--- license: mit language: - en library_name: transformers tags: - ems - esm2 - biology - protein - protein language model - cafa 5 - protein function prediction --- # ESM-2 for Protein Function Prediction This model is not intended for protein function prediction, but rather as a checkpoint for further fine-tuning, especially with Low Rank Adaptation (LoRA). This is an experimental model fine-tuned from the [esm2_t6_8M_UR50D](https://huggingface.co/facebook/esm2_t6_8M_UR50D) model for multi-label classification. In particular, the model is fine-tuned on the CAFA-5 protein sequence dataset available [here](https://huggingface.co/datasets/AmelieSchreiber/cafa_5). More precisely, the `train_sequences.fasta` file is the list of protein sequences that were trained on, and the `train_terms.tsv` file contains the gene ontology protein function labels for each protein sequence. For more details on using ESM-2 models for multi-label sequence classification, [see here](https://huggingface.co/docs/transformers/model_doc/esm). Due to the potentially complicated class weighting necessary for the hierarchical ontology, further fine-tuning will be necessary. ## Fine-Tuning The model was fine-tuned for 7 epochs at a learning rate of `5e-5`, and achieves the following metrics: ``` Validation Loss: 0.0027, Validation Micro F1: 0.3672, Validation Macro F1: 0.9967, Validation Micro Precision: 0.6052, Validation Macro Precision: 0.9996, Validation Micro Recall: 0.2626, Validation Macro Recall: 0.9966 ``` ## Using the model First, downlowd the file `go-basic.obo` [from here](https://huggingface.co/datasets/AmelieSchreiber/cafa_5) and store the file locally, then provide the local path in the the code below: ```python import torch from transformers import AutoTokenizer, EsmForSequenceClassification from sklearn.metrics import precision_recall_fscore_support # 1. Parsing the go-basic.obo file def parse_obo_file(file_path): with open(file_path, 'r') as f: data = f.read().split("[Term]") terms = [] for entry in data[1:]: lines = entry.strip().split("\n") term = {} for line in lines: if line.startswith("id:"): term["id"] = line.split("id:")[1].strip() elif line.startswith("name:"): term["name"] = line.split("name:")[1].strip() elif line.startswith("namespace:"): term["namespace"] = line.split("namespace:")[1].strip() elif line.startswith("def:"): term["definition"] = line.split("def:")[1].split('"')[1] terms.append(term) return terms parsed_terms = parse_obo_file("go-basic.obo") # Replace `go-basic.obo` with your path # 2. Load the saved model and tokenizer model_path = "AmelieSchreiber/cafa_5_protein_function_prediction" loaded_model = EsmForSequenceClassification.from_pretrained(model_path) loaded_tokenizer = AutoTokenizer.from_pretrained(model_path) # 3. The predict_protein_function function def predict_protein_function(sequence, model, tokenizer, go_terms): inputs = tokenizer(sequence, return_tensors="pt", padding=True, truncation=True, max_length=1022) model.eval() with torch.no_grad(): outputs = model(**inputs) predictions = torch.sigmoid(outputs.logits) predicted_indices = torch.where(predictions > 0.05)[1].tolist() functions = [] for idx in predicted_indices: term_id = unique_terms[idx] # Use the unique_terms list from your training script for term in go_terms: if term["id"] == term_id: functions.append(term["name"]) break return functions # 4. Predicting protein function for an example sequence example_sequence = "MAYLGSLVQRRLELASGDRLEASLGVGSELDVRGDRVKAVGSLDLEEGRLEQAGVSMA" # Replace with your protein sequence predicted_functions = predict_protein_function(example_sequence, loaded_model, loaded_tokenizer, parsed_terms) print(predicted_functions) ```