Structure based mutation analysis of GBA

Introduction

After the sequence based mutation analysis, as described in Task 6, a structure based mutation analysis of ten mutations (listed in the table below) was carried out. For the analysis, several different tools have been used. TThe different tools and the corresponding steps, applied in this analysis are described in more detail in this workflow for reasons of clarity.

Structure Selection

To carry out a structure-based analysis of the mutations chosen in Task 6, a crystal structure had to be chosen. According to Uniprot there are 19 different crystal structures of glucocerebrosidase available. 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. The structure can either be downloaded from the PDB website or by using the script fetchpdb, which validates the ID and downloads the corresponding structure.

Mutation Mapping

Figure 1 shows the positions of the analyzed mutations in the original structure of 2NT0. 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 mutations at 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 mutation positions are located all over the protein. The amino acid properties of the different mutant and wildtype structures have already been analysed in Task 6.

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

SCRWL4 was applied ten times, once for each mutation. The resulting conformations of the mutants are visualized in Figure 3. For this representation the hydrogens of the SCWRL mutant structures have been removed to simplify the comparison with the other two structures. 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). This fact may be due to the different polar interactions of the mutants.

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).

Minimise

Figure 5 shows the interesting positions with hilighted mutants and wild type residues of the pdb files obtained with Minimise after having applied the steps as indicated in the workflow. The hydrogens of the structures have been removed as well.

Figure 5: Wildtype amino acids (red) and mutations (green) created with Minimise. Polar interactions are shown with dotted lines.

Gromacs

Figure 6 shows the interesting positions with hilighted mutants and wild type residues of the pdb files obtained with Gromacs after having applied the steps indicated in the workflow. The hydrogens of the structures have been removed as well.

Figure 6: Wildtype amino acids (red) and mutations (cyan) created with Gromacs. Polar interactions are shown with dotted lines.

Polar Interactions

Polar interactions are crucial for the structue, and therefore function of a protein. A mutation of a single amino acid could therefore alter the features and appearance of a protein. Analyzing polar interactions may therefore help to determine whether a mutation is damaging or neutral. If the polar interactions, which are present in the wild type structure, are still formed after the mutation, the mutation may be tolerated, otherwise it should be damaging.

The table below shows the residues forming polar interactions with the mutant/wild type amino acid. The polar interactions can be seen in Figure 3, Figure 5 and Figure 6 as well, but one may not clearly distinguish, whether an interaction is only formed by e.g. the wild type or by wild type and mutant. To determine the interaction partners, the tool Pymol was used [actions -> find -> polar contacts -> to other atoms in object].

Mutations 1, 2, 5, 7, 9 and 10 show in most cases (SCWRL, Minimise, Gromacs) the same polar interactions as the wild type and should therefore not have a big influence. The other mutations (3,4,6 and 8) form however additional bonds or miss some interactions which are present in the wild type. Interestingly, the most common mutation found in Gaucher Disease forms the same polar interactions as the wildtype.

Clashes or Holes

Furthermore it was analyzed whether the mutations cause clashes or holes in the protein structure. The following table shows whether the mutations created/minimized with Pymol, SCWRL, Minimise and Gromacs lead to structural inconsistency compared to the wildtype glucocerebrosidase (2NT0).

None of the mutations lead to clashes or holes in the protein structure, but some of the mutations cause a different surface. Mutation 6 leads to a different surface, no matter whith which tool they were created or minimized. This is quite interesting as Serine and Asparagine are structurally and chemically very similar. Regarding the polar interactions, they are not identical.

Overall one would assume that the surface od the resulting protein is changed if a mutation leads to different polar interactions and if the mutations takes place inside a structural element. Mutation 1 leads to a different surface when build with Pymol Mutagenesis and Gromacs. The mutated residue is part of a secondary structural element, the mutated amino acid has a different polarity than the wildtype and the Pymol Mutagenesis build forms an additional hydrogen bond. These facts could explain the different surface. Mutation 2 does not lead to a different surface. This is quite interesting regarding the Pymol Mutagenesis Build, as this one forms completely different hydrogen bonds than the wildtype. The fact that the mutated residue is not part of a secondary structural element and that Asparagine and Aspartic Acid have a similar molar mass could be an explanation for the not altered surface. Mutation 3 leads to a different surface whem niminised with SCRWL or Minimize. The polar interactions are always different to the ones formed by the wild type, no matter which tool was used. Furthermore the mutated amino acid is structurally very different to the wildtype amino acid. Mutation 4 results in a different surfacce when using the tool Gromacs. The mutated amino acid forms different polar interactions than the wild type, no matter which tool was used. Therefore it is quite interesting, that the surface is only altered when gromacs is used.

Energy Comparison

The energy of a protein is an indication for its stability: the lower the more stable is the protein. Therefore a comparison of energy between the different mutations and wildtypes could be an indication whether a mutation could be damaging. If the energy of the mutated protein is much higher than the one of the wildtype protein it might be an indication that this mutation is damaging.

In this section, the energies of the structures, obtained with different minimization and modeling tools (SCWRL, FoldX, Minimise and Gromacs) are listed for each structure and for the wildtype (if available).

SCWRL

The table below shows the minimal energies for the different mutated structures obtained after the sidechain modelling with SCWRL. Most of the mutations are about the same energy value. Only Mutation 5 shows a much higher energy, which shows, that the protein is much less stable than if other resiudes are mutated. This indicates that Mutation 5 is a damaging mutation.

FoldX

The total energies calculated with FoldX are shown in the table below. The differences between the wild type and the different mutant structures have been calculated and are listed in the table as well.

The mutated structures have a higher energy than the wildtype protein. Once again it is Mutation 5 having the highest energy and therefore being the least stable structure. The other mutations show similar energies.

Minimise

The total energies calculated with minimise are shown in the table below. The differences between the wild type and the different mutant structures have been calculated and are listed in the table as well.

The energy values of the mutated proteins are higher than the energy of the wildtype protein, which indicates that the mutated ones are less stable. This time Mutation 8 shows the highest energy and variance from the wildtype protein. Mutation 5 is also significantly higher than the average distance. Mutation 9 shows a slightly higher energy than most of the other mutations. This might be an indication, that Mutation 5, 8 and 9 are more damaging than the other mutations.

Gromacs

Wildtype

Correlation between nsteps and runtime of mdrun

The following table shows the measured time for mdrun for different nsteps and force fields. It also shows the steps it really took to calculate the lowest energy. Nsteps specify the maximum number of steps to integrate or minimize during the simulation. Therefore the computation time should ne higher, the more steps have been performed. This fact can be observed in the table below. With the force fields AMBER03 and CHARMM27 it took less than 1000 steps to reach the minimum, so computation times for 1000 and 5000 are the same. Figure 7 shows the correlation between nsteps and the runtime (real time)of mdrun.

Figure 7: Correlation between nsteps and the runtime of mdrun for different force fields

Force Fields: AMBER03, CHARMM27 and OPLS/AA

AMBER03

Bond

Angle

Potential

Plots with bond, angle and potential

Figure 8: GROMACS Energy for the AMBER03 forcefield with nsteps 10.

Figure 9: GROMACS Energy for the AMBER03 forcefield with nsteps 100.

Figure 10: GROMACS Energy for the AMBER03 forcefield with nsteps 500.

Figure 11: GROMACS Energy for the AMBER03 forcefield with nsteps 1000.

Figure 12: GROMACS Energy for the AMBER03 forcefield with nsteps 5000.

CHARMM27

Bond

Angle

Potential

Plots with bond, angle and potential

Figure 13: GROMACS Energy for the CHARMM27 forcefield with nsteps 10.

Figure 14: GROMACS Energy for the CHARMM27 forcefield with nsteps 50.

Figure 15: GROMACS Energy for the CHARMM27 forcefield with nsteps 100.

Figure 16: GROMACS Energy for the CHARMM27 forcefield with nsteps 500.

Figure 17: GROMACS Energy for the CHARMM27 forcefield with nsteps 1000.

Figure 18: GROMACS Energy for the CHARMM27 forcefield with nsteps 5000.

OPLS/AA

Bond

Angle

Potential

Plots with bond, angle and potential

Figure 19: GROMACS Energy for the OPLS/AA forcefield with nsteps 10.

Figure 20: GROMACS Energy for the OPLS/AA forcefield with nsteps 50.

Figure 21: GROMACS Energy for the OPLS/AA forcefield with nsteps 100.

Figure 22: GROMACS Energy for the OPLS/AA forcefield with nsteps 500.

Figure 23: GROMACS Energy for the OPLS/AA forcefield with nsteps 1000.

Figure 24: GROMACS Energy for the OPLS/AA forcefield with nsteps 5000.

Mutations

Mutation 1: Gly - Ser (Pos. 10)

Figure 25: GROMACS Energy for the first mutation with AMBER03 forcefield and nsteps 500.

Mutation 2: Asp - Asn (Pos. 24)

Figure 26: GROMACS Energy for the second mutation with AMBER03 forcefield and nsteps 500.

Mutation 3: His - Arg (Pos. 60)

Figure 27: GROMACS Energy for the third mutation with AMBER03 forcefield and nsteps 500.

Mutation 4: Arg - Gln (Pos. 120)

Figure 28: GROMACS Energy for the fourth mutation with AMBER03 forcefield and nsteps 500.

Mutation 5: Pro - Leu (Pos. 182)

Figure 29: GROMACS Energy for the fifth mutation with AMBER03 forcefield and nsteps 500.

Mutation 6: Ser - Asn (Pos. 271)

Figure 30: GROMACS Energy for the sixth mutation with AMBER03 forcefield and nsteps 500.

Mutation 7: Asn - Ser (Pos. 370)

Figure 31: GROMACS Energy for the seventh mutation with AMBER03 forcefield and nsteps 500.

Mutation 8: His - Arg (Pos. 311)

Figure 32: GROMACS Energy for the eighth mutation with AMBER03 forcefield and nsteps 500.

Mutation 9: Met - Val (Pos. 416)

Figure 33: GROMACS Energy for the ninth mutation with AMBER03 forcefield and nsteps 500.

Mutation 10: Leu - Pro (Pos. 470)

Figure 34: GROMACS Energy for the tenth mutation with AMBER03 forcefield and nsteps 500.

Discussion

References