mAbs (Dec 2022)

In silico proof of principle of machine learning-based antibody design at unconstrained scale

  • Rahmad Akbar,
  • Philippe A. Robert,
  • Cédric R. Weber,
  • Michael Widrich,
  • Robert Frank,
  • Milena Pavlović,
  • Lonneke Scheffer,
  • Maria Chernigovskaya,
  • Igor Snapkov,
  • Andrei Slabodkin,
  • Brij Bhushan Mehta,
  • Enkelejda Miho,
  • Fridtjof Lund-Johansen,
  • Jan Terje Andersen,
  • Sepp Hochreiter,
  • Ingrid Hobæk Haff,
  • Günter Klambauer,
  • Geir Kjetil Sandve,
  • Victor Greiff

DOI
https://doi.org/10.1080/19420862.2022.2031482
Journal volume & issue
Vol. 14, no. 1

Abstract

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Generative machine learning (ML) has been postulated to become a major driver in the computational design of antigen-specific monoclonal antibodies (mAb). However, efforts to confirm this hypothesis have been hindered by the infeasibility of testing arbitrarily large numbers of antibody sequences for their most critical design parameters: paratope, epitope, affinity, and developability. To address this challenge, we leveraged a lattice-based antibody-antigen binding simulation framework, which incorporates a wide range of physiological antibody-binding parameters. The simulation framework enables the computation of synthetic antibody-antigen 3D-structures, and it functions as an oracle for unrestricted prospective evaluation and benchmarking of antibody design parameters of ML-generated antibody sequences. We found that a deep generative model, trained exclusively on antibody sequence (one dimensional: 1D) data can be used to design conformational (three dimensional: 3D) epitope-specific antibodies, matching, or exceeding the training dataset in affinity and developability parameter value variety. Furthermore, we established a lower threshold of sequence diversity necessary for high-accuracy generative antibody ML and demonstrated that this lower threshold also holds on experimental real-world data. Finally, we show that transfer learning enables the generation of high-affinity antibody sequences from low-N training data. Our work establishes a priori feasibility and the theoretical foundation of high-throughput ML-based mAb design.

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