Skip to yearly menu bar Skip to main content


Poster

Multi-Scale Representation Learning for Protein Fitness Prediction

Zuobai Zhang · Pascal Notin · Yining Huang · Aurelie Lozano · Vijil Chenthamarakshan · Debora Marks · Payel Das · Jian Tang

[ ]
Wed 11 Dec 4:30 p.m. PST — 7:30 p.m. PST

Abstract:

Designing novel functional proteins crucially depends on accurately modeling their fitness landscape. Given the limited availability of functional annotations from wet-lab experiments, previous methods have primarily relied on self-supervised models trained on vast, unlabeled protein sequence or structure datasets. While initial protein representation learning studies solely focused on either sequence or structural features, recent hybrid architectures have sought to merge these modalities to harness their respective strengths. However, these sequence-structure models have so far achieved only incremental improvements when compared to the leading sequence-only approaches, highlighting unresolved challenges in effectively leveraging these modalities together. Moreover, the function of certain proteins is highly dependent on the granular aspects of their surface topology, which have been overlooked by prior models.To address these limitations, we introduce the Sequence-Structure-Surface Fitness (S3F) model — a novel multimodal representation learning framework that integrates protein features across several scales. Our approach combines sequence representations from a protein language model with Geometric Vector Perceptron networks encoding protein backbone and detailed surface topology. The proposed method achieves state-of-the-art fitness prediction on the ProteinGym benchmark encompassing 217 substitution deep mutational scanning assays, and provides insights into the determinants of protein function.Code will be released upon acceptance.

Live content is unavailable. Log in and register to view live content