scDrug+ is the updated version of scDrug: From scRNA-seq to Drug Repositioning with a new drug-response prediction function on molecules based on their molecular structure and the gene expression profile of the cell line/ patient in the second part Drug Response Prediction of the workflow.
The scDrug+ constructed a workflow for comprehensive analysis on single-cell RNA sequencing (scRNA-seq) data. It provided a powerful tool with various functions, from fundamental data analysis to drug response prediction, and treatment suggestions.
The scDrug+ went through three parts on raw scRNA-seq data investigation: Single-Cell Data Analysis, Drug Response Prediction, and Treatment Selection.
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Single-Cell Data Analysis performed data preprocessing, clustering, cell type annotation, Gene Set Enrichment Analysis (GSEA), and survival analysis.
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Drug Response Prediction estimated the half maximal inhibitory concentration (IC50) of cell clusters, and reported the cell death percentages as drug kill efficacy.
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Treatment Selection listed treatment combinations of given cell clusters.
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Clone the repository to local directory, e.g.,
./scDrug.git clone https://github.com/ailabstw/scDrugplus.git ./scDrug -
Build the Docker image tagged
sc-drug.docker build -t sc-drug ./scDrug -
Run the Docker container named
scDrugwith/docker/pathmounted to/server/pathto access files within the Docker container.docker run -it --name scDrug -v /server/path:/docker/path --privileged sc-drug -
In the Docker container
scDrug, pull the Docker imagecibersortx/fractionsused in treatment selection./etc/init.d/docker start docker pull cibersortx/fractionsNote 1: Get
CONTAINER_IDwith commanddocker ps -aand start the container withdocker start -i CONTAINER_ID. Note 2: If docker-in-docker cannot be operated on the user's computer, the user can pull and run the CIBERSORTx container outside the scDrug container as long as a shared folder is mounted on both containers for file sharing.
Note: Refer to example for a detail illustration of the usage for the scDrug.
Single-Cell Data Analysis took the scRNA-seq data in a 10x-Genomics-formatted mtx directory or a CSV file as input, performed fundamental data analysis, and output a Scanpy Anndata object scanpyobj.h5ad, a UMAP umap_cluster.png and differentially expressed genes (DEGs) cluster_DEGs.csv of the clustering result, and a gene expression profile (GEP) file GEP.txt.
Optionally, Single-Cell Data Analysis carried out batch correction, cell type annotation and Gene Set Enrichment Analysis (GSEA), and provided additional UMAPs showing batch effects and cell types (umap_batch.png and umap_cell_type.png), and the GSEA result GSEA_results.csv. For cell type annotation, we used scMatch: a single-cell gene expression profile annotation tool using reference datasets.
Furthermore, Single-Cell Data Analysis could take previously produced Anndata as input and applied sub-clustering on specified clusters.
- Run
python3 single_cell_analysis.py -hto show the help messages as follow for Single-Cell Data Analysis.
usage: single_cell_analysis.py [-h] -i INPUT [-f FORMAT] [-o OUTPUT] [-r RESOLUTION] [--impute] [--auto-resolution] [-m METADATA]
[-b BATCH] [-c CLUSTERS] [--cname CNAME] [--GEP] [--annotation] [--gsea] [--cpus CPUS] [--survival]
[--tcga TCGA] [--id ID] [--prefix PREFIX] [--not_treated]
scRNA-seq data analysis
optional arguments:
-h, --help show this help message and exit
-i INPUT, --input INPUT
path to input 10x directory or CSV file
-f FORMAT, --format FORMAT
input format, 10x (default) | csv | h5ad (Anndata object for subclustering with --clusters CLUSTERS)
-o OUTPUT, --output OUTPUT
path to output directory, default='./'
-r RESOLUTION, --resolution RESOLUTION
resolution for clustering, default=0.6
--impute do imputation. default: no
--auto-resolution automatically determine resolution for clustering
-m METADATA, --metadata METADATA
path to metadata CSV file for batch correction (index as input in first column)
-b BATCH, --batch BATCH
column in metadata (or adata.obs) for batch correction, e.g. 'PatientID'
-c CLUSTERS, --clusters CLUSTERS
perform single cell analysis only on specified clusters, e.g. '1,3,8,9'
--cname CNAME which variable should be used when selecting clusters; required when clusters are provided. Default:
'louvain'
--GEP generate Gene Expression Profile file.
--annotation perform cell type annotation
--gsea perform gene set enrichment analysis (GSEA)
--cpus CPUS number of CPU used for auto-resolution and annotation, default=1
--survival perform survival analysis
--tcga TCGA path to TCGA data
--id ID Specify TCGA project id in the format "TCGA-xxxx", e.g., "TCGA-LIHC"
--prefix PREFIX Any prefix before matrix.mtx, genes.tsv and barcodes.tsv.
--not_treated only consider untreated samples from TCGA for survival analysis.
- Apply Single-Cell Data Analysis with batch correction, clustering resolution 1.0, cell type annotation and GSEA.
python3 single_cell_analysis.py --input INPUT --metadata METADATA --batch BATCH --resolution 1.0 --annotation --gsea
- Single-Cell Data Analysis for sub-clustering on specified clusters at automatically determined resolution run under 4 cpus.
python3 single_cell_analysis.py -f h5ad --input scanpyobj.h5ad --clusters CLUSTERS --auto-resolution --cpus 4
Drug Response Prediction examined scanpyobj.h5ad generated in Single-Cell Data Analysis, reported clusterwise IC50 and cell death percentages to drugs in the GDSC database via CaDRReS-Sc (a recommender system framework for in silico drug response prediction), or drug sensitivity AUC in the PRISM database from [DepMap Portal PRISM-19Q4] (https://doi.org/10.1038/s43018-019-0018-6). The output the prediction results are IC50_prediction.csv and drug_kill_prediction.csv while using parameter --model GDSC, and AUC_prediction.csv whlie using parameter --model PRISM.
- Run
python3 drug_response_prediction.py -hto show the help messages as follow for Drug Response Prediction.
usage: drug_response_prediction.py [-h] -i INPUT [-o OUTPUT] [-c CLUSTERS] [-m MODEL] [--n_drugs N_DRUGS]
Drug response prediction
optional arguments:
-h, --help show this help message and exit
-i INPUT, --input INPUT
path to input Anndata object (h5ad file)
-o OUTPUT, --output OUTPUT
path to output directory, default='./'
-c CLUSTERS, --clusters CLUSTERS
perform sensitivity prediction on specified clusters, e.g. '1,3,8,9', default='All'
-m MODEL, --model MODEL
the sensitivity screening is from GDSC ic50/PRISM auc, e.g. GDSC, PRISM
--n_drugs N_DRUGS the number of drugs to visualize for each cluster
- Predict drug response on specified clusters (here for default all clusters) with Drug Response Prediction.
python3 drug_response_prediction.py --input scanpyobj.h5ad
Drug Response Prediction on new drugs predicts the drug response of the input molecules which using parameter --smiles /path/to/molecules_smiles.csv with the drug response prediction result on known drugs IC50_prediction.csv (with parameter --model GDSC) or AUC_prediction.csv (with parameter --model PRISM) generated in Drug Response Prediction.
- The input format for unknown molecules is as follows:
| mol_name | smiles |
|---|---|
| mol_1 | O=NN(CCCl)C(=O)NCCCl |
| mol_2 | Nc1ccn(C2OC(CO)C(O)C2O)c(=O)n1 |
- Run
python3 new_drug_prediction.py -hto show the help messages as follow for Drug Response Prediction on new drugs.
usage: new_drug_prediction.py [-h] -i INPUT -smiles INPUT_SMILES [-m MODEL] [-o OUTPUT]
Drug response prediction
optional arguments:
-h, --help show this help message and exit
-i INPUT, --input INPUT
path to input drug response prediction (csv file)
-smiles INPUT_SMILES, --smiles INPUT
path to input the smiles string of unknown molecules (csv file)
-o OUTPUT, --output OUTPUT
path to the output directory, default='./'
-m MODEL, --model MODEL
the sensitivity screening in the previous analysis is from GDSC ic50/PRISM AUC, e.g. GDSC, PRISM, default='PRISM'
- Predict drug response on new drugs and specified clusters (here for default all clusters) with Drug Response Prediction on new drugs.
python3 new_drug_prediction.py --input /path/to/AUC_prediction --smiles molecules_smiles.csv
In Treatment Selection, we first imputed cell fractions of bulk GEPs from the LINCS L1000 database with single-cell GEP GEP.txt created in Single-Cell Data Analysis via Docker version of CIBERSORTx Cell Fractions, which enumerated the proportions of distinct cell subpopulations in tissue expression profiles. Then, we selected treatment combinations from the LINCS L1000 database with the CIBERSORTx result, and generated plots and a dataframe to show the drug effect.
Impute Cell Fractions took the reference sample file GEP.txt as input to run CIBERSORTx Cell Fractions with bulk GEP of user specified or automatically determined cell type, and output CIBERSORTx result files to the output directory, including CIBERSORTx_Adjusted.txt. The cell type for bulk GEP involved A375 (malignant melanoma), A549 (non-small cell lung carcinoma), HCC515 (non-small cell lung adenocarcinoma), HEPG2 (hepatocellular carcinoma), HT29 (colorectal adenocarcinoma), MCF7 (breast adenocarcinoma), PC3 (prostate adenocarcinoma), YAPC (Pancreatic carcinoma).
- Run
python3 CIBERSORTx_fractions.py -hto show the help messages as follow for Impute Cell Fractions.
usage: CIBERSORTx_fractions.py [-h] -i INPUT [-o OUTPUT] [-l LINCS] [-c CLUSTERS] -u USERNAME -t TOKEN
[--celltype CELLTYPE] [--develop]
impute the fractions of previous identified cell subsets under each bulk sample in the LINCS L1000 database.
optional arguments:
-h, --help show this help message and exit
-i INPUT, --input INPUT
path to input single-cell GEP file
-o OUTPUT, --output OUTPUT
path to output directory, default='./'
-l LINCS, --lincs LINCS
path to LINCS data directory
-c CLUSTERS, --clusters CLUSTERS
perform combined treatment prediction on specified clusters, e.g. '1,3,8,9'
-u USERNAME, --username USERNAME
email address registered on CIBERSORTx website
-t TOKEN, --token TOKEN
token obtained from CIBERSORTx website
--celltype CELLTYPE choose a cell line from the options. If no name is provided, we will automatically
determine the cell type. Options: A375 (malignant melanoma), A549 (non-small cell lung
carcinoma), HCC515 (non-small cell lung adenocarcinoma), HEPG2 (hepatocellular carcinoma),
HT29 (colorectal adenocarcinoma), MCF7 (breast adenocarcinoma), PC3 (prostate
adenocarcinoma), YAPC (Pancreatic carcinoma)
--develop Only for development version.
- Impute Cell Fractions via CIBERSORTx Cell Fractions with single-cell GEP
GEP.txtand LINCS L1000 bulk GEP of automatically determined cell type.
python3 CIBERSORTx_fractions.py --input GEP.txt --username USERNAME --token TOKEN
Note: To obtain USERNAME and TOKEN, register and request for access to CIBERSORTx Docker on CIBERSORTx website.
Select Treatment Combinations takes the CIBERSORTx result CIBERSORTx_Results.txt and the L1000 instance info file as input, selects treatment combinations for the given cell type from the LINCS L1000 database, and output the report of the identified treatment combinations (treatment_combinations.pdf).
- Run
python3 treatment_selection.py -hto show the help messages as follow for Select Treatment Combinations.
usage: treatment_selection.py [-h] -i INPUT [-o OUTDIR] [-t THRESHOLD] [-c CON_THRESHOLD] --celltype CELLTYPE
[--metadata METADATA]
Select treatment combination from the LINCS L1000 database.
optional arguments:
-h, --help show this help message and exit
-i INPUT, --input INPUT
CIBERSORTx output file.
-o OUTDIR, --outdir OUTDIR
path to output directory, default='./'
-t THRESHOLD, --threshold THRESHOLD
Sensitivity threshold. Range: [-1,0), default:-0.9
-c CON_THRESHOLD, --con_threshold CON_THRESHOLD
Consistency threshold. Range: [-1,0), default:-0.75
--celltype CELLTYPE Same as the cell type for decomposition. Options: A375 | A549 | HEPG2 | HT29 | MCF7 | PC3 | YAPC
--metadata METADATA the L1000 instance info file, e.g., 'GSE70138_Broad_LINCS_inst_info_2017-03-06.txt'
- Select Treatment Combinations with the L1000 metadata.
python3 treatment_selection.py --input CIBERSORTx_Adjusted.txt --celltype CELLTYPE --metadata METADATA