Datasets:

HarriziSaad
/

IDP-Pathogenicity-Model

Languages:

English

Tags:

mitochondrial-variants

pathogenicity-prediction

protein-language-model

ESM-2

machine-learning

bioinformatics

License:

Dataset card Files Files and versions

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IDP-Pathogenicity-Model

File size: 7,067 Bytes

f07511a

# -*- coding: utf-8 -*-
"""Untitled17.ipynb

Automatically generated by Colab.

Original file is located at
    https://colab.research.google.com/drive/1GwdSjrwh3f6QCzOa8KHr_XkWy0KmZvdV
"""

import pandas as pd
import numpy as np
from pathlib import Path
from sklearn.preprocessing import StandardScaler
from sklearn.metrics import roc_auc_score, average_precision_score, roc_curve, precision_recall_curve
from sklearn.linear_model import LogisticRegression
import matplotlib.pyplot as plt
from tqdm import tqdm
import pickle
import torch
import torch.nn as nn
import warnings
warnings.filterwarnings('ignore')


PATHS = {
    'features': BASE_PATH / 'features',
    'embeddings': BASE_PATH / 'embeddings',
    'models': BASE_PATH / 'models',
    'results': BASE_PATH / 'results',
    'figures': BASE_PATH / 'results' / 'figures',
}

df_features = pd.read_parquet(PATHS['features'] / 'features_classical_full.parquet')

id_cols = ['mutation_idx', 'uniprot_acc', 'gene_symbol', 'position', 'wt_aa', 'mut_aa', 'label']
feature_cols = [c for c in df_features.columns if c not in id_cols]

X_features = df_features[feature_cols].values.astype(np.float32)
X_features = np.nan_to_num(X_features, nan=0.0, posinf=0.0, neginf=0.0)
y = df_features['label'].values
proteins = df_features['uniprot_acc'].values

X_emb_combined = np.load(PATHS['embeddings'] / 'embeddings_combined_full.npy').astype(np.float32)
X_emb_local = np.load(PATHS['embeddings'] / 'embeddings_local_full.npy').astype(np.float32)

print(f"    {X_features.shape}")
print(f"    {X_emb_combined.shape}")



from sklearn.decomposition import PCA

pca_combined = PCA(n_components=128, random_state=42)
X_emb_pca = pca_combined.fit_transform(X_emb_combined).astype(np.float32)

pca_local = PCA(n_components=64, random_state=42)
X_emb_local_pca = pca_local.fit_transform(X_emb_local).astype(np.float32)



configs = [
    {'name': 'Features classiques', 'X': X_features},
    {'name': 'Embeddings ESM-2', 'X': X_emb_pca},
    {'name': 'Features + Embeddings', 'X': np.concatenate([X_features, X_emb_pca], axis=1)},
    {'name': 'Features + Emb. Local', 'X': np.concatenate([X_features, X_emb_local_pca], axis=1)},
]

class SimpleMLP(nn.Module):
    def __init__(self, input_dim, hidden_dim=256):
        super().__init__()
        self.net = nn.Sequential(
            nn.Linear(input_dim, hidden_dim),
            nn.ReLU(),
            nn.Dropout(0.3),
            nn.Linear(hidden_dim, hidden_dim // 2),
            nn.ReLU(),
            nn.Dropout(0.2),
            nn.Linear(hidden_dim // 2, 1),
            nn.Sigmoid()
        )

    def forward(self, x):
        return self.net(x).squeeze()

def train_mlp(X_train, y_train, X_test, input_dim, device, epochs=50, lr=0.001):

    model = SimpleMLP(input_dim).to(device)
    optimizer = torch.optim.Adam(model.parameters(), lr=lr, weight_decay=1e-4)
    criterion = nn.BCELoss()

    X_train_t = torch.FloatTensor(X_train).to(device)
    y_train_t = torch.FloatTensor(y_train).to(device)
    X_test_t = torch.FloatTensor(X_test).to(device)

    model.train()
    batch_size = 512

    for epoch in range(epochs):
        perm = torch.randperm(len(X_train_t))

        for i in range(0, len(X_train_t), batch_size):
            idx = perm[i:i+batch_size]

            optimizer.zero_grad()
            outputs = model(X_train_t[idx])
            loss = criterion(outputs, y_train_t[idx])
            loss.backward()
            optimizer.step()

    model.eval()
    with torch.no_grad():
        y_pred = model(X_test_t).cpu().numpy()

    return y_pred

def evaluate_lpocv_gpu(X, y, proteins, device, epochs=30):

    unique_proteins = np.unique(proteins)
    results = []

    scaler = StandardScaler()
    X_scaled = scaler.fit_transform(X)

    for protein in tqdm(unique_proteins, desc="LPOCV GPU"):
        test_mask = proteins == protein
        train_mask = ~test_mask

        if test_mask.sum() < 2:
            continue

        X_train, y_train = X_scaled[train_mask], y[train_mask]
        X_test, y_test = X_scaled[test_mask], y[test_mask]

        y_pred = train_mlp(X_train, y_train, X_test, X.shape[1], device, epochs=epochs)

        for pred, true in zip(y_pred, y_test):
            results.append({'y_true': true, 'y_pred': float(pred)})

    df_res = pd.DataFrame(results)

    if len(df_res) > 0 and len(df_res['y_true'].unique()) > 1:
        auc_roc = roc_auc_score(df_res['y_true'], df_res['y_pred'])
        auc_pr = average_precision_score(df_res['y_true'], df_res['y_pred'])
    else:
        auc_roc, auc_pr = 0, 0

    return auc_roc, auc_pr, df_res

results_all = {}

for cfg in configs:
    print(f"\n   📊 {cfg['name']}...")

    auc_roc, auc_pr, df_res = evaluate_lpocv_gpu(
        cfg['X'], y, proteins, device, epochs=30
    )

    results_all[cfg['name']] = {
        'auc_roc': auc_roc,
        'auc_pr': auc_pr,
        'predictions': df_res,
        'n_features': cfg['X'].shape[1],
    }

    print(f"      AUC-ROC: {auc_roc:.4f}")
    print(f"      AUC-PR:  {auc_pr:.4f}")


def evaluate_lpocv_logreg(X, y, proteins):

    unique_proteins = np.unique(proteins)
    results = []

    scaler = StandardScaler()
    X_scaled = scaler.fit_transform(X)

    for protein in tqdm(unique_proteins, desc="LPOCV LogReg", leave=False):
        test_mask = proteins == protein
        train_mask = ~test_mask

        if test_mask.sum() < 2:
            continue

        X_train, y_train = X_scaled[train_mask], y[train_mask]
        X_test, y_test = X_scaled[test_mask], y[test_mask]

        model = LogisticRegression(max_iter=500, C=0.1, random_state=42)
        model.fit(X_train, y_train)
        y_pred = model.predict_proba(X_test)[:, 1]

        for pred, true in zip(y_pred, y_test):
            results.append({'y_true': true, 'y_pred': pred})

    df_res = pd.DataFrame(results)

    if len(df_res) > 0:
        auc_roc = roc_auc_score(df_res['y_true'], df_res['y_pred'])
        auc_pr = average_precision_score(df_res['y_true'], df_res['y_pred'])
    else:
        auc_roc, auc_pr = 0, 0

    return auc_roc, auc_pr

for cfg in configs:
    auc_roc, auc_pr = evaluate_lpocv_logreg(cfg['X'], y, proteins)
    results_all[cfg['name']]['auc_roc_logreg'] = auc_roc
    results_all[cfg['name']]['auc_pr_logreg'] = auc_pr
    print(f"   {cfg['name']}: LogReg AUC-ROC = {auc_roc:.4f}")


comparison_data = []
for name, res in results_all.items():
    comparison_data.append({
        'Configuration': name,
        'Features': res['n_features'],
        'AUC-ROC (MLP)': res['auc_roc'],
        'AUC-PR (MLP)': res['auc_pr'],
        'AUC-ROC (LogReg)': res.get('auc_roc_logreg', 0),
    })

df_comparison = pd.DataFrame(comparison_data)
df_comparison = df_comparison.sort_values('AUC-ROC (MLP)', ascending=False)

print("\n" + df_comparison.to_string(index=False))

best_name = df_comparison.iloc[0]['Configuration']
best_auc = df_comparison.iloc[0]['AUC-ROC (MLP)']
print(f"\n   🏆 Meilleur: {best_name} (AUC-ROC = {best_auc:.4f})")

df_comparison.to_csv(PATHS['results'] / 'comparison_final.csv', index=False)