Task 4: Structural Alignments

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lab journal task 4

PDB structures selection

We first selected a set of structures that span different ranges of sequence identity to the reference structure (1A6Z). The domain A of the reference structure has the CATH annotation 3.30.500.10.9 (Murine Class I Major Histocompatibility Complex H2-DB subunit A domain 1) and the domain b 2.60.40.10 (immunoglobulins). We decided to take the domain A as template and only searched for structures with a similar annotation to 3.30.500.10.9, since the immunglobulin domain is only bound to the protein and not directly connected. Also, because the disease causing mutations are all located in the MHC domain. <xr id="selected structures"/> list the structures, their CATH numbers and percent sequence idenity to the reference. Unfortunately, we could not find a structure with a sequence identity over 60%. The most similar structure we could find was 1qvo with 39% identity.

<figtable id="selected structures">

category ID chain domain CATH number Sequence identity (%) protein (organism)
reference 1A6Z A 1 3.30.500.10 - HFE (Homo sapiens)
identical sequence 1DE4 A 1 3.30.500.10 100 HFE (Homo sapiens)
> 30% SeqID 1QVO A 01 3.30.500.10 39 HLA class I histocompatibility antigen, A-11 alpha chain (Homo sapiens)
< 30% SeqID 1S7X A 00 3.30.500.10 29 H-2 class I histocompatibility antigen, D-B alpha chain (Mus musculus)
CAT 2IA1 A 01 3.30.500.20 11.1 BH3703 protein (Bacillus halodurans)
CA 3NCI A 01 3.30.342.10 5.8 DNA polymerase (Enterobacteria phage RB69)
C 1VZY A 01 3.55.30.10 2.8 33 KDA CHAPERONIN (Bacillus subtilis)
different CATH 1MUS A 01 1.10.246.40 12.6 Tn5 transposase (Escherichia coli)
Table 1: Table of the selected pdb structures, the chain, the CATH annotation, their sequence identity to the refeerence 1A6Z_A and the protein type.

</figtable>

Results

In Pymol, each structure from <xr id="selected structures"/> was aligned to the reference 1A6Z_A using only the C_alpha atoms and also using all the atoms. The resulting RMSD values are specified in <xr id="score results"/>. The numbers in brackets after the RMSD values indicate the number of aligned residues that were used to compute the corresponding values.

<figtable id="score results">

PDB ID Seq. identity (%) Pymol LGA SSAP TopMatch CE
RMSD (only C_alpha) RMSD (all atom) RMSD LGA_S RMSD SSAP_Score RMSD S S_r RMSD Score
1DE4_A 100 0.675 (237) 0.767 (1836) 1.14 (267) 95.77 1.60 (272) 93.07 1.08 260 1.03 1.19 (267) 543
1QVO_A 39 2.165 (233) 2.279 (1565) 2.29 (259) 67.86 2.58 (268) 86.39 2.62 228 2.50 2.44 (266) 432
1S7X_A 29 1.889 (233) 2.049 (1557) 2.12 (256) 71.90 2.36 (267) 86.25 2.66 227 2.56 2.29 (265) 342
2IA1_A 11.1 18.132 (74) 18.283 (501) 2.83 (86) 19.44 15.85 (140) 56.19 2.91 76 2.82 3.93 (93) 300
3NCI_A 5.8 16.561 (26) 17.329 (178) 3.11 (84) 17.19 14.54 (168) 30.18 3.05 53 2.94 4.47 (75) 333
1VZY_A 2.8 6.260 (29) 6.951 (168) 3.25 (63) 13.44 26.34 (208) 58.01 2.61 68 2.53 5.80 (91) 245
1MUS_A 12.6 23.521 (180) 23.891 (1143) 2.82 (69) 16.02 18.53 (215) 46.30 3.58 69 3.43 6.61 (78) 379
Table 2: Results of the structural alignments of the selected proteins to the template 1A6Z_A. The different alignment scores are listed for each method and the numbers of equivalent residues are stated in brackets after the RMSD.

</figtable>

Images of the superimposed structures, using the C_alpha atoms, are shown in <xr id="pymol str. al.">. The pictures show clearly that a successful superposition is only possible if the two structures share a certain level of sequence identity. 1QVO_A could be aligned to the reference with a low RMSD (39% sequenc identity), but 1S7X_A has a even lower value, although the sequenc identity is smaller (29%). This could be explained by the fact that 1S7X_A is the exact mouse ortholog of the human Murine Class I Major Histocompatibility Complex H2-DB chain A (1A6Z_A) and therfore has a nearly identical structure. Apart from the three structures 1DE4_A, 1QVO_A and 1S7X_A, the other proteins could not really be superimposed to the reference, see the high RMSD values in column 3 and also the low number of equivalent residues in <xr id="score results"/>. Using all the atoms for the computation of the RMSD did not increase the quality of the alignments and the RMSD, see column 4 <xr id="score results"/>.

<figtable id="pymol str. al.">

1DE4_A (red) aligned to 1A6Z_A (green). The sequences are identical and thus the alignment is perfect.
1QVO_A (red) aligned to 1A6Z_A (green). Both proteins share a high sequence identity and could be aligned quite good.
1S7X_A (red) aligned to 1A6Z_A (green). Although the two sequences only share 29% sequence identity, they could be aligned very good. This can be explained by the fact that the proteins are orthologs from two different species.
2IA1_A (red) aligned to 1A6Z_A (green). The two proteins could not be aligned well despite the fat that they share the same CAT numbers.
3NCI_A (red) aligned to 1A6Z_A (green). The alignment was not successful.
1VZY_A (red) aligned to 1A6Z_A (green). Because the proteins only share the same C number, the alignment is not good.
1MUS_A (red) aligned to 1A6Z_A (green). The proteins have completely different CATH annotations and therefore different structrues that cannot be aligned.
Table 3: Visualisation of the pariwise structural alignments of all selected proteins to the template 1A6Z_A using the C_alpha atoms. The template is shown in green and the target in red.

</figtable>


Different structural alignments were applied to superimpose all the structures to the reference structure . The resulting alignments scores are specified in <xr id="score results"/>.






  • Pymol only uses a subset of atoms for the computation of the RMSD.
  • LGA computes the RMSD from all atoms under distance cutoff. It therfore uses more atoms than Pymol if the proteins are similar, but few if the structures are more divergent.
  • SSAP
  • TopMatch
  • CE

Structural alignments for evaluating sequence alignments