v4.1

• Index
• User Guide
• Menus
• Tips & Tricks
• Tutorial
• • Main
  • Gale Rhodes's Basic Tutorial
  • Analysing an active site
  • Building a functionnal unit from a monomer
  • Crystal Symmetries
  • Electron Density Maps
  • Hydrophobic patches
  • Contact surfaces
  • Energy minimisation
  • Identifying distorted residues
  • Fitting Residues into Electron Density
  • Superposing Proteins
  • Searching 3D motifs
  • Making Phi/Psi statistics
  • Homology modelling
  • Building Loops
  • SWISS-MODEL Workspace

• Download
• Feedback
• Art Gallery
• References

Step by Step

• First of all, open the pdb file 1HBG (it is included in the tutorial package).
• Hide all the sidechains by option-clicking (right mouse button for PC users) on the sidechain column of the control panel, and colour the whole molecule in white by option-clicking in one of the colour boxes of the control panel . Then, scroll at the bottom of the control panel and colour the heme in yellow.
• Repeat the same procedure with the file 1gdi, but this time, colour the protein in red, and the heme in violet. Now hit the "=" key of the numerical keyboard to automatically recenter the view (right mouse button for PC users).

At this stage, you should be in this situation.

• Now select the "Magic fit" option of the "Tool" menu and accept all default parameters. The two proteins should now be superimposed. Here again, recenter and expand the view by hitting the "=" key (right mouse button for PC users).

At this stage, you should be in this situation.

• Now bring the align window to front, and move the cursor onto the Trp15 of 1gdi. As you can see, it will blink from blue to yellow in the display window, allowing you to immediately know where it lays in the protein. In addition, if you look at the bottom left of the align window, you will see a RMS distance. This is the rms deviation between backbone atoms of 1gdi:Trp15 and 1hbg:Lys15.
  The value is high (4.108), because the alignment you see in the window is just the raw sequence of each protein The Trp15 does not correspond to the Lys15. What you will have to do now is generate the structural alignment.

Generating the Structural Alignment

• Click on the name 1gdi on the left of the align window to bring this protein to front (the control Panel should reflect the change). Now use the option "Generate Structural Alignment" of the menu "Tools", and go back onto the Trp15 of 1GDI. It should now be aligned with the Ala18 of 1hbg, and its rmsd should be much lower (2.745).
• While you're at this stage, choose the option "Colour by RMS" from the "Tool Menu" and look at the alignment window. Amino acids will appear in dark blue if they have a close correspondent in the reference structure, and appear brighter (from blue to yellow) when their rmsd increases, up to be red if they have no correspondent in the reference structure.
  The result is that loops inexistent in the reference are clearly visible in red in the main window (as you can see in the small icon at the top of the page).

• Click on the little text icon of the Align window. A text window containing the structural alignment that will look like the one below, depending on the options you have set in the alignment preferences should appear.

• Now Select the "Save Alignment item of the File menu. This will save your preview as a text file. Note that it is not necessary to look at the preview, you can also directly save the structural alignment file.
• The Magic Fit does a crude superimpostion. You can achieve a much better one by using the "iterative Magic fit" option of the Tool menu. Try it!
• Other means to achieve a better superimposition are to use the "Select AA matching Ref. structure" item of the "Select" menu, providing your RMS deviation cutoff value (for example 2.5) and then using the "Fit Molecule Auto" item of the "Tool" menu. Alternatively, you can refine the superimposition by manually selecting parts (for example Helixes) and then using the "Fit Molecule Auto".