Task 5: Homology Modeling

lab journal task 5

1A6Z chain A was used as modeling target for all three methods.

Modeller

We used Modeller to create models based on a single template and multiple templates.

Single template

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<figtable id="Modeller single">

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<xr id="Modeller single"/> lists the selected templates and the Modeller results for the different template structures and alignment methods. In addition to the standard pairwise sequence alignment based on dynamic programming, we also used Modeller's alignment.alig2dn() method to improve the alignment by including secondary structure information and improved the alignments manually. The RMSD and TM score are given for all models. The TM score ranges in the interval of (0, 1]. A value below 0.17 indicates a random similarity and a TM score above 0.5 corresponds to two structures with the same fold in CATH or SCOP (see TM score). Including the secondary structure information did only improve the model of the most distant homolog 1CD1_A.

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

Figure 1:Superposition of the target 1A6Z_A (green), the template 1QVO_A (red) and the model (purple). Two different alignment methods were used to create the input alignment. for Modeller.

a) classical pairwise sequence alignment

b) inclusion of secondary structure information in the alignment

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

Figure 2:Superposition of the target 1A6Z_A (green), the template 1S7X_A (red) and the model (purple). Two different alignment methods were used to create the input alignment. for Modeller.

a) classical pairwise sequence alignment

b) inclusion of secondary structure information in the alignment

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

Figure 3:Superposition of the target 1A6Z_A (green), the template 1CD1_A (red) and the model (purple). Two different alignment methods were used to create the input alignment. for Modeller.

a) classical pairwise sequence alignment

b) inclusion of secondary structure information in the alignment

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Multiple templates

We also user more than one template in a modeling step. Therefore, we created three sets of structures, one with close homologes, one with distant homologes and one combined set.

<figtable id="multiple sets">

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<xr id="multiple sets"/> specifies the three sets.

<figtable id="multiple sets">

Table 3: Results of the modeling with multiple templates. We computed models using 2 structures as templates and also using three structures.

	close homology		distant homology		mixed homology
Template	1QVO_A, 1ZAG_A	1QVO_A, 1ZAG_A, 1RJZ_D	3HUJ_C, 1CD1_A	3HUJ_C, 1CD1_A, 1VZY_A	1QVO_A, 1CD1_A
RMSD	3.432	2.431	4.130	7.741	3.974
TM score	0.6553	0.7638	0.5607	0.3814	0.5846
Pymol visualisation	Visualisation of the target (green) and the model created from 1QVO_A and 1ZAG_A (purple).	Visualisation of the target (green) and model created from 1QVO_A, 1ZAG_A and 1RJZ_D (purple).	Visualisation of the target (green) and model model created from 3HUJ_C and 1CD1_A (purple).	Visualisation of the target (green) and model created from 3HUJ_C, 1CD1_A and 1VZY_A (purple).	Visualisation of the target (green) and the model created from 1QVO_A and 1CD1_A (purple).

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Swiss-Model

We used Swiss-Model to create models using 1QVO_A, 1S7X_A and 1CD1_A as template.

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Table 4: .

	1QVO_A	1S7X_A	1CD1_A
Template	1QVO_A	1S7X_A	1CD1_A
Seq. identity	39%	29%	21%
RMSD	2.847		3.604
TM score	0.6774		0.6121
Pymol visualisation	Visualisation of the target (green), the template 1QVO_A and the model (purple).		Visualisation of the target (green), the template 1CD1_A and the model (purple).

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I-TASSER