--- name: bio-workflows-chipseq-pipeline description: End-to-end ChIP-seq workflow from FASTQ files to annotated peaks. Covers QC, alignment, peak calling with MACS3, and peak annotation with ChIPseeker. Use when processing ChIP-seq data from alignment through peak annotation. tool_type: mixed primary_tool: MACS3 workflow: true depends_on: - read-qc/fastp-workflow - read-alignment/bowtie2-alignment - alignment-files/duplicate-handling - chip-seq/peak-calling - chip-seq/peak-annotation - chip-seq/chipseq-qc qc_checkpoints: - after_qc: "Q30 >85%, adapter content <5%" - after_alignment: "Mapping rate >80%, unique mapping >70%" - after_peaks: "FRiP >1% (ideally >5%), peak count reasonable" measurable_outcome: Execute skill workflow successfully with valid output within 15 minutes. allowed-tools: - read_file - run_shell_command --- # ChIP-seq Pipeline Complete workflow from raw ChIP-seq FASTQ files to annotated peaks. ## Workflow Overview ``` FASTQ files (IP + Input) | v [1. QC & Trimming] -----> fastp | v [2. Alignment] ---------> Bowtie2 | v [3. BAM Processing] ----> sort, markdup, filter | v [4. Peak Calling] ------> MACS3 | v [5. QC] ----------------> FRiP, fingerprint plots | v [6. Annotation] --------> ChIPseeker | v Annotated peaks + QC report ``` ## Primary Path: Bowtie2 + MACS3 + ChIPseeker ### Step 1: Quality Control with fastp ```bash # Process both IP and Input samples for sample in IP_rep1 IP_rep2 Input_rep1 Input_rep2; do fastp -i ${sample}_R1.fastq.gz -I ${sample}_R2.fastq.gz \ -o trimmed/${sample}_R1.fq.gz -O trimmed/${sample}_R2.fq.gz \ --detect_adapter_for_pe \ --qualified_quality_phred 20 \ --length_required 25 \ --html qc/${sample}_fastp.html done ``` ### Step 2: Alignment with Bowtie2 ```bash # Build index (once) bowtie2-build genome.fa bt2_index/genome # Align for sample in IP_rep1 IP_rep2 Input_rep1 Input_rep2; do bowtie2 -p 8 -x bt2_index/genome \ -1 trimmed/${sample}_R1.fq.gz \ -2 trimmed/${sample}_R2.fq.gz \ --no-mixed --no-discordant \ --maxins 1000 \ 2> aligned/${sample}.log | \ samtools view -@ 4 -bS -q 30 - | \ samtools sort -@ 4 -o aligned/${sample}.bam done ``` **QC Checkpoint:** Check alignment rate - Overall alignment >80% - Unique mapping >70% ### Step 3: BAM Processing ```bash for sample in IP_rep1 IP_rep2 Input_rep1 Input_rep2; do # Mark and remove duplicates samtools fixmate -m aligned/${sample}.bam - | \ samtools sort - | \ samtools markdup -r - aligned/${sample}.dedup.bam # Index samtools index aligned/${sample}.dedup.bam # Remove chrM reads (high mitochondrial is common) samtools view -h aligned/${sample}.dedup.bam | \ grep -v chrM | \ samtools view -b - > aligned/${sample}.final.bam samtools index aligned/${sample}.final.bam done ``` ### Step 4: Peak Calling with MACS3 ```bash # Narrow peaks (TFs, sharp histone marks like H3K4me3) macs3 callpeak \ -t aligned/IP_rep1.final.bam aligned/IP_rep2.final.bam \ -c aligned/Input_rep1.final.bam aligned/Input_rep2.final.bam \ -f BAMPE \ -g hs \ -n experiment \ --outdir peaks \ -q 0.01 # Broad peaks (H3K27me3, H3K36me3) macs3 callpeak \ -t aligned/IP_rep1.final.bam aligned/IP_rep2.final.bam \ -c aligned/Input_rep1.final.bam aligned/Input_rep2.final.bam \ -f BAMPE \ -g hs \ -n experiment_broad \ --outdir peaks \ --broad \ --broad-cutoff 0.1 ``` ### Step 5: QC Metrics ```bash # Calculate FRiP (Fraction of Reads in Peaks) total_reads=$(samtools view -c aligned/IP_rep1.final.bam) reads_in_peaks=$(bedtools intersect -a aligned/IP_rep1.final.bam -b peaks/experiment_peaks.narrowPeak -u | samtools view -c) frip=$(echo "scale=4; $reads_in_peaks / $total_reads" | bc) echo "FRiP: $frip" # Generate bigWig for visualization bamCoverage -b aligned/IP_rep1.final.bam \ -o bigwig/IP_rep1.bw \ --normalizeUsing RPKM \ -p 8 # Fingerprint plot (assess enrichment) plotFingerprint \ -b aligned/IP_rep1.final.bam aligned/Input_rep1.final.bam \ --labels IP Input \ -o qc/fingerprint.pdf ``` **QC Checkpoint:** Assess enrichment quality - FRiP >1% (ideally >5% for good enrichment) - Fingerprint shows clear separation between IP and Input ### Step 6: Peak Annotation with ChIPseeker ```r library(ChIPseeker) library(TxDb.Hsapiens.UCSC.hg38.knownGene) library(org.Hs.eg.db) txdb <- TxDb.Hsapiens.UCSC.hg38.knownGene # Read peaks peaks <- readPeakFile('peaks/experiment_peaks.narrowPeak') # Annotate peak_anno <- annotatePeak(peaks, TxDb = txdb, annoDb = 'org.Hs.eg.db', tssRegion = c(-3000, 3000)) # Visualize plotAnnoPie(peak_anno) plotDistToTSS(peak_anno) # Export write.csv(as.data.frame(peak_anno), 'peaks/annotated_peaks.csv') # Get genes with peaks in promoter promoter_peaks <- as.data.frame(peak_anno) promoter_genes <- unique(promoter_peaks$SYMBOL[grepl('Promoter', promoter_peaks$annotation)]) write.table(promoter_genes, 'peaks/promoter_genes.txt', row.names = FALSE, col.names = FALSE, quote = FALSE) ``` ## Parameter Recommendations | Step | Parameter | Narrow Peaks | Broad Peaks | |------|-----------|--------------|-------------| | MACS3 | --broad | No | Yes | | MACS3 | -q | 0.01 | - | | MACS3 | --broad-cutoff | - | 0.1 | | MACS3 | -g | hs/mm/ce/dm | Same | | Bowtie2 | -q (samtools) | 30 | 30 | ## Troubleshooting | Issue | Likely Cause | Solution | |-------|--------------|----------| | Few peaks | Low enrichment, wrong parameters | Check fingerprint, adjust -q threshold | | Many peaks | High noise, PCR duplicates | Remove duplicates, use stricter -q | | Low FRiP | Poor antibody, low enrichment | Check antibody, increase sequencing | | Peaks in blacklist | Technical artifacts | Filter against ENCODE blacklist | ## Complete Pipeline Script ```bash #!/bin/bash set -e THREADS=8 GENOME="genome.fa" INDEX="bt2_index/genome" IP_SAMPLES="IP_rep1 IP_rep2" INPUT_SAMPLES="Input_rep1 Input_rep2" OUTDIR="results" mkdir -p ${OUTDIR}/{trimmed,aligned,peaks,qc,bigwig} # Step 1: QC for sample in $IP_SAMPLES $INPUT_SAMPLES; do fastp -i ${sample}_R1.fastq.gz -I ${sample}_R2.fastq.gz \ -o ${OUTDIR}/trimmed/${sample}_R1.fq.gz \ -O ${OUTDIR}/trimmed/${sample}_R2.fq.gz \ --html ${OUTDIR}/qc/${sample}_fastp.html -w ${THREADS} done # Step 2-3: Align and process for sample in $IP_SAMPLES $INPUT_SAMPLES; do bowtie2 -p ${THREADS} -x ${INDEX} \ -1 ${OUTDIR}/trimmed/${sample}_R1.fq.gz \ -2 ${OUTDIR}/trimmed/${sample}_R2.fq.gz \ --no-mixed --no-discordant 2> ${OUTDIR}/qc/${sample}_align.log | \ samtools view -@ ${THREADS} -bS -q 30 - | \ samtools fixmate -m - - | \ samtools sort -@ ${THREADS} - | \ samtools markdup -r - ${OUTDIR}/aligned/${sample}.bam samtools index ${OUTDIR}/aligned/${sample}.bam done # Step 4: Peak calling ip_bams=$(for s in $IP_SAMPLES; do echo "${OUTDIR}/aligned/${s}.bam"; done | tr '\n' ' ') input_bams=$(for s in $INPUT_SAMPLES; do echo "${OUTDIR}/aligned/${s}.bam"; done | tr '\n' ' ') macs3 callpeak -t ${ip_bams} -c ${input_bams} \ -f BAMPE -g hs -n experiment \ --outdir ${OUTDIR}/peaks -q 0.01 echo "Pipeline complete. Peaks: ${OUTDIR}/peaks/experiment_peaks.narrowPeak" ``` ## Related Skills - chip-seq/peak-calling - MACS3 parameters and options - chip-seq/peak-annotation - ChIPseeker annotation details - chip-seq/differential-binding - Compare conditions with DiffBind - chip-seq/chipseq-qc - Comprehensive QC metrics - chip-seq/motif-analysis - Find enriched motifs in peaks