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---
name: bio-systems-biology-metabolic-reconstruction
description: Build genome-scale metabolic models from genome sequences using CarveMe and gapseq for automated reconstruction. Generate draft models ready for curation and analysis. Use when creating metabolic models for organisms without existing models.
tool_type: cli
primary_tool: CarveMe
measurable_outcome: Execute skill workflow successfully with valid output within 15 minutes.
allowed-tools:
- read_file
- run_shell_command
---
# Metabolic Reconstruction
## CarveMe (Recommended)
```bash
# Install CarveMe
pip install carveme
# Basic reconstruction from protein FASTA
carve genome.faa -o model.xml
# Specify output format
carve genome.faa -o model.xml --format sbml
carve genome.faa -o model.json --format json
# Gap-fill for specific media
carve genome.faa -o model.xml --gapfill M9
# Available media: M9, LB, M9[glc], M9[glyc], etc.
```
## CarveMe Options
```bash
# Use diamond instead of blastp (faster)
carve genome.faa -o model.xml --diamond
# Specify organism type
carve genome.faa -o model.xml --grampos # Gram-positive
carve genome.faa -o model.xml --gramneg # Gram-negative (default)
# Initialize from template model
carve genome.faa -o model.xml --init M9
# Verbose output for debugging
carve genome.faa -o model.xml -v
```
## gapseq (Alternative)
```bash
# Install gapseq
git clone https://github.com/jotech/gapseq
cd gapseq
./gapseq check # Check dependencies
# Full reconstruction workflow
./gapseq find -p all genome.fasta # Find metabolic pathways
./gapseq find -t all genome.fasta # Find transporters
./gapseq draft -r genome-all-Reactions.tbl \
-t genome-Transporters.tbl \
-p genome-all-Pathways.tbl \
-c genome.fasta
./gapseq fill -m genome-draft.RDS -c genome.fasta -n M9
```
## Python API for CarveMe
```python
import subprocess
def reconstruct_model(fasta_path, output_path, media='M9', grampos=False):
'''Run CarveMe reconstruction
Args:
fasta_path: Path to protein FASTA file
output_path: Output model file path (.xml or .json)
media: Gap-filling media (M9, LB, etc.)
grampos: True for Gram-positive organisms
Model size expectations:
- Bacteria: 1000-2500 reactions typical
- Fungi: 1500-3000 reactions
- Archaea: 800-1500 reactions
'''
cmd = ['carve', fasta_path, '-o', output_path, '--gapfill', media]
if grampos:
cmd.append('--grampos')
subprocess.run(cmd, check=True)
return output_path
```
## Load and Inspect Draft Model
```python
import cobra
model = cobra.io.read_sbml_model('model.xml')
print(f'Reactions: {len(model.reactions)}')
print(f'Metabolites: {len(model.metabolites)}')
print(f'Genes: {len(model.genes)}')
# Check if model can grow
solution = model.optimize()
print(f'Growth rate: {solution.objective_value:.4f}')
# List exchange reactions (available nutrients)
for rxn in model.exchanges[:10]:
print(f'{rxn.id}: {rxn.reaction}')
```
## Quality Metrics
```python
def assess_model_quality(model):
'''Basic quality assessment for draft model
Returns metrics to evaluate reconstruction quality.
'''
metrics = {
'reactions': len(model.reactions),
'metabolites': len(model.metabolites),
'genes': len(model.genes),
'gene_reaction_ratio': len(model.reactions) / max(1, len(model.genes))
}
# Count reaction types
metrics['exchanges'] = len(model.exchanges)
metrics['transport'] = len([r for r in model.reactions if 'transport' in r.name.lower()])
# Test growth
sol = model.optimize()
metrics['can_grow'] = sol.status == 'optimal' and sol.objective_value > 0.001
# Gene-reaction rules
metrics['orphan_reactions'] = len([r for r in model.reactions if not r.genes])
return metrics
```
## Multiple Genome Reconstruction
```python
import os
from pathlib import Path
def batch_reconstruction(fasta_dir, output_dir, media='M9'):
'''Reconstruct models for multiple genomes
Use for comparative genomics or community modeling.
'''
os.makedirs(output_dir, exist_ok=True)
for fasta in Path(fasta_dir).glob('*.faa'):
output = Path(output_dir) / f'{fasta.stem}.xml'
reconstruct_model(str(fasta), str(output), media=media)
print(f'Completed: {fasta.name}')
```
## Community Model Construction
```python
def merge_models(model_paths, community_name='community'):
'''Create community model from individual organisms
For microbiome FBA, need to create a shared compartment
for metabolite exchange between organisms.
'''
import cobra
models = [cobra.io.read_sbml_model(p) for p in model_paths]
# Add species prefix to all components
for i, model in enumerate(models):
species_id = f'sp{i+1}'
for rxn in model.reactions:
rxn.id = f'{species_id}_{rxn.id}'
for met in model.metabolites:
met.id = f'{species_id}_{met.id}'
for gene in model.genes:
gene.id = f'{species_id}_{gene.id}'
# Merge into community model
community = models[0].copy()
for model in models[1:]:
community.merge(model)
return community
```
## Related Skills
- systems-biology/model-curation - Validate and curate draft models
- systems-biology/flux-balance-analysis - Analyze reconstructed models
- database-access/entrez-fetch - Download genome sequences
<!-- AUTHOR_SIGNATURE: 9a7f3c2e-MD-BABU-MIA-2026-MSSM-SECURE -->