AlphaFold: Difference between revisions
(Marked this version for translation) |
m (Use Commands template rather then Commands2) |
||
| Line 34: | Line 34: | ||
<!--T:8--> | <!--T:8--> | ||
2. Create a Python virtual environment and activate it: | 2. Create a Python virtual environment and activate it: | ||
{{ | {{Commands | ||
|virtualenv --no-download ~/alphafold_env | |virtualenv --no-download ~/alphafold_env | ||
|source ~/alphafold_env/bin/activate | |source ~/alphafold_env/bin/activate | ||
| Line 41: | Line 41: | ||
<!--T:9--> | <!--T:9--> | ||
3. Install a specific version of AlphaFold and its python dependencies: | 3. Install a specific version of AlphaFold and its python dependencies: | ||
{{ | {{Commands | ||
|prompt=(alphafold_env) [name@server ~] | |prompt=(alphafold_env) [name@server ~] | ||
|pip install --no-index --upgrade pip | |pip install --no-index --upgrade pip | ||
| Line 64: | Line 64: | ||
<tab name="General"> | <tab name="General"> | ||
1. From a login node, create the data folder: | 1. From a login node, create the data folder: | ||
{{ | {{Commands | ||
|prompt=(alphafold_env) [name@server ~] | |prompt=(alphafold_env) [name@server ~] | ||
|export DOWNLOAD_DIR{{=}}$SCRATCH/alphafold/data | |export DOWNLOAD_DIR{{=}}$SCRATCH/alphafold/data | ||
| Line 257: | Line 257: | ||
<!--T:35--> | <!--T:35--> | ||
First read our [[Singularity]] documentation as there are particularities of each cluster that one must take into account. Then [[Singularity#Creating_images_on_Compute_Canada_clusters| build a Singularity container]]: | First read our [[Singularity]] documentation as there are particularities of each cluster that one must take into account. Then [[Singularity#Creating_images_on_Compute_Canada_clusters| build a Singularity container]]: | ||
{{ | {{Commands | ||
|cd $SCRATCH | |cd $SCRATCH | ||
|module load singularity | |module load singularity | ||
Revision as of 14:50, 28 June 2022
AlphaFold is a machine-learning model for the prediction of protein folding.
This page discusses how to use AlphaFold v2.0, the version that was entered in CASP14 and published in Nature.
Source code and documentation for AlphaFold can be found at their GitHub page. Any publication that discloses findings arising from using this source code or the model parameters should cite the AlphaFold paper.
Using Python wheel
Available wheels
You can list available wheels using the avail_wheels command:
[name@server ~]$ avail_wheels alphafold
name version python arch
--------- --------- -------- -------
alphafold 2.2.2 py3 generic
Installing AlphaFold in a Python virtual environment
1. Load AlphaFold dependencies:
[name@server ~]$ module load gcc/9.3.0 openmpi/4.0.3 cuda/11.4 cudnn/8.2.0 kalign/2.03 hmmer/3.2.1 openmm-alphafold/7.5.1 hh-suite/3.3.0 python/3.8
Only python 3.7 and 3.8 are currently supported.
2. Create a Python virtual environment and activate it:
[name@server ~]$ virtualenv --no-download ~/alphafold_env
[name@server ~]$ source ~/alphafold_env/bin/activate
3. Install a specific version of AlphaFold and its python dependencies:
(alphafold_env) [name@server ~] pip install --no-index --upgrade pip
(alphafold_env) [name@server ~] pip install --no-index alphafold==2.2.2
4. Validate it
(alphafold_env) [name@server ~] run_alphafold.py --help
Databases
Note that AlphaFold requires a set of datasets/databases to be downloaded into the $SCRATCH.
Important: The database must live in the $SCRATCH
1. From a login node, create the data folder:
(alphafold_env) [name@server ~] export DOWNLOAD_DIR=$SCRATCH/alphafold/data
(alphafold_env) [name@server ~] mkdir -p $DOWNLOAD_DIR
2. With your virtual environment activated, you can download the data:
(alphafold_env) [name@server ~] download_all_data.sh $DOWNLOAD_DIR
Note that this step cannot be done from compute nodes but rather from a login node. Since the download might take a while we suggest to start the download in a screen or Tmux session.
1. Set DOWNLOAD_DIR:
(alphafold_env) [name@server ~] export DOWNLOAD_DIR=/datashare/alphafold
Afterwards, the structure of your data should be similar to:
(alphafold_env) [name@server ~] tree -d $DOWNLOAD_DIR
$DOWNLOAD_DIR/ # Total: ~ 2.2 TB (download: 428 GB)
bfd/ # ~ 1.8 TB (download: 271.6 GB)
# 6 files.
mgnify/ # ~ 64 GB (download: 32.9 GB)
mgy_clusters.fa
params/ # ~ 3.5 GB (download: 3.5 GB)
# 5 CASP14 models,
# 5 pTM models,
# LICENSE,
# = 11 files.
pdb70/ # ~ 56 GB (download: 19.5 GB)
# 9 files.
pdb_mmcif/ # ~ 206 GB (download: 46 GB)
mmcif_files/
# About 180,000 .cif files.
obsolete.dat
uniclust30/ # ~ 87 GB (download: 24.9 GB)
uniclust30_2018_08/
# 13 files.
uniref90/ # ~ 59 GB (download: 29.7 GB)
uniref90.fasta
Running AlphaFold
AlphaFold has at most 8 cpus hardcoded since it does not benefit from using more than 8.
Edit to your needs the following submission script:
#!/bin/bash
#SBATCH --job-name=alphafold_run
#SBATCH --account=def-someprof # adjust this to match the accounting group you are using to submit jobs
#SBATCH --time=08:00:00 # adjust this to match the walltime of your job
#SBATCH --cpus-per-task=8 # a MAXIMUM of 8 core, Alpafold has no benefit to use more
#SBATCH --mem=20G # adjust this according to the memory you need
# Load modules dependencies
module load gcc/9.3.0 openmpi/4.0.3 cuda/11.4 cudnn/8.2.0 kalign/2.03 hmmer/3.2.1 openmm-alphafold/7.5.1 hh-suite/3.3.0 python/3.8
DOWNLOAD_DIR=$SCRATCH/alphafold/data # set the appropriate path to your downloaded data
INPUT_DIR=$SCRATCH/alphafold/input # set the appropriate path to your supporting data
OUTPUT_DIR=${SCRATCH}/alphafold/output # set the appropriate path to your supporting data
# Generate your virtual environment in $SLURM_TMPDIR
virtualenv --no-download ${SLURM_TMPDIR}/env
source ${SLURM_TMPDIR}/env/bin/activate
# Install alphafold and its dependencies
pip install --no-index --upgrade pip
pip install --no-index alphafold==2.2.2
# Edit with the proper arguments, run your commands
# run_alphafold.py --help
run_alphafold.py \
--data_dir=${DOWNLOAD_DIR} \
--fasta_paths=${INPUT_DIR}/YourSequence.fasta,${INPUT_DIR}/AnotherSequence.fasta \
--bfd_database_path=${DOWNLOAD_DIR}/bfd/bfd_metaclust_clu_complete_id30_c90_final_seq.sorted_opt \
--pdb70_database_path=${DOWNLOAD_DIR}/pdb70/pdb70 \
--template_mmcif_dir=${DOWNLOAD_DIR}/pdb_mmcif/mmcif_files \
--uniclust30_database_path=${DOWNLOAD_DIR}/uniclust30/uniclust30_2018_08/uniclust30_2018_08 \
--uniref90_database_path=${DOWNLOAD_DIR}/uniref90/uniref90.fasta \
--hhblits_binary_path=${EBROOTHHMINSUITE}/bin/hhblits \
--hhsearch_binary_path=${EBROOTHHMINSUITE}/bin/hhsearch \
--jackhmmer_binary_path=${EBROOTHMMER}/bin/jackhmmer \
--kalign_binary_path=${EBROOTKALIGN}/bin/kalign \
--mgnify_database_path=${DOWNLOAD_DIR}/mgnify/mgy_clusters_2018_12.fa \
--output_dir=${OUTPUT_DIR} \
--obsolete_pdbs_path=${DOWNLOAD_DIR}/pdb_mmcif/obsolete.dat \
--max_template_date=2020-05-14 \
--model_preset=monomer_casp14
#!/bin/bash
#SBATCH --job-name=alphafold_run
#SBATCH --account=def-someprof # adjust this to match the accounting group you are using to submit jobs
#SBATCH --time=08:00:00 # adjust this to match the walltime of your job
#SBATCH --gres=gpu:1 # a GPU helps to accelerate the inference part only
#SBATCH --cpus-per-task=8 # a MAXIMUM of 8 core, Alpafold has no benefit to use more
#SBATCH --mem=20G # adjust this according to the memory you need
# Load modules dependencies
module load gcc/9.3.0 openmpi/4.0.3 cuda/11.4 cudnn/8.2.0 kalign/2.03 hmmer/3.2.1 openmm-alphafold/7.5.1 hh-suite/3.3.0 python/3.8
DOWNLOAD_DIR=$SCRATCH/alphafold/data # set the appropriate path to your downloaded data
INPUT_DIR=$SCRATCH/alphafold/input # set the appropriate path to your supporting data
OUTPUT_DIR=${SCRATCH}/alphafold/output # set the appropriate path to your supporting data
# Generate your virtual environment in $SLURM_TMPDIR
virtualenv --no-download ${SLURM_TMPDIR}/env
source ${SLURM_TMPDIR}/env/bin/activate
# Install alphafold and its dependencies
pip install --no-index --upgrade pip
pip install --no-index alphafold==2.2.2
# Edit with the proper arguments, run your commands
# run_alphafold.py --help
run_alphafold.py \
--data_dir=${DOWNLOAD_DIR} \
--fasta_paths=${INPUT_DIR}/YourSequence.fasta,${INPUT_DIR}/AnotherSequence.fasta \
--bfd_database_path=${DOWNLOAD_DIR}/bfd/bfd_metaclust_clu_complete_id30_c90_final_seq.sorted_opt \
--pdb70_database_path=${DOWNLOAD_DIR}/pdb70/pdb70 \
--template_mmcif_dir=${DOWNLOAD_DIR}/pdb_mmcif/mmcif_files \
--uniclust30_database_path=${DOWNLOAD_DIR}/uniclust30/uniclust30_2018_08/uniclust30_2018_08 \
--uniref90_database_path=${DOWNLOAD_DIR}/uniref90/uniref90.fasta \
--hhblits_binary_path=${EBROOTHHMINSUITE}/bin/hhblits \
--hhsearch_binary_path=${EBROOTHHMINSUITE}/bin/hhsearch \
--jackhmmer_binary_path=${EBROOTHMMER}/bin/jackhmmer \
--kalign_binary_path=${EBROOTKALIGN}/bin/kalign \
--mgnify_database_path=${DOWNLOAD_DIR}/mgnify/mgy_clusters_2018_12.fa \
--output_dir=${OUTPUT_DIR} \
--obsolete_pdbs_path=${DOWNLOAD_DIR}/pdb_mmcif/obsolete.dat \
--max_template_date=2020-05-14 \
--model_preset=monomer_casp14 \
--use_gpu_relax=True
Then submit the job to the scheduler:
(alphafold_env) [name@server ~] sbatch --job-name alphafold-X alphafold-gpu.sh
Using Singularity
AlphaFold documentation explains how to run the software using Docker. We do not provide Docker, but instead provide Singularity. It is recommended to use a virtual environment and a Python wheel available from the Compute Canada "wheelhouse".
First read our Singularity documentation as there are particularities of each cluster that one must take into account. Then build a Singularity container:
[name@server ~]$ cd $SCRATCH
[name@server ~]$ module load singularity
[name@server ~]$ singularity build alphafold.sif docker://uvarc/alphafold:2.2.0
Running AlphaFold within Singularity
AlphaFold has at most 8 cpus hardcoded since it does not benefit from using more than 8.
Create a directory alphafold_output to hold the output files:
[name@server ~]$ mkdir $SCRATCH/alphafold_output
Then edit the job submission script:
#!/bin/bash
#SBATCH --job-name alphafold-run
#SBATCH --account=def-someprof # adjust this to match the accounting group you are using to submit jobs
#SBATCH --time=08:00:00 # adjust this to match the walltime of your job
#SBATCH --gres=gpu:1 # a GPU helps to accelerate the inference part only
#SBATCH --cpus-per-task=8 # a MAXIMUM of 8 core, Alpafold has no benefit to use more
#SBATCH --mem=20G # adjust this according to the memory you need
module load singularity
export PYTHONNOUSERSITE=True
ALPHAFOLD_DATA_PATH=/path/to/alphafold/databases
ALPHAFOLD_MODELS=/path/to/alphafold/databases/params
# Run the command
singularity run --nv \
-B $ALPHAFOLD_DATA_PATH:/data \
-B $ALPHAFOLD_MODELS \
-B .:/etc \
--pwd /app/alphafold alphaFold.sif \
--fasta_paths=/path/to/input.fasta \
--uniref90_database_path=/data/uniref90/uniref90.fasta \
--data_dir=/data \
--mgnify_database_path=/data/mgnify/mgy_clusters.fa \
--bfd_database_path=/data/bfd/bfd_metaclust_clu_complete_id30_c90_final_seq.sorted_opt \
--uniclust30_database_path=/data/uniclust30/uniclust30_2018_08/uniclust30_2018_08 \
--pdb70_database_path=/data/pdb70/pdb70 \
--template_mmcif_dir=/data/pdb_mmcif/mmcif_files \
--obsolete_pdbs_path=/data/pdb_mmcif/obsolete.dat \
--max_template_date=2020-05-14 \
--output_dir=alphafold_output \
--model_names='model_1' \
--preset=casp14 \
--use_gpu_relax=True
AlphaFold launches multithreaded analysis using up to 8 CPUs before running model inference on the GPU.
Memory requirements will vary with different size proteins.
Bind-mount the current working directory to /etc inside the container for the cache file ld.so.cache [-B .:/etc]. The --nv flag is used to enable the GPU support. Submit this job script ('alpharun_jobscript.sh') using the Slurm sbatch command.
[name@server ~]$ sbatch alpharun_jobscript.sh
On successful completion, the output directory should have the following files:
[name@server ~]$ tree alphafold_output/input
alphafold_output
└── input
├── features.pkl
├── msas
│ ├── bfd_uniclust_hits.a3m
│ ├── mgnify_hits.sto
│ └── uniref90_hits.sto
├── ranked_0.pdb
├── ranking_debug.json
├── relaxed_model_1.pdb
├── result_model_1.pkl
├── timings.json
└── unrelaxed_model_1.pdb
2 directories, 10 files