Structure based mutation analysis of GBA

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Revision as of 22:20, 29 June 2011 by Braunt (talk | contribs) (Introduction)

Introduction

A detailed list of the ten mutations analyzed in this section, can be found in Task 6.

Structure Selection

To carry out a structure-based analysis of the mutations chosen in Task 7 a crystal structure had to be chosen. According to Uniprot 19 different crystal structures of glucocerebrosidase exist. The table below shows the six different structures with a resolution of or better than 2 Angstrom. 2NT0 is chosen as template for the analysis carried out in this section, as no residues are missing, the R-value is quite low, and it has the best resolution among the structures without missing residues. Only incomplete structures have been resolved near the physiological pH (7.4), therefore a structure resolved at a more acid pH had to be chosen.


PDB ID Resolution [Å] R-factor Coverage pH # Missing Residues (A/B)
1OGS 2.00 0.195 4.6 0
2NT0 1.79 0.181 . 4.5 0
2V3D 1.96 0.157 6.5 9/8
2V3E 2.00 0.163 7.5 7/7
2V3F 1.95 0.154 6.5 8/14
3GXI 1.84 0.193 NULL 0


Mutation Mapping

The ten positions at which the mutations analyzed in this task take place, are hilighted in the structure of 2NT0 shown in Figure 1. As already mentioned in Task 5 and 6, one can clearly see that two mutations are next to the active site residues Glu235 and Glu340, namley the positions 120 and 311. The wildtype residues at these positions (Arg120 and His311) are known to form hydrogen bonds with the active sites and should therefore be quite important for function and structure. <ref>Kim et al., Crystal Structure of the Salmonella enterica Serovar Typhimurium Virulence Factor SrfJ, a Glycoside Hydrolase Family Enzyme. Journal of Bacteriology, 2009, p. 6550-6554, Vol. 191, No. 21 </ref> The other eight mutations positions are located all over the protein.


Figure 1: 2NT0 with hilighted mutation positions (red) and active site residues (blue).
Figure 2: Close-up of active site of 2NT0 with hilighted mutation positions (red) and active site residues (blue).

SCWRL

SCWRL is a tool, specifically designed for side-chain conformation predictions, given a fixed backbone from an experimental determined structure. <ref>G. G. Krivov, M. V. Shapovalov, and R. L. Dunbrack, Jr. Improved prediction of protein side-chain conformations with SCWRL4. Proteins (2009). </ref>

Usage

  • Create pdb-File only containing chain A of the protein (e.g with pymol): 2NT0_A.pdb
  • Extract sequence (e.g with repairPDB) and change all letters of protein sequence to lower case and introduce mutation in capital letters: mutantSequence.seq
    • Note, that only one mutation should be inserted per sequence -> results in 10 mutant sequence files.
  • Commandline: scwrl4 -i 2NT0_A.pdb -s mutantSequence.seq -o 2NT0_mutant.pdb > scwrl.log

Results

SCRWL4 was applied ten times, once for each mutation. The resulting conformations of the mutants are visualized in Figure 3. Figure 3 additionally shows the wildtype amino acids and the mutants created with the mutagenesis method of pymol. The conformations, created with SCWRL4 and pymol vary greatly. Only in mutation 9 they seem to be quite similar. Figure 4 shows a superposition of the wild type protein and the mutated proteins in cartoon representation. This shows that SCWRL did not only change the mutant residues, but also changed some beta sheets at the bottom of the structure (shown in green). These changes are consistent in all ten mutant structures.


Figure 3: Wildtype amino acids (red) and mutations created with SCWRL (green) and pymol mutagenesis (orange) hilighted on the structure of 2NT0.
Figure 4: Cartoon representation of 2NT0, chain A (gray) superimposed with the resulting structures of SCWRL (green).


Mutation 1 2 3 4 5 6 7 8 9 10
Minimal Energy 351.329 348.659 350.017 355.416 473.454 364.148 352.615 362.604 354.98 375.976

Energy Calculation

FoldX

Minimise

Gromacs

Discussion