English

A decoupled alignment kernel for peptide membrane permeability predictions

Machine Learning 2025-11-27 v1

Abstract

Cyclic peptides are promising modalities for targeting intracellular sites; however, cell-membrane permeability remains a key bottleneck, exacerbated by limited public data and the need for well-calibrated uncertainty. Instead of relying on data-eager complex deep learning architecture, we propose a monomer-aware decoupled global alignment kernel (MD-GAK), which couples chemically meaningful residue-residue similarity with sequence alignment while decoupling local matches from gap penalties. MD-GAK is a relatively simple kernel. To further demonstrate the robustness of our framework, we also introduce a variant, PMD-GAK, which incorporates a triangular positional prior. As we will show in the experimental section, PMD-GAK can offer additional advantages over MD-GAK, particularly in reducing calibration errors. Since our focus is on uncertainty estimation, we use Gaussian Processes as the predictive model, as both MD-GAK and PMD-GAK can be directly applied within this framework. We demonstrate the effectiveness of our methods through an extensive set of experiments, comparing our fully reproducible approach against state-of-the-art models, and show that it outperforms them across all metrics.

Keywords

Cite

@article{arxiv.2511.21566,
  title  = {A decoupled alignment kernel for peptide membrane permeability predictions},
  author = {Ali Amirahmadi and Gökçe Geylan and Leonardo De Maria and Farzaneh Etminani and Mattias Ohlsson and Alessandro Tibo},
  journal= {arXiv preprint arXiv:2511.21566},
  year   = {2025}
}

Comments

submitted to Journal of Cheminformatics

R2 v1 2026-07-01T07:56:33.600Z