Agent skill

tooluniverse-variant-analysis

Production-ready VCF processing, variant annotation, mutation analysis, and structural variant (SV/CNV) interpretation for bioinformatics questions. Parses VCF files (streaming, large files), classifies mutation types (missense, nonsense, synonymous, frameshift, splice, intronic, intergenic) and structural variants (deletions, duplications, inversions, translocations), applies VAF/depth/quality/consequence filters, annotates with ClinVar/dbSNP/gnomAD/CADD via ToolUniverse, interprets SV/CNV clinical significance using ClinGen dosage sensitivity scores, computes variant statistics, and generates reports. Solves questions like "What fraction of variants with VAF < 0.3 are missense?", "How many non-reference variants remain after filtering intronic/intergenic?", "What is the pathogenicity of this deletion affecting BRCA1?", or "Which dosage-sensitive genes overlap this CNV?". Use when processing VCF files, annotating variants, filtering by VAF/depth/consequence, classifying mutations, interpreting structural variants, assessing CNV pathogenicity, comparing cohorts, or answering variant analysis questions.

View SKILL.md on GitHub Repository
Stars 2,009
Forks 275

Install this agent skill to your Project

npx add-skill https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills/tree/main/skills/tooluniverse-variant-analysis

SKILL.md

Variant Analysis and Annotation

Production-ready VCF processing and variant annotation skill combining local bioinformatics computation with ToolUniverse database integration. Designed to answer bioinformatics analysis questions about VCF data, mutation classification, variant filtering, and clinical annotation.

When to Use This Skill

Triggers:

  • User provides a VCF file (SNV/indel or SV) and asks questions about its contents
  • Questions about variant allele frequency (VAF) filtering
  • Mutation type classification queries (missense, nonsense, synonymous, etc.)
  • Structural variant interpretation requests (deletions, duplications, CNVs)
  • Variant annotation requests (ClinVar, gnomAD, CADD, dbSNP)
  • CNV pathogenicity assessment using ClinGen dosage sensitivity
  • Cohort comparison questions
  • Population frequency filtering (SNVs or SVs)
  • Intronic/intergenic variant filtering
  • Gene dosage sensitivity queries

Example Questions:

  • "What fraction of variants with VAF < 0.3 are annotated as missense mutations?"
  • "After filtering intronic/intergenic variants, how many non-reference variants remain?"
  • "What is the clinical significance of this deletion affecting BRCA1?"
  • "Which dosage-sensitive genes overlap this 500kb duplication on chr17?"
  • "How many variants have clinical significance annotations?"
  • "Compare variant counts between samples"

Core Capabilities

Capability Description
VCF Parsing Pure Python + cyvcf2 parsers. VCF 4.x, gzipped, multi-sample, SNV/indel/SV
Mutation Classification Maps SO terms, SnpEff ANN, VEP CSQ, GATK Funcotator to standard types
VAF Extraction Handles AF, AD, AO/RO, NR/NV, INFO AF formats
Filtering VAF, depth, quality, PASS, variant type, mutation type, consequence, chromosome, SV size
Statistics Ti/Tv ratio, per-sample VAF/depth stats, mutation type distribution, SV size distribution
Annotation MyVariant.info (aggregates ClinVar, dbSNP, gnomAD, CADD, SIFT, PolyPhen)
SV/CNV Analysis gnomAD SV population frequencies, DGVa/dbVar known SVs, ClinGen dosage sensitivity
Clinical Interpretation ACMG/ClinGen CNV pathogenicity classification using haploinsufficiency/triplosensitivity scores
DataFrame Convert to pandas for advanced analytics
Reporting Markdown reports with tables and statistics, SV clinical reports

Workflow Overview

Input VCF File (SNVs/indels or SVs)
    |
    v
Phase 1: Parse VCF
    |-- Pure Python parser (any VCF 4.x)
    |-- cyvcf2 parser (faster, C-based)
    |-- Extract: CHROM, POS, REF, ALT, QUAL, FILTER, INFO, FORMAT, samples
    |-- Extract per-sample: GT, VAF, depth
    |-- Extract annotations from INFO (ANN, CSQ, FUNCOTATION)
    |-- Detect variant class: SNV/indel vs SV/CNV
    |
    v
Phase 2: Classify Variants
    |-- Variant type: SNV, INS, DEL, MNV, COMPLEX, SV
    |-- Mutation type: missense, nonsense, synonymous, frameshift, splice, etc.
    |-- Impact: HIGH, MODERATE, LOW, MODIFIER
    |-- SV type: DEL, DUP, INV, BND, CNV (if structural variant)
    |
    v
Phase 3: Apply Filters
    |-- VAF range (min/max)
    |-- Read depth minimum
    |-- Quality threshold
    |-- PASS only
    |-- Variant/mutation type inclusion/exclusion
    |-- Consequence exclusion (intronic, intergenic)
    |-- Population frequency range
    |-- Chromosome selection
    |-- SV size range (for structural variants)
    |
    v
Phase 4: Compute Statistics
    |-- Variant type distribution
    |-- Mutation type distribution
    |-- Impact distribution
    |-- Chromosome distribution
    |-- Ti/Tv ratio (for SNVs)
    |-- Per-sample VAF/depth stats
    |-- Gene mutation counts
    |-- SV size distribution (for structural variants)
    |
    v
Phase 5: Annotate with ToolUniverse (optional)
    |-- MyVariant.info: ClinVar, dbSNP, gnomAD, CADD, SIFT, PolyPhen
    |-- dbSNP: Population frequencies, gene associations
    |-- gnomAD: Population allele frequencies
    |-- Ensembl VEP: Consequence prediction
    |
    v
Phase 6: Generate Report / Answer Question
    |-- Markdown report with tables
    |-- Direct answer to specific question
    |-- DataFrame for downstream analysis
    |
    v
Phase 7: Structural Variant & CNV Analysis (if SV/CNV detected)
    |-- Annotate with gnomAD SV population frequencies
    |-- Query DGVa/dbVar for known SVs (Ensembl)
    |-- Identify affected genes
    |-- Query ClinGen dosage sensitivity (HI/TS scores)
    |-- Classify pathogenicity (Pathogenic/Likely Pathogenic/VUS/Benign)
    |-- Generate SV clinical report with ACMG/ClinGen guidelines

Phase Summaries

Phase 1: VCF Parsing

Use pandas for:

  • Reading VCF as structured data
  • Quick exploratory analysis
  • When you need to manipulate columns and rows

Use python_implementation tools for:

  • Production parsing with annotation extraction
  • Multi-sample VCF handling
  • VAF extraction from FORMAT fields
  • Large file streaming

Key functions:

python
vcf_data = parse_vcf("input.vcf")           # Pure Python (always works)
vcf_data = parse_vcf_cyvcf2("input.vcf")    # Fast C-based (if installed)
df = variants_to_dataframe(vcf_data.variants, sample="TUMOR")  # For pandas

Phase 2: Variant Classification

Automatic classification from annotations:

  • SnpEff ANN field
  • VEP CSQ field
  • GATK Funcotator FUNCOTATION field
  • Standard INFO keys: EFFECT, EFF, TYPE

Mutation types supported: missense, nonsense, synonymous, frameshift, splice_site, splice_region, inframe_insertion, inframe_deletion, intronic, intergenic, UTR_5, UTR_3, upstream, downstream, stop_lost, start_lost

See references/mutation_classification_guide.md for full details

Phase 3: Filtering

Common filtering patterns:

python
# Somatic-like variants
criteria = FilterCriteria(
    min_vaf=0.05, max_vaf=0.95,
    min_depth=20, pass_only=True,
    exclude_consequences=["intronic", "intergenic", "upstream", "downstream"]
)

# High-confidence germline
criteria = FilterCriteria(
    min_vaf=0.25, min_depth=30, pass_only=True,
    chromosomes=["1", "2", ..., "22", "X", "Y"]
)

# Rare pathogenic candidates
criteria = FilterCriteria(
    min_depth=20, pass_only=True,
    mutation_types=["missense", "nonsense", "frameshift"]
)

See references/vcf_filtering.md for all filter options

Phase 4: Statistics

Use pandas for:

  • Complex aggregations (groupby, pivot tables)
  • Custom statistical tests
  • Data exploration

Use python_implementation for:

  • Standard variant statistics (Ti/Tv, type distribution)
  • Per-sample VAF/depth summary
  • Quick mutation type counts

Phase 5: ToolUniverse Annotation

When to use ToolUniverse annotation tools:

  1. ClinVar clinical significance: Use MyVariant.info or dbSNP tools
  2. Population frequencies: Use MyVariant.info (aggregates gnomAD, ExAC, 1000G)
  3. Pathogenicity scores: Use MyVariant.info (aggregates CADD, SIFT, PolyPhen)
  4. Consequence prediction: Use Ensembl VEP tools

Best practices:

  • Annotate variants with rsIDs first (most reliable)
  • Use MyVariant.info for batch annotation (aggregates multiple sources)
  • Limit to top variants (max_annotate=50-100) to respect rate limits
  • Query dbSNP/gnomAD directly for specific use cases

Key tools:

  • MyVariant_query_variants: Batch annotation (ClinVar, dbSNP, gnomAD, CADD)
  • dbsnp_get_variant_by_rsid: Population frequencies
  • gnomad_get_variant: Basic variant metadata
  • EnsemblVEP_annotate_rsid: Consequence prediction

See references/annotation_guide.md for detailed examples

Phase 6: Report Generation

Report includes:

  1. Summary Statistics (total variants, type counts, Ti/Tv)
  2. Mutation Type Distribution (table with counts and percentages)
  3. Impact Distribution
  4. Chromosome Distribution
  5. VAF Distribution (per-sample)
  6. Clinical Significance
  7. Top Mutated Genes
  8. Variant Annotations (ClinVar-annotated variants)

Phase 7: Structural Variant & CNV Analysis

When VCF contains SV calls (SVTYPE=DEL/DUP/INV/BND):

  1. Identify affected genes (from VCF annotation or coordinate overlap)
  2. Query ClinGen dosage sensitivity:
    python
    clingen = ClinGen_dosage_by_gene(gene_symbol="BRCA1")
# Returns: haploinsufficiency_score, triplosensitivity_score
  3. Check population frequency:
    python
    gnomad_sv = gnomad_get_sv_by_gene(gene_symbol="BRCA1")
# Returns: SVs with AF, AC, AN
  4. Classify pathogenicity:
    • Pathogenic: Deletion + HI score = 3, AF < 0.0001
    • Likely Pathogenic: Deletion + HI score = 2, AF < 0.001
    • VUS: HI/TS score = 0-1, AF 0.001-0.01
    • Benign: AF > 0.01

ClinGen dosage score interpretation:

  • 3: Sufficient evidence for dosage pathogenicity (HIGH impact)
  • 2: Some evidence (MODERATE impact)
  • 1: Little evidence (LOW impact)
  • 0: No evidence (MINIMAL impact)
  • 40: Dosage sensitivity unlikely

See references/sv_cnv_analysis.md for full SV workflow

Answering BixBench Questions

Pattern 1: VAF + Mutation Type Fraction

Question: "What fraction of variants with VAF < X are annotated as Y mutations?"

python
result = answer_vaf_mutation_fraction(
    vcf_path="input.vcf",
    max_vaf=0.3,
    mutation_type="missense",
    sample="TUMOR"
)
# Returns: fraction, total_below_vaf, matching_mutation_type

Pattern 2: Cohort Comparison

Question: "What is the difference in mutation frequency between cohorts?"

python
result = answer_cohort_comparison(
    vcf_paths=["cohort1.vcf", "cohort2.vcf"],
    mutation_type="missense",
    cohort_names=["Treatment", "Control"]
)
# Returns: cohorts, frequency_difference

Pattern 3: Filter and Count

Question: "After filtering X, how many Y remain?"

python
result = answer_non_reference_after_filter(
    vcf_path="input.vcf",
    exclude_intronic_intergenic=True
)
# Returns: total_input, non_reference, remaining

ToolUniverse Tools Reference

SNV/Indel Annotation

Tool When to Use Parameters Response
MyVariant_query_variants Batch annotation query (rsID/HGVS) ClinVar, dbSNP, gnomAD, CADD
dbsnp_get_variant_by_rsid Population frequencies rsid Frequencies, clinical significance
gnomad_get_variant gnomAD metadata variant_id (CHR-POS-REF-ALT) Basic variant info
EnsemblVEP_annotate_rsid Consequence prediction variant_id (rsID) Transcript impact

Structural Variant Annotation

Tool When to Use Parameters Response
gnomad_get_sv_by_gene SV population frequency gene_symbol SVs with AF, AC, AN
gnomad_get_sv_by_region Regional SV search chrom, start, end SVs in region
ClinGen_dosage_by_gene Dosage sensitivity gene_symbol HI/TS scores, disease
ClinGen_dosage_region_search Dosage-sensitive genes in region chromosome, start, end All genes with HI/TS scores
ensembl_get_structural_variants Known SVs from DGVa/dbVar chrom, start, end, species Clinical significance

See references/annotation_guide.md for detailed tool usage examples

Common Use Patterns

Pattern 1: Quick VCF Summary

Parse VCF, compute statistics, generate report.

python
report = variant_analysis_pipeline("input.vcf", output_file="report.md")

Pattern 2: Filtered Analysis

Parse VCF, apply multi-criteria filter, compute statistics on filtered set.

python
report = variant_analysis_pipeline(
    vcf_path="input.vcf",
    filters=FilterCriteria(min_vaf=0.1, min_depth=20, pass_only=True),
    output_file="filtered_report.md"
)

Pattern 3: Annotated Report

Parse VCF, annotate top variants with ClinVar/gnomAD/CADD, generate clinical report.

python
report = variant_analysis_pipeline(
    vcf_path="input.vcf",
    annotate=True,
    max_annotate=50,
    output_file="annotated_report.md"
)

Pattern 4: BixBench Question Answering

Parse VCF, apply specific filters, compute targeted statistics to answer precise questions.

python
result = answer_vaf_mutation_fraction(
    vcf_path="input.vcf",
    max_vaf=0.3,
    mutation_type="missense"
)

Pattern 5: Cohort Comparison

Parse multiple VCFs, compare mutation frequencies across cohorts.

python
result = answer_cohort_comparison(
    vcf_paths=["cohort1.vcf", "cohort2.vcf"],
    mutation_type="missense"
)

When to Use pandas vs python_implementation

Use pandas when:

  • You need to read VCF as a flat table
  • You want to do custom aggregations (groupby, pivot)
  • You need to join with other data
  • You're doing exploratory data analysis
  • You want to export to CSV/Excel

Use python_implementation when:

  • You need production-grade VCF parsing
  • You need to extract INFO annotations (ANN, CSQ)
  • You need per-sample VAF/depth extraction
  • You need to classify mutation types
  • You need standard variant statistics (Ti/Tv)
  • You need to integrate with ToolUniverse annotation

Best approach: Use python_implementation for parsing/classification, then convert to DataFrame for custom analysis:

python
# Parse and classify
vcf_data = parse_vcf("input.vcf")
passing, failing = filter_variants(vcf_data.variants, criteria)

# Convert to DataFrame for custom analysis
df = variants_to_dataframe(passing, sample="TUMOR")

# Now use pandas
missense_high_vaf = df[(df['mutation_type'] == 'missense') & (df['vaf'] >= 0.3)]

Limitations

  • VCF annotation required for mutation classification: If VCF has no ANN/CSQ/FUNCOTATION in INFO, mutation types will be "unknown" until ToolUniverse annotation is applied
  • Multi-allelic variants: Parser takes first ALT allele for type classification
  • ToolUniverse annotation rate: API-based, limited to ~100 variants per batch by default to respect rate limits
  • gnomAD tool: Returns basic metadata only (not full allele frequencies); use MyVariant.info for gnomAD AF
  • Large VCFs: Pure Python parser streams line-by-line; cyvcf2 is recommended for files with >100K variants

Reference Documentation

  • references/vcf_filtering.md: Complete filter options and examples
  • references/mutation_classification_guide.md: Detailed mutation type classification rules
  • references/annotation_guide.md: ToolUniverse annotation workflows with examples
  • references/sv_cnv_analysis.md: Complete SV/CNV interpretation workflow

Utility Scripts

  • scripts/parse_vcf.py: Standalone VCF parsing script
  • scripts/filter_variants.py: Command-line variant filtering
  • scripts/annotate_variants.py: Batch variant annotation

Quick Start

See QUICK_START.md for:

  • Python SDK examples (pipeline, question functions, individual tools)
  • MCP conversational examples
  • Common recipes (somatic analysis, clinical screening, population frequency)
  • Expected output formats
  • Troubleshooting guide

Recommended Agent Skills

Expand your agent's capabilities with these related and highly-rated skills.

FreedomIntelligence/OpenClaw-Medical-Skills

vcf-annotator

Annotate VCF variants with VEP, ClinVar, gnomAD frequencies, and ancestry-aware context. Generates prioritised variant reports.

2,009 275
Explore
FreedomIntelligence/OpenClaw-Medical-Skills

chemist-analyst

Analyzes events through chemistry lens using molecular structure, reaction mechanisms, thermodynamics, kinetics, and analytical techniques (spectroscopy, chromatography, mass spectrometry). Provides insights on chemical processes, material properties, reaction pathways, synthesis, and analytical methods. Use when: Chemical reactions, material analysis, synthesis planning, process optimization, environmental chemistry. Evaluates: Molecular structure, reaction mechanisms, yield, selectivity, safety, environmental impact.

2,009 275
Explore
FreedomIntelligence/OpenClaw-Medical-Skills

bio-alignment-io

Read, write, and convert multiple sequence alignment files using Biopython Bio.AlignIO. Supports Clustal, PHYLIP, Stockholm, FASTA, Nexus, and other alignment formats for phylogenetics and conservation analysis. Use when reading, writing, or converting alignment file formats.

2,009 275
Explore
FreedomIntelligence/OpenClaw-Medical-Skills

sleep-analyzer

分析睡眠数据、识别睡眠模式、评估睡眠质量,并提供个性化睡眠改善建议。支持与其他健康数据的关联分析。

2,009 275
Explore
FreedomIntelligence/OpenClaw-Medical-Skills

metabolomics-workbench-database

Access NIH Metabolomics Workbench via REST API (4,200+ studies). Query metabolites, RefMet nomenclature, MS/NMR data, m/z searches, study metadata, for metabolomics and biomarker discovery.

2,009 275
Explore
FreedomIntelligence/OpenClaw-Medical-Skills

bio-hi-c-analysis-matrix-operations

Balance, normalize, and transform Hi-C contact matrices using cooler and cooltools. Apply iterative correction (ICE), compute expected values, and generate observed/expected matrices. Use when normalizing or transforming Hi-C matrices.

2,009 275
Explore

Didn't find tool you were looking for?

Be as detailed as possible for better results