2020 DOCK tutorial 3 with PDBID 4F4P

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This tutorial teaches you how to dock a drug molecule to a receptor.

/*This page is under construction*/

I. Introduction

DOCK

DOCK is an important molecular docking program in molecular modeling and drug design. It enables you to dock a small molecule (ligand) to a binding pocket of certain protein target (receptor) and find out correct binding geometry, types and number of interactions involve in binding and energies associate with binding. For this tutorial DOCK6.9 package was used. Purpose of using DOCK6.9 in this tutorial is to re-dock a ligand to a binding pocket of the receptor protein for pose reproduction and find out lead compounds which have stronger binding affinity with our receptor binding site.

Virtual Screening

This is a protocol widely used in drug design which enable you to find out small molecules that have higher binding affinity with the binding pocket of protein of interest by screening a millions of compounds in a virtual database (such as ZINC).

Organization of directories

Log in to the seawulf cluster and go to your group directory. Use following command to create files.

mkdir 001.files 002.surface_spheres 003.gridbox 004.dock 005.virtual_screen 006.virtual_screen_mpi 007.cartesianmin 008.rescore

4F4P

4F4P is the crystal structure of Tyrosine Kinase SYK in complex with ligand LASW836. You can get the pdb file from here [1]. The resolution is 2.37 Å. Click Download Files -> PDB Format to download PDB file.

Figure 1: 4F4P.pdb which contains protein receptor, ligand, sulphate ion and water molecules. (Missing residues in the protein receptor ignored since those are located away from the binding site)

II. Preparation of the ligand and receptor

Checking the structure

Read the article related to the PDB file [2] to understand protonation states, charges and other important information regarding the receptor and the ligand.

Open the pdb file through chimera and look at the structure.

Identify the main components of the model (receptor, ligand, solvent, cofactors). In our case, the PDB file contains one protein chain, ligand(OSB), sulfate ion(SO4(2-)) as a cofactor and water molecules (H2O).

Next, we are going to generate the receptor file and the ligand file.

Prepare the Receptor file

With the PDB file loaded by chimera, do Select -> Residue -> SO4 to select the sulfate. Use Actions -> Atoms/Bonds -> Delete to delete it. Then do Select -> Residue -> HOH to select the water molecules. Use the same method to delete it. Then do Select -> Structure -> (0SB) to select ligand molecule. Use the same method to delete it. Save the receptor as 4f4p_rec_noh.mol2.

OR

With the PDB file loaded by chimera, hold the control button and click on the protein chain to select a protein residue. Then click up arrow button to select the whole protein chain (Receptor). Then Select -> Invert(all models) to invert your selection (This will select all the components in your PDB file except receptor). Then do Actions->Atoms/bonds->Delete. You will remain with a protein receptor. Save the receptor as 4f4p_rec_noh.mol2.


Figure 2: Receptor with no Hydrogens and charges (4f4p_rec_noh.mol2)

Prepare the Ligand File

Open the pdf file again. Do Select -> Structure -> ligand(0SB) to select the ligand. Do Select -> Invert (all models), then delete the selected atoms. This will left the ligand molecule only. Save it as 4f4p_lig_noh.mol2.

Figure 3: Ligand with no Hydrogens and charges (4f4p_lig_noh.mol2)

Adding hydrogen and charge

Now we are going to add hydrogen atoms and charges to our receptor and ligand. Open 4f4p_rec_noh.mol2 file using Chimera and use the following instructions to prepare the receptor file to be used in DOCK. Tools -> Structure editing -> AddH. This command will add hydrogen to the receptor. Tools -> Structure editing -> Add Charge. This command will add charge to atoms to make the receptor neutral. Save the file as 4f4p_rec_h.mol2


Open 4f4p_lig_noh.mol2, follow the same steps for ligand file, add hydrogen. The Chimera added 2 hydrogens to the nitrogen where it is supposed to be only one, as referred in the pdb report. So remove one hydrogen. (Hold Ctrl and select extra H, then Actions -> Atoms/Bonds -> delete.) (Therefore, Be really concern when adding Hydrogens using chimera since it is automatically adding unwanted hydrogen atoms. Compare your protonation state with PDB report and make sure you have correct structure after adding hydrogens.) After removing hydrogen add charges to the ligand Tools -> Structure editing -> Add Charge. After this save the file as 4f4p_lig_h.mol2.

Figure 4: Ligand with Hydrogen and charges (4f4p_lig_h.mol2)

copy the 4f4p_rec_h.mol2, 4f4p_rec_noh.mol2, 4f4p_lig_noh.mol2, 4f4p_lig_h.mol2 files in to 001.files directory

III. Generating receptor surface and spheres

Creating a surface (DMS) file

Open the 4f4p_rec_noh.mol2 file in chimera. Then Action -> surface -> show -> Shows the surface of the receptor without H.

Tools -> Structure editing -> write DMS -> name: 4f4p_rec_noh.dms -> This command saves the surface of the receptor in dms format.

Figure 5: Surface of the receptor (4f4p_rec_noh.dms)

copy the 4f4p_rec.dms file in to 002.surface_spheres directory.

Generating spheres

Go to 002.surface_spheres folder Create a new input file to create spheres by

 vi INSPH

then type the following lines inside the file.

 4f4p_rec_noh.dms
 R
 X
 0.0
 4.0
 1.4
 4f4p_rec.sph

The first line 4f4p_rec_noh.dms specifies the input file. R indicates that spheres generated will be outside of the receptor surface. X specifies all the points will be used. 0.0 is the distance in angstroms and it will avoid steric clashes. 4.0 is the maximum surface radius of the spheres and 1.4 is the minimum radius in angstroms.The last line 4f4p_rec.sph creates the sph file that contains clustered spheres.

Once the INSPH file is ready, type the following command to generate the spheres.

 sphgen -i INSPH -o OUTSPH

Once sphgen command is successful, 4f4p_rec.sph file will be created. Open it up using Chimera along with 4f4p_rec_noh.mol2 file. You should get a similar output like the image below.

Figure 6:Chimera view of generated spheres along with the receptor(4f4p_rec_noh.mol2 + 4f4p_rec.sph)

Selecting Spheres

Here we will be selecting the spheres which defines the binding pocket of the ligand because we are trying to direct the ligand towards that binding site rather than all over the receptor. To select the spheres type the following command.

 sphere_selector 4f4p_rec.sph ../001.files/4f4p_noh_lig.mol2 10.0

This command will select all of the spheres within 10.0 angstroms of the ligand and output them to selected_spheres.sph. Visualize the selected spheres using Chimera to make sure the correct spheres are selected. Notice that, spheres around the ligand binding site are kept and all the other spheres are deleted in the image below.

Figure 7: Selected spheres along with the receptor (4f4p_rec_noh.mol2 + selected_spheres.sph)

IV. Generating box and grid

Generating box

Move to 003.gridbox directory Create a new file showbox.in and write the following lines in the file(# means comment ).

 Y.  #Say 'Yes' to make a box
 8.0   #The boundary of the box is at least 8 Angstroms from any spheres
 ../002.surface_spheres/selected_spheres.sph.  #The location and file name of the sphere file
 1    #Use the first cluster of spheres (only 1 cluster in this case)
 4f4p.box.pdb.  #The output filename

Use the following command to generate the box.

 showbox < showbox.in

If this step is successful, you should see a new file (4f4p.box.pdb) in 003.gridbox folder.

4f4p selected sphere with box

Generating Grid

Create a new input file called grid.in and write the following information there.

 compute_grids                             yes
 grid_spacing                              0.4
 output_molecule                           no
 contact_score                             no
 energy_score                              yes
 energy_cutoff_distance                    9999
 atom_model                                a
 attractive_exponent                       6
 repulsive_exponent                        9
 distance_dielectric                       yes
 dielectric_factor                         4
 bump_filter                               yes
 bump_overlap                              0.75
 receptor_file                             ../001.files/4f4p_rec_h.mol2
 box_file                                  4f4p.box.pdb
 vdw_definition_file                       /gpfs/projects/AMS536/zzz.programs/dock6.9_release/parameters/vdw_AMBER_parm99.defn
 score_grid_prefix                         grid

save the file and run the following command.

  grid -i grid.in -o grid.out

V. Energy Minimization

Before doing docking pose reproduction, energy minimization can be done in order to remove unfavorable intra-molecular clashes of ligand. (If not it will affect the later steps of docking)

Go to 004.dock folder and open a file called min.in and type following content there.

 conformer_search_type                                        rigid
 use_internal_energy                                          yes
 internal_energy_rep_exp                                      12
 internal_energy_cutoff                                       100.0
 ligand_atom_file                                             ../001.files/4f4p_lig_h.mol2
 limit_max_ligands                                            no
 skip_molecule                                                no
 read_mol_solvation                                           no
 calculate_rmsd                                               yes
 use_rmsd_reference_mol                                       ../001.files/4f4p_lig_h.mol2
 use_database_filter                                          no
 orient_ligand                                                no
 bump_filter                                                  no
 score_molecules                                              yes
 contact_score_primary                                        no
 contact_score_secondary                                      no
 grid_score_primary                                           yes
 grid_score_secondary                                         no
 grid_score_rep_rad_scale                                     1
 grid_score_vdw_scale                                         1
 grid_score_es_scale                                          1
 grid_score_grid_prefix                                       ../003.gridbox/grid
 multigrid_score_secondary                                    no
 dock3.5_score_secondary                                      no
 continuous_score_secondary                                   no
 footprint_similarity_score_secondary                         no
 pharmacophore_score_secondary                                no
 descriptor_score_secondary                                   no
 gbsa_zou_score_secondary                                     no
 gbsa_hawkins_score_secondary                                 no
 SASA_score_secondary                                         no
 amber_score_secondary                                        no
 minimize_ligand                                              yes
 simplex_max_iterations                                       1000
 simplex_tors_premin_iterations                               0
 simplex_max_cycles                                           1
 simplex_score_converge                                       0.1
 simplex_cycle_converge                                       1.0
 simplex_trans_step                                           1.0
 simplex_rot_step                                             0.1
 simplex_tors_step                                            10.0
 simplex_random_seed                                          0
 simplex_restraint_min                                        yes
 simplex_coefficient_restraint                                10.0
 atom_model                                                   all
 vdw_defn_file                                                /gpfs/projects/AMS536/zzz.programs/dock6.9_release/parameters/vdw_AMBER_parm99.defn
 flex_defn_file                                               /gpfs/projects/AMS536/zzz.programs/dock6.9_release/parameters/flex.defn
 flex_drive_file                                              /gpfs/projects/AMS536/zzz.programs/dock6.9_release/parameters/flex_drive.tbl
 ligand_outfile_prefix                                        4f4p.lig.min
 write_orientations                                           no
 num_scored_conformers                                        1
 rank_ligands                                                 no

Save the file and run the following command. If you have done correctly, you will get a ouput file called 4f4p.lig.min__scored.mol2.

 dock6 -i min.in -o min.out
Figure: Receptor with energy minimized ligand