Skip to content

saorisakaue/GREP

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

81 Commits
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

GREP: Genome for REPositioning drugs v1.0.0

GREP can quantify an enrichment of the user-defined set of genes in the target of clinical indication categories and capture potentially repositionable drugs targeting the gene set. Both can be run in a few seconds!

Overview

The user input is a gene list from any source of genomic studies. GREP tells you (i) what kind of disease categories are pharmaco-genetically associated with the gene set and (ii) what kind of medications can have a potential for being repositioned to another indication.

Publication/Citation

Our paper is out!!!

Sakaue S and Okada Y. GREP: Genome for REPositioning drugs. Bioinformatics. 2019

Please cite this paper if you use GREP or any material in this repository.

Requirements

GREP is a command line python software, and the following libraries are required.

  • scipy
  • argparse
  • numpy
  • pandas

This software is compatible with both versions of python: 2 and 3.

Installation

In order to get started with GREP, you can clone this repo by the following commands,

$ git clone https://github.com/saorisakaue/GREP
$ cd ./GREP

Or, you can also use pip to install

currently under development

Usage

An example basic command is as follows;

$ python grep.py --genelist ./example/megastroke.genes --out my_GREP_test  --test ATC --output-drug-name

Prepare your input

Make a text file with one column, which contains genes by HGNC gene symbol. Please have a look at ./example/ directory for example gene sets.

  • ./example/megastroke.genes can be used as genes identified by MEGASTROKE consortium (Nat Genet 2018).
  • ./example/RA_trans.genes can be used as genes identified in RA meta-analysis by Okada et al (Nature 2014).

FYI: How can I define a gene set from GWAS sumstats?

If your would like to perform post-GWAS analysis, and if you would like to convert SNP-level statisitcs to gene-level ones, here are some of the options.

To make a gene set, define P value threshold of your choice, and make a text file with a set of genes which pass that threshold using the output from the above softwares.

Options

Option name Descriptions Required Default
--genelist, -g Input your list of genes as a text file with one column. Yes None
--out, -o An output prefix. Yes None
--test, -t Choose from ATC or ICD for a drug indication categorization system. Yes None
--output-drug-name, -d If you want to know the drug names targeting your genes, set this flag (without any arguments after that). No False
--background, -b A list of all genes in the scope of your analysis if available. This will be used as background genes. No All the genes targeted by the drugs in the database

What is ATC and ICD test ?

  • ATC; The Anatomical Therapeutic Chemical (ATC) Classification System is used for the classification of active ingredients of drugs according to the organ or system on which they act and their therapeutic, pharmacological and chemical properties. Large annotation has 14 anatomical categories, which are further categorized into ~90 detailed classes in total. Drug-category information was retrieved from KEGG DRUG website.
  • ICD; The 10th revision of the International Statistical Classification of Diseases and Related Health Problems categorizes diseases into 26 large groups, which are further subdivided into ~ 200 classes. Drug-indicated disease category information was retrieved from TTD website.

Output files

The above command generates two text files for ATC analysis (tests for large categories and detailed categories), and one file for ICD analysis with the first line being a header. Below is an example output from ATC analysis for large categories.

$ head my_GREP_test.ATC.large.txt
#Group	GroupName	OddsRatio	FisherExactP	TargetGene:DrugNames
A	ALIMENTARY TRACT AND METABOLISM	0.8160667251975418	0.7076001488153763	ACACB:metformin;TRPV4:citric acid
B	BLOOD AND BLOOD FORMING ORGANS	5.287042099507928	0.004721436181224572	F11:conestat alfa;FGA:alteplase,anistreplase,reteplase,tenecteplase;KLKB1:ecallantide,conestat alfa;PDE3A:cilostazol;PLG:streptokinase,alteplase,anistreplase,urokinase,reteplase,tenecteplase,melagatran,aminocaproic acid,tranexamic acid
C	CARDIOVASCULAR SYSTEM	1.4418238993710693	0.327034895762871	ATP2A2:gallopamil;EDNRA:bosentan,ambrisentan,sitaxentan,macitentan;PDE3A:amrinone,milrinone,enoximone,trapidil;PLG:ranolazine
Column Column Name Descriptions
1 Group An alphabetical code for each category.
2 GroupName A description of the anatomical category.
3 OddsRatio The enrichment odds ratio quantifying the degree of the overlap between genes included in the input and genes targeted by the drugs included in the category tested.
4 FisherExactP The enrichment P value by Fisher's exact test (one-sided).
5 TargetGene:DrugNames The overpapped genes and the drugs targeting those genes (if any).

Licence

This software is freely available for academic users. Usage for commercial purposes is not allowed. Please refer to the LICENCE page.

Creative Commons License

Acknowledgement

We thank Masa Kanai for helping us refactor the software implementation.

Contact

Any questions? Saori Sakaue (ssakaue[at]sg.med.osaka-u.ac.jp)

About

GREP: Genome for REPositioning drugs

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages