#!/usr/bin/env nextflow
// Path to an input file, or a pattern for multiple inputs
// Note - $baseDir is the location of this workflow file main.nf
// Define Input variables
params.reads = "$baseDir/../test_data/*.fastq.gz"
params.pairedEnd = false
params.designFile = "$baseDir/../test_data/design_ENCSR238SGC_SE.txt"
params.genome = 'GRCm38'
params.genomes = []
params.bwaIndex = params.genome ? params.genomes[ params.genome ].bwa ?: false : false
params.genomeSize = params.genome ? params.genomes[ params.genome ].genomesize ?: false : false
params.chromSizes = params.genome ? params.genomes[ params.genome ].chromsizes ?: false : false
params.fasta = params.genome ? params.genomes[ params.genome ].fasta ?: false : false
params.cutoffRatio = 1.2
params.outDir= "$baseDir/output"
params.extendReadsLen = 100
params.topPeakCount = 600
params.references = "$baseDir/../docs/references.md"
// Check inputs
if( params.bwaIndex ){
bwaIndex = Channel
.fromPath(params.bwaIndex)
.ifEmpty { exit 1, "BWA index not found: ${params.bwaIndex}" }
} else {
exit 1, "No reference genome specified."
}
// Define List of Files
readsList = Channel
.fromPath( params.reads )
.flatten()
.map { file -> [ file.getFileName().toString(), file.toString() ].join("\t")}
.collectFile( name: 'fileList.tsv', newLine: true )
// Define regular variables
pairedEnd = params.pairedEnd
designFile = params.designFile
genomeSize = params.genomeSize
genome = params.genome
chromSizes = params.chromSizes
fasta = params.fasta
cutoffRatio = params.cutoffRatio
outDir = params.outDir
extendReadsLen = params.extendReadsLen
topPeakCount = params.topPeakCount
references = params.references
// Check design file for errors
process checkDesignFile {
publishDir "$outDir/design", mode: 'copy'
input:
designFile
file readsList
output:
file("design.tsv") into designFilePaths
script:
if (pairedEnd) {
"""
python3 $baseDir/scripts/check_design.py -d $designFile -f $readsList -p
"""
}
else {
"""
python $baseDir/scripts/check_design.py -d $designFile -f $readsList
"""
}
}
// Define channel for raw reads
if (pairedEnd) {
rawReads = designFilePaths
.splitCsv(sep: '\t', header: true)
.map { row -> [ row.sample_id, [row.fastq_read1, row.fastq_read2], row.experiment_id, row.biosample, row.factor, row.treatment, row.replicate, row.control_id ] }
} else {
rawReads = designFilePaths
.splitCsv(sep: '\t', header: true)
.map { row -> [ row.sample_id, [row.fastq_read1], row.experiment_id, row.biosample, row.factor, row.treatment, row.replicate, row.control_id ] }
}
// Trim raw reads using trimgalore
process trimReads {
tag "$sampleId-$replicate"
publishDir "$outDir/${task.process}", mode: 'copy'
input:
set sampleId, reads, experimentId, biosample, factor, treatment, replicate, controlId from rawReads
output:
set sampleId, file('*.fq.gz'), experimentId, biosample, factor, treatment, replicate, controlId into trimmedReads
file('*trimming_report.txt') into trimgaloreResults
file('version_*.txt') into trimReadsVersions
script:
if (pairedEnd) {
"""
python3 $baseDir/scripts/trim_reads.py -f ${reads[0]} ${reads[1]} -s $sampleId -p
"""
}
else {
"""
python3 $baseDir/scripts/trim_reads.py -f ${reads[0]} -s $sampleId
"""
}
}
// Align trimmed reads using bwa
process alignReads {
tag "$sampleId-$replicate"
publishDir "$outDir/${task.process}", mode: 'copy'
input:
set sampleId, reads, experimentId, biosample, factor, treatment, replicate, controlId from trimmedReads
file index from bwaIndex.first()
output:
set sampleId, file('*.bam'), experimentId, biosample, factor, treatment, replicate, controlId into mappedReads
file('*.flagstat.qc') into mappedReadsStats
file('version_*.txt') into alignReadsVersions
script:
if (pairedEnd) {
"""
python3 $baseDir/scripts/map_reads.py -f ${reads[0]} ${reads[1]} -r ${index}/genome.fa -s $sampleId -p
"""
}
else {
"""
python3 $baseDir/scripts/map_reads.py -f $reads -r ${index}/genome.fa -s $sampleId
"""
}
}
// Dedup reads using sambamba
process filterReads {
tag "$sampleId-$replicate"
publishDir "$outDir/${task.process}", mode: 'copy'
input:
set sampleId, mapped, experimentId, biosample, factor, treatment, replicate, controlId from mappedReads
output:
set sampleId, file('*.bam'), file('*.bai'), experimentId, biosample, factor, treatment, replicate, controlId into dedupReads
set sampleId, file('*.bam'), experimentId, biosample, factor, treatment, replicate, controlId into convertReads
file('*.flagstat.qc') into dedupReadsStats
file('*.pbc.qc') into dedupReadsComplexity
file('*.dedup.qc') into dupReads
file('version_*.txt') into filterReadsVersions
script:
if (pairedEnd) {
"""
python3 $baseDir/scripts/map_qc.py -b $mapped -p
"""
}
else {
"""
python3 $baseDir/scripts/map_qc.py -b $mapped
"""
}
}
// Define channel collecting dedup reads into new design file
dedupReads
.map{ sampleId, bam, bai, experimentId, biosample, factor, treatment, replicate, controlId ->
"$sampleId\t$bam\t$bai\t$experimentId\t$biosample\t$factor\t$treatment\t$replicate\t$controlId\n"}
.collectFile(name:'design_dedup.tsv', seed:"sample_id\tbam_reads\tbam_index\texperiment_id\tbiosample\tfactor\ttreatment\treplicate\tcontrol_id\n", storeDir:"$outDir/design")
.into { dedupDesign; preDiffDesign }
// Quality Metrics using deeptools
process experimentQC {
publishDir "$outDir/${task.process}", mode: 'copy'
input:
file dedupDesign
output:
file('*.{pdf,npz}') into experimentQCStats
file('version_*.txt') into experimentQCVersions
script:
"""
python3 $baseDir/scripts/experiment_qc.py -d $dedupDesign -e $extendReadsLen
"""
}
// Convert reads to bam
process convertReads {
tag "$sampleId-$replicate"
publishDir "$outDir/${task.process}", mode: 'copy'
input:
set sampleId, deduped, experimentId, biosample, factor, treatment, replicate, controlId from convertReads
output:
set sampleId, file('*.tagAlign.gz'), file('*.bed{pe,se}.gz'), experimentId, biosample, factor, treatment, replicate, controlId into tagReads
file('version_*.txt') into convertReadsVersions
script:
if (pairedEnd) {
"""
python3 $baseDir/scripts/convert_reads.py -b $deduped -p
"""
}
else {
"""
python3 $baseDir/scripts/convert_reads.py -b $deduped
"""
}
}
// Calculate Cross-correlation using phantompeaktools
process crossReads {
tag "$sampleId-$replicate"
publishDir "$outDir/${task.process}", mode: 'copy'
input:
set sampleId, seTagAlign, tagAlign, experimentId, biosample, factor, treatment, replicate, controlId from tagReads
output:
set sampleId, seTagAlign, tagAlign, file('*.cc.qc'), experimentId, biosample, factor, treatment, replicate, controlId into xcorReads
set file('*.cc.qc'), file('*.cc.plot.pdf') into crossReadsStats
file('version_*.txt') into crossReadsVersions
script:
if (pairedEnd) {
"""
python3 $baseDir/scripts/xcor.py -t $seTagAlign -p
"""
}
else {
"""
python3 $baseDir/scripts/xcor.py -t $seTagAlign
"""
}
}
// Define channel collecting tagAlign and xcor into design file
xcorDesign = xcorReads
.map{ sampleId, seTagAlign, tagAlign, xcor, experimentId, biosample, factor, treatment, replicate, controlId ->
"$sampleId\t$seTagAlign\t$tagAlign\t$xcor\t$experimentId\t$biosample\t$factor\t$treatment\t$replicate\t$controlId\n"}
.collectFile(name:'design_xcor.tsv', seed:"sample_id\tse_tag_align\ttag_align\txcor\texperiment_id\tbiosample\tfactor\ttreatment\treplicate\tcontrol_id\n", storeDir:"$outDir/design")
// Make Experiment design files to be read in for downstream analysis
process defineExpDesignFiles {
publishDir "$outDir/design", mode: 'copy'
input:
file xcorDesign
output:
file('*.tsv') into experimentObjs mode flatten
script:
"""
python3 $baseDir/scripts/experiment_design.py -d $xcorDesign
"""
}
// Make Experiment design files to be read in for downstream analysis
process poolAndPsuedoReads {
tag "${experimentObjs.baseName}"
publishDir "$outDir/design", mode: 'copy'
input:
file experimentObjs
output:
file('*.tsv') into experimentPoolObjs
script:
if (pairedEnd) {
"""
python3 $baseDir/scripts/pool_and_psuedoreplicate.py -d $experimentObjs -c $cutoffRatio -p
"""
}
else {
"""
python3 $baseDir/scripts/pool_and_psuedoreplicate.py -d $experimentObjs -c $cutoffRatio
"""
}
}
// Collect list of experiment design files into a single channel
experimentRows = experimentPoolObjs
.splitCsv(sep:'\t', header:true)
.map { row -> [ row.sample_id, row.tag_align, row.xcor, row.experiment_id, row.biosample, row.factor, row.treatment, row.replicate, row.control_id, row.control_tag_align] }
// Call Peaks using MACS
process callPeaksMACS {
tag "$sampleId-$replicate"
publishDir "$outDir/${task.process}", mode: 'copy'
input:
set sampleId, tagAlign, xcor, experimentId, biosample, factor, treatment, replicate, controlId, controlTagAlign from experimentRows
output:
set sampleId, file('*.narrowPeak'), file('*.fc_signal.bw'), file('*.pvalue_signal.bw'), experimentId, biosample, factor, treatment, replicate, controlId into experimentPeaks
file('*.xls') into callPeaksMACSsummit
file('version_*.txt') into callPeaksMACSVersions
script:
if (pairedEnd) {
"""
python3 $baseDir/scripts/call_peaks_macs.py -t $tagAlign -x $xcor -c $controlTagAlign -s $sampleId -g $genomeSize -z $chromSizes -p
"""
}
else {
"""
python3 $baseDir/scripts/call_peaks_macs.py -t $tagAlign -x $xcor -c $controlTagAlign -s $sampleId -g $genomeSize -z $chromSizes
"""
}
}
// Define channel collecting peaks into design file
peaksDesign = experimentPeaks
.map{ sampleId, peak, fcSignal, pvalueSignal, experimentId, biosample, factor, treatment, replicate, controlId ->
"$sampleId\t$peak\t$fcSignal\t$pvalueSignal\t$experimentId\t$biosample\t$factor\t$treatment\t$replicate\t$controlId\n"}
.collectFile(name:'design_peak.tsv', seed:"sample_id\tpeaks\tfc_signal\tpvalue_signal\texperiment_id\tbiosample\tfactor\ttreatment\treplicate\tcontrol_id\n", storeDir:"$outDir/design")
// Calculate Consensus Peaks
process consensusPeaks {
publishDir "$outDir/${task.process}", mode: 'copy'
publishDir "$outDir/design", mode: 'copy', pattern: '*.{csv|tsv}'
input:
file peaksDesign
file preDiffDesign
output:
file('*.replicated.*') into consensusPeaks
file('*.rejected.*') into rejectedPeaks
file('design_diffPeaks.csv') into designDiffPeaks
file('design_annotatePeaks.tsv') into designAnnotatePeaks, designMotifSearch
file('unique_experiments.csv') into uniqueExperiments
file('version_*.txt') into consensusPeaksVersions
script:
"""
python3 $baseDir/scripts/overlap_peaks.py -d $peaksDesign -f $preDiffDesign
"""
}
// Annotate Peaks
process peakAnnotation {
publishDir "$outDir/${task.process}", mode: 'copy'
input:
file designAnnotatePeaks
output:
file("*chipseeker*") into peakAnnotation
file('version_*.txt') into peakAnnotationVersions
script:
"""
Rscript $baseDir/scripts/annotate_peaks.R $designAnnotatePeaks $genome
"""
}
// Motif Search Peaks
process motifSearch {
publishDir "$outDir/${task.process}", mode: 'copy'
input:
file designMotifSearch
output:
file("*memechip") into motifSearch
file("*narrowPeak") into filteredPeaks
file('version_*.txt') into motifSearchVersions
script:
"""
python3 $baseDir/scripts/motif_search.py -d $designMotifSearch -g $fasta -p $topPeakCount
"""
}
// Define channel to find number of unique experiments
uniqueExperimentsList = uniqueExperiments
.splitCsv(sep: '\t', header: true)
// Calculate Differential Binding Activity
process diffPeaks {
publishDir "$outDir/${task.process}", mode: 'copy'
input:
file designDiffPeaks
val noUniqueExperiments from uniqueExperimentsList.count()
output:
file('*_diffbind.bed') into diffPeaks
file('*_diffbind.csv') into diffPeaksCounts
file('*.pdf') into diffPeaksStats
file('normcount_peaksets.txt') into normCountPeaks
file('version_*.txt') into diffPeaksVersions
when:
noUniqueExperiments > 1
script:
"""
Rscript $baseDir/scripts/diff_peaks.R $designDiffPeaks
"""
}
// Collect Software Versions and references
process softwareReport {
input:
trimReadsVersions
alignReadsVersions
filterReadsVersions
convertReadsVersions
crossReadsVersions
callPeaksMACSVersions
consensusPeaksVersions
peakAnnotationVersions
motifSearchVersions
diffPeaksVersions
experimentQCVersions
references
output:
file('*_mqc.yaml') into softwareVersions
file('*_mqc.txt') into softwareReferences
script:
"""
python3 $baseDir/scripts/generate_versions.py -o software_versions
python3 $baseDir/scripts/generate_references.py -r $references -o software_references
"""
}