OpenClaw-Medical-Skills protein-interaction-network-analysis
Analyze protein-protein interaction networks using STRING, BioGRID, and SASBDB databases. Maps protein identifiers, retrieves interaction networks with confidence scores, performs functional enrichment analysis (GO/KEGG/Reactome), and optionally includes structural data. No API key required for core functionality (STRING). Use when analyzing protein networks, discovering interaction partners, identifying functional modules, or studying protein complexes.
install
source · Clone the upstream repo
git clone https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills
Claude Code · Install into ~/.claude/skills/
T=$(mktemp -d) && git clone --depth=1 https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills "$T" && mkdir -p ~/.claude/skills && cp -r "$T/skills/tooluniverse-protein-interactions" ~/.claude/skills/freedomintelligence-openclaw-medical-skills-protein-interaction-network-analysis && rm -rf "$T"
OpenClaw · Install into ~/.openclaw/skills/
T=$(mktemp -d) && git clone --depth=1 https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills "$T" && mkdir -p ~/.openclaw/skills && cp -r "$T/skills/tooluniverse-protein-interactions" ~/.openclaw/skills/freedomintelligence-openclaw-medical-skills-protein-interaction-network-analysis && rm -rf "$T"
manifest:
skills/tooluniverse-protein-interactions/SKILL.mdsafety · automated scan (medium risk)
This is a pattern-based risk scan, not a security review. Our crawler flagged:
- pip install
- references .env files
Always read a skill's source content before installing. Patterns alone don't mean the skill is malicious — but they warrant attention.
source content
Protein Interaction Network Analysis
Comprehensive protein interaction network analysis using ToolUniverse tools. Analyzes protein networks through a 4-phase workflow: identifier mapping, network retrieval, enrichment analysis, and optional structural data.
Features
✅ Identifier Mapping - Convert protein names to database IDs (STRING, UniProt, Ensembl) ✅ Network Retrieval - Get interaction networks with confidence scores (0-1.0) ✅ Functional Enrichment - GO terms, KEGG pathways, Reactome pathways ✅ PPI Enrichment - Test if proteins form functional modules ✅ Structural Data - Optional SAXS/SANS solution structures (SASBDB) ✅ Fallback Strategy - STRING primary (no API key) → BioGRID secondary (if key available)
Databases Used
| Database | Coverage | API Key | Purpose |
|---|---|---|---|
| STRING | 14M+ proteins, 5,000+ organisms | ❌ Not required | Primary interaction source |
| BioGRID | 2.3M+ interactions, 80+ organisms | ✅ Required | Fallback, curated data |
| SASBDB | 2,000+ SAXS/SANS entries | ❌ Not required | Solution structures |
Quick Start
Basic Usage
from tooluniverse import ToolUniverse from python_implementation import analyze_protein_network # Initialize ToolUniverse tu = ToolUniverse() # Analyze protein network result = analyze_protein_network( tu=tu, proteins=["TP53", "MDM2", "ATM", "CHEK2"], species=9606, # Human confidence_score=0.7 # High confidence ) # Access results print(f"Mapped: {len(result.mapped_proteins)} proteins") print(f"Network: {result.total_interactions} interactions") print(f"Enrichment: {len(result.enriched_terms)} GO terms") print(f"PPI p-value: {result.ppi_enrichment.get('p_value', 1.0):.2e}")
Expected Output
🔍 Phase 1: Mapping 4 protein identifiers... ✅ Mapped 4/4 proteins (100.0%) 🕸️ Phase 2: Retrieving interaction network... ✅ STRING: Retrieved 6 interactions 🧬 Phase 3: Performing enrichment analysis... ✅ Found 245 enriched GO terms (FDR < 0.05) ✅ PPI enrichment significant (p=3.45e-05) ✅ Analysis complete!
Use Cases
1. Single Protein Analysis
Discover interaction partners for a protein of interest:
result = analyze_protein_network( tu=tu, proteins=["TP53"], # Single protein species=9606, confidence_score=0.7 ) # Top 5 partners will be in the network for edge in result.network_edges[:5]: print(f"{edge['preferredName_A']} ↔ {edge['preferredName_B']} " f"(score: {edge['score']})")
2. Protein Complex Validation
Test if proteins form a functional complex:
# DNA damage response proteins proteins = ["TP53", "ATM", "CHEK2", "BRCA1", "BRCA2"] result = analyze_protein_network(tu=tu, proteins=proteins) # Check PPI enrichment if result.ppi_enrichment.get("p_value", 1.0) < 0.05: print("✅ Proteins form functional module!") print(f" Expected edges: {result.ppi_enrichment['expected_number_of_edges']:.1f}") print(f" Observed edges: {result.ppi_enrichment['number_of_edges']}") else: print("⚠️ Proteins may be unrelated")
3. Pathway Discovery
Find enriched pathways for a protein set:
result = analyze_protein_network( tu=tu, proteins=["MAPK1", "MAPK3", "RAF1", "MAP2K1"], # MAPK pathway confidence_score=0.7 ) # Show top enriched processes print("\nTop Enriched Pathways:") for term in result.enriched_terms[:10]: print(f" {term['term']}: p={term['p_value']:.2e}, FDR={term['fdr']:.2e}")
4. Multi-Protein Network Analysis
Build complete interaction network for multiple proteins:
# Apoptosis regulators proteins = ["TP53", "BCL2", "BAX", "CASP3", "CASP9"] result = analyze_protein_network( tu=tu, proteins=proteins, confidence_score=0.7 ) # Export network for Cytoscape import pandas as pd df = pd.DataFrame(result.network_edges) df.to_csv("apoptosis_network.tsv", sep="\t", index=False)
5. With BioGRID Validation
Use BioGRID for experimentally validated interactions:
# Requires BIOGRID_API_KEY in environment result = analyze_protein_network( tu=tu, proteins=["TP53", "MDM2"], include_biogrid=True # Enable BioGRID fallback ) print(f"Primary source: {result.primary_source}") # "STRING" or "BioGRID"
6. Including Structural Data
Add SAXS/SANS solution structures:
result = analyze_protein_network( tu=tu, proteins=["TP53"], include_structure=True # Query SASBDB ) if result.structural_data: print(f"\nFound {len(result.structural_data)} SAXS/SANS entries:") for entry in result.structural_data: print(f" {entry.get('sasbdb_id')}: {entry.get('title')}")
Parameters
analyze_protein_network()
Parameters
analyze_protein_network()| Parameter | Type | Default | Description |
|---|---|---|---|
| ToolUniverse | Required | ToolUniverse instance |
| list[str] | Required | Protein identifiers (gene symbols, UniProt IDs) |
| int | 9606 | NCBI taxonomy ID (9606=human, 10090=mouse) |
| float | 0.7 | Min interaction confidence (0-1). 0.4=low, 0.7=high, 0.9=very high |
| bool | False | Use BioGRID if STRING fails (requires API key) |
| bool | False | Include SASBDB structural data (slower) |
| bool | True | Suppress ToolUniverse loading warnings |
Species IDs (Common)
- Homo sapiens (human)9606
- Mus musculus (mouse)10090
- Rattus norvegicus (rat)10116
- Drosophila melanogaster (fruit fly)7227
- Caenorhabditis elegans (worm)6239
- Danio rerio (zebrafish)7955
- Saccharomyces cerevisiae (yeast)559292
Confidence Score Guidelines
| Score | Level | Description | Use Case |
|---|---|---|---|
| 0.15 | Very low | All evidence | Exploratory, hypothesis generation |
| 0.4 | Low | Medium evidence | Default STRING threshold |
| 0.7 | High | Strong evidence | Recommended - reliable interactions |
| 0.9 | Very high | Strongest evidence | Core interactions only |
Results Structure
ProteinNetworkResult
Object
ProteinNetworkResult@dataclass class ProteinNetworkResult: # Phase 1: Identifier mapping mapped_proteins: List[Dict[str, Any]] mapping_success_rate: float # Phase 2: Network retrieval network_edges: List[Dict[str, Any]] total_interactions: int # Phase 3: Enrichment analysis enriched_terms: List[Dict[str, Any]] ppi_enrichment: Dict[str, Any] # Phase 4: Structural data (optional) structural_data: Optional[List[Dict[str, Any]]] # Metadata primary_source: str # "STRING" or "BioGRID" warnings: List[str]
Network Edge Format (STRING)
{ "stringId_A": "9606.ENSP00000269305", # Protein A STRING ID "stringId_B": "9606.ENSP00000258149", # Protein B STRING ID "preferredName_A": "TP53", # Protein A name "preferredName_B": "MDM2", # Protein B name "ncbiTaxonId": 9606, # Species "score": 0.999, # Combined confidence (0-1) "nscore": 0.0, # Neighborhood score "fscore": 0.0, # Gene fusion score "pscore": 0.0, # Phylogenetic profile score "ascore": 0.947, # Coexpression score "escore": 0.951, # Experimental score "dscore": 0.9, # Database score "tscore": 0.994 # Text mining score }
Enrichment Term Format
{ "category": "Process", # GO category "term": "GO:0006915", # GO term ID "description": "apoptotic process", # Term description "number_of_genes": 4, # Genes in your set "number_of_genes_in_background": 1234, # Genes in genome "p_value": 1.23e-05, # Enrichment p-value "fdr": 0.0012, # FDR correction "inputGenes": "TP53,MDM2,BAX,CASP3" # Matching genes }
Workflow Details
4-Phase Analysis Pipeline
┌─────────────────────────────────────────────────────────────┐ │ Phase 1: Identifier Mapping │ │ ─────────────────────────────────────────────────────────── │ │ STRING_map_identifiers() │ │ • Validates protein names exist in database │ │ • Converts to STRING IDs for consistency │ │ • Returns mapping success rate │ └─────────────────────────────────────────────────────────────┘ ↓ ┌─────────────────────────────────────────────────────────────┐ │ Phase 2: Network Retrieval │ │ ─────────────────────────────────────────────────────────── │ │ PRIMARY: STRING_get_network() (no API key needed) │ │ • Retrieves all pairwise interactions │ │ • Returns confidence scores by evidence type │ │ │ │ FALLBACK: BioGRID_get_interactions() (if enabled) │ │ • Used if STRING fails or for validation │ │ • Requires BIOGRID_API_KEY │ └─────────────────────────────────────────────────────────────┘ ↓ ┌─────────────────────────────────────────────────────────────┐ │ Phase 3: Enrichment Analysis │ │ ─────────────────────────────────────────────────────────── │ │ STRING_functional_enrichment() │ │ • GO terms (Process, Component, Function) │ │ • KEGG pathways │ │ • Reactome pathways │ │ • FDR-corrected p-values │ │ │ │ STRING_ppi_enrichment() │ │ • Tests if proteins interact more than random │ │ • Returns p-value for functional coherence │ └─────────────────────────────────────────────────────────────┘ ↓ ┌─────────────────────────────────────────────────────────────┐ │ Phase 4: Structural Data (Optional) │ │ ─────────────────────────────────────────────────────────── │ │ SASBDB_search_entries() │ │ • SAXS/SANS solution structures │ │ • Protein flexibility and conformations │ │ • Complements crystal/cryo-EM data │ └─────────────────────────────────────────────────────────────┘
Installation & Setup
Prerequisites
# Install ToolUniverse (if not already installed) pip install tooluniverse # Or with extras pip install tooluniverse[all]
Optional: BioGRID API Key
For BioGRID fallback functionality:
- Register for free API key: https://webservice.thebiogrid.org/
- Add to
file:.envBIOGRID_API_KEY=your_key_here
Skill Files
tooluniverse-protein-interactions/ ├── SKILL.md # This file ├── python_implementation.py # Main implementation ├── QUICK_START.md # Quick reference ├── DOMAIN_ANALYSIS.md # Design rationale ├── PHASE2_COMPLETE.md # Tool testing results ├── PHASE4_IMPLEMENTATION_COMPLETE.md └── KNOWN_ISSUES.md # ToolUniverse limitations
Known Limitations
1. ToolUniverse Verbose Output
Issue: ToolUniverse prints 40+ warning messages during analysis.
Workaround: Filter output when running:
python your_script.py 2>&1 | grep -v "Error loading tools"
See
KNOWN_ISSUES.md2. BioGRID Requires API Key
BioGRID fallback requires free API key. STRING works without any API key.
3. SASBDB May Have API Issues
SASBDB endpoints occasionally return errors. Structural data is optional.
Performance
Typical Execution Times
| Operation | Time | Notes |
|---|---|---|
| Identifier mapping | 1-2 sec | For 5 proteins |
| Network retrieval | 2-3 sec | Depends on network size |
| Enrichment analysis | 3-5 sec | For 374 terms |
| Full 4-phase analysis | 6-10 sec | Excluding ToolUniverse overhead |
Note: Add 4-8 seconds per tool call for ToolUniverse loading (framework limitation).
Optimization Tips
- Disable structural data if not needed:
include_structure=False - Use higher confidence scores to reduce network size:
confidence_score=0.9 - Filter output to avoid processing warning messages
- Reuse ToolUniverse instance across multiple analyses
Troubleshooting
"Error: 'protein_ids' is a required property"
✅ Fixed in this skill - All parameter names verified in Phase 2 testing.
No interactions found
- Check protein names are correct (case-sensitive)
- Try lower confidence score:
confidence_score=0.4 - Verify species ID is correct
- Check if proteins actually interact (not all proteins have known interactions)
BioGRID not working
- Ensure
is set in environmentBIOGRID_API_KEY - Check API key is valid at https://webservice.thebiogrid.org/
- BioGRID is optional - STRING works without it
Slow performance
- This is expected (see KNOWN_ISSUES.md)
- ToolUniverse framework reloads tools on every call
- Use output filtering to reduce processing time
Examples
See
python_implementation.py
- Complete TP53 network analysisexample_tp53_analysis()
- Main function with all optionsanalyze_protein_network()
- Result data structureProteinNetworkResult
References
- STRING: https://string-db.org/ (14M+ proteins, 5,000+ organisms)
- BioGRID: https://thebiogrid.org/ (2.3M+ interactions, experimentally validated)
- SASBDB: https://www.sasbdb.org/ (2,000+ SAXS/SANS entries)
- ToolUniverse: https://github.com/mims-harvard/ToolUniverse
Support
For issues with:
- This skill: Check KNOWN_ISSUES.md and troubleshooting section
- ToolUniverse framework: See TOOLUNIVERSE_BUG_REPORT.md
- API errors: Check database status pages (STRING, BioGRID, SASBDB)
License
Same as ToolUniverse framework license.