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[](https://versuz.dev/skills/freedomintelligence-openclaw-medical-skills-skills-boltzgen)Free SKILL.md scraped from GitHub. Clone the repo or copy the file directly into your Claude Code skills directory.
npx versuz@latest install freedomintelligence-openclaw-medical-skills-skills-boltzgengit clone https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills.gitcp OpenClaw-Medical-Skills/SKILL.MD ~/.claude/skills/freedomintelligence-openclaw-medical-skills-skills-boltzgen/SKILL.md---
name: boltzgen
description: >
All-atom protein design using BoltzGen diffusion model. Use this skill when:
(1) Need side-chain aware design from the start,
(2) Designing around small molecules or ligands,
(3) Want all-atom diffusion (not just backbone),
(4) Require precise binding geometries,
(5) Using YAML-based configuration.
For backbone-only generation, use rfdiffusion.
For sequence-only design, use proteinmpnn.
For structure validation, use boltz.
license: MIT
category: design-tools
tags: [structure-design, sequence-design, diffusion, all-atom, binder]
proteinbase_slug: boltzgen
proteinbase_url: https://proteinbase.com/design-methods/boltzgen
biomodals_script: modal_boltzgen.py
---
# BoltzGen All-Atom Design
## Prerequisites
| Requirement | Minimum | Recommended |
|-------------|---------|-------------|
| Python | 3.10+ | 3.11 |
| CUDA | 12.0+ | 12.1+ |
| GPU VRAM | 24GB | 48GB (L40S) |
| RAM | 32GB | 64GB |
## How to run
> **First time?** See [Installation Guide](../../docs/installation.md) to set up Modal and biomodals.
### Option 1: Modal (recommended)
```bash
# Clone biomodals
git clone https://github.com/hgbrian/biomodals && cd biomodals
# Run BoltzGen (requires YAML config file)
modal run modal_boltzgen.py \
--input-yaml binder_config.yaml \
--protocol protein-anything \
--num-designs 50
# With custom GPU
GPU=L40S modal run modal_boltzgen.py \
--input-yaml binder_config.yaml \
--protocol protein-anything \
--num-designs 100
```
**GPU**: L40S (48GB) recommended | **Timeout**: 120min default
**Available protocols**: `protein-anything`, `peptide-anything`, `protein-small_molecule`, `nanobody-anything`, `antibody-anything`
### Option 2: Local installation
```bash
git clone https://github.com/HannesStark/boltzgen.git
cd boltzgen
pip install -e .
python sample.py config=config.yaml
```
### Option 3: Python API
```python
from boltzgen import BoltzGen
model = BoltzGen.load_pretrained()
designs = model.sample(
target_pdb="target.pdb",
num_samples=50,
binder_length=80
)
```
**GPU**: L40S (48GB) | **Time**: ~30-60s per design
## Key parameters (CLI)
| Parameter | Default | Description |
|-----------|---------|-------------|
| `--input-yaml` | required | Path to YAML design specification |
| `--protocol` | `protein-anything` | Design protocol |
| `--num-designs` | 10 | Number of designs to generate |
| `--steps` | all | Pipeline steps to run (e.g., `design inverse_folding`) |
## YAML configuration
BoltzGen uses an **entity-based YAML format** where you specify designed proteins and target structures as entities.
**Important notes:**
- Residue indices use `label_seq_id` (1-indexed), not author residue numbers
- File paths are relative to the YAML file location
- Target files should be in CIF format (PDB also works but CIF preferred)
- Run `boltzgen check config.yaml` to verify your specification before running
### Basic Binder Config
```yaml
entities:
# Designed protein (variable length 80-140 residues)
- protein:
id: B
sequence: 80..140
# Target from structure file
- file:
path: target.cif
include:
- chain:
id: A
# Specify binding site residues (optional but recommended)
binding_types:
- chain:
id: A
binding: 45,67,89
```
### Binder with Specific Binding Site
```yaml
entities:
- protein:
id: G
sequence: 60..100
- file:
path: 5cqg.cif
include:
- chain:
id: A
binding_types:
- chain:
id: A
binding: 343,344,251
structure_groups: "all"
```
### Peptide Design (Cyclic)
```yaml
entities:
- protein:
id: S
sequence: 10..14C6C3 # With cysteines for disulfide
- file:
path: target.cif
include:
- chain:
id: A
constraints:
- bond:
atom1: [S, 11, SG]
atom2: [S, 18, SG] # Disulfide bond
```
## Design protocols
| Protocol | Use Case |
|----------|----------|
| `protein-anything` | Design proteins to bind proteins or peptides |
| `peptide-anything` | Design cyclic peptides to bind proteins |
| `protein-small_molecule` | Design proteins to bind small molecules |
| `nanobody-anything` | Design nanobody CDRs |
| `antibody-anything` | Design antibody CDRs |
## Output format
```
output/
├── sample_0/
│ ├── design.cif # All-atom structure (CIF format)
│ ├── metrics.json # Confidence scores
│ └── sequence.fasta # Sequence
├── sample_1/
│ └── ...
└── summary.csv
```
**Note**: BoltzGen outputs CIF format. Convert to PDB if needed:
```python
from Bio.PDB import MMCIFParser, PDBIO
parser = MMCIFParser()
structure = parser.get_structure("design", "design.cif")
io = PDBIO()
io.set_structure(structure)
io.save("design.pdb")
```
## Sample output
### Successful run
```
$ modal run modal_boltzgen.py --input-yaml binder.yaml --protocol protein-anything --num-designs 10
Running: boltzgen run binder.yaml --output /tmp/out --protocol protein-anything --num_designs 10
[INFO] Loading BoltzGen model...
[INFO] Generating designs...
[INFO] Running inverse folding...
[INFO] Running structure prediction...
[INFO] Filtering and ranking...
[INFO] Pipeline complete
Results saved to: ./out/boltzgen/2501161234/
```
**Output directory structure:**
```
out/boltzgen/2501161234/
├── intermediate_designs/ # Raw diffusion outputs
│ ├── design_0.cif
│ └── design_0.npz
├── intermediate_designs_inverse_folded/
│ ├── refold_cif/ # Refolded complexes
│ └── aggregate_metrics_analyze.csv
└── final_ranked_designs/
├── final_10_designs/ # Top designs
└── results_overview.pdf # Summary plots
```
**What good output looks like:**
- Refolding RMSD < 2.0A (design folds as predicted)
- ipTM > 0.5 (confident interface)
- All designs complete pipeline without errors
## Decision tree
```
Should I use BoltzGen?
│
├─ What type of design?
│ ├─ All-atom precision needed → BoltzGen ✓
│ ├─ Ligand binding pocket → BoltzGen ✓
│ └─ Standard miniprotein → RFdiffusion (faster)
│
├─ What matters most?
│ ├─ Side-chain packing → BoltzGen ✓
│ ├─ Speed / diversity → RFdiffusion
│ ├─ Highest success rate → BindCraft
│ └─ AF2 optimization → ColabDesign
│
└─ Compute resources?
├─ Have L40S/A100 (48GB+) → BoltzGen ✓
└─ Only A10G (24GB) → Consider RFdiffusion
```
## Typical performance
| Campaign Size | Time (L40S) | Cost (Modal) | Notes |
|---------------|-------------|--------------|-------|
| 50 designs | 30-45 min | ~$8 | Quick exploration |
| 100 designs | 1-1.5h | ~$15 | Standard campaign |
| 500 designs | 5-8h | ~$70 | Large campaign |
**Per-design**: ~30-60s for typical binder.
---
## Verify
```bash
find output -name "*.cif" | wc -l # Should match num_samples
```
---
## Troubleshooting
**Verify config first**: Always run `boltzgen check config.yaml` before running the full pipeline
**Slow generation**: Use fewer designs for initial testing, then scale up
**OOM errors**: Use A100-80GB or reduce `--num-designs`
**Wrong binding site**: Residue indices use `label_seq_id` (1-indexed), check in Molstar viewer
### Error interpretation
| Error | Cause | Fix |
|-------|-------|-----|
| `RuntimeError: CUDA out of memory` | Large design or long protein | Use A100-80GB or reduce designs |
| `FileNotFoundError: *.cif` | Target file not found | File paths are relative to YAML location |
| `ValueError: invalid chain` | Chain not in target | Verify chain IDs with Molstar or PyMOL |
| `modal: command not found` | Modal CLI not installed | Run `pip install modal && modal setup` |
---
**Next**: Validate with `boltz` or `chai` → `protein-qc` for filtering.