Generating decoys (Reed's way)
Written on April 3, 2018.
All scripts for this tutorial can be found in:
/mnt/nfs/home/rstein/zzz.scripts/DUDE_SCRIPTS/
Setting up SMILES directory
Before starting, you need a SMILES file with the format (SMILES first, ID second):
S(Nc1c(O)cc(C(=O)O)cc1)(c2c(scc2)C(=O)O)(=O)=O 116
You also need an input file named "decoy_generation.in" with the following lines:
PROTONATE YES MWT 20 125 LOGP 0.4 3.6 RB 1 5 HBA 0 4 HBD 0 3 CHARGE 0 2 DECOYS PER LIGAND 50
If your SMILES file is already protonated as you want it, set "PROTONATE NO".
This file specifies that for each ligand protomer, 50 decoys will be retrieved with the following properties:
- within 125 Daltons - within 3.6 logP - within 5 rotatable bonds - within 4 hydrogen bond acceptors - within 3 hydrogen bond donors - within +/- 2 charge - 0.35 or less Tanimoto
These are the default values, but you can input your desired minimum and maximum values that decoys can differ by, relative to the ligands.
For "DECOYS PER LIGAND", input the number of decoys that each ligand protomer should have.
Once you have created this file, run the following command to create the decoy generation directory:
python /mnt/nfs/home/rstein/zzz.scripts/DUDE_SCRIPTS/0000_protonate_setup_dirs.py {SMILES_FILE} {NEW_DIR_NAME}
Provide a directory name that you want in place of {NEW_DIR_NAME}. This will create the directory with subdirectories named "ligand_${number}" for each of the ligands in the SMILES file you input.
Retrieving decoys from ZINC15
If you have edited the "decoy_generation.in" file which is now located in {NEW_DIR_NAME} as you want, you can run the following command:
python /mnt/nfs/home/rstein/zzz.scripts/DUDE_SCRIPTS/0001_qsub_generate_decoys.py {NEW_DIR_NAME}
Jobs will run 5 at a time until completed. This should take a few hours, depending on how many ligands you input.
Removing decoys that are too similar to known ligands
To remove any decoys retrieved that are too similar to all the ligands you have retrieved decoys for, run the following command:
python /mnt/nfs/home/rstein/zzz.scripts/DUDE_SCRIPTS/0002_remove_similar_compounds.py {NEW_DIR_NAME}
This will run on the queue.
Assigning accepted decoys to each ligand protomer
Now that the previous script has removed any decoys that were too similar to known ligands, we can assign the remaining decoys to the ligand protomers. Make sure you have the "decoy_generation_input.txt" file from before in {NEW_DIR_NAME}.
To filter the decoys, run the following command:
python /mnt/nfs/home/rstein/zzz.scripts/DUDE_SCRIPTS/0003_qsub_filter_decoys.py {NEW_DIR_NAME}
This will run on the queue. A log file called "FILTER_DECOYS.log" will be generated in {NEW_DIR_NAME} with information and any errors.
Copying decoy .db2.gz files into your directories
Now that we have assigned decoys to your ligand protomers, we can copy these decoys into your own directory of choice. To do this, run the following command:
python /mnt/nfs/home/rstein/zzz.scripts/DUDE_SCRIPTS/0004_copy_decoys_to_new_dir.py {NEW_DIR_NAME} {COPY_TO_DIR}
where {COPY_TO_DIR} is a new directory that will be created where your decoys will be copied into. In this directory, two subdirectories will be created:
"ligands" - this will include "ligands.smi" which includes all the SMILES strings that have at least 50 property matched decoys "decoys" - this will include the decoy .db2.gz files for docking and "decoys.smi" which contains all the SMILES strings for property matched decoys
IMPORTANT: It is possible that there were not 50 property-matched decoys for all of your ligand protomers. The "ligands.smi" file in {COPY_TO_DIR} will not include these. Make sure you do not dock these if you calculate enrichment values.
Visualizing property distributions
To visualize the distributions of molecular properties of matched decoys relative to the ligands, run the following command:
python /mnt/nfs/home/rstein/zzz.scripts/DUDE_SCRIPTS/0005_plot_properties.py {NEW_DIR_NAME}
There will be 6 images in {NEW_DIR_NAME} for molecular weight, logP, number of rotatable bonds, number of hydrogen bond donors, number of hydrogen bond acceptors, and net charge of ligands and decoys.
Visualizing decoy Tanimotos to ligands
To visualize how different the matched decoys are to the input ligands, run the following command:
python /mnt/nfs/home/rstein/zzz.scripts/DUDE_SCRIPTS/0006_plot_tanimoto_to_lig.py {NEW_DIR_NAME}
There will be a box and whisker plot image in {NEW_DIR_NAME} showing the Tanimotos calculated between each ligand and all decoys.