Skip to content
/ ERVmap Public
forked from mtokuyama/ERVmap

ERVmap is one part curated database of human proviral ERV loci and one part a stringent algorithm to determine which ERVs are transcribed in their RNA seq data.

License

Notifications You must be signed in to change notification settings

eipm/ERVmap

 
 

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

ERVmap

ERVmap is one part curated database of human proviral ERV loci and one part a stringent algorithm to determine which ERVs are transcribed in their RNA seq data.

Actions Status Github EIPM Docker Hub GitHub Container Registry

Citation

Tokuyama M. et. al., ERVmap analysis reveals genome-wide transcription of human endogenous retroviruses. Proc Natl Acad Sci USA 2018 Dec 11;115(50):12565-12572. doi: 10.1073/pnas.1814589115.

How to use it

Install

This version of the tool consists on 2 steps: 1. alignment to the human genome (GRC38) and 2. quantification of the ERV regions. To download and install ERVmap latest version provided as docker image, simply type:

docker pull eipm/ervmap:latest

NOTE: for a specific version replace latest with the release version.

How to run ERVmap

To run ERVmap, you'd need: 1. an indexed genome reference for STAR; 2. A bed file with the curated ERV regions on the human genome (see ERVmap.bed); 3. the input FASTQ data (gzipped). Assuming that your sample is called SAMPLE, and has 2 FASTQ files (one per read) in the folder /path/to/input/data; the reference genome is in /path/to/genome and the ERV bed file is in /path/to/erv/file here is the command:

docker run --rm  \
    -u $(id -u):$(id -g) \
    -v /path/to/input/data:/data:ro \
    -v /path/to/genome:/genome:ro \
    -v /path/to/erv/file:/resources:ro \
    -v /path/to/output:/results \
    ervmap \
    --read1 /data/SAMPLE_1.fastq.gz \
    --read2 /data/SAMPLE_2.fastq.gz \
    --output SAMPLE/SAMPLE. \
    --mode ALL

This command will generate the alignment files (BAMs) in the /path/to/output/SAMPLE/ folder and all files will have the prefix SAMPLE.. The generated files will be:

SAMPLE.Aligned.sortedByCoord.out.bam
SAMPLE.Aligned.sortedByCoord.out.bam.bai
SAMPLE.ERVresults.txt
SAMPLE.Log.final.out
SAMPLE.Log.out
SAMPLE.Log.progress.out
SAMPLE.SJ.out.tab

(See STAR documentation for the description of the output files of the STAR aligner ). The results of ERV quantification will be in the SAMPLE.ERVresults.txt file. This is a tab-delimited file with 7 columns from bedtools. For example:

1       896176  898458  5803    500     +       70
1       1412251 1418852 5804    500     +       36
1       3801730 3806808 5807    500     +       6
1       4178468 4187573 5808    500     +       1

The --mode option

This option can only have 3 values: { ALL, STAR, BED }:

  • ALL to run both the STAR aligner and the ERV quantification from start to finish;
  • STAR to only perform the alignment;
  • BED to only run the ERV quantification.

Optional parameters (recommended)

There are a few parameters that can be added to the ERVmap image to make the process more efficient.

  • --cpus 20: if you have a multi-core system (and you should have one), you can specify the number of CPUs to use (e.g. 20);
  • --limit-ram 48000000000: this limits the amount of RAM used to avoid overusing the resources You can see the full set of parameters by typing: docker run --rm ervmap.

There are also other parameters from Docker that should be included before ervmap in the command line, e.g.

    --memory 50G \
    --memory-swap 100G

Nextflow version

To run this pipeline using Nextflow, simply run the following: nextflow -C nextflow.config run main.nf where nextflow.config include the minimum set of parameters to run ERVmap within the docker container. Specifically:

params {
    genome='/path/to/genome'               # external path to the indexed genome for the STAR aligner
    inputDir='path/to/input/folder'        # external path of the input data
    inputPattern="*{1,2}.fastq.gz"         # pattern to search for input FASTQ files, or BAM files (*.{bam,bam.bai})
    skipAlignment=false                    # if skipAlignment is true, the process ERValign is skipped, and the input dir and pattern should point to the BAM files
    outputDir='/path/to/output/folder'     # external path of the output results
    starTmpDir='/path/to/STAR/temp/folder' # external path of the STAR aligner temporary folder. REQUIRED
    localOutDir='.'                        # internal path of the results
    cpus=20                                # Number of cpus/threads to use for the alignment 
    limitMemory=1850861158                 # memory limit for STAR
    debug='off'                            # either [on|off] 
}

NOTE: Adjust the memory settings of the docker container if needed, but recall that STAR requires about 32G of RAM (see Optional Parameters).

NOTE: The BAM files are rsync'ed into the outputDir folder. Make sure to have sufficient disk space. By cleaning up the work folder, e.g. by running nextflow clean, the bam files will be removed. The ERVmap results are copied into outputDir and thus are permanent.


Published version

Please note that the instructions hereafter refer to the orignal published version (see ERVmap on GitHub)

Installing

Install dependencies

bedtools2
cufflinks
bwa-0.7.17
cufflinks-2.2.1.Linux_x86_64
python
samtools-1.8
tophat-2.1.1.Linux_x86_64
tophat2
trim (http://graphics.med.yale.edu/trim/)

Install .pl and r files

erv_genome.pl
interleaved.pl
run_clean_htseq.pl
clean_htseq.pl
merge_count.pl
normalize_with_file.pl
normalize_deseq.r

Map data to human genome (hg38)

This step will yield raw counts for cellular genes and ERVmap loci as separate files.

For single-end sequences

erv_genome.pl -stage 1 -stage2 6 -fastq /${i}_SS.fastq.gz

For pair-end sequences

interleaved.pl --read1  ${i}_R1.fastq.gz  --read2 ${i}_R2.fastq.gz > ${i}.fastq.gz
erv_genome.pl -stage 1 -stage2 6 -fastq /${i}.fastq.gz

Store output files

mkdir -p output
mv ./sample/herv_coverage_GRCh38_genome.txt ./output/erv/${i}.e
mv ./sample/GRCh38/htseq.cnt ./output/cellular/${i}.c

Clean up data, merge, and normalize

These steps will yield normalized ERV read counts based on size factors obtained through DESeq2 analysis. Use the output files from above.

run_clean_htseq.pl ./output/cellular c c2 __
merge_count.pl 3 6 e ./output/erv > ./output/erv/merged_erv.txt
merge_count.pl 0 1 c2 ./output/cellular > ./output/cellular/merged_cellular.txt
normalize_deseq.r  ./output/cellular/merged_cellular.txt ./output/cellular/normalized_cellular ./output/cellular/normalized_factors
normalize_with_file.pl ./output/cellular/normalized_factors ./output/erv/merged_erv.txt > ./output/$folder_name.txt

Authors

  • Maria Tokuyama
  • Yong Kong

About

ERVmap is one part curated database of human proviral ERV loci and one part a stringent algorithm to determine which ERVs are transcribed in their RNA seq data.

Topics

Resources

License

Code of conduct

Security policy

Stars

Watchers

Forks

Packages

 
 
 

Languages

  • Perl 48.2%
  • Shell 25.4%
  • Nextflow 14.5%
  • Dockerfile 9.3%
  • R 2.6%