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Germline-aware deep learning models and benchmarks for predicting antibody VH-VL pairing.


ABSTRACT: Variable heavy (VH) and variable light (VL) chain pairing is a critical determinant of antibody diversity, stability, and antigen-binding specificity. Identifying productive VH - VL combinations experimentally is labor-intensive and costly, motivating the development of computational methods that can more efficiently predict compatible heavy - light chain pairs. In this work, we present a comprehensive framework that includes a new benchmark dataset and three deep learning models, each trained with a different negative sampling strategy: random pairing, V-gene mismatching, and full V(D)J germline mismatching. Our dataset includes natural pairs and these three types of synthetic negatives to simulate increasingly realistic biological constraints. Furthermore, we present a lightweight yet highly effective BERT-based model that achieves over 90% accuracy in discriminating natural from synthetic VH - VL pairs. Through extensive evaluation, we demonstrate that V(D)J-informed negative sampling significantly improves model generalization and biological interpretability. By providing reproducible baselines and a biologically grounded benchmark, this work lays the foundation for future development of efficient computational tools in antibody engineering.

SUBMITTER: Joubbi S 

PROVIDER: S-EPMC12536629 | biostudies-literature | 2025 Dec

REPOSITORIES: biostudies-literature

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Germline-aware deep learning models and benchmarks for predicting antibody VH-VL pairing.

Joubbi Sara S   D'Arco Enrico E   Maccari Giuseppe G   Milazzo Paolo P   Micheli Alessio A  

mAbs 20251017 1


Variable heavy (VH) and variable light (VL) chain pairing is a critical determinant of antibody diversity, stability, and antigen-binding specificity. Identifying productive VH - VL combinations experimentally is labor-intensive and costly, motivating the development of computational methods that can more efficiently predict compatible heavy - light chain pairs. In this work, we present a comprehensive framework that includes a new benchmark dataset and three deep learning models, each trained w  ...[more]

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