bioservices
关于
BioServices provides a unified Python interface to query 40+ bioinformatics databases like UniProt and KEGG with a consistent API. It's best for complex workflows requiring cross-database analysis and ID mapping across multiple services. For simpler, single-database lookups, consider alternatives like gget or biopython.
快速安装
Claude Code
推荐npx skills add K-Dense-AI/claude-scientific-skills -a claude-code/plugin add https://github.com/K-Dense-AI/claude-scientific-skillsgit clone https://github.com/K-Dense-AI/claude-scientific-skills.git ~/.claude/skills/bioservices在 Claude Code 中复制并粘贴此命令以安装该技能
技能文档
BioServices
Overview
BioServices is a Python package providing programmatic access to approximately 40 bioinformatics web services and databases. Retrieve biological data, perform cross-database queries, map identifiers, analyze sequences, and integrate multiple biological resources in Python workflows. The package handles both REST and SOAP/WSDL protocols transparently.
Version note: Examples target bioservices 1.16.0 (PyPI, Mar 2026). Requires Python 3.9–3.12. UniProt REST changes in mid-2022 (bioservices ≥1.10) mainly affect tabular columns names — see upstream _legacy_names if parsing breaks. ChEMBL wrappers changed at 1.6.0 (2018 API); use get_similarity, get_substructure, get_molecule instead of pre-1.6 method names.
When to Use This Skill
This skill should be used when:
- Retrieving protein sequences, annotations, or structures from UniProt, PDB, Pfam
- Analyzing metabolic pathways and gene functions via KEGG or Reactome
- Searching compound databases (ChEBI, ChEMBL, PubChem) for chemical information
- Converting identifiers between different biological databases (KEGG↔UniProt, compound IDs)
- Running sequence similarity searches (BLAST, MUSCLE alignment)
- Querying gene ontology terms (QuickGO, GO annotations)
- Accessing protein-protein interaction data (PSICQUIC, IntactComplex)
- Mining genomic data (BioMart, ArrayExpress, ENA)
- Integrating data from multiple bioinformatics resources in a single workflow
Core Capabilities
1. Protein Analysis
Retrieve protein information, sequences, and functional annotations:
from bioservices import UniProt
u = UniProt(verbose=False)
# Search for protein by name
results = u.search("ZAP70_HUMAN", frmt="tab", columns="id,genes,organism")
# Retrieve FASTA sequence
sequence = u.retrieve("P43403", "fasta")
# Map identifiers between databases
kegg_ids = u.mapping(fr="UniProtKB_AC-ID", to="KEGG", query="P43403")
Key methods:
search(): Query UniProt with flexible search termsretrieve(): Get protein entries in various formats (FASTA, XML, tab)mapping(): Convert identifiers between databases
Reference: references/services_reference.md for complete UniProt API details.
2. Pathway Discovery and Analysis
Access KEGG pathway information for genes and organisms:
from bioservices import KEGG
k = KEGG()
k.organism = "hsa" # Set to human
# Search for organisms
k.lookfor_organism("droso") # Find Drosophila species
# Find pathways by name
k.lookfor_pathway("B cell") # Returns matching pathway IDs
# Get pathways containing specific genes
pathways = k.get_pathway_by_gene("7535", "hsa") # ZAP70 gene
# Retrieve and parse pathway data
data = k.get("hsa04660")
parsed = k.parse(data)
# Extract pathway interactions
interactions = k.parse_kgml_pathway("hsa04660")
relations = interactions['relations'] # Protein-protein interactions
# Convert to Simple Interaction Format
sif_data = k.pathway2sif("hsa04660")
Key methods:
lookfor_organism(),lookfor_pathway(): Search by nameget_pathway_by_gene(): Find pathways containing genesparse_kgml_pathway(): Extract structured pathway datapathway2sif(): Get protein interaction networks
Reference: references/workflow_patterns.md for complete pathway analysis workflows.
3. Compound Database Searches
Search and cross-reference compounds across multiple databases:
from bioservices import KEGG, UniChem
k = KEGG()
# Search compounds by name
results = k.find("compound", "Geldanamycin") # Returns cpd:C11222
# Get compound information with database links
compound_info = k.get("cpd:C11222") # Includes ChEBI links
# Cross-reference KEGG → ChEMBL using UniChem
u = UniChem()
chembl_id = u.get_compound_id_from_kegg("C11222") # Returns CHEMBL278315
Common workflow:
- Search compound by name in KEGG
- Extract KEGG compound ID
- Use UniChem for KEGG → ChEMBL mapping
- ChEBI IDs are often provided in KEGG entries
Reference: references/identifier_mapping.md for complete cross-database mapping guide.
4. Sequence Analysis
Run BLAST searches and sequence alignments. NCBI requires a contact email — prefer the NCBI_EMAIL environment variable (same convention as BioPython Entrez and other repo skills):
import os
from bioservices import NCBIblast
s = NCBIblast(verbose=False)
email = os.environ["NCBI_EMAIL"] # set before running: export [email protected]
# Run BLASTP against UniProtKB
jobid = s.run(
program="blastp",
sequence=protein_sequence,
stype="protein",
database="uniprotkb",
email=email,
)
# Check job status and retrieve results
s.getStatus(jobid)
results = s.getResult(jobid, "out")
Note: BLAST jobs are asynchronous. Check status before retrieving results.
5. Identifier Mapping
Convert identifiers between different biological databases:
from bioservices import UniProt, KEGG
# UniProt mapping (many database pairs supported)
u = UniProt()
results = u.mapping(
fr="UniProtKB_AC-ID", # Source database
to="KEGG", # Target database
query="P43403" # Identifier(s) to convert
)
# KEGG gene ID → UniProt
kegg_to_uniprot = u.mapping(fr="KEGG", to="UniProtKB_AC-ID", query="hsa:7535")
# For compounds, use UniChem
from bioservices import UniChem
u = UniChem()
chembl_from_kegg = u.get_compound_id_from_kegg("C11222")
Supported mappings (UniProt):
- UniProtKB ↔ KEGG
- UniProtKB ↔ Ensembl
- UniProtKB ↔ PDB
- UniProtKB ↔ RefSeq
- And many more (see
references/identifier_mapping.md)
6. Gene Ontology Queries
Access GO terms and annotations:
from bioservices import QuickGO
g = QuickGO(verbose=False)
# Retrieve GO term information
term_info = g.Term("GO:0003824", frmt="obo")
# Search annotations
annotations = g.Annotation(protein="P43403", format="tsv")
7. Protein-Protein Interactions
Query interaction databases via PSICQUIC:
from bioservices import PSICQUIC
s = PSICQUIC(verbose=False)
# Query specific database (e.g., MINT)
interactions = s.query("mint", "ZAP70 AND species:9606")
# List available interaction databases
databases = s.activeDBs
Available databases: MINT, IntAct, BioGRID, DIP, and 30+ others.
Multi-Service Integration Workflows
BioServices excels at combining multiple services for comprehensive analysis. Common integration patterns:
Complete Protein Analysis Pipeline
Execute a full protein characterization workflow:
export [email protected]
python scripts/protein_analysis_workflow.py ZAP70_HUMAN
# Or pass email as optional second argument if NCBI_EMAIL is unset
python scripts/protein_analysis_workflow.py ZAP70_HUMAN [email protected]
This script demonstrates:
- UniProt search for protein entry
- FASTA sequence retrieval
- BLAST similarity search
- KEGG pathway discovery
- PSICQUIC interaction mapping
Pathway Network Analysis
Analyze all pathways for an organism:
python scripts/pathway_analysis.py hsa output_directory/
Extracts and analyzes:
- All pathway IDs for organism
- Protein-protein interactions per pathway
- Interaction type distributions
- Exports to CSV/SIF formats
Cross-Database Compound Search
Map compound identifiers across databases:
python scripts/compound_cross_reference.py Geldanamycin
Retrieves:
- KEGG compound ID
- ChEBI identifier
- ChEMBL identifier
- Basic compound properties
Batch Identifier Conversion
Convert multiple identifiers at once:
python scripts/batch_id_converter.py input_ids.txt --from UniProtKB_AC-ID --to KEGG
Best Practices
Output Format Handling
Different services return data in various formats:
- XML: Parse using BeautifulSoup (most SOAP services)
- Tab-separated (TSV): Pandas DataFrames for tabular data
- Dictionary/JSON: Direct Python manipulation
- FASTA: BioPython integration for sequence analysis
Rate Limiting and Verbosity
Control API request behavior:
from bioservices import KEGG
k = KEGG(verbose=False) # Suppress HTTP request details
k.TIMEOUT = 30 # Adjust timeout for slow connections
Error Handling
Wrap service calls in try-except blocks:
try:
results = u.search("ambiguous_query")
if results:
# Process results
pass
except Exception as e:
print(f"Search failed: {e}")
Organism Codes
Use standard organism abbreviations:
hsa: Homo sapiens (human)mmu: Mus musculus (mouse)dme: Drosophila melanogastersce: Saccharomyces cerevisiae (yeast)
List all organisms: k.list("organism") or k.organismIds
Integration with Other Tools
BioServices works well with:
- BioPython: Sequence analysis on retrieved FASTA data
- Pandas: Tabular data manipulation
- PyMOL: 3D structure visualization (retrieve PDB IDs)
- NetworkX: Network analysis of pathway interactions
- Galaxy: Custom tool wrappers for workflow platforms
Resources
scripts/
Executable Python scripts demonstrating complete workflows:
protein_analysis_workflow.py: End-to-end protein characterizationpathway_analysis.py: KEGG pathway discovery and network extractioncompound_cross_reference.py: Multi-database compound searchingbatch_id_converter.py: Bulk identifier mapping utility
Scripts can be executed directly or adapted for specific use cases.
references/
Detailed documentation loaded as needed:
services_reference.md: Comprehensive list of all 40+ services with methodsworkflow_patterns.md: Detailed multi-step analysis workflowsidentifier_mapping.md: Complete guide to cross-database ID conversion
Load references when working with specific services or complex integration tasks.
Installation
uv pip install "bioservices==1.16.0"
Dependencies are installed automatically. Upstream CI tests Python 3.9–3.12 (PyPI, docs).
Credentials
Most services need no API key. Exceptions:
| Service | Requirement |
|---|---|
| NCBI BLAST | Contact email via NCBI_EMAIL or email= in NCBIblast.run() |
| Some EBI services | Optional; check service docs if rate-limited |
Set once per shell session:
export [email protected]
Use a real institutional or lab address — NCBI may contact you about heavy BLAST usage.
Additional Information
For detailed API documentation and advanced features, refer to:
- Official documentation: https://bioservices.readthedocs.io/
- Source code: https://github.com/cokelaer/bioservices
- Service-specific references in
references/services_reference.md
GitHub 仓库
Frequently asked questions
What is the bioservices skill?
bioservices is a Claude Skill by K-Dense-AI. Skills package instructions and resources that Claude loads on demand, so Claude can perform bioservices-related tasks without extra prompting.
How do I install bioservices?
Use the install commands on this page: add bioservices to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.
What category does bioservices belong to?
bioservices is in the Design category, tagged react, api, automation, design and data.
Is bioservices free to use?
Yes. bioservices is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.
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