mims-harvard/tooluniverse-gwas-snp-interpretation
plugin/skills/tooluniverse-gwas-snp-interpretation/SKILL.md
Interpret a single GWAS SNP across multiple databases — GWAS Catalog hits, LD/haplotype context, eQTL evidence, regulatory annotation, ClinVar pathogenicity, gnomAD frequency. Use for 'what does this SNP do', SNP-to-mechanism tracing, and resolving lead-SNP-vs-causal-variant ambiguity. Always considers LD structure before claiming a SNP is mechanistically responsible.
$ install --global
skillsauthnpx skillsauth add mims-harvard/tooluniverse tooluniverse-gwas-snp-interpretationInstall this skill globally with one command. Works with Claude Code, Cursor, and Windsurf.
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SKILL.md
- name:
- tooluniverse-gwas-snp-interpretation
- description:
- Interpret a single GWAS SNP across multiple databases — GWAS Catalog hits, LD/haplotype context, eQTL evidence, regulatory annotation, ClinVar pathogenicity, gnomAD frequency. Use for 'what does this SNP do', SNP-to-mechanism tracing, and resolving lead-SNP-vs-causal-variant ambiguity. Always considers LD structure before claiming a SNP is mechanistically responsible.
- disable-model-invocation:
- true
GWAS SNP Interpretation Skill
SNP interpretation: a GWAS hit is a REGION, not a single causal variant. The lead SNP may not be causal — it may be in LD with the causal variant. Always check LD structure and functional annotation before concluding a specific SNP is mechanistically responsible. Use LDlink_get_proxies(variant="rs...", population="EUR") to retrieve the high-R² LD proxies (needs a free LDLINK_TOKEN) — a proxy in a coding/regulatory region is a better mechanistic candidate than the lead SNP itself. Fine-mapping (SuSiE, FINEMAP credible sets) narrows the causal set but rarely identifies a single variant with certainty. L2G scores integrate eQTL, chromatin interaction, and distance data to predict the causal gene — a lead SNP mapping to gene A may actually regulate gene B 500 kb away via a distal enhancer.
LOOK UP DON'T GUESS: never assume a SNP's functional consequence, mapped gene, or population frequency — always call gwas_get_snp_by_id and OpenTargets_get_variant_info to retrieve current annotations.
Overview
Interpret genetic variants (SNPs) from GWAS studies by aggregating evidence from multiple sources to provide comprehensive clinical and biological context.
Use Cases:
- "Interpret rs7903146" (TCF7L2 diabetes variant)
- "What diseases is rs429358 associated with?" (APOE Alzheimer's variant)
- "Clinical significance of rs1801133" (MTHFR variant)
- "Is rs12913832 in any fine-mapped loci?" (Eye color variant)
What It Does
The skill provides a comprehensive interpretation of SNPs by:
- SNP Annotation: Retrieves basic variant information including genomic coordinates, alleles, functional consequence, and mapped genes
- Association Discovery: Finds all GWAS trait/disease associations with statistical significance
- Fine-Mapping Evidence: Identifies credible sets the variant belongs to (fine-mapped causal loci)
- Gene Mapping: Uses Locus-to-Gene (L2G) predictions to identify likely causal genes
- Clinical Summary: Aggregates evidence into actionable clinical significance
Workflow
User Input: rs7903146
↓
[1] SNP Lookup
→ Get location, consequence, MAF
→ gwas_get_snp_by_id
↓
[2] Association Search
→ Find all trait/disease associations
→ gwas_get_associations_for_snp
↓
[3] Fine-Mapping (Optional)
→ Get credible set membership
→ OpenTargets_get_variant_credible_sets
↓
[4] Gene Predictions
→ Extract L2G scores for causal genes
→ (embedded in credible sets)
↓
[5] Clinical Summary
→ Aggregate evidence
→ Identify key traits and genes
↓
Output: Comprehensive Interpretation Report
Data Sources
GWAS Catalog (EMBL-EBI)
- SNP annotations: Functional consequences, mapped genes, population frequencies
- Associations: P-values, effect sizes, study metadata
- Coverage: 350,000+ publications, 670,000+ associations
Open Targets Genetics
- Fine-mapping: Statistical credible sets from SuSiE, FINEMAP methods
- L2G predictions: Machine learning-based gene prioritization
- Colocalization: QTL evidence for causal genes
- Coverage: UK Biobank, FinnGen, and other large cohorts
Input Parameters
Required
rs_id(str): dbSNP rs identifier- Format: "rs" + number (e.g., "rs7903146")
- Must be valid rsID in GWAS Catalog
Optional
include_credible_sets(bool, default=True): Query fine-mapping data- True: Complete interpretation (slower, ~10-30s)
- False: Fast associations only (~2-5s)
p_threshold(float, default=5e-8): Genome-wide significance thresholdmax_associations(int, default=100): Maximum associations to retrieve
Output Format
Returns SNPInterpretationReport containing:
1. SNP Basic Info
{
'rs_id': 'rs7903146',
'chromosome': '10',
'position': 112998590,
'ref_allele': 'C',
'alt_allele': 'T',
'consequence': 'intron_variant',
'mapped_genes': ['TCF7L2'],
'maf': 0.293
}
2. Trait Associations
[
{
'trait': 'Type 2 diabetes',
'p_value': 1.2e-128,
'beta': '0.28 unit increase',
'study_id': 'GCST010555',
'pubmed_id': '33536258',
'effect_allele': 'T'
},
...
]
3. Credible Sets (Fine-Mapping)
[
{
'study_id': 'GCST90476118',
'trait': 'Renal failure',
'finemapping_method': 'SuSiE-inf',
'p_value': 3.5e-42,
'predicted_genes': [
{'gene': 'TCF7L2', 'score': 0.863}
],
'region': '10:112950000-113050000'
},
...
]
4. Clinical Significance
Genome-wide significant associations with 100 traits/diseases:
- Type 2 diabetes
- Diabetic retinopathy
- HbA1c levels
...
Identified in 20 fine-mapped loci.
Predicted causal genes: TCF7L2
Example Usage
See QUICK_START.md for platform-specific examples.
Tools Used
GWAS Catalog Tools
gwas_get_snp_by_id: Get SNP annotationgwas_get_associations_for_snp: Get all trait associations
Open Targets Tools
OpenTargets_get_variant_info: Get variant details with population frequenciesOpenTargets_get_variant_credible_sets: Get fine-mapping credible sets with L2G
Interpretation Guide
P-value Significance Levels
- p < 5e-8: Genome-wide significant (strong evidence)
- p < 5e-6: Suggestive (moderate evidence)
- p < 0.05: Nominal (weak evidence)
L2G Score Interpretation
- > 0.5: High confidence causal gene
- 0.1-0.5: Moderate confidence
- < 0.1: Low confidence
Clinical Actionability
- High: Multiple genome-wide significant associations + in credible sets + high L2G scores
- Moderate: Genome-wide significant associations but limited fine-mapping
- Low: Suggestive associations or limited replication
Limitations
- Variant ID Conversion: OpenTargets requires chr_pos_ref_alt format, which may need allele lookup
- Population Specificity: Associations may vary by ancestry
- Effect Sizes: Beta values are study-dependent (different phenotype scales)
- Causality: Associations don't prove causation; fine-mapping improves confidence
- Currency: Data reflects published GWAS; latest studies may not be included
Best Practices
- Use Full Interpretation: Enable
include_credible_sets=Truefor clinical decisions - Check Multiple Variants: Look at other variants in the same locus
- Validate Populations: Consider ancestry-specific effect sizes
- Review Publications: Check original studies for context
- Integrate Evidence: Combine with functional data, eQTLs, pQTLs
Technical Notes
Performance
- Fast mode (no credible sets): 2-5 seconds
- Full mode (with credible sets): 10-30 seconds
- Bottleneck: OpenTargets GraphQL API rate limits
Error Handling
- Invalid rs_id: Returns error message
- No associations: Returns empty list with note
- API failures: Graceful degradation (returns partial results)
Related Skills
- Gene Function Analysis: Interpret predicted causal genes
- Disease Ontology Lookup: Understand trait classifications
- PubMed Literature Search: Find original GWAS publications
- Variant Effect Prediction: Functional consequence analysis
References
- GWAS Catalog: https://www.ebi.ac.uk/gwas/
- Open Targets Genetics: https://genetics.opentargets.org/
- GWAS Significance Thresholds: Fadista et al. 2016
- L2G Method: Mountjoy et al. 2021 (Nature Genetics)
Version
- Version: 1.0.0
- Last Updated: 2026-02-13
- ToolUniverse Version: >= 1.0.0
- Tools Required: gwas_get_snp_by_id, gwas_get_associations_for_snp, OpenTargets_get_variant_credible_sets
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