Unfolded to Folded: Unraveling the Secrets of Protein Folding with ProteusFold

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Abstract

Protein folding has long been regarded as the “holy grail” of biology, typically demanding large models and massive GPU clusters. This study introduces Pro-teusFold, a compact and interpretable model with only 993,408 parameters that achieves state-of-the-art accuracy on modest hardware with an inference time of 0.0011 seconds. By framing folding as an unfolded-to-folded sequence transformation using a novel structural tokenization, ProteusFold reduces regression complexity while preserving bond connectivity through the concept of “Synapses.” It achieves near-atomic fidelity (RMSD 0.24,Å, GDT-TS 99.85) and excels in protein–protein docking with a mean DockQ of 0.7675, with 95.5% of complexes above the 0.23 threshold. Compared to AlphaFold2’s Predicted Aligned Error (6.28), ProteusFold attains 0.396, representing an order-of-magnitude gain in positional accuracy. Beyond accuracy and efficiency, the model provides residue-level attribution analyses that highlight biologically significant residues, serving as a preliminary guide for experiments. Furthermore, ProteusFold is the first to provide atomic-level attribution of key electronic and thermal properties, offering deeper insight into folding mechanisms and pinpointing the specific atoms responsible for distinct scenarios. Moreover, a meta-analysis suggests the presence of folding hotspots , where critical residues cluster, revealing new avenues for discovery. Thus, ProteusFold delivers accuracy, interpretability, and efficiency, broadening access to protein-folding research.

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last seen: 2026-05-20T01:45:00.602351+00:00