Call SNPs and indels from aligned reads using bcftools mpileup and call. Use when detecting variants from BAM files or generating VCF from alignments.
Install with the open skills CLI (global, non-interactive — available in every Claude Code session):
npx skills add FreedomIntelligence/OpenClaw-Medical-Skills --skill "bio-variant-calling" -g -a claude-code -yOr manually — clone and copy the skill directory (SKILL.md + companion files):
git clone --depth 1 https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills /tmp/OpenClaw-Medical-Skills && cp -r /tmp/OpenClaw-Medical-Skills/skills/bio-variant-calling ~/.claude/skills/bio-variant-callingThis skill is a directory: SKILL.md is the entry point; the files below ship with it.
---
name: bio-variant-calling
description: Call SNPs and indels from aligned reads using bcftools mpileup and call. Use when detecting variants from BAM files or generating VCF from alignments.
tool_type: cli
primary_tool: bcftools
---
## Version Compatibility
Reference examples tested with: bcftools 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.
# Variant Calling
Call SNPs and indels from aligned reads using bcftools.
## Basic Workflow
```
BAM file + Reference FASTA
|
v
bcftools mpileup (generate pileup)
|
v
bcftools call (call variants)
|
v
VCF file
```
## bcftools mpileup + call
**Goal:** Detect SNPs and indels from aligned reads using the bcftools pileup-and-call pipeline.
**Approach:** Generate per-position pileup likelihoods with mpileup, then call genotypes with the multiallelic caller.
**"Call variants from my BAM file"** → Generate genotype likelihoods from aligned reads and identify variant sites using a Bayesian caller.
### Basic Variant Calling
```bash
bcftools mpileup -f reference.fa input.bam | bcftools call -mv -o variants.vcf
```
### Output Compressed VCF
```bash
bcftools mpileup -f reference.fa input.bam | bcftools call -mv -Oz -o variants.vcf.gz
bcftools index variants.vcf.gz
```
### Call Specific Region
```bash
bcftools mpileup -f reference.fa -r chr1:1000000-2000000 input.bam | \
bcftools call -mv -o region.vcf
```
### Call from Multiple BAMs
```bash
bcftools mpileup -f reference.fa sample1.bam sample2.bam sample3.bam | \
bcftools call -mv -o variants.vcf
```
### BAM List File
```bash
# bams.txt: one BAM path per line
bcftools mpileup -f reference.fa -b bams.txt | bcftools call -mv -o variants.vcf
```
## mpileup Options
**Goal:** Control pileup generation with quality thresholds, annotations, and region restrictions.
**Approach:** Set minimum mapping/base quality, request specific FORMAT/INFO tags, and restrict to target regions.
### Quality Filtering
```bash
bcftools mpileup -f reference.fa \
-q 20 \ # Min mapping quality
-Q 20 \ # Min base quality
input.bam | bcftools call -mv -o variants.vcf
```
### Annotate with Read Depth
```bash
bcftools mpileup -f reference.fa -a DP,AD input.bam | bcftools call -mv -o variants.vcf
```
### Full Annotation Set
```bash
bcftools mpileup -f reference.fa \
-a FORMAT/DP,FORMAT/AD,FORMAT/ADF,FORMAT/ADR,INFO/AD \
input.bam | bcftools call -mv -o variants.vcf
```
### Target Regions (BED)
```bash
bcftools mpileup -f reference.fa -R targets.bed input.bam | \
bcftools call -mv -o variants.vcf
```
### Max Depth
```bash
bcftools mpileup -f reference.fa -d 1000 input.bam | bcftools call -mv -o variants.vcf
```
## call Options
### Calling Models
| Flag | Model | Use Case |
|------|-------|----------|
| `-m` | Multiallelic caller | Default, recommended |
| `-c` | Consensus caller | Legacy, single sample |
### Output Variants Only
```bash
bcftools mpileup -f reference.fa input.bam | bcftools call -mv -o variants.vcf
# -v outputs variant sites only (not reference calls)
```
### Output All Sites
```bash
bcftools mpileup -f reference.fa input.bam | bcftools call -m -o all_sites.vcf
# Without -v, outputs all sites including reference
```
### Ploidy
```bash
# Haploid calling
bcftools mpileup -f reference.fa input.bam | bcftools call -m --ploidy 1 -o variants.vcf
# Specify ploidy file
bcftools mpileup -f reference.fa input.bam | bcftools call -m --ploidy-file ploidy.txt -o variants.vcf
```
### Prior Probability
```bash
# Adjust variant prior (default 1.1e-3)
bcftools mpileup -f reference.fa input.bam | bcftools call -m -P 0.001 -o variants.vcf
```
## Common Pipelines
**Goal:** Run production-ready variant calling workflows for single-sample and multi-sample analyses.
**Approach:** Chain mpileup and call with quality filters, annotations, and compressed output, optionally parallelized by chromosome.
### Standard SNP/Indel Calling
```bash
bcftools mpileup -Ou -f reference.fa \
-q 20 -Q 20 \
-a FORMAT/DP,FORMAT/AD \
input.bam | \
bcftools call -mv -Oz -o variants.vcf.gz
bcftools index variants.vcf.gz
```
### Multi-sample Calling
```bash
bcftools mpileup -Ou -f reference.fa \
-a FORMAT/DP,FORMAT/AD \
sample1.bam sample2.bam sample3.bam | \
bcftools call -mv -Oz -o cohort.vcf.gz
bcftools index cohort.vcf.gz
```
### Calling with Regions
```bash
bcftools mpileup -Ou -f reference.fa \
-R targets.bed \
-a FORMAT/DP,FORMAT/AD \
input.bam | \
bcftools call -mv -Oz -o targets.vcf.gz
```
### Parallel by Chromosome
```bash
for chr in chr1 chr2 chr3; do
bcftools mpileup -Ou -f reference.fa -r "$chr" input.bam | \
bcftools call -mv -Oz -o "${chr}.vcf.gz" &
done
wait
# Concatenate results
bcftools concat -Oz -o all.vcf.gz chr*.vcf.gz
bcftools index all.vcf.gz
```
## Annotation Tags
### INFO Tags
| Tag | Description |
|-----|-------------|
| `DP` | Total read depth |
| `AD` | Allelic depths |
| `MQ` | Mapping quality |
| `FS` | Fisher strand bias |
| `SGB` | Segregation based metric |
### FORMAT Tags
| Tag | Description |
|-----|-------------|
| `GT` | Genotype |
| `DP` | Read depth per sample |
| `AD` | Allelic depths per sample |
| `ADF` | Forward strand allelic depths |
| `ADR` | Reverse strand allelic depths |
| `GQ` | Genotype quality |
| `PL` | Phred-scaled likelihoods |
### Request Specific Annotations
```bash
bcftools mpileup -f reference.fa \
-a FORMAT/DP,FORMAT/AD,FORMAT/SP,INFO/AD \
input.bam | bcftools call -mv -o variants.vcf
```
## Performance Options
**Goal:** Speed up variant calling for large datasets.
**Approach:** Use multi-threading and uncompressed BCF piping to reduce I/O overhead.
### Multi-threading
```bash
bcftools mpileup -f reference.fa --threads 4 input.bam | \
bcftools call -mv --threads 4 -o variants.vcf
```
### Uncompressed BCF for Speed
```bash
bcftools mpileup -Ou -f reference.fa input.bam | bcftools call -mv -Ou | \
bcftools filter -Oz -o filtered.vcf.gz
```
## Quick Reference
| Task | Command |
|------|---------|
| Basic calling | `bcftools mpileup -f ref.fa in.bam \| bcftools call -mv -o out.vcf` |
| With quality filter | `bcftools mpileup -f ref.fa -q 20 -Q 20 in.bam \| bcftools call -mv` |
| Region | `bcftools mpileup -f ref.fa -r chr1:1-1000 in.bam \| bcftools call -mv` |
| Multi-sample | `bcftools mpileup -f ref.fa s1.bam s2.bam \| bcftools call -mv` |
| With annotations | `bcftools mpileup -f ref.fa -a DP,AD in.bam \| bcftools call -mv` |
## Common Errors
| Error | Cause | Solution |
|-------|-------|----------|
| `no FASTA reference` | Missing -f | Add `-f reference.fa` |
| `reference mismatch` | Wrong reference | Use same reference as alignment |
| `no variants called` | Low quality/depth | Lower quality thresholds |
## Related Skills
- vcf-basics - View and query resulting VCF
- filtering-best-practices - Filter variants by quality
- variant-normalization - Normalize indels
- alignment-files/pileup-generation - Alternative pileup generation
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