MAHLER: Integrating Metadynamics and Inverse Folding to Predict Antibody-Antigen Kinetics

Date:

June 12, 2026

2026

Type:

Preprint

Publication:

bioRxiv

Author(s):

Mary Pitman, Punit K. Jha, Amogh Sood, Dominic Rufa, Kevin Ryczko, Andrea Bortolato, Da Teng, Pratyush Tiwary

Abstract

Binding kinetics are crucial for antibody function, shaping pharmacokinetics and in vivo efficacy beyond what equilibrium affinity captures. We present “Metadynamics-Anchored Hybrid Learning for Engineering off-Rates (MAHLER)”, a fully open-source machine learning/physics hybrid method that predicts relative antibody-antigen residence times at scale. Incorporating inverse-folding models into molecular dynamics simulations, MAHLER shows first-in-class screening-grade accuracy in calculating relative antibody-antigen dissociation kinetics across a family of point mutants. After initial antigen-specific setup, each prediction takes only 4 minutes on a single NVIDIA A100 GPU, compared to days even with already enhanced molecular dynamics simulations. This provides practical kinetics-aware complement to current computational design approaches that focus primarily on binding affinity for antibody-antigen complexes.

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