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Bibliographic Details
Main Author: Vila, Jorge
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.10115
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author Vila, Jorge
author_facet Vila, Jorge
contents One of the most puzzling and unsolved challenges in molecular biology is understanding how proteins fold. Despite having advanced predictive tools that can accurately estimate the native structures of proteins, we still lack a comprehensive model that explains how amino acid sequences dictate folding pathways and trajectories. This manuscript takes a fresh approach to this problem by resorting to the principle of least action. This approach enables us to explore an intriguing question: how does a protein achieve its native state at a constant folding rate and within a time frame that is biologically plausible? A response to this inquiry will help us understand why proteins must fold along specific pathways and identify the boundary conditions that restrict their availability. It will also clarify why different folding pathways could be characterized by a common effective folding trajectory. Finally, it will provide a clear explanation for Levinthal's paradox. Our results are expected to pave the way for a more profound understanding of how proteins fold, shedding light on how the amino acid sequence and its surrounding environment encode the protein's folding pathways and, consequently, the protein's three-dimensional structure.
format Preprint
id arxiv_https___arxiv_org_abs_2512_10115
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Decoding How Proteins Fold
Vila, Jorge
Biomolecules
One of the most puzzling and unsolved challenges in molecular biology is understanding how proteins fold. Despite having advanced predictive tools that can accurately estimate the native structures of proteins, we still lack a comprehensive model that explains how amino acid sequences dictate folding pathways and trajectories. This manuscript takes a fresh approach to this problem by resorting to the principle of least action. This approach enables us to explore an intriguing question: how does a protein achieve its native state at a constant folding rate and within a time frame that is biologically plausible? A response to this inquiry will help us understand why proteins must fold along specific pathways and identify the boundary conditions that restrict their availability. It will also clarify why different folding pathways could be characterized by a common effective folding trajectory. Finally, it will provide a clear explanation for Levinthal's paradox. Our results are expected to pave the way for a more profound understanding of how proteins fold, shedding light on how the amino acid sequence and its surrounding environment encode the protein's folding pathways and, consequently, the protein's three-dimensional structure.
title Decoding How Proteins Fold
topic Biomolecules
url https://arxiv.org/abs/2512.10115