bio-epidemiological-genomics-pathogen-typing
$
npx mdskill add GPTomics/bioSkills/bio-epidemiological-genomics-pathogen-typingType bacterial isolates using MLST and SNP-based strain typing.
- Identify strain types and track outbreak clones from bacterial genomes.
- Integrates mlst and chewBBACA CLI tools for sequence analysis.
- Executes typing by running commands against input FASTA files.
- Outputs structured typing results in tab-separated value format.
SKILL.md
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---
name: bio-epidemiological-genomics-pathogen-typing
description: Perform multi-locus sequence typing (MLST), core genome MLST, and SNP-based strain typing for bacterial isolate characterization using mlst and chewBBACA. Use when identifying strain types, tracking outbreak clones, or characterizing bacterial isolates.
tool_type: cli
primary_tool: mlst
---
## Version Compatibility
Reference examples tested with: mlst 2.23+, numpy 1.26+, pandas 2.2+, scanpy 1.10+, scipy 1.12+
Before using code patterns, verify installed versions match. If versions differ:
- Python: `pip show <package>` then `help(module.function)` to check signatures
- CLI: `<tool> --version` then `<tool> --help` to confirm flags
If code throws ImportError, AttributeError, or TypeError, introspect the installed
package and adapt the example to match the actual API rather than retrying.
# Pathogen Typing
**"Type my bacterial isolates by MLST"** → Assign multi-locus sequence types to bacterial genomes for isolate characterization, outbreak clone identification, and strain tracking.
- CLI: `mlst assembly.fasta` for 7-gene MLST typing
- CLI: `chewBBACA.py AlleleCall` for core genome MLST (cgMLST)
## MLST with mlst Tool
```bash
# Install mlst
conda install -c bioconda mlst
# Basic MLST typing
mlst genome.fasta
# Output: genome.fasta ecoli ST131 adk(53) fumC(40) gyrB(47) ...
# Batch typing
mlst *.fasta > typing_results.tsv
# Specify scheme
mlst --scheme senterica genome.fasta
# List available schemes
mlst --list
# Include allele sequences in output
mlst --csv genome.fasta > results.csv
```
## Parse MLST Results
```python
import pandas as pd
import subprocess
def run_mlst(fasta_files, scheme=None):
'''Run MLST on multiple genomes
Returns DataFrame with:
- Sample name
- Scheme (auto-detected or specified)
- Sequence type (ST)
- Allele profiles
ST interpretation:
- Known ST: Matches existing type in database
- Novel allele: New allele combination, may be unreported ST
- Failed: Unable to determine (poor assembly or wrong scheme)
'''
cmd = ['mlst'] + fasta_files
if scheme:
cmd.extend(['--scheme', scheme])
result = subprocess.run(cmd, capture_output=True, text=True)
lines = result.stdout.strip().split('\n')
data = [line.split('\t') for line in lines]
return pd.DataFrame(data, columns=['file', 'scheme', 'ST'] +
[f'locus{i}' for i in range(1, len(data[0])-2)])
```
## Core Genome MLST (cgMLST)
```bash
# chewBBACA for cgMLST
pip install chewbbaca
# Download or create schema
chewBBACA.py DownloadSchema -sp "Salmonella enterica" -o schema_dir
# Run cgMLST
chewBBACA.py AlleleCall -i genomes/ -g schema_dir -o results/
# Analyze results
chewBBACA.py ExtractCgMLST -i results/results_alleles.tsv \
-o cgmlst_results.tsv --threshold 0.95
```
## cgMLST Distance Analysis
**Goal:** Compute pairwise allelic distances between isolates and cluster them to identify potential outbreak groups.
**Approach:** Count allelic differences between each pair of isolate profiles (ignoring missing data), then apply single-linkage hierarchical clustering with a pathogen-specific distance threshold.
```python
import pandas as pd
import numpy as np
def calculate_cgmlst_distance(profiles):
'''Calculate allelic distances between isolates
Distance interpretation (typical thresholds):
- 0-5 allele differences: Same cluster (likely recent transmission)
- 6-15 differences: Related (possible epidemiological link)
- >15 differences: Different clones
Note: Thresholds are pathogen-specific. Consult literature.
'''
n = len(profiles)
distances = np.zeros((n, n))
for i in range(n):
for j in range(i+1, n):
# Count allelic differences (excluding missing data)
diff = sum(1 for a, b in zip(profiles.iloc[i], profiles.iloc[j])
if a != b and a != 0 and b != 0)
distances[i, j] = distances[j, i] = diff
return pd.DataFrame(distances, index=profiles.index, columns=profiles.index)
def identify_clusters(distance_matrix, threshold=5):
'''Identify cgMLST clusters
Threshold values by organism:
- E. coli: 10 alleles
- Salmonella: 7 alleles
- Listeria: 7 alleles
- S. aureus: 24 alleles
'''
from scipy.cluster.hierarchy import linkage, fcluster
# Convert to condensed distance matrix
condensed = distance_matrix.values[np.triu_indices(len(distance_matrix), k=1)]
# Hierarchical clustering
Z = linkage(condensed, method='single')
clusters = fcluster(Z, t=threshold, criterion='distance')
return dict(zip(distance_matrix.index, clusters))
```
## SNP-Based Typing
```python
def snp_typing_from_vcf(vcf_file, reference_positions):
'''Extract SNP profile for typing
Some organisms use canonical SNP positions for typing
(e.g., Mycobacterium tuberculosis lineages)
'''
from cyvcf2 import VCF
vcf = VCF(vcf_file)
profile = {}
for pos in reference_positions:
chrom, position = pos.split(':')
for variant in vcf(f'{chrom}:{position}-{position}'):
profile[pos] = variant.ALT[0] if variant.ALT else variant.REF
return profile
```
## Enterobase Integration
```python
import requests
def query_enterobase(st, organism='ecoli'):
'''Query Enterobase for ST metadata
Enterobase provides:
- Geographic distribution
- Temporal trends
- Associated serotypes
- Virulence gene profiles
'''
# Note: Requires API token
url = f'https://enterobase.warwick.ac.uk/api/v2.0/{organism}/sts/{st}'
# Would need authentication headers
# response = requests.get(url, headers={'Authorization': f'Bearer {token}'})
print(f'Query Enterobase for ST{st}: {url}')
return None # Placeholder - requires authentication
```
## Related Skills
- epidemiological-genomics/phylodynamics - Time-scaled trees from typed isolates
- epidemiological-genomics/transmission-inference - Outbreak investigation
- metagenomics/kraken-classification - Species identification
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