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---
name: bio-workflows-somatic-variant-pipeline
description: End-to-end somatic variant calling from tumor-normal paired samples using Mutect2 or Strelka2. Covers preprocessing, variant calling, filtering, and annotation for cancer genomics. Use when calling somatic mutations from tumor-normal pairs.
tool_type: cli
primary_tool: GATK Mutect2
measurable_outcome: Execute skill workflow successfully with valid output within 15 minutes.
allowed-tools:
- read_file
- run_shell_command
---
# Somatic Variant Pipeline
Complete workflow for calling somatic mutations from tumor-normal paired samples.
## Pipeline Overview
```
Tumor BAM + Normal BAM
│
├── Preprocessing (if needed)
│ └── MarkDuplicates, BQSR
│
├── Variant Calling
│ ├── Mutect2 (GATK) - SNVs + indels
│ └── Strelka2 - SNVs + indels (faster)
│
├── Filtering
│ ├── FilterMutectCalls
│ ├── Contamination estimation
│ └── Orientation bias filtering
│
├── Annotation
│ ├── Funcotator / VEP
│ └── Cancer-specific databases
│
└── Output: Filtered somatic VCF
```
## Mutect2 Workflow (GATK)
### Step 1: Panel of Normals (Optional but Recommended)
```bash
# Create PON from multiple normal samples
for normal in normal1.bam normal2.bam normal3.bam; do
sample=$(basename $normal .bam)
gatk Mutect2 \
-R reference.fa \
-I $normal \
--max-mnp-distance 0 \
-O ${sample}.vcf.gz
done
# Combine into PON
gatk GenomicsDBImport \
-R reference.fa \
--genomicsdb-workspace-path pon_db \
-V normal1.vcf.gz \
-V normal2.vcf.gz \
-V normal3.vcf.gz \
-L intervals.bed
gatk CreateSomaticPanelOfNormals \
-R reference.fa \
-V gendb://pon_db \
-O pon.vcf.gz
```
### Step 2: Call Somatic Variants
```bash
gatk Mutect2 \
-R reference.fa \
-I tumor.bam \
-I normal.bam \
-normal normal_sample_name \
--germline-resource af-only-gnomad.vcf.gz \
--panel-of-normals pon.vcf.gz \
--f1r2-tar-gz f1r2.tar.gz \
-O unfiltered.vcf.gz
```
### Step 3: Learn Orientation Bias
```bash
gatk LearnReadOrientationModel \
-I f1r2.tar.gz \
-O read-orientation-model.tar.gz
```
### Step 4: Calculate Contamination
```bash
gatk GetPileupSummaries \
-I tumor.bam \
-V small_exac_common.vcf.gz \
-L small_exac_common.vcf.gz \
-O tumor_pileups.table
gatk GetPileupSummaries \
-I normal.bam \
-V small_exac_common.vcf.gz \
-L small_exac_common.vcf.gz \
-O normal_pileups.table
gatk CalculateContamination \
-I tumor_pileups.table \
-matched normal_pileups.table \
-O contamination.table \
--tumor-segmentation segments.table
```
### Step 5: Filter Variants
```bash
gatk FilterMutectCalls \
-R reference.fa \
-V unfiltered.vcf.gz \
--contamination-table contamination.table \
--tumor-segmentation segments.table \
--ob-priors read-orientation-model.tar.gz \
-O filtered.vcf.gz
# Extract PASS variants
bcftools view -f PASS filtered.vcf.gz -Oz -o somatic_final.vcf.gz
```
## Strelka2 Workflow (Faster Alternative)
```bash
# Configure
configureStrelkaSomaticWorkflow.py \
--normalBam normal.bam \
--tumorBam tumor.bam \
--referenceFasta reference.fa \
--runDir strelka_run
# Execute
strelka_run/runWorkflow.py -m local -j 16
# Output files
# strelka_run/results/variants/somatic.snvs.vcf.gz
# strelka_run/results/variants/somatic.indels.vcf.gz
# Merge SNVs and indels
bcftools concat \
strelka_run/results/variants/somatic.snvs.vcf.gz \
strelka_run/results/variants/somatic.indels.vcf.gz \
-a -Oz -o strelka_somatic.vcf.gz
```
## Annotation
### Funcotator (GATK)
```bash
gatk Funcotator \
-R reference.fa \
-V somatic_final.vcf.gz \
-O annotated.vcf.gz \
--output-file-format VCF \
--data-sources-path funcotator_dataSources.v1.7 \
--ref-version hg38
```
### VEP with Cancer Databases
```bash
vep -i somatic_final.vcf.gz -o annotated.vcf \
--vcf --cache --offline \
--assembly GRCh38 \
--everything \
--plugin CADD,cadd_scores.tsv.gz \
--custom cosmic.vcf.gz,COSMIC,vcf,exact,0,CNT \
--fork 4
```
## Complete Pipeline Script
```bash
#!/bin/bash
set -euo pipefail
TUMOR_BAM=$1
NORMAL_BAM=$2
NORMAL_NAME=$3
REFERENCE=$4
OUTPUT_PREFIX=$5
GNOMAD=$6
PON=$7
THREADS=16
echo "=== Step 1: Mutect2 calling ==="
gatk Mutect2 \
-R $REFERENCE \
-I $TUMOR_BAM \
-I $NORMAL_BAM \
-normal $NORMAL_NAME \
--germline-resource $GNOMAD \
--panel-of-normals $PON \
--f1r2-tar-gz ${OUTPUT_PREFIX}_f1r2.tar.gz \
--native-pair-hmm-threads $THREADS \
-O ${OUTPUT_PREFIX}_unfiltered.vcf.gz
echo "=== Step 2: Learn orientation bias ==="
gatk LearnReadOrientationModel \
-I ${OUTPUT_PREFIX}_f1r2.tar.gz \
-O ${OUTPUT_PREFIX}_orientation.tar.gz
echo "=== Step 3: Pileup summaries ==="
gatk GetPileupSummaries \
-I $TUMOR_BAM \
-V $GNOMAD \
-L $GNOMAD \
-O ${OUTPUT_PREFIX}_tumor_pileups.table
gatk GetPileupSummaries \
-I $NORMAL_BAM \
-V $GNOMAD \
-L $GNOMAD \
-O ${OUTPUT_PREFIX}_normal_pileups.table
echo "=== Step 4: Calculate contamination ==="
gatk CalculateContamination \
-I ${OUTPUT_PREFIX}_tumor_pileups.table \
-matched ${OUTPUT_PREFIX}_normal_pileups.table \
-O ${OUTPUT_PREFIX}_contamination.table \
--tumor-segmentation ${OUTPUT_PREFIX}_segments.table
echo "=== Step 5: Filter variants ==="
gatk FilterMutectCalls \
-R $REFERENCE \
-V ${OUTPUT_PREFIX}_unfiltered.vcf.gz \
--contamination-table ${OUTPUT_PREFIX}_contamination.table \
--tumor-segmentation ${OUTPUT_PREFIX}_segments.table \
--ob-priors ${OUTPUT_PREFIX}_orientation.tar.gz \
-O ${OUTPUT_PREFIX}_filtered.vcf.gz
echo "=== Step 6: Extract PASS variants ==="
bcftools view -f PASS ${OUTPUT_PREFIX}_filtered.vcf.gz \
-Oz -o ${OUTPUT_PREFIX}_somatic.vcf.gz
bcftools index -t ${OUTPUT_PREFIX}_somatic.vcf.gz
echo "=== Step 7: Statistics ==="
bcftools stats ${OUTPUT_PREFIX}_somatic.vcf.gz > ${OUTPUT_PREFIX}_stats.txt
echo "=== Pipeline complete ==="
echo "Somatic variants: ${OUTPUT_PREFIX}_somatic.vcf.gz"
echo "Stats: ${OUTPUT_PREFIX}_stats.txt"
```
## Tumor-Only Mode
When matched normal is unavailable:
```bash
gatk Mutect2 \
-R reference.fa \
-I tumor.bam \
--germline-resource af-only-gnomad.vcf.gz \
--panel-of-normals pon.vcf.gz \
-O tumor_only.vcf.gz
```
Note: Higher false positive rate without matched normal.
## Key Resources
| Resource | Purpose |
|----------|---------|
| gnomAD AF-only | Germline filtering |
| Panel of Normals | Technical artifact removal |
| COSMIC | Known cancer mutations |
| Funcotator data sources | Functional annotation |
## Quality Metrics
```bash
# Variant counts by filter status
bcftools query -f '%FILTER\n' filtered.vcf.gz | sort | uniq -c
# Ti/Tv ratio (expect ~2-3 for somatic)
bcftools stats filtered.vcf.gz | grep TSTV
# Variant allele frequency distribution
bcftools query -f '%AF\n' somatic_final.vcf.gz | \
awk '{print int($1*100)/100}' | sort -n | uniq -c
```
## Related Skills
- variant-calling/gatk-variant-calling - Germline variant calling
- variant-calling/filtering-best-practices - Filtering strategies
- variant-calling/variant-annotation - VEP/SnpEff annotation
- copy-number/cnvkit-analysis - Somatic CNV calling
- variant-calling/variant-annotation - Germline pipeline
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