Metadata-Version: 2.1
Name: eQTac
Version: 1.0.16
Summary: The eQTac method.
Home-page: https://github.com/JFF1594032292/eQTac
Author: Jiang Feng
Author-email: 1594032292@qq.com
Classifier: Programming Language :: Python :: 3
Classifier: License :: OSI Approved :: BSD License
Requires-Python: >=3.8
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: numpy==1.22.4
Requires-Dist: pandas==1.4.3
Requires-Dist: pybedtools==0.8.2
Requires-Dist: pysam==0.16.0.1
Requires-Dist: rpy2==3.5.11
Requires-Dist: scipy==1.8.1

# eQTac
EQTac is a method to predict the potential regulatory elements (PREs) and their target genes, based on the eQTL datasets, the only additional data was ATAC-seq or ChIP-seq peak data. 
## Schematic 
![](./imgs/Schematic.png)
## Dependence
Conda is recommended:
```
conda create -n eqtac python=3.8 r-base=3.6 bioconda::r-gkmsvm=0.80
```
python >= 3.8
### Python packages
```
numpy == 1.22.4
pandas == 1.4.3
pybedtools == 0.8.2
pysam == 0.16.0.1
rpy2 == 3.5.11
scipy == 1.8.1
```
### Other software (need manual installation)
```
plink == v1.90b6.24 (not plink2, plink should in $PATH)
bedtools == v2.30.0 (bedtools should in $PATH)
R = 3.6
    r-gkmSVM == 0.8.0
```
## Installation & test example
```
# installation
pip install eQTac 

# test examples
git clone https://github.com/JFF1594032292/eQTac.git # just for test
cd eQTac/Utilities_pipeline
nohup sh example_All_pipeline.sh &
```
Then it will generate an `output_eQTac` folder, which contained results file `test.geno.vcf.gz.PRE_score.eQTac_result.FDR.txt`. (example takes 3~5min)

## Input data
1. Data used in model training:
    1. **Positive sets in bed format.** It's usually the peak data from ATAC-seq or ChIP-seq, we recomended to trim peaks to the core region (e.g. summits $\pm$ 100bp). See `test_data/test.positive.bed`.
    2. **Excluded sets in bed format.** It's usually the peak data from ATAC-seq or ChIP-seq, but with more relaxed thresholds (e.g. p=0.2). These region will be removed from generated negative regions, in order to remove potential positive sequences from negative sets. See `test_data/test`.exclude.bed.
    3. **Fasta file with .fai index.** Usually the human genome sequnce file in fasta format. See `test_data/test.hg19.chr17.fa`.
2. Data used in eQTac calculation.
    1. **PRE.bed**. The candidate regions used to assess chromatin accessibility scores across different individuals and then calculate correlation with target genes. See `test_data/test.pre.bed`.
    2. **Genotype data in plink format**. Individual genotype in eQTL datasets. See `test_data/test.geno.bed, test_data/test.geno.bim, test_data/test.geno.fam`.
    3. **Expression file**. The expresion values are normalized expression values (see GTEx) and already corrected for covariates. See `test_data/test.exp_residual`.
    4. **Snplist file.** SNP list file used in eQTac analysis. Note: only single nucleotide mutations. See `test_data/test.geno.snplist`.
## Usage pattern
We provided three level patterns: (1) pipeline level. (2) part level. (3) function level.
### Pipeline-level pattern
For the function level pattern, we provide a script: Part-All-eQTac_pipeline.py.
It can be used as `Utilities_pipeline/example_All_pipeline.sh`:
```
python Part-All-eQTac_pipeline.py \
	-p test_data/test.positive.bed \
	-ex test_data/test.exclude.bed \
	-pre test_data/test.pre.bed \
	--geno test_data/test.geno \
	--snp test_data/test.geno.snplist \
	-fa test_data/test.hg19.chr17.fa \
	-exp test_data/test.exp_residual \
	-n 100 \
	-o output_eQTac \
	-t 3 -l 10 -k 6 -c 10 -g 2 -e 0.01
```
### Part-level pattern
For the function level pattern, we provide four scripts:
```
Part-1-Train_model.py
Part-2-Generate_PRE_fa.py
Part-3-Predict_PRE_score.py
Part-4-Calculate_eQTac_correlation.py
```
It can be used as `Utilities_pipeline/example_Part_pipeline.sh`:
```
python Part-1-Train_model.py \
	-p test_data/test.positive.bed \
	-ex test_data/test.exclude.bed \
	-o output_eQTac_part \
	-t 3 -l 10 -k 6 -c 10 -g 2 -e 0.01

python Part-2-Generate_PRE_fa.py \
	-pre test_data/test.pre.bed \
	--geno test_data/test.geno \
	--snp test_data/test.geno.snplist \
	-fa test_data/test.hg19.chr17.fa \
	-o output_eQTac_part

python Part-3-Predict_PRE_score.py \
	-m output_eQTac_part/test.positive.pos.svmmodel.3_10_6_0.01.model.txt \
	-l output_eQTac_part/test.geno.snplist.bed--test.pre.bed.pre_snplist.ld_info \
	-mfa output_eQTac_part/test.geno.snplist.bed--test.pre.bed.pre_snplist.ld_info.snplist.bed.mutate.fa \
	-geno test_data/test.geno \
	-snp output_eQTac_part/test.geno.snplist.bed--test.pre.bed.pre_snplist \
	-T 1 \
	-o output_eQTac_part

python Part-4-Calculate_eQTac_correlation.py \
	-pre output_eQTac_part/test.geno.vcf.gz.PRE_score \
	-exp test_data/test.exp_residual \
	-n 50 \
	-o output_eQTac_part
```
### Function-level pattern
For the function level pattern, we provide a series of functions:
```
from eQTac.get_nullseq import get_nullseq
from eQTac.filter_bkg import filter_bkg
from eQTac.generate_snp_dict import generate_snp_dict
from eQTac.generate_PRE import generate_PRE
from eQTac.generate_mut_fa import generate_mut_fa
from eQTac.geno2score import geno2score
from eQTac.eQTac_correlation import eQTac_correlation
from eQTac.eQTac_permutation import eQTac_permutation
from eQTac.control_FDR import control_FDR
```
These functions can be used to construct the whole pipeline.
### Recomend
We recomend to use the **pipeline-level** pattern at first to make sure that all input formats are valid. 

Then use the **part-level** pattern to debug parameters. (e.g. training a best performance model). The first step is the most time-consuming step, we recomended to use the part-level pattern to save the SVM model `xxx.svmmodel.3_10_6_0.01.model.txt`.

If you are familiar with this pipeline, you can directly use the **function-level** pattern to construct your own pipeline.
## Notes
1. The test result is very volatile, because of the small size of test dataset (only ~6MB length of sequences). The results will be stable with tens of thousands or more peaks used as positive set.
