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档案由构建时根据 SKILL.md 与安装命令自动衍生,可能与作者实际意图存在差异。
需要注意: 未限定 allowed-tools,默认拥有全部工具权限。
---
name: boltzgen
description: BoltzGen is an all-atom diffusion model that generates antibody, nanobody, and de novo miniprote…
category: 通用
runtime: Python
---
# boltzgen 输出预览
## PART A: 任务判断
- 适用问题:通用任务拆解、检查和交付。
- 输入要求:目标材料、限制条件、期望输出和验收方式。
- 证据边界:围绕“When to Use This Skill / Quick Start / Installation”读取原文规则,不把推断写成作者承诺。
## PART B: 执行结果
- **01** 任务判断:确认你的需求是否属于通用任务拆解、检查和交付,并标出输入、限制和预期结果。
- **02** 执行计划:优先按“When to Use This Skill / Quick Start / Installation”拆成步骤,说明每一步会读取什么、修改什么、产出什么。
- **03** 交付结果:给出可复制的命令、文件改动、检查清单或内容草稿,并说明如何继续迭代。
- **04** 风险边界:结合 读取文件、写入/修改文件、执行终端命令、读取环境变量、会按任务需要访问外部网络、需要准备 Vendor-specific API Key 给出执行前确认项。
## Running Rules
- 读取文件、写入/修改文件、执行终端命令、读取环境变量;会按任务需要访问外部网络;需要准备 Vendor-specific API Key。
- 先小样例验证,再放大到真实任务。
- 交付时同时给结果、检查口径和下一步迭代建议。 原文出现了 `/by`、`/mnt` 这类斜杠命令;如果你的 Agent 支持命令触发,优先用命令开场,再补充目标和边界。
告诉 Agent 目标文件或材料、期望结果、不可改范围、是否允许联网或执行命令。本 Skill 的权限画像是:读取文件、写入/修改文件、执行终端命令、读取环境变量。
先用一个小任务确认它会围绕“When to Use This Skill / Quick Start / Installation”工作;涉及文件或命令时,先看 diff、日志、预览或测试结果。
检查最终产物是否包含明确结果、必要证据和下一步动作;如果输出泛泛而谈,就补充输入、边界和验收标准后重跑。
---
name: boltzgen
description: BoltzGen is an all-atom diffusion model that generates antibody, nanobody, and de novo miniprote…
category: 通用
source: 001TMF/blatant-why
---
# boltzgen
## 什么时候使用
- boltzgen 是一个通用扩展技能,按 SKILL 适合处理通用任务拆解、检查、交付和复盘,核心价值是把输入、判断、执行、验证和交付边界固定下来,避免 Agent 泛泛回答。 把任务拆成可执行、可检查、可继续迭代的步骤;使用前要准备…
- 面向通用任务拆解、检查和交付,优先处理能明确输入、步骤和验收标准的工作。
## 需要提供什么
- 目标材料、目录范围、期望结果和不可改动内容。
- 是否允许联网、执行命令、读写文件或调用外部服务。
## 执行规则
- 围绕「When to Use This Skill / Quick Start / Installation」组织步骤,不把推断写成作者事实。
- 读取文件、写入/修改文件、执行终端命令、读取环境变量;会按任务需要访问外部网络;需要准备 Vendor-specific API Key。
- 先跑小样例,确认结果可检查后再扩大任务范围。
## 输出要求
- 给出最终产物、关键证据、验证方式和下一步动作。
- 信息不足时标记 unknown,不编造命令、平台或依赖。 作者原文负责流程事实;仓库文件负责来源和命令;流狐只补充适用场景、限制和质量判断。
skill "boltzgen" {
输入层 -> 用户目标 + 目标文件 + 禁止范围 + 验收标准
上下文层 -> When to Use This Skill / Quick Start / Installation
规则层 -> SKILL.md 触发条件 / 执行顺序 / 输出格式
运行层 -> Python | 读取文件、写入/修改文件、执行终端命令、读取环境变量 | 会按任务需要访问外部网络
安全层 -> 需要准备 Vendor-specific API Key + 小任务验证 + diff / 日志复核
输出层 -> 可复制结果 + 检查清单 + 下一步迭代
} BoltzGen — Antibody / Nanobody / Binder Design
BoltzGen is an all-atom diffusion model that generates antibody, nanobody,
and de novo miniprotein backbones conditioned on a target structure and a
set of binding (hotspot) residues. Sequences are assigned by AntiFold, then
each design is independently refolded with Protenix to produce ipTM, pTM,
pLDDT, ipSAE, and CA-RMSD metrics. This skill teaches the exact
Write → Bash → Read pattern for invoking BoltzGen via its CLI on local
GPU (default), HPC (RunPod via by-deploy-compute), or Tamarind cloud.
The legacy CLI name was proteus-ab. It has been renamed to BoltzGen
throughout. If you see proteus-ab in older docs or scripts, treat it as
the same engine — the binary on PATH is now boltzgen.
When to Use This Skill
Use BoltzGen when you have:
- ✅ A cleaned target structure (CIF or PDB) with unambiguous chain IDs
- ✅ A defined epitope or hotspot set expressed in
label_seq_idnumbering - ✅ A modality decision in hand — VHH single-domain, full antibody Fab, or de novo miniprotein
- ✅ GPU compute available — local (CUDA-capable, ≥24 GB VRAM), HPC (RunPod), or Tamarind cloud
- ✅ A design budget — typical preview is 10–20 designs; production is 50–200
Do NOT use BoltzGen when:
- ❌ You need to validate a known antibody sequence against a target → use Protenix directly (no design needed)
- ❌ You need to score or filter an existing batch of designs → use by-scoring (ipSAE) and by-screening
- ❌ No epitope is known or characterised → run by-research + by-epitope-analysis first; designing with no
binding_typesis wasteful - ❌ You want a small-molecule binder → BoltzGen designs proteins/peptides only
- ❌ You need ranked, published results → use by-display /
/by:results
Quick Start
A 20-design VHH preview against TNF-α (PDB 1TNF, epitope residues 45–52 and 78–85) on a local GPU:
# Step 1: write spec via the Write tool — see scripts/boltzgen_submit.py for a builder
# Step 2: submit (dry-run prints the command; remove --dry-run to launch)
python scripts/boltzgen_submit.py \
--spec workspace/tnf_spec.yaml \
--protocol nanobody-anything \
--num-designs 20 \
--budget 48 \
--target local \
--output workspace/tnf_out
# Step 3: parse results into a CSV with sequences + metrics
python scripts/parse_designs.py \
--output-dir workspace/tnf_out \
--csv workspace/tnf_designs.csv
Expected runtime: ~10–25 min on a single H100/A100 (Stage 4 Protenix refolding dominates).
Expected output: a CSV ranked by iptm descending, typically 60–80% of designs
with iptm > 0.4, 20–40% with iptm > 0.6.
Installation
| Software | Version | License | Commercial Use | Installation |
|---|---|---|---|---|
| BoltzGen | ≥0.1.0 | MIT | ✅ Permitted | Clone https://github.com/HannesStark/boltzgen; install per repo README |
| Protenix | v1.x (368M) | Apache-2.0 | ✅ Permitted | Bundled with BoltzGen install; downloads weights on first run |
| AntiFold | ≥1.0 | MIT | ✅ Permitted | Bundled with BoltzGen install |
| CUDA toolkit | ≥11.8 | NVIDIA EULA | ✅ Permitted | Match your driver version |
| Python | ≥3.10 | PSF | ✅ Permitted | Use the conda env shipped by BoltzGen |
| pyyaml | ≥6.0 | MIT | ✅ Permitted | pip install pyyaml (used by the helper scripts) |
System requirements:
| Requirement | Details |
|---|---|
| BoltzGen path env | BOLTZGEN_DIR (or legacy PROTEUS_AB_DIR) pointing at the repo clone |
| Model weights env | PROTEUS_MODELS_DIR — typically ~/.cache/boltzgen |
| LayerNorm env | LAYERNORM_TYPE=openfold — mandatory for correct inference |
| GPU | CUDA-capable, ≥24 GB VRAM recommended (40 GB for antibody-anything with budget ≥ 128) |
| CLI binary | boltzgen (on PATH after env setup) |
License Compliance: All packages permit commercial use in AI applications.
For HPC (RunPod) deployment, see the by-deploy-compute skill — it handles
container image selection, secret injection, GPU type, and S3 mounting.
For Tamarind cloud, point the helper scripts at --target tamarind
(requires TAMARIND_API_KEY env var).
Inputs
Required:
- Target structure file — CIF (preferred) or PDB
- Single chain or multi-chain
- Clean chain IDs (
A,B, …) — no0or unusual letters - Resolved coordinates for the epitope region (no missing density)
- Entities YAML spec — see
references/entities-yaml-spec.md- Lists the target file, chains to include, and
binding_typesepitope ranges - Optional scaffold entity (Fab framework or nanobody scaffold)
- Lists the target file, chains to include, and
- Protocol —
nanobody-anything,antibody-anything,protein-anything,peptide-anything, orprotein-redesign
Alternative inputs:
- Binding residue list (Python list of ints) — converted to range notation by
boltzgen_submit.py(see range table inreferences/entities-yaml-spec.md) - Pre-built scaffold YAML — point a second entity at
$BOLTZGEN_DIR/example/fab_scaffolds/*.yamlornanobody_scaffolds/*.yaml
Optional:
- MSA mode —
none(default),precomputed(A3M files), ornim(NVIDIA NIM API) - Budget — diffusion steps; 48 preview, 96–128 production
--prefilter— drops low-quality designs before the expensive Protenix refolding (recommended fornum_designs ≥ 50)
⚠️ CRITICAL: Binding residues use label_seq_id (1-indexed, sequential, per-chain).
Mistakenly using auth_seq_id is the single most common cause of wasted campaigns.
See references/entities-yaml-spec.md for the full schema and conversion rules.
Outputs
All outputs land under the directory passed as --output.
Primary results:
| File | Format | Description |
|---|---|---|
final_ranked_designs/final_designs_metrics_*.csv |
CSV | Per-design metrics sorted by iptm descending |
final_ranked_designs/*.cif |
CIF | Refolded structures for each ranked design |
pae/*.npz |
NPZ | PAE matrices used to recompute ipSAE downstream |
designed_backbones/*.cif |
CIF | Stage-1 backbones (pre-refolding) |
run_config.json |
JSON | Reproducibility manifest — protocol, budget, seed, spec hash |
CSV columns (in order):
| Column | Type | Description |
|---|---|---|
design_id |
string | Unique design identifier |
iptm |
float | Interface predicted TM-score (0–1) — primary ranking |
ptm |
float | Predicted TM-score (0–1) |
plddt |
float | Mean per-residue confidence (0–100) |
design_iptm |
float | Stage-1 ipTM before refolding |
ipsae_min |
float | Minimum of directional ipSAE scores (0–1) |
rmsd |
float | CA-RMSD between designed and refolded backbones (Å) |
sequence |
string | Full amino acid sequence of the designed chain(s) |
Sorted by iptm descending. Hard filters applied downstream by by-scoring:
ipTM > 0.5, pLDDT > 70, RMSD < 3.5 Å. The composite score combines
ipSAE_min (0.50), ipTM (0.30), and inverted liability count (0.20).
The helper script scripts/parse_designs.py flattens multi-seed ensembles
into a single CSV and adds the seed column.
Clarification Questions
⚠️ CRITICAL: ASK THIS FIRST — confirm the target structure, epitope, and modality before running anything.
- Target structure (ASK THIS FIRST) — Do you have a cleaned CIF/PDB for the target, with confirmed chain IDs? If only a UniProt accession, run by-research + Protenix first to obtain a structure.
- Epitope / hotspot residues — Which residues should the binder target? Provide as a Python list of
label_seq_idintegers per chain. If unknown, run by-epitope-analysis first. - Modality — VHH single-domain, full antibody (VH/VL Fab), or de novo miniprotein? See
references/antibody-design-best-practices.mdfor selection criteria. - Design count — How many designs? Preview (10–20) for quick sanity check; production (50–200) once epitope is validated.
- Compute target — Local GPU (default), HPC via RunPod, or Tamarind cloud? Local is preferred when a GPU is present; HPC for batched runs > 100 designs.
- Scaffold preference — Use a specific therapeutic framework (e.g., adalimumab) or let BoltzGen pick defaults? Most runs use defaults; specify a scaffold only when humanization or framework matching is required.
- MSA mode — Default
noneis fine for the first pass. Switch toprecomputedornimonly if pLDDT < 70 across the top designs.
See references/antibody-design-best-practices.md for the modality decision
tree and expected pass rates by target class.
Standard Workflow
🚨 MANDATORY: USE SCRIPTS EXACTLY AS SHOWN — DO NOT WRITE INLINE CODE 🚨
This skill follows the Write → Bash → Read pattern. The two scripts under
scripts/ are the canonical entry points.
Step 1 — Write the entities YAML
Use the Write tool to create the spec file. The minimal form:
# workspace/design_spec.yaml
entities:
- file:
path: ./target.cif
include:
- chain:
id: A
binding_types:
- chain:
id: A
binding: 45..52,78..85
Range notation rules and conversion tables: references/entities-yaml-spec.md.
✅ VERIFICATION: yamllint workspace/design_spec.yaml returns no errors.
Step 2 — Submit via boltzgen_submit.py
python scripts/boltzgen_submit.py \
--spec workspace/design_spec.yaml \
--protocol nanobody-anything \
--num-designs 20 \
--budget 48 \
--msa-mode none \
--target local \
--output workspace/output \
--prefilter
Targets:
| Target | Behaviour |
|---|---|
local (default) |
Invokes boltzgen run directly on the current host |
hpc |
Prints the deployment command and hands off to the by-deploy-compute skill |
tamarind |
Submits via Tamarind API (requires TAMARIND_API_KEY) |
Add --dry-run to any target to print the command and exit |
✅ VERIFICATION: Console shows ✓ boltzgen completed: <N> designs written to <path> on success.
Step 3 — Parse and rank
python scripts/parse_designs.py \
--output-dir workspace/output \
--csv workspace/designs.csv
This walks final_ranked_designs/, handles multi-seed ensembles by merging
all final_designs_metrics_*.csv files, and writes a single canonical CSV.
✅ VERIFICATION: Console shows ✓ parse_designs completed: <N> rows / <path>.
Step 4 — Hand off to by-scoring / by-screening
The CSV is the input to downstream skills. Do not re-derive metrics inline.
⚠️ CRITICAL — DO NOT:
- ❌ Write inline
subprocess.run(["boltzgen", ...])calls → useboltzgen_submit.py - ❌ Parse the CSV with ad-hoc
pd.read_csvfiltering → useparse_designs.pythenby-scoring - ❌ Edit the entities YAML by hand on every run → use the script's
--binding-residuesflag to generate ranges - ❌ Use absolute
/mnt/...paths in spec files → use paths relative to the spec file
When Scripts Fail
Follow the standard script-failure hierarchy:
| Level | Frequency | Action |
|---|---|---|
| 1. Fix and Retry | 90% | Install missing package (pip install pyyaml), export missing env var (LAYERNORM_TYPE=openfold), re-run |
| 2. Modify Script | 5% | Edit boltzgen_submit.py or parse_designs.py to handle a new flag or output layout |
| 3. Use as Reference | 4% | Read the script, hand-craft a one-off boltzgen run invocation for unusual cases |
| 4. Write from Scratch | 1% | Only when BoltzGen's output schema has changed substantially — document why in run_config.json |
Common decision tree:
- Missing env var → Step 1 (
export LAYERNORM_TYPE=openfold; export PROTEUS_MODELS_DIR=~/.cache/boltzgen) - CUDA OOM → Step 1 (reduce
--num-designsor--budget) - New CLI flag in a BoltzGen upgrade → Step 2 (add the flag to
boltzgen_submit.py) - Multi-seed run with a non-standard directory layout → Step 3
- Output schema renamed columns → Step 4
Decision Points
Protocol selection
| Protocol | Format | Chains | Designs / Run | When to Choose |
|---|---|---|---|---|
nanobody-anything |
VHH single-domain | 1 | 10–50 | Fast iteration, tissue penetration, intracellular delivery |
antibody-anything |
VH/VL Fab pair | 2 | 20–100 | Fc effector function, higher affinity, therapeutic format |
protein-anything |
De novo miniprotein | 1 | 10–100 | When PXDesign is unavailable or failing; novel binders 65–150 aa |
peptide-anything |
Linear peptide | 1 | 20–100 | Short binders, MHC ligands, cell-penetrating peptides |
protein-redesign |
Redesign existing | 1 | 10–50 | Improving an existing binder's affinity or expression |
Compute target
| Target | When to Use | Cost Order |
|---|---|---|
local (default) |
A GPU is present; ≤ 100 designs; iterating on epitope or scaffold | Cheapest |
hpc (RunPod via by-deploy-compute) |
Batches > 100 designs; need A100/H100 you don't own | Medium |
tamarind (cloud fallback) |
No GPU, no HPC access, willing to pay per run | Highest |
MSA mode
| Mode | When |
|---|---|
none |
Default. Sufficient for most runs |
precomputed |
You have MMseqs2 / HHblits A3M files and top designs show pLDDT < 70 |
nim |
Remote MSA needed and NIM API key available |
See references/antibody-design-best-practices.md for budget × protocol × hit-rate guidance.
Common Issues
| Issue | Cause | Solution | Details |
|---|---|---|---|
FileNotFoundError on model weights |
PROTEUS_MODELS_DIR not set |
export PROTEUS_MODELS_DIR=~/.cache/boltzgen and verify weights are present |
references/entities-yaml-spec.md |
LAYERNORM_TYPE error or silent NaNs |
Env var missing | export LAYERNORM_TYPE=openfold before every run |
— |
All designs have iptm < 0.4 |
Bad epitope (buried residues, wrong numbering) | Re-verify with auth_seq_id→label_seq_id conversion; check SASA > 0.25 for all epitope residues |
references/antibody-design-best-practices.md |
| CUDA OOM during Stage 4 (refolding) | Target + binder too large for VRAM | Reduce --num-designs, drop --budget to 48, or move to HPC with 80 GB GPU |
references/pipeline-stages.md |
No CSV in final_ranked_designs/ |
Run failed silently or output dir wrong | find <output> -name 'final_designs_metrics_*.csv'; check run_config.json and stderr |
— |
| Very similar sequences across all designs | Budget too low; diversity not explored | Increase --budget to 96–128; try a different scaffold |
references/antibody-design-best-practices.md |
auth_seq_id used in binding: |
Wrong residues targeted | Convert to label_seq_id; the spec uses 1-indexed sequential numbering per chain |
references/entities-yaml-spec.md |
Spaces in range notation (7..12, 27..34) |
YAML parses but BoltzGen rejects | Remove spaces: 7..12,27..34 |
references/entities-yaml-spec.md |
| Scaffold path not found | $BOLTZGEN_DIR not expanded |
Use an absolute path or shell-expand before writing the YAML | — |
antibody-anything slower than expected |
Single-chain VHH was the right choice | Switch to nanobody-anything unless Fc / Fab is required |
references/antibody-design-best-practices.md |
MSA mode nim very slow |
NIM API latency | Use none for iteration; switch only when pLDDT < 70 persists |
— |
| Stage-3 pre-filter discards > 80% | Bad backbones from Stage 1 (wrong epitope) | Re-examine binding residues; try a different scaffold | references/pipeline-stages.md |
| Multi-seed CSV columns differ across seeds | Older BoltzGen versions changed schema | parse_designs.py normalises columns; upgrade BoltzGen if persistent |
— |
boltzgen: command not found |
PATH not set after env activation | Activate the BoltzGen conda env or add $BOLTZGEN_DIR/bin to PATH |
— |
| HPC submission stalls in queue | Wrong GPU class requested | See by-deploy-compute for RunPod GPU selection | — |
Best Practices
- 🚨 CRITICAL: Always export
LAYERNORM_TYPE=openfoldandPROTEUS_MODELS_DIRbefore running — silent NaNs otherwise. - 🚨 CRITICAL: Binding residues use
label_seq_id, notauth_seq_id. Verify the conversion before launching. - ✅ REQUIRED: Run a 10–20 design preview before any production run > 50 designs. Confirms epitope is reachable.
- ✅ REQUIRED: Enable
--prefilterfornum_designs ≥ 50. Saves 20–50% GPU time. - ✅ Prefer local GPU as the default compute target. Only escalate to HPC (RunPod) for batches > 100 or when no local GPU is available. Tamarind is the last-resort cloud fallback.
- ✅ Choose VHH (
nanobody-anything) unless Fc effector function is required — faster, fewer designs needed. - ✅ Use the helper scripts (
boltzgen_submit.py,parse_designs.py); do not hand-craftboltzgen runinvocations. - ✅ Always pass output to by-scoring and by-screening — never rank by
iptmalone for a final shortlist. - ✨ Optional: Pin a specific Fab scaffold when humanization is a downstream requirement (see scaffold catalog below).
- ❌ DON'T rerun a campaign with a different epitope without first checking SASA — buried residues waste compute.
Suggested Next Steps
After BoltzGen completes, route through the standard scoring → screening → display pipeline.
| Next skill | Why |
|---|---|
| by-scoring | Recompute ipSAE_min from PAE matrices; apply hard filters (ipTM > 0.5, pLDDT > 70, RMSD < 3.5 Å); produce composite score |
| by-screening | Run the full screening battery — liabilities, developability, MHC II, aggregation; outputs PASS / FAIL per design |
| by-display | Format the ranked shortlist into a human-readable table (/by:results) |
| by-campaign-manager | Update campaign state (campaignState.designs[]), checkpoint, and decide on next iteration |
| by-epitope-analysis | If all designs failed, re-examine the epitope (SASA, conservation, structural accessibility) |
| by-failure-diagnosis | If pass rate is < 5%, classify the failure mode (epitope / scaffold / numerical) |
Chain rationale: BoltzGen produces raw structural metrics; by-scoring normalises and combines them; by-screening adds biophysical filters; by-display is the user-facing artifact. The campaign manager closes the loop with state and history.
Related Skills
Upstream (run before BoltzGen):
- by-research — Target dossier, prior art, scaffold suggestions
- by-epitope-analysis — Hotspot residues with SASA and conservation
- by-hypothesis-debate — Strategy selection (modality, scaffold, budget) when multiple approaches are viable
- Protenix — If only a sequence is available, predict the target structure first
Downstream (run after BoltzGen):
- by-scoring — ipSAE recomputation + composite score
- by-screening — Full developability and liability battery
- by-display — Format and present ranked designs
- by-campaign-manager — State checkpoint and next-iteration decision
Alternative / complementary:
- pxdesign — De novo miniprotein binder design (non-antibody). Use
boltzgenprotein-anythingonly as a fallback when pxdesign is unavailable. - by-deploy-compute — HPC (RunPod) and Tamarind deployment details for offloading BoltzGen runs
Scaffold Templates
Pre-built scaffold YAMLs ship with BoltzGen under $BOLTZGEN_DIR/example/.
Add a second entity in the spec to use one; omit for built-in defaults.
Fab scaffolds (14)
| Scaffold | PDB | File |
|---|---|---|
| Adalimumab | 6cr1 | fab_scaffolds/adalimumab.6cr1.yaml |
| Belimumab | 7m3n | fab_scaffolds/belimumab.7m3n.yaml |
| Crenezumab | 5vzo | fab_scaffolds/crenezumab.5vzo.yaml |
| Dupilumab | 8d96 | fab_scaffolds/dupilumab.8d96.yaml |
| Golimumab | 5wuv | fab_scaffolds/golimumab.5wuv.yaml |
| Guselkumab | 7unp | fab_scaffolds/guselkumab.7unp.yaml |
| mAb1 | 7q0g | fab_scaffolds/mab1.7q0g.yaml |
| Necitumumab | 5stx | fab_scaffolds/necitumumab.5stx.yaml |
| Nirsevimab | 8hkq | fab_scaffolds/nirsevimab.8hkq.yaml |
| Sarilumab | 7moe | fab_scaffolds/sarilumab.7moe.yaml |
| Secukinumab | 5yy2 | fab_scaffolds/secukinumab.5yy2.yaml |
| Tezepelumab | 6oaj | fab_scaffolds/tezepelumab.6oaj.yaml |
| Tralokinumab | 6ux9 | fab_scaffolds/tralokinumab.6ux9.yaml |
| Ustekinumab | 3hn3 | fab_scaffolds/ustekinumab.3hn3.yaml |
Nanobody scaffolds (4)
| Scaffold | PDB | File |
|---|---|---|
| Caplacizumab | 7eow | nanobody_scaffolds/caplacizumab.7eow.yaml |
| Vobarilizumab | 7xl0 | nanobody_scaffolds/vobarilizumab.7xl0.yaml |
| Gefurulimab | 8coh | nanobody_scaffolds/gefurulimab.8coh.yaml |
| Ozoralizumab | 8z8v | nanobody_scaffolds/ozoralizumab.8z8v.yaml |
Example with explicit scaffold:
entities:
- file:
path: ./target.cif
include:
- chain:
id: A
binding_types:
- chain:
id: A
binding: 45..52,78..85
- file:
path: $BOLTZGEN_DIR/example/fab_scaffolds/adalimumab.6cr1.yaml
References
Detailed documentation:
references/entities-yaml-spec.md— Full schema for the entities YAML: target entity, include blocks, binding ranges, scaffold entities, and common mistakes.references/pipeline-stages.md— Six-stage internal pipeline (Design → Inverse Fold → Pre-filter → Refold → Analysis → Filtering) with per-stage timing and success indicators.references/antibody-design-best-practices.md— VHH vs scFv vs Fab selection, MSA mode choice, expected pass rates by target difficulty, hotspot count recommendations.
Scripts:
scripts/boltzgen_submit.py— Reads the entities YAML + flags, builds the CLI command, and invokes locally or hands off to HPC / Tamarind. Supports--dry-run.scripts/parse_designs.py— Walks a BoltzGen output directory, merges multi-seed CSVs, and writes a single canonical CSV of design IDs, scores, and sequences.
External documentation:
- BoltzGen repository — https://github.com/HannesStark/boltzgen
- Protenix (refolding engine) — https://github.com/bytedance/Protenix
- AntiFold (inverse folding) — https://github.com/oxpig/AntiFold
License: All referenced engines (BoltzGen, Protenix, AntiFold) permit commercial use.
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