| name | esmfold2 |
| description | Biohub ESMFold2 / ESMFold2-Fast all-atom co-folding (Candido et al. 2026, github.com/Biohub/esm). Single-sequence and MSA modes; protein, DNA, RNA, ligand (CCD/SMILES), modified residues. FoldBench Ab-Ag 50-55%, PPI 70-77% DockQ-pass. Also covers the ESMC-{300M,600M,6B} protein language models from the same release: masked-LM logits, hidden states, mutation scoring, contact prediction, and the SAE interpretability head. MIT-licensed weights on HuggingFace org `biohub`. Use this skill when: (1) Predicting complex structures with single-sequence input, (2) Validating designed binders with ESMFold2-Fast, (3) Running ESMFold2 with MSA input, (4) Getting ESMC embeddings or per-residue mutation scores, (5) Choosing kernel backend and sampling-step settings for paper-faithful throughput.
|
| license | Apache-2.0 |
| category | biomodels |
| requirements | ["gpu"] |
| metadata | {"display-name":"ESMFold2","third_party":[{"kind":"weights","name":"ESMFold2 / ESMC","provider":"Biohub","license":"MIT","terms_url":"https://github.com/Biohub/esm/blob/main/LICENSE.md"}]} |
ESMFold2 (Biohub)
All-atom diffusion co-folding from the Biohub ESM release (2026). ESMFold2 =
48 pair layers with MSA support; ESMFold2-Fast = 24 layers, single-sequence
only, ~1.7x faster.
License: MIT (code github.com/Biohub/esm + weights HF biohub/*).
Paper: "Language Modeling Materializes a World Model of Protein Biology" (2026).
Install
CUDA 12.x GPU (H100/A100-class); Python 3.12 only. Fresh venv; needs
egress to HF Hub, GitHub, PyPI:
pip install --no-cache-dir uv
uv venv --python 3.12 /work/venv && source /work/venv/bin/activate
uv pip install \
"torch>=2.5,<2.8" einops "biotite>=1.0" rdkit msgpack-numpy biopython \
scikit-learn brotli attrs pandas cloudpathlib httpx tenacity zstd pydssp \
pygtrie accelerate huggingface_hub safetensors "numpy<3" networkx \
sentencepiece tokenizers regex packaging filelock pyyaml typing_extensions \
"transformers @ git+https://github.com/Biohub/transformers.git@3a8956fb4d4ea16b0ec8e71deef2c2909b6a5cbf"
uv pip install --no-deps "esm @ git+https://github.com/Biohub/esm.git@f652b471"
uv pip install ninja packaging wheel setuptools
MAX_JOBS=8 uv pip install --no-deps --no-build-isolation "flash-attn<3"
The bundled esmfold2_gpu Modal env (remote-compute-modal skill) is the
canonical, version-pinned recipe.
Gotchas:
- Default kernel backend is
None (reference PyTorch, ~12x slower than paper). Call model.set_kernel_backend('fused') after from_pretrained(). See section below.
- Match torch CUDA build to your driver; the pin
<2.8 targets CUDA 12.2.
- Weights via Xet bridge ~300 MB/s: ESMFold2 1.36 GB, ESMFold2-Fast 0.76 GB. Set
HF_HOME=/work/hf_cache.
Usage — local model
from esm.models.esmfold2 import (
ESMFold2InputBuilder, StructurePredictionInput,
ProteinInput, DNAInput, RNAInput, LigandInput, Modification,
)
from transformers.models.esmfold2.modeling_esmfold2 import ESMFold2Model
model = ESMFold2Model.from_pretrained("biohub/ESMFold2").cuda().eval()
spi = StructurePredictionInput(sequences=[
ProteinInput(id="A", sequence=target_seq),
ProteinInput(id="B", sequence=binder_seq),
])
results = ESMFold2InputBuilder().fold(
model, spi,
num_loops=10,
num_sampling_steps=68,
num_diffusion_samples=5,
seed=0,
)
best = max(results, key=lambda r: float(r.iptm if r.iptm is not None
else r.plddt.mean()))
open("pred.cif", "w").write(best.complex.to_mmcif())
Paper-faithful FoldBench settings: 10 loops, 68 sampling steps, 25 seeds
x 5 diffusion samples; rank by ipTM (complexes) or pLDDT (monomers); MSA mode
adds msa_depth=1024 with 10% column masking and ESMC dropout 0.3.
Model variants on HF biohub/
| repo | size | pair layers | MSA | use |
|---|
ESMFold2 | 0.94 GB + ccd.pkl 0.42 GB | 48 | yes | full eval |
ESMFold2-Fast | 0.76 GB | 24 | no | fast single-seq |
ESMFold2-Experimental{,-Fast} | 0.90 / 0.72 GB | 48 / 24 | — | design search (Alg 11) |
ESMFold2-Experimental{,-Fast}-Cutoff2025 | 0.90 / 0.72 GB | — | — | design search + critic |
ESMFold2-Experimental-Fast-base{300M,600M,6B}-step{250k..1500k} | — | — | — | 15 critic ensemble |
Throughput: set_kernel_backend("fused") is REQUIRED
Default is the slow path. ESMFold2Model.from_pretrained(...) loads with
_kernel_backend=None (reference PyTorch) and chunk_size=64. You MUST call:
model = ESMFold2Model.from_pretrained("biohub/ESMFold2").cuda().eval()
model.set_kernel_backend("fused")
model.set_chunk_size(None)
"fused" gives ~1.5–6× trunk speedup over the reference backend, growing with
L; end-to-end fold() is diffusion-bound at short L so fused breaks even
around L≈300–400. Fused vs reference outputs are numerically consistent (pLDDT
within noise). "fused" (Triton, bundled with the GPU torch wheel) is
inference-only — auto-disables under backprop. Above ~L=1400
(chunk_size=128) it hits illegal memory access — fall back to
set_kernel_backend(None) + set_chunk_size(64); validated through L=1024.
Do NOT use set_kernel_backend("cuequivariance"): the
cuequivariance-torch==0.10.0 wheel lacks the compiled ops and silently
falls back to the reference path. apply_torch_compile() is an
alternative (NOT additive — call set_kernel_backend(None) first).
ESMFold2-Experimental* — design hook
Experimental variants expose res_type_soft for gradient-guided design — see
references/design-hook.md. Do NOT use the fused backend with them (fp32/bf16
dtype crash; the reference path is correct).
Gotcha: cusolver SVD poison + structseq constructor
The Kabsch alignment in modeling_esmfold2_common.py calls
torch.linalg.svd(H32, driver="gesvd") on batched 3x3 matrices. NaN/Inf inputs
(degenerate diffusion samples) corrupt the cusolver workspace — all subsequent
CUDA calls fail with "illegal memory access". Monkeypatch: redirect small
batched SVDs to CPU:
_orig_svd = torch.linalg.svd
def _safe_svd(A, full_matrices=True, driver=None):
if A.is_cuda and A.shape[-1] <= 4 and A.shape[-2] <= 4:
Acpu = A.detach().float().cpu()
if not torch.isfinite(Acpu).all():
Acpu = torch.nan_to_num(Acpu, nan=0.0, posinf=1e6, neginf=-1e6)
out = _orig_svd(Acpu, full_matrices=full_matrices)
return type(out)(tuple(t.to(A.device, A.dtype) for t in out))
return _orig_svd(A, full_matrices=full_matrices, driver=driver)
torch.linalg.svd = _safe_svd
Note type(out)(tuple(...)), not type(out)(*(...)) — torch.return_types.* are
C structseqs whose constructor takes a single tuple argument.
With-MSA mode
ESMFold2 supports per-chain MSA input via ProteinInput(id, sequence, msa=MSA).
The MSA object lives at esm.utils.msa.msa.MSA:
from esm.utils.msa.msa import MSA
msa_A = MSA.from_a3m("/path/chain_A.a3m", max_sequences=2048)
msa_B = MSA.from_a3m("/path/chain_B.a3m", max_sequences=2048)
inp = StructurePredictionInput(sequences=[
ProteinInput(id="A", sequence=seq_A, msa=msa_A),
ProteinInput(id="B", sequence=seq_B, msa=msa_B),
])
Gotchas:
MSA.from_a3m(remove_insertions=True) asserts equal row lengths after
insertion removal. ColabFold a3m files often carry trailing null bytes and
off-by-one rows vs the query — tr -d '\000' and force row 0 to the exact
query sequence (or MSA.from_sequences on manually cleaned, query-length rows).
- ESMFold2-Fast does NOT support MSA (single-seq only).
- With-MSA mode improves AbAg interface pass-rate per the paper's evaluation.
Paper-matched inference configuration
The paper's FoldBench protocol (section A.2.11):
| Parameter | Paper default | Paper "20lp" | Notes |
|---|
num_loops (folding-trunk recycles) | 10 | 20 | +2pp on AbAg |
num_sampling_steps (diffusion) | 68 | 68 | EDM-tuned; do NOT use 200 |
| seeds x diffusion samples | 25 x 5 | 25 x 5 | Fig S6/S7 oracle = best-of-125 |
Training data cutoff
ESMFold2 and ESMFold2-Fast both use a Sept 2021 PDB training cutoff (HF
biohub/ESMFold2 README).
ESMC language model
ESMC is the Biohub successor to ESM-2; three sizes: 300M (30L), 600M (36L),
6B (80L, d=2560). HF path: AutoModelForMaskedLM.from_pretrained("biohub/ESMC-6B").
Mask token is <mask> (id 32) — use tok.mask_token. The native-SDK _
convention does NOT apply to the HF tokenizer: _ is not in the vocab and
encodes to <unk>, silently corrupting mutation scores.
Full API, mutation scoring, SAE features, contact prediction: see
references/esmc.md.