English

Scalable Normalizing Flows Enable Boltzmann Generators for Macromolecules

Machine Learning 2024-01-10 v1 Biomolecules

Abstract

The Boltzmann distribution of a protein provides a roadmap to all of its functional states. Normalizing flows are a promising tool for modeling this distribution, but current methods are intractable for typical pharmacological targets; they become computationally intractable due to the size of the system, heterogeneity of intra-molecular potential energy, and long-range interactions. To remedy these issues, we present a novel flow architecture that utilizes split channels and gated attention to efficiently learn the conformational distribution of proteins defined by internal coordinates. We show that by utilizing a 2-Wasserstein loss, one can smooth the transition from maximum likelihood training to energy-based training, enabling the training of Boltzmann Generators for macromolecules. We evaluate our model and training strategy on villin headpiece HP35(nle-nle), a 35-residue subdomain, and protein G, a 56-residue protein. We demonstrate that standard architectures and training strategies, such as maximum likelihood alone, fail while our novel architecture and multi-stage training strategy are able to model the conformational distributions of protein G and HP35.

Keywords

Cite

@article{arxiv.2401.04246,
  title  = {Scalable Normalizing Flows Enable Boltzmann Generators for Macromolecules},
  author = {Joseph C. Kim and David Bloore and Karan Kapoor and Jun Feng and Ming-Hong Hao and Mengdi Wang},
  journal= {arXiv preprint arXiv:2401.04246},
  year   = {2024}
}
R2 v1 2026-06-28T14:11:48.589Z