KEMP-PIP: A Feature-Fusion Based Approach for Pro-inflammatory Peptide Prediction
This work addresses the challenge of costly experimental identification of PIPs for researchers in immunology and bioinformatics, though it is incremental as it builds on existing feature-fusion approaches.
The paper tackled the problem of identifying pro-inflammatory peptides (PIPs) by developing KEMP-PIP, a hybrid machine learning framework that integrates deep protein embeddings with handcrafted descriptors, achieving an MCC of 0.505, accuracy of 0.752, and AUC of 0.762 on a standard benchmark dataset, outperforming existing methods with improvements of up to 9.5% in MCC.
Pro-inflammatory peptides (PIPs) play critical roles in immune signaling and inflammation but are difficult to identify experimentally due to costly and time-consuming assays. To address this challenge, we present KEMP-PIP, a hybrid machine learning framework that integrates deep protein embeddings with handcrafted descriptors for robust PIP prediction. Our approach combines contextual embeddings from pretrained ESM protein language models with multi-scale k-mer frequencies, physicochemical descriptors, and modlAMP sequence features. Feature pruning and class-weighted logistic regression manage high dimensionality and class imbalance, while ensemble averaging with an optimized decision threshold enhances the sensitivity--specificity balance. Through systematic ablation studies, we demonstrate that integrating complementary feature sets consistently improves predictive performance. On the standard benchmark dataset, KEMP-PIP achieves an MCC of 0.505, accuracy of 0.752, and AUC of 0.762, outperforming ProIn-fuse, MultiFeatVotPIP, and StackPIP. Relative to StackPIP, these results represent improvements of 9.5% in MCC and 4.8% in both accuracy and AUC. The KEMP-PIP web server is freely available at https://nilsparrow1920-kemp-pip.hf.space/ and the full implementation at https://github.com/S18-Niloy/KEMP-PIP.