Deep learning-based variant calling with Google DeepVariant. Provides high accuracy for germline SNPs and indels from Illumina, PacBio, and ONT data. Use when calling variants with DeepVariant deep learning caller.
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-deepvariant" -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-deepvariant ~/.claude/skills/bio-variant-calling-deepvariantThis skill is a directory: SKILL.md is the entry point; the files below ship with it.
---
name: bio-variant-calling-deepvariant
description: Deep learning-based variant calling with Google DeepVariant. Provides high accuracy for germline SNPs and indels from Illumina, PacBio, and ONT data. Use when calling variants with DeepVariant deep learning caller.
tool_type: cli
primary_tool: DeepVariant
---
## Version Compatibility
Reference examples tested with: GATK 4.5+, 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.
# DeepVariant Variant Calling
## Installation
**Goal:** Install DeepVariant via Docker or Singularity container.
**Approach:** Pull the pre-built container image matching the target platform (CPU or GPU).
### Docker (Recommended)
```bash
docker pull google/deepvariant:1.6.1
# Or with GPU support
docker pull google/deepvariant:1.6.1-gpu
```
### Singularity
```bash
singularity pull docker://google/deepvariant:1.6.1
```
## Basic Usage
**Goal:** Call germline variants from aligned reads using DeepVariant's deep learning model.
**Approach:** Run the all-in-one `run_deepvariant` wrapper specifying model type, reference, reads, and output paths.
**"Call variants with DeepVariant"** → Convert aligned read pileups into image tensors, classify with a CNN, and output genotyped VCF.
### One-Step Run (run_deepvariant)
```bash
docker run -v "${PWD}:/input" -v "${PWD}/output:/output" \
google/deepvariant:1.6.1 \
/opt/deepvariant/bin/run_deepvariant \
--model_type=WGS \
--ref=/input/reference.fa \
--reads=/input/sample.bam \
--output_vcf=/output/sample.vcf.gz \
--output_gvcf=/output/sample.g.vcf.gz \
--num_shards=16
```
### Model Types
| Model | Data Type | Use Case |
|-------|-----------|----------|
| `WGS` | Illumina WGS | Whole genome sequencing |
| `WES` | Illumina WES | Whole exome/targeted |
| `PACBIO` | PacBio HiFi | Long-read HiFi |
| `ONT_R104` | ONT R10.4 | Oxford Nanopore |
| `HYBRID_PACBIO_ILLUMINA` | Mixed | Hybrid assemblies |
## Step-by-Step Workflow
**Goal:** Run DeepVariant in three explicit stages for more control over intermediate outputs.
**Approach:** Generate pileup image tensors (make_examples), classify with the CNN (call_variants), then merge and genotype (postprocess_variants).
For more control, run each step separately:
### Step 1: Make Examples
```bash
docker run -v "${PWD}:/data" google/deepvariant:1.6.1 \
/opt/deepvariant/bin/make_examples \
--mode calling \
--ref /data/reference.fa \
--reads /data/sample.bam \
--examples /data/examples.tfrecord.gz \
--gvcf /data/gvcf.tfrecord.gz
```
### Step 2: Call Variants
```bash
docker run -v "${PWD}:/data" google/deepvariant:1.6.1 \
/opt/deepvariant/bin/call_variants \
--outfile /data/call_variants.tfrecord.gz \
--examples /data/examples.tfrecord.gz \
--checkpoint /opt/models/wgs/model.ckpt
```
### Step 3: Postprocess Variants
```bash
docker run -v "${PWD}:/data" google/deepvariant:1.6.1 \
/opt/deepvariant/bin/postprocess_variants \
--ref /data/reference.fa \
--infile /data/call_variants.tfrecord.gz \
--outfile /data/output.vcf.gz \
--gvcf_outfile /data/output.g.vcf.gz \
--nonvariant_site_tfrecord_path /data/gvcf.tfrecord.gz
```
## GPU Acceleration
**Goal:** Speed up DeepVariant inference using GPU hardware.
**Approach:** Use the GPU-enabled container image with Docker `--gpus` flag.
```bash
docker run --gpus all -v "${PWD}:/data" \
google/deepvariant:1.6.1-gpu \
/opt/deepvariant/bin/run_deepvariant \
--model_type=WGS \
--ref=/data/reference.fa \
--reads=/data/sample.bam \
--output_vcf=/data/output.vcf.gz \
--num_shards=16
```
## PacBio HiFi Calling
**Goal:** Call variants from PacBio HiFi long reads.
**Approach:** Use the PACBIO model type which is trained on HiFi read characteristics.
```bash
docker run -v "${PWD}:/data" google/deepvariant:1.6.1 \
/opt/deepvariant/bin/run_deepvariant \
--model_type=PACBIO \
--ref=/data/reference.fa \
--reads=/data/hifi_aligned.bam \
--output_vcf=/data/hifi_variants.vcf.gz \
--num_shards=16
```
## ONT Calling
**Goal:** Call variants from Oxford Nanopore long reads.
**Approach:** Use the ONT_R104 model type trained on Nanopore R10.4 chemistry.
```bash
docker run -v "${PWD}:/data" google/deepvariant:1.6.1 \
/opt/deepvariant/bin/run_deepvariant \
--model_type=ONT_R104 \
--ref=/data/reference.fa \
--reads=/data/ont_aligned.bam \
--output_vcf=/data/ont_variants.vcf.gz \
--num_shards=16
```
## Exome/Targeted Sequencing
**Goal:** Call variants from exome or targeted panel data.
**Approach:** Use WES model type with a BED file restricting calling to target regions.
```bash
docker run -v "${PWD}:/data" google/deepvariant:1.6.1 \
/opt/deepvariant/bin/run_deepvariant \
--model_type=WES \
--ref=/data/reference.fa \
--reads=/data/exome.bam \
--regions=/data/targets.bed \
--output_vcf=/data/exome_variants.vcf.gz \
--num_shards=8
```
## Joint Calling with GLnexus
**Goal:** Perform joint genotyping across a cohort from DeepVariant gVCFs.
**Approach:** Generate per-sample gVCFs, then merge and jointly genotype with GLnexus using a DeepVariant-specific config.
For multi-sample cohorts, use gVCFs with GLnexus:
```bash
# Generate gVCFs for each sample
for bam in *.bam; do
sample=$(basename $bam .bam)
docker run -v "${PWD}:/data" google/deepvariant:1.6.1 \
/opt/deepvariant/bin/run_deepvariant \
--model_type=WGS \
--ref=/data/reference.fa \
--reads=/data/$bam \
--output_vcf=/data/${sample}.vcf.gz \
--output_gvcf=/data/${sample}.g.vcf.gz \
--num_shards=16
done
# Joint genotyping with GLnexus
docker run -v "${PWD}:/data" quay.io/mlin/glnexus:v1.4.1 \
/usr/local/bin/glnexus_cli \
--config DeepVariantWGS \
/data/*.g.vcf.gz \
| bcftools view - -Oz -o cohort.vcf.gz
```
## GLnexus Configurations
| Config | Use Case |
|--------|----------|
| `DeepVariantWGS` | Illumina WGS |
| `DeepVariantWES` | Illumina exome |
| `DeepVariant_unfiltered` | Keep all variants |
## Output Quality Metrics
**Goal:** Assess the quality of DeepVariant calls.
**Approach:** Generate summary statistics with bcftools stats and check Ti/Tv ratio as a quality indicator.
```bash
# Variant statistics
bcftools stats output.vcf.gz > stats.txt
# Filter by quality
bcftools view -i 'QUAL>20 && FMT/GQ>20' output.vcf.gz -Oz -o filtered.vcf.gz
# Ti/Tv ratio (expect ~2.0-2.1 for WGS)
bcftools stats output.vcf.gz | grep TSTV
```
## Benchmarking Against Truth Set
**Goal:** Evaluate DeepVariant accuracy against a GIAB truth set.
**Approach:** Run hap.py to compute precision, recall, and F1 for SNPs and indels.
```bash
# Using hap.py for GIAB benchmarking
docker run -v "${PWD}:/data" jmcdani20/hap.py:latest \
/opt/hap.py/bin/hap.py \
/data/HG002_GRCh38_truth.vcf.gz \
/data/deepvariant_output.vcf.gz \
-r /data/reference.fa \
-o /data/benchmark \
--threads 16
```
## Complete Workflow Script
**Goal:** Run DeepVariant end-to-end with indexing and statistics in a single script.
**Approach:** Wrap run_deepvariant, bcftools index, and bcftools stats in a parameterized shell script.
```bash
#!/bin/bash
set -euo pipefail
BAM=$1
REFERENCE=$2
OUTPUT_PREFIX=$3
MODEL_TYPE=${4:-WGS}
THREADS=${5:-16}
echo "=== DeepVariant: ${MODEL_TYPE} mode ==="
docker run -v "${PWD}:/data" google/deepvariant:1.6.1 \
/opt/deepvariant/bin/run_deepvariant \
--model_type=${MODEL_TYPE} \
--ref=/data/${REFERENCE} \
--reads=/data/${BAM} \
--output_vcf=/data/${OUTPUT_PREFIX}.vcf.gz \
--output_gvcf=/data/${OUTPUT_PREFIX}.g.vcf.gz \
--intermediate_results_dir=/data/${OUTPUT_PREFIX}_tmp \
--num_shards=${THREADS}
echo "=== Indexing ==="
bcftools index -t ${OUTPUT_PREFIX}.vcf.gz
bcftools index -t ${OUTPUT_PREFIX}.g.vcf.gz
echo "=== Statistics ==="
bcftools stats ${OUTPUT_PREFIX}.vcf.gz > ${OUTPUT_PREFIX}_stats.txt
echo "=== Complete ==="
echo "VCF: ${OUTPUT_PREFIX}.vcf.gz"
echo "gVCF: ${OUTPUT_PREFIX}.g.vcf.gz"
```
## Comparison with Other Callers
| Caller | Speed | Accuracy | Best For |
|--------|-------|----------|----------|
| DeepVariant | Moderate | Highest | Production, benchmarking |
| GATK HaplotypeCaller | Moderate | High | GATK ecosystem |
| bcftools | Fast | Good | Quick analysis |
| Clair3 | Fast | High | Long reads |
## Resource Requirements
| Data Type | Memory | CPU Time (30x WGS) |
|-----------|--------|-------------------|
| WGS | 64 GB | ~4-6 hours |
| WES | 32 GB | ~30 min |
| With GPU | 32 GB | ~1-2 hours (WGS) |
## Related Skills
- variant-calling/gatk-variant-calling - GATK alternative
- variant-calling/variant-calling - bcftools calling
- long-read-sequencing/clair3-variants - Long-read alternative
- variant-calling/filtering-best-practices - Post-calling filtering
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