Agent skill

tooluniverse

Use this skill when working with scientific research tools and workflows across bioinformatics, cheminformatics, genomics, structural biology, proteomics, and drug discovery. This skill provides access to 600+ scientific tools including machine learning models, datasets, APIs, and analysis packages. Use when searching for scientific tools, executing computational biology workflows, composing multi-step research pipelines, accessing databases like OpenTargets/PubChem/UniProt/PDB/ChEMBL, performing tool discovery for research tasks, or integrating scientific computational resources into LLM workflows.

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Install this agent skill to your Project

npx add-skill https://github.com/lifangda/claude-plugins/tree/main/cli-tool/skills-library/scientific-computing/other-packages/tooluniverse

SKILL.md

ToolUniverse

Overview

ToolUniverse is a unified ecosystem that enables AI agents to function as research scientists by providing standardized access to 600+ scientific resources. Use this skill to discover, execute, and compose scientific tools across multiple research domains including bioinformatics, cheminformatics, genomics, structural biology, proteomics, and drug discovery.

Key Capabilities:

  • Access 600+ scientific tools, models, datasets, and APIs
  • Discover tools using natural language, semantic search, or keywords
  • Execute tools through standardized AI-Tool Interaction Protocol
  • Compose multi-step workflows for complex research problems
  • Integration with Claude Desktop/Code via Model Context Protocol (MCP)

When to Use This Skill

Use this skill when:

  • Searching for scientific tools by function or domain (e.g., "find protein structure prediction tools")
  • Executing computational biology workflows (e.g., disease target identification, drug discovery, genomics analysis)
  • Accessing scientific databases (OpenTargets, PubChem, UniProt, PDB, ChEMBL, KEGG, etc.)
  • Composing multi-step research pipelines (e.g., target discovery → structure prediction → virtual screening)
  • Working with bioinformatics, cheminformatics, or structural biology tasks
  • Analyzing gene expression, protein sequences, molecular structures, or clinical data
  • Performing literature searches, pathway enrichment, or variant annotation
  • Building automated scientific research workflows

Quick Start

Basic Setup

python
from tooluniverse import ToolUniverse

# Initialize and load tools
tu = ToolUniverse()
tu.load_tools()  # Loads 600+ scientific tools

# Discover tools
tools = tu.run({
    "name": "Tool_Finder_Keyword",
    "arguments": {
        "description": "disease target associations",
        "limit": 10
    }
})

# Execute a tool
result = tu.run({
    "name": "OpenTargets_get_associated_targets_by_disease_efoId",
    "arguments": {"efoId": "EFO_0000537"}  # Hypertension
})

Model Context Protocol (MCP)

For Claude Desktop/Code integration:

bash
tooluniverse-smcp

Core Workflows

1. Tool Discovery

Find relevant tools for your research task:

Three discovery methods:

  • Tool_Finder - Embedding-based semantic search (requires GPU)
  • Tool_Finder_LLM - LLM-based semantic search (no GPU required)
  • Tool_Finder_Keyword - Fast keyword search

Example:

python
# Search by natural language description
tools = tu.run({
    "name": "Tool_Finder_LLM",
    "arguments": {
        "description": "Find tools for RNA sequencing differential expression analysis",
        "limit": 10
    }
})

# Review available tools
for tool in tools:
    print(f"{tool['name']}: {tool['description']}")

See references/tool-discovery.md for:

  • Detailed discovery methods and search strategies
  • Domain-specific keyword suggestions
  • Best practices for finding tools

2. Tool Execution

Execute individual tools through the standardized interface:

Example:

python
# Execute disease-target lookup
targets = tu.run({
    "name": "OpenTargets_get_associated_targets_by_disease_efoId",
    "arguments": {"efoId": "EFO_0000616"}  # Breast cancer
})

# Get protein structure
structure = tu.run({
    "name": "AlphaFold_get_structure",
    "arguments": {"uniprot_id": "P12345"}
})

# Calculate molecular properties
properties = tu.run({
    "name": "RDKit_calculate_descriptors",
    "arguments": {"smiles": "CCO"}  # Ethanol
})

See references/tool-execution.md for:

  • Real-world execution examples across domains
  • Tool parameter handling and validation
  • Result processing and error handling
  • Best practices for production use

3. Tool Composition and Workflows

Compose multiple tools for complex research workflows:

Drug Discovery Example:

python
# 1. Find disease targets
targets = tu.run({
    "name": "OpenTargets_get_associated_targets_by_disease_efoId",
    "arguments": {"efoId": "EFO_0000616"}
})

# 2. Get protein structures
structures = []
for target in targets[:5]:
    structure = tu.run({
        "name": "AlphaFold_get_structure",
        "arguments": {"uniprot_id": target['uniprot_id']}
    })
    structures.append(structure)

# 3. Screen compounds
hits = []
for structure in structures:
    compounds = tu.run({
        "name": "ZINC_virtual_screening",
        "arguments": {
            "structure": structure,
            "library": "lead-like",
            "top_n": 100
        }
    })
    hits.extend(compounds)

# 4. Evaluate drug-likeness
drug_candidates = []
for compound in hits:
    props = tu.run({
        "name": "RDKit_calculate_drug_properties",
        "arguments": {"smiles": compound['smiles']}
    })
    if props['lipinski_pass']:
        drug_candidates.append(compound)

See references/tool-composition.md for:

  • Complete workflow examples (drug discovery, genomics, clinical)
  • Sequential and parallel tool composition patterns
  • Output processing hooks
  • Workflow best practices

Scientific Domains

ToolUniverse supports 600+ tools across major scientific domains:

Bioinformatics:

  • Sequence analysis, alignment, BLAST
  • Gene expression (RNA-seq, DESeq2)
  • Pathway enrichment (KEGG, Reactome, GO)
  • Variant annotation (VEP, ClinVar)

Cheminformatics:

  • Molecular descriptors and fingerprints
  • Drug discovery and virtual screening
  • ADMET prediction and drug-likeness
  • Chemical databases (PubChem, ChEMBL, ZINC)

Structural Biology:

  • Protein structure prediction (AlphaFold)
  • Structure retrieval (PDB)
  • Binding site detection
  • Protein-protein interactions

Proteomics:

  • Mass spectrometry analysis
  • Protein databases (UniProt, STRING)
  • Post-translational modifications

Genomics:

  • Genome assembly and annotation
  • Copy number variation
  • Clinical genomics workflows

Medical/Clinical:

  • Disease databases (OpenTargets, OMIM)
  • Clinical trials and FDA data
  • Variant classification

See references/domains.md for:

  • Complete domain categorization
  • Tool examples by discipline
  • Cross-domain applications
  • Search strategies by domain

Reference Documentation

This skill includes comprehensive reference files that provide detailed information for specific aspects:

  • references/installation.md - Installation, setup, MCP configuration, platform integration
  • references/tool-discovery.md - Discovery methods, search strategies, listing tools
  • references/tool-execution.md - Execution patterns, real-world examples, error handling
  • references/tool-composition.md - Workflow composition, complex pipelines, parallel execution
  • references/domains.md - Tool categorization by domain, use case examples
  • references/api_reference.md - Python API documentation, hooks, protocols

Workflow: When helping with specific tasks, reference the appropriate file for detailed instructions. For example, if searching for tools, consult references/tool-discovery.md for search strategies.

Example Scripts

Two executable example scripts demonstrate common use cases:

scripts/example_tool_search.py - Demonstrates all three discovery methods:

  • Keyword-based search
  • LLM-based search
  • Domain-specific searches
  • Getting detailed tool information

scripts/example_workflow.py - Complete workflow examples:

  • Drug discovery pipeline (disease → targets → structures → screening → candidates)
  • Genomics analysis (expression data → differential analysis → pathways)

Run examples to understand typical usage patterns and workflow composition.

Best Practices

  1. Tool Discovery:

    • Start with broad searches, then refine based on results
    • Use Tool_Finder_Keyword for fast searches with known terms
    • Use Tool_Finder_LLM for complex semantic queries
    • Set appropriate limit parameter (default: 10)
  2. Tool Execution:

    • Always verify tool parameters before execution
    • Implement error handling for production workflows
    • Validate input data formats (SMILES, UniProt IDs, gene symbols)
    • Check result types and structures
  3. Workflow Composition:

    • Test each step individually before composing full workflows
    • Implement checkpointing for long workflows
    • Consider rate limits for remote APIs
    • Use parallel execution when tools are independent
  4. Integration:

    • Initialize ToolUniverse once and reuse the instance
    • Call load_tools() once at startup
    • Cache frequently used tool information
    • Enable logging for debugging

Key Terminology

  • Tool: A scientific resource (model, dataset, API, package) accessible through ToolUniverse
  • Tool Discovery: Finding relevant tools using search methods (Finder, LLM, Keyword)
  • Tool Execution: Running a tool with specific arguments via tu.run()
  • Tool Composition: Chaining multiple tools for multi-step workflows
  • MCP: Model Context Protocol for integration with Claude Desktop/Code
  • AI-Tool Interaction Protocol: Standardized interface for LLM-tool communication

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