AutoQSAR/DeepChem for billions of molecules: Difference between revisions
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2/25/2021 Ying Yang | 2/25/2021 Ying Yang | ||
== Train a ligand-based ML model == | |||
Model training requires GPU thus will be on gimel5 | |||
* | * Prepare the input file for training in the format of <ligand smiles>,<dock score> | ||
[[File:figure_dockscore_for_ML.png|thumb|Example distribution of dock score|350px]] | |||
* Analyze prediction | <nowiki> | ||
SMILES,DOCK score | |||
C[C@H]1COCCCN1C(=O)[C@@H]1CN2CCN1CCC2,-15.98 | |||
Cc1ccccc1-c1cc(C(=O)N2CC3(CN(C)C3)C2)n[nH]1,-17.43 | |||
CNC(=O)c1ccccc1NC(=O)[C@H]1C[C@H]2CCCCN2C1,-21.03 | |||
CC[C@H](F)CN[C@@H](CNC(=O)c1ccc(F)cc1F)C(C)C,4.73 | |||
C[C@@H]1CN(C(=O)C(=O)N[C@@H](c2cccc(F)c2)c2ccccn2)C[C@H]1N,13.34 | |||
CC(C)[C@H](NC(=O)NC[C@@H]1CCN(CCc2ccccc2)C1)C1CC1,5.9 | |||
CC[C@@H](F)CNCC1CCN(C(=O)c2ccc(F)s2)CC1,-14.68 | |||
Cc1cccc(C[C@@H](NCc2cccn2C)C2CC2)c1,-40.38 | |||
CC(C)NC(=O)c1ccc2nnc([C@H]3CN(Cc4ccccc4)CCN3C)n2c1,-23.15 | |||
</nowiki> | |||
IMHO, ML algorithm performs well with a normal distribution. | |||
If < 30% molecules cannot be docked, it's safe to ignore the non-dockable (those without a dock score). | |||
* Prepare the submission file, and submit to | |||
<nowiki> | |||
cat <<EOF > sbatch_ml_train.sh | |||
#!/bin/bash | |||
#SBATCH --job-name=ml_deepchem | |||
#SBATCH --partition=gimel5.gpu | |||
#SBATCH --gres=gpu:1 | |||
#SBATCH --ntasks=1 | |||
hostname | |||
nvidia-smi | |||
source /nfs/home/yingyang/programs/ligand_ml/anaconda/etc/profile.d/conda.sh | |||
conda activate ligand_ml | |||
# CHANGE here: to your prepared input file | |||
infile=AL-dock_5HT5a_train.csv | |||
i=1 | |||
ligand_ml train model_\${i} \${infile} | |||
ligand_ml package model_\${i} \${i} | |||
EOF | |||
sbatch sbatch_ml_train.sh | |||
</nowiki> | |||
Once the model training complete, you will see a folder 1/ and a file 1.tar.gz. | |||
Transfer the ML model in folder 1/ to Wynton | |||
scp -rp 1/ dt2.wynton.ucsf.edu:<path_to_where_to_run_prediction> | |||
== Apply the ML model to predict all molecules (smiles) of interest == | |||
Model prediction can leverage large number of CPUs thus will be on wynton | |||
=== Prepare molecules (smiles) for prediction === | |||
For example, H26.smi is the file including ZINC ids and smiles of molecules for prediction | |||
* set up the folder and break down the input smiles | |||
mkdir raw | |||
cd raw | |||
split -l 50000 ../H26.smi - | |||
cd ../ | |||
* run molecules standardization | |||
<nowiki> | |||
mkdir -p standardized | |||
set num=` ls raw/* | wc -l ` | |||
echo "Number of file to process:" $num | |||
cat << EOF > qsub_standardize.csh | |||
#\$ -S /bin/csh | |||
#\$ -cwd | |||
#\$ -pe smp 1 | |||
#\$ -l mem_free=2G | |||
#\$ -l scratch=5G | |||
#\$ -l h_rt=02:00:00 | |||
#\$ -j yes | |||
#\$ -o std.out | |||
#\$ -t 1-$num | |||
hostname | |||
date | |||
echo "" | |||
source /wynton/home/shoichetlab/yingyang/programs/ligand_ml/anaconda/etc/profile.d/conda.csh | |||
conda activate ligand_ml | |||
which python | |||
which ligand_ml | |||
echo "" | |||
set BASE_DIR=\`pwd\` | |||
# Do Not Edit Below This Point | |||
set RAW_DIR=\${BASE_DIR}/raw/ | |||
set DEST_DIR=\${BASE_DIR}/standardized/ | |||
set CUDA_VISIBLE_DEVICES=-1 | |||
python /wynton/home/shoichetlab/yingyang/scripts_ML/code/standardize.py \$SGE_TASK_ID \${RAW_DIR} \${DEST_DIR} | |||
EOF | |||
qsub qsub_standardize.csh | |||
</nowiki> | |||
Once complete, check if the number of files in the standardize folder is the same as in the raw folder | |||
=== Run ML prediction === | |||
Go to the folder where to run prediction (where ML model (1/) is located). | |||
mkdir prediction | |||
<nowiki> | |||
set in=./ | |||
set model=1 | |||
set out=prediction_1 | |||
mkdir -p ${out} | |||
set num=` ls standardized/*.csv | wc -l ` | |||
echo "Number of file to process:" $num | |||
cat << EOF >! qsub_ml_${hac}.sh | |||
#\$ -S /bin/sh | |||
#\$ -cwd | |||
#\$ -pe smp 1 | |||
#\$ -l mem_free=50G | |||
#\$ -l scratch=50G | |||
#\$ -l h_rt=01:00:00 | |||
#\$ -o qsub_ml_${hac}.out | |||
#\$ -j yes | |||
#\$ -t 1-$num | |||
hostname | |||
date | |||
echo "" | |||
source /wynton/home/shoichetlab/yingyang/programs/ligand_ml/anaconda/etc/profile.d/conda.sh | |||
conda activate ligand_ml | |||
which python | |||
which ligand_ml | |||
echo "" | |||
# Set your variables | |||
export TRAIN_DIR=\$(pwd)/${in} | |||
export MODEL_NAME=$model | |||
export MODEL=\${TRAIN_DIR}/\${MODEL_NAME} | |||
export BASE_DIR=\$(pwd)/ | |||
export DEST_DIR=\${BASE_DIR}/${out}/ | |||
# Do Not Edit Below This Point | |||
export CODE_DIR=/wynton/home/shoichetlab/yingyang/scripts_ML/code | |||
export STANDARDIZED_DIR=\${BASE_DIR}/standardized/ | |||
export INFILE=\${STANDARDIZED_DIR}/\${SGE_TASK_ID}.csv | |||
export OUTFILE=\${DEST_DIR}/\${SGE_TASK_ID}.csv | |||
# Do path magic to set things up and use 1 cpu | |||
#export LD_LIBRARY_PATH=/nfs/soft/schrodinger/2019-4/internal/lib/cuda-stubs/:\$LD_LIBRARY_PATH | |||
export LD_LIBRARY_PATH=/wynton/home/shoichetlab/yingyang/cuda-stubs/:\$LD_LIBRARY_PATH | |||
export CUDA_VISIBLE_DEVICES=-1 | |||
export CPU_STATS=\$(cat /dev/urandom | tr -cd 'a-f0-9' | head -c 32) | |||
export MY_CPU_FILE=\$(cat /dev/urandom | tr -cd 'a-f0-9' | head -c 32) | |||
sleep \$[ ( \$RANDOM % 10 ) ]s | |||
mpstat -P ALL 5 1 > /tmp/\$CPU_STATS | |||
python \${CODE_DIR}/get_idle_cpu.py /tmp/\$CPU_STATS /tmp/\$MY_CPU_FILE | |||
export MY_CPU=\$(cat /tmp/\$MY_CPU_FILE) | |||
echo "Using cpu \$MY_CPU" | |||
n=0 | |||
until [ \$n -ge 5 ] | |||
do | |||
echo "taskset -c \$MY_CPU ligand_ml evaluate \$MODEL \$INFILE \$OUTFILE --skip_standardization=True --skip_version_check=True" | |||
taskset -c \$MY_CPU ligand_ml evaluate \$MODEL \$INFILE \$OUTFILE --skip_standardization=True --skip_version_check=True && break | |||
n=\$[\$n+1] | |||
sleep 5 | |||
done | |||
EOF | |||
qsub qsub_ml.sh | |||
</nowiki> | |||
== Analyze prediction == | |||
Get the top 5% of ML prediction. A larger memory node is recommended for sorting... | |||
<nowiki> | |||
source /wynton/home/shoichetlab/yingyang/programs/miniconda3/etc/profile.d/conda.sh | |||
conda activate opencadd | |||
# 50,000 mols per file | |||
# 12,500 --> 25% | |||
# 25,000 --> 5% | |||
# 5,000 --> 1% | |||
# CHANGE here: to the prediction folder | |||
dir_ml=prediction_1 | |||
echo "Process ${dir_ml} ... " | |||
rm ml_5percent.csv | |||
touch ml_5percent.csv | |||
for f in $(ls ${dir_ml}/* ); do | |||
echo $f | |||
head -n 25000 ${f} | egrep -hiv 'score|model' >> ml_5percent.csv | |||
done | |||
python /wynton/home/shoichetlab/yingyang/scripts_ML/out_analysis/sort_qsar_prediction.py ml_5percent.csv | |||
rm ml_5percent.csv | |||
</nowiki> | |||
Once complete, the top 5% from ML prediction will be in ml_5percent_sort.csv | |||
The same procedure can be applied to other scores: dock scores, FEP predicted values... |
Latest revision as of 19:12, 12 March 2021
2/25/2021 Ying Yang
Train a ligand-based ML model
Model training requires GPU thus will be on gimel5
- Prepare the input file for training in the format of <ligand smiles>,<dock score>
SMILES,DOCK score C[C@H]1COCCCN1C(=O)[C@@H]1CN2CCN1CCC2,-15.98 Cc1ccccc1-c1cc(C(=O)N2CC3(CN(C)C3)C2)n[nH]1,-17.43 CNC(=O)c1ccccc1NC(=O)[C@H]1C[C@H]2CCCCN2C1,-21.03 CC[C@H](F)CN[C@@H](CNC(=O)c1ccc(F)cc1F)C(C)C,4.73 C[C@@H]1CN(C(=O)C(=O)N[C@@H](c2cccc(F)c2)c2ccccn2)C[C@H]1N,13.34 CC(C)[C@H](NC(=O)NC[C@@H]1CCN(CCc2ccccc2)C1)C1CC1,5.9 CC[C@@H](F)CNCC1CCN(C(=O)c2ccc(F)s2)CC1,-14.68 Cc1cccc(C[C@@H](NCc2cccn2C)C2CC2)c1,-40.38 CC(C)NC(=O)c1ccc2nnc([C@H]3CN(Cc4ccccc4)CCN3C)n2c1,-23.15
IMHO, ML algorithm performs well with a normal distribution.
If < 30% molecules cannot be docked, it's safe to ignore the non-dockable (those without a dock score).
- Prepare the submission file, and submit to
cat <<EOF > sbatch_ml_train.sh #!/bin/bash #SBATCH --job-name=ml_deepchem #SBATCH --partition=gimel5.gpu #SBATCH --gres=gpu:1 #SBATCH --ntasks=1 hostname nvidia-smi source /nfs/home/yingyang/programs/ligand_ml/anaconda/etc/profile.d/conda.sh conda activate ligand_ml # CHANGE here: to your prepared input file infile=AL-dock_5HT5a_train.csv i=1 ligand_ml train model_\${i} \${infile} ligand_ml package model_\${i} \${i} EOF sbatch sbatch_ml_train.sh
Once the model training complete, you will see a folder 1/ and a file 1.tar.gz.
Transfer the ML model in folder 1/ to Wynton
scp -rp 1/ dt2.wynton.ucsf.edu:<path_to_where_to_run_prediction>
Apply the ML model to predict all molecules (smiles) of interest
Model prediction can leverage large number of CPUs thus will be on wynton
Prepare molecules (smiles) for prediction
For example, H26.smi is the file including ZINC ids and smiles of molecules for prediction
- set up the folder and break down the input smiles
mkdir raw cd raw split -l 50000 ../H26.smi - cd ../
- run molecules standardization
mkdir -p standardized set num=` ls raw/* | wc -l ` echo "Number of file to process:" $num cat << EOF > qsub_standardize.csh #\$ -S /bin/csh #\$ -cwd #\$ -pe smp 1 #\$ -l mem_free=2G #\$ -l scratch=5G #\$ -l h_rt=02:00:00 #\$ -j yes #\$ -o std.out #\$ -t 1-$num hostname date echo "" source /wynton/home/shoichetlab/yingyang/programs/ligand_ml/anaconda/etc/profile.d/conda.csh conda activate ligand_ml which python which ligand_ml echo "" set BASE_DIR=\`pwd\` # Do Not Edit Below This Point set RAW_DIR=\${BASE_DIR}/raw/ set DEST_DIR=\${BASE_DIR}/standardized/ set CUDA_VISIBLE_DEVICES=-1 python /wynton/home/shoichetlab/yingyang/scripts_ML/code/standardize.py \$SGE_TASK_ID \${RAW_DIR} \${DEST_DIR} EOF qsub qsub_standardize.csh
Once complete, check if the number of files in the standardize folder is the same as in the raw folder
Run ML prediction
Go to the folder where to run prediction (where ML model (1/) is located).
mkdir prediction set in=./ set model=1 set out=prediction_1 mkdir -p ${out} set num=` ls standardized/*.csv | wc -l ` echo "Number of file to process:" $num cat << EOF >! qsub_ml_${hac}.sh #\$ -S /bin/sh #\$ -cwd #\$ -pe smp 1 #\$ -l mem_free=50G #\$ -l scratch=50G #\$ -l h_rt=01:00:00 #\$ -o qsub_ml_${hac}.out #\$ -j yes #\$ -t 1-$num hostname date echo "" source /wynton/home/shoichetlab/yingyang/programs/ligand_ml/anaconda/etc/profile.d/conda.sh conda activate ligand_ml which python which ligand_ml echo "" # Set your variables export TRAIN_DIR=\$(pwd)/${in} export MODEL_NAME=$model export MODEL=\${TRAIN_DIR}/\${MODEL_NAME} export BASE_DIR=\$(pwd)/ export DEST_DIR=\${BASE_DIR}/${out}/ # Do Not Edit Below This Point export CODE_DIR=/wynton/home/shoichetlab/yingyang/scripts_ML/code export STANDARDIZED_DIR=\${BASE_DIR}/standardized/ export INFILE=\${STANDARDIZED_DIR}/\${SGE_TASK_ID}.csv export OUTFILE=\${DEST_DIR}/\${SGE_TASK_ID}.csv # Do path magic to set things up and use 1 cpu #export LD_LIBRARY_PATH=/nfs/soft/schrodinger/2019-4/internal/lib/cuda-stubs/:\$LD_LIBRARY_PATH export LD_LIBRARY_PATH=/wynton/home/shoichetlab/yingyang/cuda-stubs/:\$LD_LIBRARY_PATH export CUDA_VISIBLE_DEVICES=-1 export CPU_STATS=\$(cat /dev/urandom | tr -cd 'a-f0-9' | head -c 32) export MY_CPU_FILE=\$(cat /dev/urandom | tr -cd 'a-f0-9' | head -c 32) sleep \$[ ( \$RANDOM % 10 ) ]s mpstat -P ALL 5 1 > /tmp/\$CPU_STATS python \${CODE_DIR}/get_idle_cpu.py /tmp/\$CPU_STATS /tmp/\$MY_CPU_FILE export MY_CPU=\$(cat /tmp/\$MY_CPU_FILE) echo "Using cpu \$MY_CPU" n=0 until [ \$n -ge 5 ] do echo "taskset -c \$MY_CPU ligand_ml evaluate \$MODEL \$INFILE \$OUTFILE --skip_standardization=True --skip_version_check=True" taskset -c \$MY_CPU ligand_ml evaluate \$MODEL \$INFILE \$OUTFILE --skip_standardization=True --skip_version_check=True && break n=\$[\$n+1] sleep 5 done EOF qsub qsub_ml.sh
Analyze prediction
Get the top 5% of ML prediction. A larger memory node is recommended for sorting...
source /wynton/home/shoichetlab/yingyang/programs/miniconda3/etc/profile.d/conda.sh conda activate opencadd # 50,000 mols per file # 12,500 --> 25% # 25,000 --> 5% # 5,000 --> 1% # CHANGE here: to the prediction folder dir_ml=prediction_1 echo "Process ${dir_ml} ... " rm ml_5percent.csv touch ml_5percent.csv for f in $(ls ${dir_ml}/* ); do echo $f head -n 25000 ${f} | egrep -hiv 'score|model' >> ml_5percent.csv done python /wynton/home/shoichetlab/yingyang/scripts_ML/out_analysis/sort_qsar_prediction.py ml_5percent.csv rm ml_5percent.csv
Once complete, the top 5% from ML prediction will be in ml_5percent_sort.csv
The same procedure can be applied to other scores: dock scores, FEP predicted values...