English

Biologically-Grounded Multi-Encoder Architectures as Developability Oracles for Antibody Design

Biomolecules 2026-04-13 v1 Machine Learning Quantitative Methods

Abstract

Generative models can now propose thousands of \emph{de novo} antibody sequences, yet translating these designs into viable therapeutics remains constrained by the cost of biophysical characterization. Here we present CrossAbSense, a framework of property-specific neural oracles that combine frozen protein language model encoders with configurable attention decoders, identified through a systematic hyperparameter campaign totaling over 200 runs per property. On the GDPa1 benchmark of 242 therapeutic IgGs, our oracles achieve notable improvements of 12--20\% over established baselines on three of five developability assays and competitive performance on the remaining two. The central finding is that optimal decoder architectures \emph{invert} our initial biological hypotheses: self-attention alone suffices for aggregation-related properties (hydrophobic interaction chromatography, polyreactivity), where the relevant sequence signatures -- such as CDR-H3 hydrophobic patches -- are already fully resolved within single-chain embeddings by the high-capacity 6B encoder. Bidirectional cross-attention, by contrast, is required for expression yield and thermal stability -- properties that inherently depend on the compatibility between heavy and light chains. Learned chain fusion weights independently confirm heavy-chain dominance in aggregation (wH=0.62w_H = 0.62) versus balanced contributions for stability (wH=0.51w_H = 0.51). We demonstrate practical utility by deploying CrossAbSense on 100 IgLM-generated antibody designs, illustrating a path toward substantial reduction in experimental screening costs.

Keywords

Cite

@article{arxiv.2604.09369,
  title  = {Biologically-Grounded Multi-Encoder Architectures as Developability Oracles for Antibody Design},
  author = {Simon J. Crouzet},
  journal= {arXiv preprint arXiv:2604.09369},
  year   = {2026}
}

Comments

ICLR 2026 Workshop on Generative and Experimental Perspectives for Biomolecular Design

R2 v1 2026-07-01T12:02:59.602Z