| name | bio-atac-seq-differential-accessibility |
| description | Find differentially accessible chromatin regions between conditions using DiffBind or DESeq2. Use when comparing chromatin accessibility between treatment groups, cell types, or developmental stages in ATAC-seq experiments. |
| tool_type | r |
| primary_tool | DiffBind |
Version Compatibility
Reference examples tested with: DESeq2 1.42+, GenomicRanges 1.54+, Subread 2.0+, numpy 1.26+, pandas 2.2+, scanpy 1.10+, scipy 1.12+
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.
Differential Accessibility
"Find differentially accessible regions between my conditions" → Identify chromatin regions with statistically significant changes in accessibility between treatment groups, cell types, or timepoints.
- R:
DiffBind or DESeq2 on a peak-by-sample count matrix
DiffBind Workflow
Goal: Identify differentially accessible chromatin regions between experimental conditions.
Approach: Load sample metadata and peak files into DiffBind, count reads in consensus peaks, normalize, define contrasts, and run differential analysis with DESeq2 backend.
library(DiffBind)
samples <- data.frame(
SampleID = c('ctrl_1', 'ctrl_2', 'treat_1', 'treat_2'),
Condition = c('control', 'control', 'treated', 'treated'),
Replicate = c(1, 2, 1, 2),
bamReads = c('ctrl_1.bam', 'ctrl_2.bam', 'treat_1.bam', 'treat_2.bam'),
Peaks = c('ctrl_1.narrowPeak', 'ctrl_2.narrowPeak', 'treat_1.narrowPeak', 'treat_2.narrowPeak')
)
write.csv(samples, 'samples.csv', row.names=FALSE)
dba <- dba(sampleSheet='samples.csv')
dba <- dba.count(dba)
dba <- dba.normalize(dba)
dba <- dba.contrast(dba, contrast=c('Condition', 'treated', 'control'))
dba <- dba.analyze(dba)
results <- dba.report(dba)
DiffBind with Consensus Peaks
library(DiffBind)
dba <- dba(sampleSheet='samples.csv')
dba <- dba.count(dba,
summits=250,
minOverlap=2,
score=DBA_SCORE_NORMALIZED)
dba <- dba.normalize(dba, normalize=DBA_NORM_NATIVE)
dba <- dba.contrast(dba, contrast=c('Condition', 'treated', 'control'))
dba <- dba.analyze(dba, method=DBA_DESEQ2)
results <- dba.report(dba, th=0.05, bCounts=TRUE)
write.csv(as.data.frame(results), 'differential_peaks.csv')
DiffBind Visualizations
dba.plotPCA(dba, attributes=DBA_CONDITION)
dba.plotMA(dba)
dba.plotVolcano(dba)
dba.plotHeatmap(dba, contrast=1, correlations=FALSE)
dba.plotVenn(dba, contrast=1, bDB=TRUE, bGain=TRUE, bLoss=TRUE)
Using DESeq2 Directly
Goal: Run differential accessibility analysis using DESeq2 on a peak count matrix without DiffBind.
Approach: Load peak-by-sample counts into a DESeqDataSet, filter low counts, run the DESeq2 pipeline, and extract significant differential peaks.
library(DESeq2)
library(GenomicRanges)
counts <- read.delim('peak_counts.txt', row.names=1)
coldata <- data.frame(
row.names = colnames(counts),
condition = factor(c('control', 'control', 'treated', 'treated'))
)
dds <- DESeqDataSetFromMatrix(countData=counts, colData=coldata, design=~condition)
dds <- dds[rowSums(counts(dds)) >= 10, ]
dds <- DESeq(dds)
res <- results(dds, contrast=c('condition', 'treated', 'control'))
res <- res[order(res$padj), ]
sig <- subset(res, padj < 0.05 & abs(log2FoldChange) > 1)
Count Reads in Peaks
Goal: Generate a peak-by-sample count matrix as input for differential analysis.
Approach: Convert consensus peaks to SAF format and run featureCounts to count reads from all BAM files in each peak region.
awk 'BEGIN{OFS="\t"; print "GeneID\tChr\tStart\tEnd\tStrand"}
{print $1"_"$2"_"$3, $1, $2, $3, "."}' consensus_peaks.bed > peaks.saf
featureCounts \
-a peaks.saf \
-F SAF \
-o peak_counts.txt \
-p \
--countReadPairs \
-T 8 \
*.bam
Python Alternative
import pandas as pd
import numpy as np
from scipy import stats
def simple_differential(counts_file, groups):
'''Simple differential accessibility test.'''
counts = pd.read_csv(counts_file, sep='\t', index_col=0, comment='#')
cpm = counts.div(counts.sum()) * 1e6
log_cpm = np.log2(cpm + 1)
group1 = [c for c in counts.columns if groups[c] == 'control']
group2 = [c for c in counts.columns if groups[c] == 'treated']
results = []
for peak in counts.index:
g1_vals = log_cpm.loc[peak, group1]
g2_vals = log_cpm.loc[peak, group2]
log2fc = g2_vals.mean() - g1_vals.mean()
t_stat, pval = stats.ttest_ind(g1_vals, g2_vals)
results.append({
'peak': peak,
'log2FoldChange': log2fc,
'pvalue': pval
})
df = pd.DataFrame(results)
df['padj'] = stats.false_discovery_control(df['pvalue'])
return df
Annotate Differential Peaks
Goal: Map differential peaks to nearby genes and genomic features for biological interpretation.
Approach: Use ChIPseeker to annotate peaks with promoter/intron/intergenic classification and distance to nearest TSS.
library(ChIPseeker)
library(TxDb.Hsapiens.UCSC.hg38.knownGene)
diff_peaks <- dba.report(dba)
peakAnno <- annotatePeak(diff_peaks, TxDb=TxDb.Hsapiens.UCSC.hg38.knownGene)
plotAnnoPie(peakAnno)
plotDistToTSS(peakAnno)
genes <- as.data.frame(peakAnno)$geneId
Filter Results
sig_peaks <- dba.report(dba, th=0.05, fold=1)
opened <- sig_peaks[sig_peaks$Fold > 0]
closed <- sig_peaks[sig_peaks$Fold < 0]
export.bed(opened, 'opened_peaks.bed')
export.bed(closed, 'closed_peaks.bed')
Multi-factor Designs
samples$Batch <- factor(c('A', 'B', 'A', 'B'))
dba <- dba(sampleSheet=samples)
dba <- dba.count(dba)
dba <- dba.normalize(dba)
dba <- dba.contrast(dba, design='~Batch + Condition')
dba <- dba.analyze(dba)
Related Skills
- atac-seq/atac-peak-calling - Generate input peaks
- differential-expression/deseq2-basics - DESeq2 methods
- chip-seq/differential-binding - Similar DiffBind workflow
- pathway-analysis/go-enrichment - Analyze differential genes