| name | bio-atac-seq-nucleosome-positioning |
| description | Extract nucleosome positions from ATAC-seq data using NucleoATAC, ATACseqQC, and fragment analysis. Use when analyzing chromatin organization, identifying nucleosome-free regions at promoters, or characterizing nucleosome occupancy patterns from ATAC-seq fragment size distributions. |
| tool_type | mixed |
| primary_tool | NucleoATAC |
Version Compatibility
Reference examples tested with: Rsamtools 2.18+, matplotlib 3.8+, numpy 1.26+, pyBigWig 0.3+, pysam 0.22+, samtools 1.19+
Before using code patterns, verify installed versions match. If versions differ:
- Python:
pip show <package> then help(module.function) to check signatures
- R:
packageVersion('<pkg>') then ?function_name to verify parameters
- 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.
Nucleosome Positioning
"Map nucleosome positions from ATAC-seq" → Separate nucleosome-free and mono-nucleosome fragments by size, then call nucleosome center positions and occupancy scores.
- CLI:
nucleoatac run --bed peaks.bed --bam atac.bam --fasta ref.fa
- R:
ATACseqQC::splitGAlignmentsByCut() for fragment separation
Extract nucleosome positions and occupancy from ATAC-seq fragment size patterns.
Background
ATAC-seq fragments reflect chromatin structure:
- < 100 bp: Nucleosome-free regions (NFR)
- 180-247 bp: Mono-nucleosome
- 315-473 bp: Di-nucleosome
- 558-615 bp: Tri-nucleosome
ATACseqQC (R)
Installation
BiocManager::install('ATACseqQC')
Fragment Size Distribution
library(ATACseqQC)
library(Rsamtools)
bamfile <- 'sample.bam'
fragSize <- fragSizeDist(bamfile, 'sample')
Nucleosome Positioning
Goal: Map nucleosome positions around TSS using ATAC-seq fragment size classes.
Approach: Read BAM, apply Tn5 shift correction, split fragments into NFR and mono-nucleosome classes by size, then compute signal profiles around TSS.
library(ATACseqQC)
library(TxDb.Hsapiens.UCSC.hg38.knownGene)
library(BSgenome.Hsapiens.UCSC.hg38)
txs <- transcripts(TxDb.Hsapiens.UCSC.hg38.knownGene)
tss <- promoters(txs, upstream=1000, downstream=1000)
gal <- readBamFile(bamfile, asMates=TRUE, bigFile=TRUE)
gal_shifted <- shiftGAlignmentsList(gal)
objs <- splitGAlignmentsByCut(gal_shifted, txs=txs,
genome=BSgenome.Hsapiens.UCSC.hg38)
nfr <- objs$NussomeFree
mono <- objs$mononucleosome
sigs <- featureAlignedSignal(cvglist=objs,
feature.gr=tss,
upstream=1000,
downstream=1000)
V-Plot (Fragment Size vs Position)
vp <- vPlot(gal_shifted, tss,
genome=BSgenome.Hsapiens.UCSC.hg38,
upstream=1000, downstream=1000)
Footprinting
library(MotifDb)
motif <- query(MotifDb, 'CTCF')[[1]]
library(motifmatchr)
motif_pos <- matchMotifs(motif, BSgenome.Hsapiens.UCSC.hg38,
genome='hg38', out='positions')
fp <- factorFootprints(gal_shifted, motif_pos,
genome=BSgenome.Hsapiens.UCSC.hg38,
upstream=100, downstream=100)
NucleoATAC (Python)
Installation
pip install nucleoatac
Run NucleoATAC
Goal: Call precise nucleosome center positions and occupancy scores from ATAC-seq data.
Approach: Run NucleoATAC on defined genomic regions with a reference genome, producing nucleosome position calls and occupancy tracks.
nucleoatac run --bed regions.bed --bam sample.bam --fasta reference.fa \
--out nucleoatac_output --cores 8
Output Files
| File | Description |
|---|
.nucpos.bed | Nucleosome positions |
.nucpos.redundant.bed | All nucleosome calls |
.nfrpos.bed | NFR positions |
.occ.bedgraph | Nucleosome occupancy track |
.nucmap_combined.bed | Combined nucleosome map |
Visualize Output
bedGraphToBigWig nucleoatac_output.occ.bedgraph chrom.sizes nucleosome_occ.bw
Fragment Analysis (Custom)
Extract Fragment Sizes
Goal: Visualize ATAC-seq fragment size distribution to assess nucleosome periodicity.
Approach: Extract template lengths from properly paired reads, then plot the histogram with NFR and mono-nucleosome cutoff markers.
import pysam
import numpy as np
import matplotlib.pyplot as plt
bam = pysam.AlignmentFile('sample.bam', 'rb')
fragment_sizes = []
for read in bam.fetch():
if read.is_proper_pair and read.is_read1:
frag_size = abs(read.template_length)
if 0 < frag_size < 1000:
fragment_sizes.append(frag_size)
bam.close()
plt.figure(figsize=(10, 6))
plt.hist(fragment_sizes, bins=200, edgecolor='none', alpha=0.7)
plt.axvline(100, color='red', linestyle='--', label='NFR cutoff')
plt.axvline(180, color='blue', linestyle='--', label='Mono-nuc start')
plt.xlabel('Fragment Size (bp)')
plt.ylabel('Count')
plt.legend()
plt.savefig('fragment_distribution.png', dpi=300)
Split by Fragment Size
samtools view -h sample.bam | \
awk '$9 > -100 && $9 < 100 || $1 ~ /^@/' | \
samtools view -b > nfr.bam
samtools view -h sample.bam | \
awk '($9 >= 180 && $9 <= 247) || ($9 <= -180 && $9 >= -247) || $1 ~ /^@/' | \
samtools view -b > mono_nuc.bam
Signal Around Features
import pysam
import numpy as np
import pyBigWig
def signal_around_sites(bam_file, sites, upstream=1000, downstream=1000):
bam = pysam.AlignmentFile(bam_file, 'rb')
window_size = upstream + downstream
signal = np.zeros(window_size)
for chrom, pos, strand in sites:
start = pos - upstream if strand == '+' else pos - downstream
end = pos + downstream if strand == '+' else pos + upstream
for read in bam.fetch(chrom, max(0, start), end):
if read.is_proper_pair and read.is_read1:
frag_center = read.reference_start + abs(read.template_length) // 2
rel_pos = frag_center - start
if 0 <= rel_pos < window_size:
signal[rel_pos] += 1
bam.close()
return signal / len(sites)
tss_sites = []
nfr_signal = signal_around_sites('nfr.bam', tss_sites)
mono_signal = signal_around_sites('mono_nuc.bam', tss_sites)
DANPOS
Installation
conda install -c bioconda danpos
Run DANPOS
danpos.py dpos sample.bam -o danpos_output
danpos.py dpeak -b treatment.bam -c control.bam -o danpos_diff
Complete Workflow
Goal: Run end-to-end nucleosome positioning analysis from BAM to heatmaps and V-plots.
Approach: Read BAM, shift reads for Tn5 offset, split fragments by size class, compute signal profiles around TSS, and generate heatmaps and V-plots.
library(ATACseqQC)
library(TxDb.Hsapiens.UCSC.hg38.knownGene)
library(BSgenome.Hsapiens.UCSC.hg38)
bamfile <- 'sample.bam'
fragSize <- fragSizeDist(bamfile, 'sample')
pdf('fragment_size.pdf')
plot(fragSize)
dev.off()
gal <- readBamFile(bamfile, asMates=TRUE, bigFile=TRUE)
gal_shifted <- shiftGAlignmentsList(gal)
txs <- transcripts(TxDb.Hsapiens.UCSC.hg38.knownGene)
tss <- promoters(txs, upstream=2000, downstream=2000)
objs <- splitGAlignmentsByCut(gal_shifted, txs=txs,
genome=BSgenome.Hsapiens.UCSC.hg38)
sigs <- featureAlignedSignal(cvglist=objs,
feature.gr=tss,
upstream=2000,
downstream=2000)
pdf('nucleosome_heatmap.pdf', width=8, height=10)
featureAlignedHeatmap(sigs, tss, upstream=2000, downstream=2000)
dev.off()
pdf('vplot.pdf')
vPlot(gal_shifted, tss, genome=BSgenome.Hsapiens.UCSC.hg38,
upstream=1000, downstream=1000)
dev.off()
export(objs$NuclsomeFree, 'nfr.bam')
export(objs$mononucleosome, 'mono_nucleosome.bam')
Related Skills
- atac-seq/atac-peak-calling - Call accessibility peaks
- atac-seq/atac-qc - Quality control metrics
- atac-seq/footprinting - TF footprinting
- chip-seq/peak-annotation - Annotate nucleosome positions