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---
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library_name: transformers
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tags: []
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---
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# NOTE
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The GitHub with the implementation and requirements.txt can be found [here](https://github.com/Synthyra/FastPLMs.git)
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# Profluent-E1
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[Synthyra's version of Profluent-E1](https://github.com/Synthyra/Profluent-E1-300M) is a faithful implementation of Profluent's [E1](https://www.profluent.bio/showcase/e1) models ([license](https://github.com/Profluent-AI/E1/tree/main?tab=License-1-ov-file)) that integrates Huggingface AutoModel compatability and nice embedding functionality.
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## Use with 🤗 transformers
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### Supported models
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```python
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model_dict = {
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# Synthyra/Profluent-E1-150M
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'Profluent-E1-150M': 'Profluent-Bio/E1-150m',
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# Synthyra/Profluent-E1-150M
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'Profluent-E1-300M': 'Profluent-Bio/E1-300m',
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# Synthyra/Profluent-E1-150M
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'Profluent-E1-600M': 'Profluent-Bio/E1-600m',
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}
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```
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```python
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import torch
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from transformers import AutoModelForMaskedLM
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device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
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model = AutoModelForMaskedLM.from_pretrained('Synthyra/Profluent-E1-150M', trust_remote_code=True, dtype=torch.bfloat16).eval().to(device)
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sequences = ['MPRTEIN', 'MSEQWENCE']
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batch = model.prep_tokens.get_batch_kwargs(sequences, device=device)
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output = model(**batch) # get all hidden states with output_hidden_states=True
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print(output.logits.shape) # language modeling logits, (batch_size, seq_len, vocab_size), (2, 11, 34)
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print(output.last_hidden_state.shape) # last hidden state of the model, (batch_size, seq_len, hidden_size), (2, 11, 768)
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print(output.loss) # language modeling loss if you passed labels
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#print(output.hidden_states) # all hidden states if you passed output_hidden_states=True (in tuple)
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#print(outout.attentions) # all attention matrices if you passed output_attentions=True (in tuple)
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```
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Our E1 implementation also supports sequence and token level classification tasks like ESM2. Simply pass the number of labels during initialization.
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```python
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from transformers import AutoModelForSequenceClassification, AutoModelForTokenClassification
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model = AutoModelForSequenceClassification.from_pretrained('Synthyra/Profluent-E1-150M', num_labels=2, trust_remote_code=True)
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logits = model(**batch, labels=labels).logits
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print(logits.shape) # (batch_size, num_labels), (2, 2)
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```
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E1 weights were trained in bf16 and are in bf16 by default. You can load them in the precision of your choosing by leveraging the dtype parameter:
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```python
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import torch
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model = AutoModelForMaskedLM.from_pretrained('Synthyra/Profluent-E1-150M', trust_remote_code=True, dtype=torch.float) # fp32
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```
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## Embed entire datasets with no new code
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To embed a list of protein sequences **fast**, just call embed_dataset. Sequences are sorted to reduce padding tokens, so the initial progress bar estimation is usually much longer than the actual time it will take.
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Example:
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```python
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embedding_dict = model.embed_dataset(
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sequences=[
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'MALWMRLLPLLALLALWGPDPAAA', ... # list of protein sequences
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],
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batch_size=2, # adjust for your GPU memory
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max_len=512, # adjust for your needs
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full_embeddings=False, # if True, no pooling is performed
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embed_dtype=torch.float32, # cast to what dtype you want
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pooling_types=['mean', 'cls'], # more than one pooling type will be concatenated together
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sql=False, # if True, embeddings will be stored in SQLite database
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sql_db_path='embeddings.db',
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save=True, # if True, embeddings will be saved as a .pth file
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save_path='embeddings.pth',
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)
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# embedding_dict is a dictionary mapping sequences to their embeddings as tensors for .pth or numpy arrays for sql
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```
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```
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model.embed_dataset()
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Args:
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sequences: List of protein sequences
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batch_size: Batch size for processing
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max_len: Maximum sequence length
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full_embeddings: Whether to return full residue-wise (True) embeddings or pooled (False)
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pooling_type: Type of pooling ('mean' or 'cls')
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sql: Whether to store embeddings in SQLite database - will be stored in float32
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sql_db_path: Path to SQLite database
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Returns:
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Dictionary mapping sequences to embeddings, or None if sql=True
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Note:
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- If sql=True, embeddings can only be stored in float32
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- sql is ideal if you need to stream a very large dataset for training in real-time
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- save=True is ideal if you can store the entire embedding dictionary in RAM
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- sql will be used if it is True and save is True or False
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- If your sql database or .pth file is already present, they will be scanned first for already embedded sequences
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- Sequences will be truncated to max_len and sorted by length in descending order for faster processing
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```
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## Fine-tuning with 🤗 peft
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```python
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model = AutoModelForSequenceClassification.from_pretrained('Synthyra/Profluent-E1-150M', num_labels=2, trust_remote_code=True)
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# these modules handle E1 attention layers
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target_modules = ["q_proj", "k_proj", "v_proj", "o_proj"]
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lora_config = LoraConfig(
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r=8, # choose lora parameters to your liking
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lora_alpha=16,
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lora_dropout=0.01,
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bias="none",
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target_modules=target_modules,
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)
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# Apply LoRA to the model
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model = get_peft_model(model, lora_config)
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# Unfreeze the classifier head
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for param in model.classifier.parameters():
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param.requires_grad = True
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```
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For a more thourough example of fine-tuning, check out our example script [here](https://github.com/Synthyra/FastPLMs/blob/main/fine_tuning_example.py).
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### Citation
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If you use any of this implementation or work please cite the following DOI and Profluent's paper.
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```
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@misc {FastPLMs,
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author = { Hallee, Logan and Bichara, David and Gleghorn, Jason P.},
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title = { FastPLMs: Fast, efficient, protien language model inference from Huggingface AutoModel.},
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year = {2024},
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url = { https://huggingface.co/Synthyra/ESMplusplus_small },
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DOI = { 10.57967/hf/3726 },
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publisher = { Hugging Face }
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}
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```
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```
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@article{Jain_Beazer_Ruffolo_Bhatnagar_Madani_2025,
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title={E1: Retrieval-Augmented Protein Encoder Models},
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url={https://www.biorxiv.org/content/early/2025/11/13/2025.11.12.688125},
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DOI={10.1101/2025.11.12.688125},
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journal={bioRxiv},
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publisher={Cold Spring Harbor Laboratory},
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author={Jain, Sarthak and Beazer, Joel and Ruffolo, Jeffrey A and Bhatnagar, Aadyot and Madani, Ali},
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year={2025}
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}
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``` |
