Protein Structure and Dynamics
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A new deep generative method is described, Rosetta Fold diffusion 2 (RFdiffusion2), enabling enzymes to be designed from sequence agnostic descriptions of functional group locations without inverse rotamer generation and demonstrates the potential of atomic resolution generative models for the design of de novo enzymes directly from their reaction mechanisms.
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Designing new enzymes typically begins with idealized arrangements of catalytic functional groups around a reaction transition state, then attempts to generate protein structures that precisely position these groups. Current AI-based methods can create active enzymes but require predefined residue positions and rely on reverse-building residue backbones from side-chain placements, which limits design flexibility. Here we show that a new deep generative model, RoseTTAFold diffusion 2 (RFdiffusion2), overcomes these constraints by designing enzymes directly from functional group geometries without specifying residue order or performing inverse rotamer generation. RFdiffusion2 successfully generates scaffolds for all 41 active sites in a diverse benchmark, compared to 16 using previous methods. We further design enzymes for three distinct catalytic mechanisms and identify active candidates after experimentally testing fewer than 96 sequences in each case. These results highlight the potential of atomic-level generative modeling to create de novo enzymes directly from reaction mechanisms.
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@article{Ahern2025Atom,
title = {Atom-level enzyme active site scaffolding using RFdiffusion2},
author = {Woody Ahern and Jason Yim and Doug Tischer and Saman Salike and Seth M. Woodbury and Donghyo Kim and Indrek Kalvet and Yakov Kipnis and Brian Coventry and Han Altae-Tran and Magnus S. Bauer and Regina Barzilay and Tommi Jaakkola and Rohith Krishna and David Baker},
journal = {Nature Methods},
year = {2025},
doi = {10.1038/s41592-025-02975-x},
url = {https://doi.org/10.1038/s41592-025-02975-x}
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