CRYSTAL;
<VdWDesign>2;
<OutPDB>false;
<pdb_hydrogens>false;
<complex_with_DNA> true;
<END>#;
<JOBEND>#;
<ENDFILE>#;

gromacs

Gromacs

1. fetchpdb

The fetch-pdb script first checks, if it was called with an valid PDB-id. If the entered PDB code has 4letters, the script tries to download the pdb-file from the server. The successfully downloaded folder gets unzipped and everything except the actual pdb file is removed.

2. repairPDB

3. SCWRL

4.pdb2gmx

5. MDP

6.grompp

7.System Minimization

8.Analyzation

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go back to Task 6 Sequence based mutation analysis

go to Reference Sequence BCKDHA