bio-atac-seq-atac-peak-calling
This skill performs peak calling on ATAC-seq data using MACS3 with parameters optimized for identifying open chromatin regions from aligned BAM files. Use it when analyzing accessible chromatin from ATAC-seq experiments, as it applies ATAC-specific settings like Tn5 shift correction, paired-end mode, and duplicate retention that differ from standard ChIP-seq peak calling approaches.
git clone --depth 1 https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills /tmp/bio-atac-seq-atac-peak-calling && cp -r /tmp/bio-atac-seq-atac-peak-calling/skills/bio-atac-seq-atac-peak-calling ~/.claude/skills/bio-atac-seq-atac-peak-callingSKILL.md
## Version Compatibility
Reference examples tested with: Bowtie2 2.5.3+, MACS3 3.0+, samtools 1.19+
Before using code patterns, verify installed versions match. If versions differ:
- CLI: `<tool> --version` then `<tool> --help` to confirm flags
If code throws ImportError, AttributeError, or TypeError, introspect the installed
package and adapt the example to match the actual API rather than retrying.
# ATAC-seq Peak Calling
**"Call peaks from my ATAC-seq data"** → Identify open chromatin regions using ATAC-specific parameters (no input control, shifted Tn5 cut sites, paired-end mode).
- CLI: `macs3 callpeak -t atac.bam -f BAMPE -g hs --nomodel --shift -75 --extsize 150`
## Basic MACS3 for ATAC-seq
**Goal:** Identify open chromatin regions from ATAC-seq data using ATAC-specific peak calling parameters.
**Approach:** Run MACS3 in paired-end mode with Tn5 shift correction, no model building, and duplicate retention since ATAC-seq generates natural duplicates at accessible sites.
```bash
# Standard ATAC-seq peak calling
macs3 callpeak \
-t sample.bam \
-f BAMPE \
-g hs \
-n sample \
--outdir peaks/ \
-q 0.05 \
--nomodel \
--shift -75 \
--extsize 150 \
--keep-dup all \
-B
```
## Key ATAC-seq Parameters
```bash
# Explained parameters
macs3 callpeak \
-t sample.bam \ # Treatment BAM
-f BAMPE \ # Paired-end BAM (uses fragment size)
-g hs \ # Genome size: hs (human), mm (mouse)
-n sample \ # Output name prefix
--nomodel \ # Don't build shifting model
--shift -75 \ # Shift reads to center on Tn5 cut site
--extsize 150 \ # Extend reads to this size
--keep-dup all \ # Keep duplicates (ATAC has natural duplicates)
-B \ # Generate bedGraph for visualization
--call-summits # Call peak summits
```
## Why These Parameters?
| Parameter | Reason |
|-----------|--------|
| --nomodel | ATAC doesn't have control, can't build model |
| --shift -75 | Centers on Tn5 insertion site |
| --extsize 150 | Smooths signal around cut sites |
| --keep-dup all | Tn5 creates duplicate cuts at accessible sites |
| -f BAMPE | Uses actual fragment size from paired-end |
## Paired-End vs Single-End
```bash
# Paired-end (recommended for ATAC)
macs3 callpeak -f BAMPE -t sample.bam ...
# Single-end (less common)
macs3 callpeak -f BAM -t sample.bam \
--nomodel --shift -75 --extsize 150 ...
```
## Call Peaks on NFR Only
**Goal:** Call peaks using only nucleosome-free fragments for sharper regulatory element detection.
**Approach:** Filter BAM to fragments <100 bp (NFR), then call peaks with adjusted shift/extsize parameters matching the shorter fragment size.
```bash
# First, filter to nucleosome-free reads (<100bp fragments)
samtools view -h sample.bam | \
awk 'substr($0,1,1)=="@" || ($9>0 && $9<100) || ($9<0 && $9>-100)' | \
samtools view -b > nfr.bam
# Call peaks on NFR
macs3 callpeak \
-t nfr.bam \
-f BAMPE \
-g hs \
-n sample_nfr \
--nomodel \
--shift -37 \
--extsize 75 \
--keep-dup all \
-q 0.01
```
## Broad Peaks (Optional)
```bash
# For broader accessible regions
macs3 callpeak \
-t sample.bam \
-f BAMPE \
-g hs \
-n sample_broad \
--nomodel \
--shift -75 \
--extsize 150 \
--broad \
--broad-cutoff 0.1
```
## Batch Processing
**Goal:** Call peaks on multiple ATAC-seq samples in one pass.
**Approach:** Loop over BAM files and run MACS3 with consistent ATAC-specific parameters for each sample.
```bash
#!/bin/bash
GENOME=hs # hs for human, mm for mouse
OUTDIR=peaks
mkdir -p $OUTDIR
for bam in *.bam; do
sample=$(basename $bam .bam)
echo "Processing $sample..."
macs3 callpeak \
-t $bam \
-f BAMPE \
-g $GENOME \
-n $sample \
--outdir $OUTDIR \
--nomodel \
--shift -75 \
--extsize 150 \
--keep-dup all \
-q 0.05 \
-B \
--call-summits
done
```
## Output Files
| File | Description |
|------|-------------|
| _peaks.narrowPeak | Peak locations (BED-like) |
| _summits.bed | Peak summit positions |
| _peaks.xls | Peak statistics (Excel format) |
| _treat_pileup.bdg | Signal track (bedGraph) |
| _control_lambda.bdg | Background (if control provided) |
## narrowPeak Format
```
chr1 100 500 peak1 500 . 10.5 50.2 45.1 200
```
Columns: chrom, start, end, name, score, strand, signalValue, pValue, qValue, summit_offset
## Convert to BigWig
```bash
# Sort bedGraph
sort -k1,1 -k2,2n sample_treat_pileup.bdg > sample.sorted.bdg
# Convert to BigWig
bedGraphToBigWig sample.sorted.bdg chrom.sizes sample.bw
```
## Merge Replicates
```bash
# Pool BAMs before peak calling (recommended for final peaks)
samtools merge -@ 8 merged.bam rep1.bam rep2.bam rep3.bam
# Call peaks on merged
macs3 callpeak -t merged.bam -f BAMPE -g hs -n merged ...
```
## IDR for Replicate Consistency
**Goal:** Identify reproducible peaks across biological replicates using the Irreproducible Discovery Rate framework.
**Approach:** Call peaks on each replicate independently, then run IDR to score peak reproducibility and filter to a high-confidence set.
```bash
# Call peaks on each replicate
macs3 callpeak -t rep1.bam -f BAMPE -g hs -n rep1 ...
macs3 callpeak -t rep2.bam -f BAMPE -g hs -n rep2 ...
# Run IDR
idr --samples rep1_peaks.narrowPeak rep2_peaks.narrowPeak \
--input-file-type narrowPeak \
--output-file idr_peaks.txt \
--plot
# Filter by IDR threshold
awk '$5 >= 540' idr_peaks.txt > reproducible_peaks.bed
```
## Related Skills
- read-alignment/bowtie2-alignment - Align ATAC-seq reads
- atac-seq/atac-qc - Quality control
- chip-seq/peak-calling - ChIP-seq comparison
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